The effects of millimeter (40 GHz) and centimeter (8.15-18.00 GHz)
low-intensity waves on the production of tumor necrosis factor (TNE) in
macrophages and lymphocytes from exposed mice as well as in exposed
isolated cells were compared. It was found that the dynamics of TNF
secretory activity of cells varies depending on the frequency and
duration of exposure. The application of millimeter waves induced a
nonmonotonous course of the dose-effect curve for TNF changes in
macrophages and splenocytes. Alternately, a stimulation and a decrease
in TNF production were observed following the application of millimeter
waves. On the contrary, centimeter waves provoked an activation in
cytokine production. It is proposed that, in contrast to millimeter
waves, the single application of centimeter waves to animals (within 2
to 96 h) or isolated cells (within 0.5 to 2.5 h) induced a much more
substantial stimulation of immunity.
Biofizika. 2002 Mar-Apr;47(2):376-81.
Immunomodulating effect of electromagnetic waves on production of
tumor necrosis factor in mice with various rates of neoplasm growth.
Institute of Cell Biophysics, Russian Academy of Sciences, Pushchino, Moscow Region, 142290 Russia.
Abstract
The effects of low-density centimeter waves (8.15-18 GHz, 1
microW/cm2, 1 h daily for 14 days; MW) on tumor necrosis factor
production in macrophages of mice with different growth rate of a cancer
solid model produced after hypodermic injection of Ehrlich carcinoma
ascites cells into hind legs were studied. After irradiation, an
increase in the concentration of tumor necrosis factor in
immunocompetent cells of healthy and, specially, of tumor-bearing
animals was observed; and the effect of stimulation was higher upon
exposure of mice carrying rapidly growing tumors. We suggest that the
significant immunomodulating effect of low-density microwaves can be
utilized for tumor growth suppression.
Biofizika. 2001 Jan-Feb;46(1):131-5.
Effect of centimeter microwaves and the combined magnetic field on
the tumor necrosis factor production in cells of mice with experimental
tumors.
Institute of Cell Biophysics, Russian Academy of Sciences, Pushchino, Moscow Region, 142290 Russia.
Abstract
The effect of fractionated exposure to low-intensity microwaves
(8.15-18 GHz, 1 microW/cm2, 1.5 h daily for 7 days) and combined weak
magnetic field (constant 65 1 microT; alternating–100 nT, 3-10 Hz) on
the production of tumor necrosis factor in macrophages of mice with
experimental solid tumors produced by transplantation of Ehrlich ascites
carcinoma was studied. It was found that exposure of mice to both
microwaves and magnetic field enhanced the adaptive response of the
organism to the onset of tumor growth: the production of tumor necrosis
factor in peritoneal macrophages of tumor-bearing mice was higher than
in unexposed mice.
Effect of magnetic and ultrasound therapy on clinical manifestations
and general parameters of efficiency in the treatment of pulmonary
tuberculosis.
[Article in Ukrainian]
Savchenko VI, Samosiuk IZ.
The authors have analized general efficiency coefficients of the
treatment of 117 patients with the first diagnized pulmonary
tuberculosis. The patients were divided into a control and main group.
61 patients of the main group at the initial stage of complex treatment
in addition to a standard chemotherapy have recieved magnetic and
ultrasound therapy. During the treatment the patients underwent complex
clinical and X-ray examination. The patients of the main group have been
detected to have better signs of recovering compared with the control
group. The signs were the following: more rapid disappearing of main
clinical symptoms, radiological marks of tuberculosis such as focal and
infiltrative alterations and decay cavity closing, cessation of
bacterioexcretion.
Probl Tuberk. 2000;(2):18-21.
Magnetic laser therapy in combination with lymphotropic drugs
administration in treating teenagers with common forms of tuberculosis.
The paper shows the efficiency of combined use of magnetic laser
therapy (MLT) and lymphotropic drug therapy in 40 teenagers with common
forms of tuberculosis. The use of laser makes it possible to modify
methods of regional lymphotropic therapy, to prolong its use and
increase indications for it. MLT in combination with lymphotropic drug
therapy accelerates positive changes and hence enhances the efficiency
of tuberculosis treatment.
Probl Tuberk. 2001;(2):11-2.
Very high frequency electromagnetic irradiation in multimodal
treatment of patients with disseminated infiltrative pulmonary
tuberculosis.
[Article in Russian]
Iakovleva LP, Lineva ZE, Mozhokina GN.
Multimodality treatment involving very high-frequency electromagnetic
radiation (VHFER) in combination with the antioxidants alpha-tocopherol
and sodium thiosulfate, which had been performed in 27 patients with
disseminated infiltrative pulmonary tuberculosis, was effective. As
compared to patients receiving chemotherapy in combination with
electromagnetic radiation (n = 29) and routine chemotherapy alone (n =
29), these patients had more benefits from the multimodality treatment
in terms of bacterial isolation cessation and reduced hospital stay by
1.5-2 months, minimal pneumofibrotic changes occurred in 63% of the
patients. Combined VHFER and antioxidative therapy were found to exert a
normalizing effect on lipid peroxidation and immunity.
Probl Tuberk. 1999;(6):30-2.
Impact of combined magnetic and laser radiation of regional
pulmonary blood flow in patients with destructive pulmonary
tuberculosis.
[Article in Russian]
Iakubenia ON, Tostik SI, Iakubenia GI.
Rheopulmonography was used to study regional pulmonary blood flow in
30 patients with destructive pulmonary tuberculosis before and after
combined magnetic and laser radiation (an experimental group) and in 28
patients receiving the routine chemotherapy (a control group). The use
of combined exposure of a constant magnetic field and laser radiation
was found to promote pulmonary vascular tone, better microcirculatory
blood flow, and increased pulse blood filling in the affected portion of
the lung.
Probl Tuberk. 1997;(6):50-3.Links
Use of centimetric range microwave therapy in multimodality of treatment patients with destructive pulmonary tuberculosis.
[Article in Russian]
Savula MM, Kravchenko NS.
Centimeter microwave therapy (CMWT) was employed in the multimodality
treatment of 50 patients with destructive pulmonary tuberculosis. Its
results were compared with a matched control group comprising 43
patients. CMWT increased the rate of decay cavity closure, improved
bronchial patency and prevented its deterioration. This was followed by
improved lipid peroxidation, antioxidative activity, and an
immunological responsiveness of the body.
Probl Tuberk. 1995;(6):17-20.
Significance of the functional state of blood phagocytes in the
choice of optimal regime of EHF therapy of patients with pulmonary
tuberculosis.
[Article in Russian]
Novikova LN, Kaminskaia GO, Efimova LN.
A trial entered 136 patients with active tuberculosis of the lungs.
86 patients received conventional chemotherapy and a course of microwave
therapy. Control patients received chemotherapy alone. Phagocyte cell
viability and NB-test served as assessment laboratory criteria.
Millimetric waves in the treatment of pulmonary tuberculosis potentiate
the treatment efficacy documented as more rapid infiltration resolution
and cavern closure through the mechanism of normalization of phagocyte
cell function. The choice of wave length is principal: 5.6 mm waves
affect phagocyte function negatively, 6.4 mm waves produce more
significant positive effect in young patients with new local lesions
while 7.1 mm waves in older patients and in severe involvement. In vitro
radiation of the patients’ blood using different wave lengths and
subsequent performance of NB-test provides objective information for
choice of optimal treatment regimen.
Probl Tuberk. 1994;(4):2-4.
Effectiveness of chemotherapy combined with ultrahigh-frequency
electromagnetic radiation for the treatment of patients with pulmonary
tuberculosis.
[Article in Russian]
Khomenko AG, Chukanov VI, Novikova LN.
A procedure was developed to determine the optimum wavelength used
for each patient individually. Ultrahigh-frequency electromagnetic
radiation was studied in 54 patients with various pulmonary tuberculosis
forms for its impact on the course of the disease. Treatment was
performed by using a YAVOR device at 6.4 and 7.1 mm. Is was found that
following 10 sessions of UHF therapy used in combination with specific
chemicals, caverns were closed in 50% of patients 2-3 months after
therapy and in the controls 5-6 months later. Infiltrates in the lesion
areas were resolved 2-3 weeks after UHF exposure, whereas in the
controls 1-2 months following drug therapy alone.
Tubal pregnancy: the experience of early rehabilitative treatment.
[Article in Russian]
Strugatskii VM, Strizhakov AN, Shmeleva SV.
The surgical treatment for tubal pregnancy including laparoscopy and
antibacterial therapy were combined in 30 females with early start (on
postoperative day 1) of rehabilitation: psychotherapy, diet, therapeutic
exercise, low-frequency magnetotherapy. Hysterosalpingography and
dynamic dopplerography assessed the effect as good.
The results of treatment of 86 patients with the use of
magnetotherapy in combination with galvanization and intratissue
electrophoresis are presented. To create an electric field, the
“Potok-1” apparatus with a density of current equal to 0.05-0.1 mA/cm2
was employed. Simultaneously, the “MAG-30” apparatus for low-frequency
magnetotherapy with induction of 30 mT and area of exposure of 20 cm2
was applied to a trophic ulcer site. The use of magnetogalvanotherapy in
the complex of treatment of trophic ulcers of the lower extremities is
recommended.
Pol Tyg Lek. 1991 Sep 9-30;46(37-39):717-9.
Use of magnetic field in treatment of trophic leg ulcers.
[Article in Polish]
Sieron A, Zmudzinski J, Cieslar G, Adamek M.
III Katedry i Kliniki Chorob Wewnetrznych Sl. AM w Bytomiu.
Theoretical basis and favourable therapeutical application of
magnetic field in case of trophic ulcerations of the lower limbs are
discussed. As a clinical example of such action a case of a 39-year old
female patient with trophic ulceration of the leg is presented.
Practical advantages of magnetotherapy in similar to the described case
patients are suggested.
Klin Khir. 1991;(7):60-3.
Treatment of trophic ulcers of the lower extremities using a magnetic field.
[Article in Russian]
Alekseenko AV, Gusak VV.
The experience with treatment of 126 patients with ulcerous-necrotic
lesion of the lower extremities of different genesis was summarized. A
comparative evaluation of the effectiveness of treatment depending on a
type of the magnetic field: the constant, alternating, or travelling
impulse one was carried out. The most effective was the use of a
travelling impulse magnetic field. The results of the investigation
performed give grounds to recommend the wide use of magnetotherapy in
the complex treatment of trophic ulcers of the lower extremities
Front Hum Neurosci. 2015 Jun 16;9:303. doi: 10.3389/fnhum.2015.00303. eCollection 2015.
Possible Mechanisms Underlying the Therapeutic Effects of Transcranial Magnetic Stimulation.
Chervyakov AV1, Chernyavsky AY2, Sinitsyn DO3, Piradov MA1.
Author information1Research Center of Neurology , Moscow , Russia.
2Moscow
Institute of Physics and Technology, Russian Academy of Sciences ,
Moscow , Russia ; Faculty of Computational Mathematics and Cybernetics,
Moscow State University , Moscow , Russia.
3Research
Center of Neurology , Moscow , Russia ; Semenov Institute of Chemical
Physics, Russian Academy of Sciences , Moscow , Russia.
Abstract
Transcranial magnetic stimulation
(TMS) is an effective method used to diagnose and treat many
neurological disorders. Although repetitive TMS (rTMS) has been used to
treat a variety of serious pathological conditions including stroke,
depression, Parkinson’s disease, epilepsy, pain, and migraines, the
pathophysiological mechanisms underlying the effects of long-term TMS
remain unclear. In the present review, the effects of rTMS on
neurotransmitters and synaptic plasticity are described, including the
classic interpretations of TMS effects on synaptic plasticity via
long-term potentiation and long-term depression. We also discuss the
effects of rTMS on the genetic apparatus of neurons, glial cells, and
the prevention of neuronal death. The neurotrophic effects of rTMS on
dendritic growth and sprouting and neurotrophic factors are described,
including change in brain-derived neurotrophic factor concentration
under the influence of rTMS. Also, non-classical effects of TMS related
to biophysical effects of magnetic fields are described, including the
quantum effects, the magnetic spin effects, genetic magnetoreception,
the macromolecular effects of TMS, and the electromagnetic theory of
consciousness. Finally, we discuss possible interpretations of TMS
effects according to dynamical systems theory. Evidence suggests that a
rTMS-induced magnetic field should be considered a separate physical
factor that can be impactful at the subatomic level and that rTMS is
capable of significantly altering the reactivity of molecules
(radicals). It is thought that these factors underlie the therapeutic
benefits of therapy with TMS. Future research on these mechanisms will
be instrumental to the development of more powerful and reliable TMS
treatment protocols.
Brain. 2012 Oct 5. [Epub ahead of print]
Magnetic flimmers: ‘light in the electromagnetic darkness’
Martens JW, Koehler PJ, Vijselaar J.
Source
1 Department of Humanities, Utrecht University, Utrecht, The Netherlands.
Abstract
Transcranial magnetic stimulation has become an important field for
both research in neuroscience and for therapy since Barker in 1985
showed that it was possible to stimulate the human motor cortex with an
electromagnet. Today for instance, transcranial magnetic stimulation can
be used to measure nerve conduction velocities and to create virtual
lesions in the brain. The latter option creates the possibility to
inactivate parts of the brain temporarily without permanent damage. In
2008, the American Food and Drugs Administration approved repetitive
transcranial magnetic stimulation as a therapy for major depression
under strict conditions. Repetitive transcranial magnetic stimulation
has not yet been cleared for treatment of other diseases, including
schizophrenia, anxiety disorders, obesity and Parkinson’s disease, but
results seem promising. Transcranial magnetic stimulation, however, was
not invented at the end of the 20th century. The discovery of
electromagnetism, the enthusiasm for electricity and electrotherapy, and
the interest in Beard’s concept of neurasthenia already resulted in the
first electromagnetic treatments in the late 19th and early 20th
century. In this article, we provide a history of electromagnetic
stimulation circa 1900. From the data, we conclude that Mesmer’s late
18th century ideas of ‘animal magnetism’ and the 19th century absence of
physiological proof had a negative influence on the acceptance of this
therapy during the first decades of the 20th century. Electromagnetism
disappeared from neurological textbooks in the early 20th century to
recur at the end of that century.
Stroke. 2005 Oct 27; [Epub ahead of print]
Repetitive Transcranial Magnetic Stimulation of Contralesional Primary Motor Cortex Improves Hand Function After Stroke.
Takeuchi N, Chuma T, Matsuo Y, Watanabe I, Ikoma K.
From the Department of Rehabilitation Medicine, Hokkaido University Graduate School of Medicine, Sapporo 060-0814, Japan.
BACKGROUND AND PURPOSE: A recent report has demonstrated that the
contralesional primary motor cortex (M1) inhibited the ipsilesional M1
via an abnormal transcallosal inhibition (TCI) in stroke patients. We
studied whether a decreased excitability of the contralesional M1
induced by 1 Hz repetitive transcranial magnetic stimulation (rTMS)
caused an improved motor performance of the affected hand in stroke
patients by releasing the TCI.
METHODS: We conducted a double-blind study of real versus sham rTMS
in stroke patients. After patients had well- performed motor training to
minimize the possibility of motor training during the motor
measurement, they were randomly assigned to receive a subthreshold rTMS
at the contralesional M1 (1 Hz, 25 minutes) or sham stimulation.
RESULTS: When compared with sham stimulation, rTMS reduced the
amplitude of motor-evoked potentials in contralesional M1 and the TCI
duration, and rTMS immediately induced an improvement in pinch
acceleration of the affected hand, although a plateau in motor
performance had been reached by the previous motor training. This
improvement in motor function after rTMS was significantly correlated
with a reduced TCI duration.
CONCLUSIONS: We have demonstrated that a disruption of the TCI by the
contralesional M1 virtual lesion caused a paradoxical functional
facilitation of the affected hand in stroke patients; this suggests a
new neurorehabilitative strategy for stroke patients.
Schizophr Bull. 2005 Oct 27; [Epub ahead of print]
Therapeutic Effects of Individualized Alpha Frequency Transcranial
Magnetic Stimulation ({alpha} TMS) on the Negative on the Negative
Symptoms of Schizophrenia.
Jin Y, Potkin SG, Kemp AS, Huerta ST, Alva G, Thai TM, Carreon D, Bunney WE Jr.
Department of Psychiatry and Human Behavior, University of California, Irvine, School of Medicine.
Previous research in clinical electroencephalography (EEG) has
demonstrated that reduction of alpha frequency (8-13 Hz) EEG activity
may have particular relevance to the negative symptoms of schizophrenia.
Repetitive Transcranial Magnetic Stimulation (rTMS) was utilized to
investigate this relationship by assessing the therapeutic effects of
stimulation set individually at each subject’s peak alpha frequency
(alphaTMS). Twenty-seven subjects, with predominantly negative symptom
schizophrenia, received 2 weeks of daily treatment with either alphaTMS,
3 Hz, 20 Hz, or sham stimulation bilaterally over the dorsolateral
prefrontal cortex. Individualized alphaTMS demonstrated a significantly
larger (F 3,33 = 4.7, p = .007) therapeutic effect (29.6% reduction in
negative symptoms) than the other 3 conditions (< 9%). Furthermore,
these clinical improvements were found to be highly correlated (r =
0.86, p = .001) with increases (34%) in frontal alpha amplitude
following alphaTMS. These results affirm that the resonant features of
alpha frequency EEG play an important role in the pathophysiology of
schizophrenia and merit further investigation as a particularly
efficacious frequency for rTMS treatments.
Neuroreport. 2005 Nov 7;16(16):1839-42.
Effects of repetitive transcranial magnetic stimulation in depression: a magnetoencephalographic study.
Maihofner C, Ropohl A, Reulbach U, Hiller M, Elstner S, Kornhuber J, Sperling W.
Departments of aNeurology bPsychiatry and Psychotherapy cInstitute
for Experimental Physiology and Pathophysiology, University of Erlangen –
Nuremberg, Erlangen, Germany.
Recently, repetitive transcranial magnetic stimulation has evolved as
a potential therapeutic tool to interfere with brain changes associated
with neurological and psychiatric diseases. Little is known about its
mode of action, however. Here, we investigated effects of repetitive
transcranial magnetic stimulation on spontaneous magnetoencephalographic
activity in patients with major depression. Before treatment, depressed
patients showed a significant increase in slow magnetoencephalographic
activity (2-6 Hz) over the left prefrontal cortex, compared with healthy
controls. This activity significantly decreased during 10 days of
repetitive transcranial magnetic stimulation, paralleled by clinical
improvement. We conclude that therapeutic repetitive transcranial
magnetic stimulation effects can be mirrored by changes of spontaneous
magnetoencephalographic activity.
Psychiatry Res. 2005 Nov 15;137(1-2):1-10. Epub 2005 Oct 12.
Transcranial magnetic stimulation in treatment-resistant depressed patients: A double-blind, placebo-controlled trial.
Rossini D, Lucca A, Zanardi R, Magri L, Smeraldi E.
Department of Psychiatry, School of Medicine, Vita-Salute University,
San Raffaele Hospital, via Stamira d’Ancona 20, Milan 20127, Italy.
This 5-week, randomized, double-blind, placebo-controlled trial
investigated the efficacy and tolerability of high frequency repetitive
transcranial magnetic stimulation (rTMS) directed to the left prefrontal
cortex in drug-resistant depressed patients. Fifty-four patients were
randomly assigned to receive 10 daily applications of either real or
sham rTMS. Subjects assigned to receive active stimulation were divided
into two further subgroups according to the intensity of stimulation:
80% vs. 100% of motor threshold (MT). At study completion, the response
rates were 61.1% (n=11), 27.8% (n=5) and 6.2% (n=1) for the 100% MT
group, 80% MT group and sham group, respectively. A significant
difference (Pearson chi(2) test) was found between the 100% MT and sham
groups, while the 80% MT group did not differ significantly from the
sham group. Between the two active groups, a marginally significant
difference was observed. Analysis of variance with repeated measures on
Hamilton Depression Rating Scale scores revealed a significantly
different decrease over time of depressive symptomatology among the
three treatment groups. Treatment response appeared to be unrelated to
the demographic and clinical characteristics recorded, and on the whole
the technique was well tolerated. The results of this double-blind trial
showed that rTMS may be a useful and safe adjunctive treatment for
drug-resistant depressed patients.
Neuroreport. 2005 Nov 7;16(16):1849-1852.
Repetitive transcranial magnetic stimulation over the right dorsolateral prefrontal cortex affects strategic decision-making.
Wout MV, Kahn RS, Sanfey AG, Aleman A.
aDepartment of Psychonomics, Helmholtz Research Institute, University
of Utrecht bDepartment of Psychiatry, Rudolf Magnus Institute of
Neuroscience, University Medical Center Utrecht, Utrecht cBCN
NeuroImaging Center, Groningen, The Netherlands dDepartment of
Psychology, University of Arizona, Tucson, Arizona, USA.
Although decision-making is typically seen as a rational process,
emotions play a role in tasks that include unfairness. Recently,
activation in the right dorsolateral prefrontal cortex during offers
experienced as unfair in the Ultimatum Game was suggested to subserve
goal maintenance in this task. This is restricted to correlational
evidence, however, and it remains unclear whether the dorsolateral
prefrontal cortex is crucial for strategic decision-making. The present
study used repetitive transcranial magnetic stimulation in order to
investigate the causal role of the dorsolateral prefrontal cortex in
strategic decision-making in the Ultimatum Game. The results showed that
repetitive transcranial magnetic stimulation over the right
dorsolateral prefrontal cortex resulted in an altered decision-making
strategy compared with sham stimulation. We conclude that the
dorsolateral prefrontal cortex is causally implicated in strategic
decision-making in healthy human study participants.
Psychiatry Res. 2005 Nov 15;137(1-2):113-21. Epub 2005 Oct 11.
Chronic repetitive transcranial magnetic stimulation is
antidepressant but not anxiolytic in rat models of anxiety and
depression.
Hargreaves GA, McGregor IS, Sachdev PS.
School of Psychiatry, University of New South Wales, Sydney, 2052,
Australia; Neuropsychiatric Institute, Prince of Wales Hospital, Barker
Street, Randwick, NSW 2031, Australia.
Transcranial magnetic stimulation (TMS) has been proposed as a
treatment for depression and anxiety disorders. While the antidepressant
effect has been modelled in animals, there have been few attempts to
examine a possible anxiolytic effect of repetitive TMS (rTMS) in animal
models. We administered 18 days of rTMS to male Sprague-Dawley rats. On
days 10 through 18, rats were tested in several anxiety models (social
interaction, emergence, elevated plus-maze, and predator odor avoidance)
and in the forced swim test. No group differences were apparent on any
of the anxiety models, while TMS produced an antidepressant effect in
the forced swim test. Interestingly, on day 1 of the forced swim test,
the home cage control group displayed increased swimming behaviour
compared with sham-treated animals, suggesting an observable level of
stress may have accompanied sham treatment. The results from the forced
swim test suggested that TMS had modest antidepressant properties, but
it did not show anxiolytic properties in the models examined. The study
also suggested that stress associated with handling should be taken into
account in the interpretation of TMS studies in animals.
PLoS Biol. 2005 Oct 18;3(11):e362 [Epub ahead of print]
Improvement of Tactile Discrimination Performance and Enlargement of Cortical Somatosensory Maps after 5 Hz rTMS.
Tegenthoff M, Ragert P, Pleger B, Schwenkreis P, Forster AF, Nicolas V, Dinse HR.
Department of Neurology, Ruhr-University Bochum, BG-Kliniken Bergmannsheil, Bochum, Germany.
Repetitive transcranial magnetic stimulation (rTMS) is increasingly
used to investigate mechanisms of brain functions and plasticity, but
also as a promising new therapeutic tool. The effects of rTMS depend on
the intensity and frequency of stimulation and consist of changes of
cortical excitability, which often persists several minutes after
termination of rTMS. While these findings imply that cortical processing
can be altered by applying current pulses from outside the brain,
little is known about how rTMS persistently affects learning and
perception. Here we demonstrate in humans, through a combination of
psychophysical assessment of two-point discrimination thresholds and
functional magnetic resonance imaging (fMRI), that brief periods of 5 Hz
rTMS evoke lasting perceptual and cortical changes. rTMS was applied
over the cortical representation of the right index finger of primary
somatosensory cortex, resulting in a lowering of discrimination
thresholds of the right index finger. fMRI revealed an enlargement of
the right index finger representation in primary somatosensory cortex
that was linearly correlated with the individual rTMS-induced perceptual
improvement indicative of a close link between cortical and perceptual
changes. The results demonstrate that repetitive, unattended stimulation
from outside the brain, combined with a lack of behavioral information,
are effective in driving persistent improvement of the perception of
touch. The underlying properties and processes that allow cortical
networks, after being modified through TMS pulses, to reach new
organized stable states that mediate better performance remain to be
clarified.
Exp Neurol. 2005 Sep 26; [Epub ahead of print]
Repetitive transcranial magnetic stimulation of the dorsolateral
prefrontal cortex excitability in patients with major depressive
disorder.
Bajbouj M, Brakemeier EL, Schubert F, Lang UE, Neu P, Schindowski C, Danker-Hopfe H.
Department of Psychiatry, Charite-University Medicine Berlin, Campus Benjamin Franklin, Eschenallee 3, 14050 Berlin, Germany.
Repetitive transcranial magnetic stimulation (rTMS) of the
dorsolateral prefrontal cortex is a relatively non-invasive technique
with putative therapeutic effects in major depression. However, the
exact neurophysiological basis of these effects needs further
clarification. Therefore, we studied the impact of ten daily sessions of
left, dorsolateral prefrontal rTMS on motor cortical excitability, as
revealed by transcranial magnetic stimulation-elicited motor-evoked
potentials in 30 patients. As compared to the non-responders, responders
(33%) showed changes in parameters pointing towards a reduced cortical
excitability. These results suggest that repetitive transcranial
magnetic stimulation of the dorsolateral, prefrontal cortex may have
inhibitory effects on motor cortical neuronal excitability in patients
with major depressive disorder. Furthermore, measurement of motor
cortical excitability may be a useful tool for investigating and
monitoring inhibitory brain effects of antidepressant stimulation
techniques like rTMS.
Prog Brain Res. 2005;150:527-35.
Neural plasticity and recovery of function.
Ward NS.
Wellcome Department of Imaging Neuroscience, Institute of Neurology,
University College London, 12 Queen Square, London WC1N 3BG, UK.
Recovery of the function after stroke is a consequence of many
factors including resolution of oedema and survival of the ischaemic
penumbra. In addition there is a growing interest in the role of central
nervous system (CNS) reorganization. Much of the evidence supporting
this comes from animal models of focal brain injury, but non-invasive
techniques such as functional magnetic resonance imaging, transcranial
magnetic stimulation, electroencephalography and magnetoencephalography
now allow the study of the working human brain. Using these techniques
it is apparent that the motor system of the brain adapts to damage in a
way that attempts to preserve motor function. This has been demonstrated
after stroke, as part of the ageing process, and even after disruption
of normal motor cortex with repetitive transcranial magnetic
stimulation. The result of this reorganization is a new functional
architecture, one which will vary from patient to patient depending on
the anatomy of the damage, the biological age of the patient and lastly
the chronicity of the lesion. The success of any given therapeutic
intervention will depend on how well it interacts with this new
functional architecture. Thus it is crucial that the study of novel
therapeutic strategies for treating motor impairment after stroke take
account of this. This review maps out the attempts to describe
functionally relevant adaptive changes in the human brain following
focal damage. A greater understanding of how these changes are related
to the recovery process will allow not only the development of novel
therapeutic techniques that are based on neurobiological principles and
designed to minimize impairment in patients suffering from stroke, but
also to target these therapies at the appropriate patients.
Prog Neuropsychopharmacol Biol Psychiatry. 2005 Oct 19; [Epub ahead of print]
A double-blind sham controlled study of right prefrontal repetitive
transcranial magnetic stimulation (rTMS): Therapeutic and cognitive
effect in medication free unipolar depression during 4 weeks.
Januel D, Dumortier G, Verdon CM, Stamatiadis L, Saba G, Cabaret W,
Benadhira R, Rocamora JF, Braha S, Kalalou K, Vicaut PE, Fermanian J.
Unite de recherche clinique, EPS de Ville Evrard a Saint Denis, G03, 5 Rue du Dr Delafontaine 93200 Saint-Denis, France.
BACKGROUND: Transcranial magnetic stimulation (TMS) has become a therapeutic tool in psychiatric diseases.
METHODOLOGY: The objective was to evaluate the efficacy of TMS in
unipolar depression: the percentage of responders (>50% HDRS
reduction) and remission (HDRS score </=8, after four weeks of active
TMS treatment in depressed patients free of any antidepressive agent
versus placebo-TMS.
RESULTS: 27 patients were randomized in two groups: rTMS (N=11)
versus sham TMS (N=16). Statistical differences were detected between
sham and TMS treated groups on remission (0/16 versus 4/11 p=0.032, 1/16
versus 6/11 0.028 and 1/16 versus 7/11 p=0.011 at day 14, day 21 and
day 28, respectively) and on response (2/16 versus 5/11 at day 14 (NS),
2/16 versus 7/11 p=0.0115 at day 21 and 1/16 versus 7/11 (p=0.025) day
28, respectively, using the exact Fisher test). Significant differences
were observed between day 1 versus day 8 (p<0.01), day 15, day 21 and
day 28 (p<0.001) in TMS group and only versus day 21 (p<0.01) and
day 28 (p<0.05) for the sham group. ANOVA comparison between TMS and
sham groups was significant at day 14 and day 28 (p<0.05).
LIMITATIONS: The few number of patients.
CONCLUSION: Our study has shown an efficacy of right rTMS in free
medication unipolar depression over a month. Nevertheless, number of
patients included is limited and multicentric studies will be necessary
to specify the antidepressive action of TMS.
Ann Neurol. 2005 Oct 20; [Epub ahead of print]
Altered plasticity of the human motor cortex in Parkinson’s disease.
Ueki Y, Mima T, Ali Kotb M, Sawada H, Saiki H, Ikeda A, Begum T, Reza F, Nagamine T, Fukuyama H.
Human Brain Research Center, Kyoto University Graduate School of Medicine, Sakyo-ku, Kyoto, Japan.
Interventional paired associative stimulation (IPAS) to the
contralateral peripheral nerve and cerebral cortex can enhance the
primary motor cortex (M1) excitability with two synchronously arriving
inputs. This study investigated whether dopamine contributed to the
associative long-term potentiation-like effect in the M1 in Parkinson’s
disease (PD) patients. Eighteen right-handed PD patients and 11
right-handed age-matched healthy volunteers were studied. All patients
were studied after 12 hours off medication with levodopa replacement
(PD-off). Ten patients were also evaluated after medication (PD-on). The
IPAS comprised a single electric stimulus to the right median nerve at
the wrist and subsequent transcranial magnetic stimulation of the left
M1 with an interstimulus interval of 25 milliseconds (240 paired stimuli
every 5 seconds for 20 minutes). The motor-evoked potential amplitude
in the right abductor pollicis brevis muscle was increased by IPAS in
healthy volunteers, but not in PD patients. IPAS did not affect the
motor-evoked potential amplitude in the left abductor pollicis brevis.
The ratio of the motor-evoked potential amplitude before and after IPAS
in PD-off patients increased after dopamine replacement. Thus, dopamine
might modulate cortical plasticity in the human M1, which could be
related to higher order motor control, including motor learning. Ann
Neurol 2006.
HNO. 2005 Sep 17; [Epub ahead of print]
Treatment of chronic tinnitus with neuronavigated repetitive Transcranial Magnetic Stimulation (rTMS).
Klinik fur HNO-Heilkunde der Universitat Regensburg, .
BACKGROUND AND OBJECTIVE: Idiopathic tinnitus is a frequent and
debilitating disorder of largely unknown pathophysiology. Focal brain
activation in the auditory cortex has recently been demonstrated in
chronic tinnitus. Low-frequency rTMS can reduce cortical
hyperexcitability.
PATIENTS AND METHODS: In 12 patients with chronic tinnitus, fusion of
[(18)F]deoxyglucose-PET and structural MRI (T1, MPRAGE) scans allowed
the area of increased metabolic activity in the auditory cortex to be
exactly identified; this area was selected as the target for rTMS. A
neuronavigational system adapted for TMS positioning enabled the
relative positions of the figure-8 coil and the target area to be
monitored. Repetitive TMS (110% motor threshold; 1 Hz; 2000 stimuli per
day over 5 days) was performed using a placebo-controlled crossover
design. A sham coil system was used for the placebo stimulation.
Treatment outcome was assessed with a specific tinnitus questionnaire
(Goebel and Hiller).
RESULTS: In all 12 patients an asymmetrically increased metabolic
activation of the gyrus of Heschl was detected. The tinnitus score was
significantly improved after 5 days of active rTMS, an effect not seen
after placebo stimulation.
CONCLUSION: These preliminary results show that neuronavigated rTMS
may improve our understanding and treatment of chronic tinnitus.
Clin Neurophysiol. 2005 Oct 24; [Epub ahead of print]
Transcranial magnetic and electrical stimulation compared: Does TES activate intracortical neuronal circuits?
Brocke J, Irlbacher K, Hauptmann B, Voss M, Brandt SA.
Department of Neurology, Berlin NeuroImaging Center, Charite, 10117 Berlin, Germany.
OBJECTIVE: To determine whether, and under which conditions,
transcranial electrical stimulation (TES) and transcranial magnetic
stimulation (TMS) can activate similar neuronal structures of the human
motor cortex, as indicated by electromyographic recordings.
METHODS: Focal TMS was performed on three subjects inducing a
postero-anterior directed current (p-a), TES with postero-anteriorly
(p-a) and latero-medially (l-m) oriented electrodes. We analyzed the
onset latencies and amplitudes (single-pulse) and intracortical
inhibition and excitation (paired-pulse).
RESULTS: TMS p-a and TES p-a produced muscle responses with the same
onset latency, while TES l-m led to 1.4-1.9ms shorter latencies.
Paired-pulse TMS p-a and TES p-a induced inhibition at short
inter-stimulus intervals (ISI) (maximum: 2-3ms) and facilitation at
longer ISIs (maximum: 10ms). No inhibition but a strong facilitation was
obtained from paired-pulse TES l-m (ISIs 1-5ms).
CONCLUSIONS: Our findings support the hypothesis, that current
direction is the most relevant factor in determining the mode of
activation for both TMS and TES: TMS p-a and TES p-a are likely to
activate the corticospinal neurons indirectly. In contrast, TES l-m may
preferentially activate the corticospinal fibres directly, distant of
the neuronal body. SIGNIFICANCE: TES is a suitable tool to induce
intracortical inhibition and excitation.
Neurosci Behav Physiol. 2005 Mar;35(3):313-7.
The effects of L-DOPA and transcranial magnetic stimulation on behavioral reactions in kindled rats.
Godlevskii LS, Kobolev EV.
Odessa State Medical University, 2 Valikhovskii Lane, 65026 Odessa, Ukraine.
Acute experiments were performed on rats to produce a model of
chronic epileptic activity–pharmacological kindling by repeated doses of
picrotoxin (1.0-1.2 mg/kg, i.p.). During the early period following
kindling (24 h from the last dose of epileptogen), animals showed
decreases in measures of investigative behavior as measured in an open
field test, along with reductions in sexual and feeding behavior. The
severity of these impairments had decreased by two weeks from the last
picrotoxin dose. Both treatment with L-DOPA (100 mg/kg, i.p.) and
transcranial magnetic stimulation (20 impulses with induction, peak 1.5
T) were accompanied by increases in measures of investigative, sexual,
and feeding behavior in the animals, suggesting that mechanism of action
of transcranial magnetic stimulation in relation to kindling-induced
behavioral abnormalities is mediated by activation of the dopaminergic
system of the brain.
Eur J Neurosci. 2005 Nov;22(9):2392-6.
High-frequency repetitive transcranial magnetic stimulation over the
hand area of the primary motor cortex disturbs predictive grip force
scaling.
Nowak DA, Voss M, Huang YZ, Wolpert DM, Rothwell JC.
Sobell Department of Motor Neuroscience and Movements Disorders, Institute of Neurology, University College London, London, UK.
When we repetitively lift an object, our grip force is influenced by
the mechanical object properties of the preceding lift, irrespective of
whether the subsequent lift is performed with the same hand or the hand
opposite to the preceding lift. This study investigates if repetitive
high-frequency transcranial magnetic stimulation (rTMS) over the
dominant primary motor cortex affects this relationship. After
completion of 10 lifts of an object using the dominant hand, rTMS was
applied over the dominant primary motor cortex for 20 s. On the first
lift following rTMS, the peak grip force was significantly higher than
on the lift preceding rTMS. Moreover, this measure remained elevated
throughout the following set of lifts after rTMS. rTMS did not change
the peak lift force generated by more proximal arm muscles. The same
effect was observed when the lifts following rTMS over the dominant
motor cortex were performed with the ipsilateral hand. These effects
were not observed when subjects rested both hands on their lap or when a
sham stimulation was applied for the same period of time. These
preliminary data suggest that rTMS over the sensorimotor cortex disturbs
predictive grip force planning.
J Psychiatr Res. 2005 Oct 28; [Epub ahead of print]
Striatal dopamine release after prefrontal repetitive transcranial
magnetic stimulation in major depression: Preliminary results of a
dynamic [(123)I] IBZM SPECT study.
Pogarell O, Koch W, Popperl G, Tatsch K, Jakob F, Zwanzger P, Mulert C, Rupprecht R, Moller HJ, Hegerl U, Padberg F.
Department of Psychiatry, Ludwig-Maximilians-University, Nussbaumstr. 7, D-80336 Munich, Germany.
Though there is considerable evidence that prefrontal repetitive
transcranial magnetic stimulation (rTMS) exerts antidepressant effects,
the neurobiological action of rTMS in patients with depression is poorly
understood. Preclinical studies in animals and humans have demonstrated
that prefrontal rTMS can induce dopamine release in mesostriatal and
mesolimbic regions. We therefore investigated whether rTMS also
modulates striatal dopaminergic neurotransmission in depressed patients
using a dynamic [(123)I] iodobenzamide (IBZM) single photon emission
computed tomography (SPECT) approach. Five patients with a major
depressive episode (DSM-IV) underwent an acute 10Hz rTMS challenge with
3000 stimuli over the left dorsolateral prefrontal cortex during an
[(123)I] IBZM-SPECT bolus and constant infusion protocol. In four
subjects the protocol was repeated after a three week rTMS standard
treatment. Striatal IBZM binding to dopamine D(2) receptors was assessed
with a region-of-interest (ROI) technique. The change in striatal IBZM
binding after the rTMS challenge was regarded as measure of change in
endogenous striatal dopamine. Data of nine SPECT investigations showed a
significant reduction by 9.6+/-6.2% in IBZM binding to striatal
dopamine D(2) receptors after rTMS challenge compared to baseline
(p=0.01, Wilcoxon test). In this preliminary study, the reduction of
IBZM binding observed after rTMS challenge is suggestive of a release in
endogenous dopamine induced by prefrontal rTMS. In future, this
approach can be used to differentiate specific and non-specific
reward-related effects of rTMS on dopaminergic neurotransmission.
Vision Res. 2005 Oct 26; [Epub ahead of print]
Processing of global form and motion in migraineurs.
Ditchfield JA, McKendrick AM, Badcock DR.
School of Psychology, University of Western Australia, 35 Stirling Hwy, Crawley, WA 6009, Australia.
Previous studies have identified anomalies of cortical visual
processing in migraineurs that appear to extend beyond V1. Migraineurs
respond differently than controls to transcranial magnetic stimulation
of V5, and can demonstrate impairments of global motion processing. This
study was designed to assess the integrity of intermediate stages of
both motion and form processing in people with migraine. We measured the
ability to integrate local orientation information into a global form
percept, and to integrate local motion information into a global motion
percept. Control subjects performed significantly better than
migraineurs on both tasks, suggesting a diffuse visual cortical
processing anomaly in migraine.
J Clin Neurosci. 2005 Oct 25; [Epub ahead of print]
The use of transcranial magnetic stimulation in the clinical evaluation of suspected myelopathy.
Chan YC, Mills KR.
Department of Clinical Neurophysiology, King’s College Hospital, London SE5 9RS.
Central motor conduction time (CMCT) and motor evoked potential (MEP)
latencies measured by using transcranial magnetic stimulation (TMS) are
parameters used to evaluate electrophysiologic function of the
corticospinal motor tract. We present 5 cases to illustrate how the use
of TMS had contributed to clinical management. CMCT and MEP latency
measurements were found to be useful in determining the significance of
lesions seen on neuroimaging and helped clinical decisions in the
presence of multiple lesions or multiple clinical conditions that cause
similar clinical manifestations. TMS study is particularly useful in
localizing levels of conduction defect.
Exp Brain Res. 2005 May;163(1):21-31. Epub 2005 Feb 3.
Silent period to transcranial magnetic
Kimiskidis VK, Papagiannopoulos S, Sotirakoglou K, Kazis DA, Kazis A, Mills KR.
Department of Neurology III, G. Papanikolaou Hospital, Aristotle University of Thessaloniki, 57010 Thessaloniki, Greece. kimiskid@med.auth.gr
Silent period (SP) is widely used in transcranial magnetic
stimulation studies. Methodologically, SP is usually elicited at
stimulus intensities corresponding to a certain percentage of
corticomotor threshold. Because this approach might lead to factitious
SP changes, the present study was designed to develop, in a stepwise
manner, a method for investigating SP independently of corticomotor
threshold. First, stimulus-response (S-R) curves of SP against stimulus
intensity (SI) were constructed and quantitatively described in healthy
volunteers. Second, various methodological issues such as the optimum
model for describing the relationship between SP duration and SI and the
importance of the type of stimulating coil were addressed. Finally, the
proposed method and a commonly used method (eliciting SPs at 130% MT
SI) were directly compared for a group of epileptic patients for whom
administration of oxcarbazepine resulted in significant corticomotor
threshold elevation. Twenty-one subjects (eleven females, median age, 38
years) were studied. SPs were obtained with a figure-of-eight coil
using a standardized procedure (recording, FDI). Pilot experiments
indicated that at least four trials were required, at each intensity
level, to estimate the mean SP duration within 10% of the true mean.
Therefore, SPs were determined from the average of four trials with 5%
increments from 5 to 100% maximum SI. In a second set of experiments,
SPs were obtained for fifteen subjects using a circular coil. In a third
set of experiments, eight epileptic patients were studied before and
after administration of oxcarbazepine (mean dose 1553 mg, range 900-1800
mg). The S-R curves were fitted to a Boltzman function and to
first-order to fourth-order polynomial and sigmoid functions. The
Boltzman function described the data accurately (R2=0.947-0.990). In
addition, direct comparison of the six models with an F-test proved the
superiority of the first. The best-fit parameters of the reference
curve, i.e. the maximum and minimum values, the slope, and V50 (the SI
at which SP duration is halfway between Min and Max) were 230.8+/-3.31
ms (x+/-SEM), -11.51+/-3.31 ms, 11.56+/-0.65%, and 49.82+/-0.65%,
respectively. When the curves obtained with the circular coil were
compared with those obtained with the figure-of-eight coil, there were
differences between V50 (51.69+/-0.72 vs 47.95+/-0.82, P<0.001) and
SP threshold (31.15 vs 24.77, P<0.01) whereas the other best-fit
values did not differ significantly. Oxcarbazepine increased
corticomotor threshold from 45.3+/-5.8% at baseline to 59.4+/-10.4%
(P<0.001). According to the commonly used method, the drug
significantly prolonged SP (from 117.6+/-42.4 ms to 143.5+/-46.5 ms,
P<0.001) and, consequently, enhanced brain inhibition. In contrast,
study of the SP curves led to the conclusion that oxcarbazepine does not
affect the Max value and slope but significantly increases V50 and SP
threshold (from 54.5+/-4.9% to 59.9+/-7.2% and from 29.1+/-6.4% to
34.6+/-6.8%, respectively, P<0.01). These findings imply that
oxcarbazepine does not enhance brain inhibitory mechanisms. Thus, in
situations characterized by significant changes in corticomotor
threshold the proposed method provides results clearly different from a
commonly used approach. It is concluded that S-R curves obtained with a
figure-of-eight coil in 5% increments and fitted to a Boltzman function
provide an accurate, comprehensive, and clinically applicable method for
exploring SP.
Invest Radiol. 1998 Jun;33(6):336-40.
Echoplanar BOLD fMRI of brain activation induced by concurrent transcranial magnetic stimulation.
Bohning DE, Shastri A, Nahas Z, Lorberbaum JP, Andersen SW, Dannels WR, Haxthausen EU, Vincent DJ, George MS.
Department of Radiology, Medical University of South Carolina, Charleston 29425, USA. bohninde@musc.edu
RATIONALE AND OBJECTIVES: The authors demonstrate the feasibility of
combining transcranial magnetic stimulation (TMS) and functional
magnetic resonance imaging (fMRI) inside an MR scanner to noninvasively
stimulate and image regional brain activity.
METHODS: Echoplanar blood oxygen level dependent (BOLD)-based fMRI
studies of TMS response were performed on three human volunteers inside a
standard 1.5 T MR scanner using independent computer control to
interleave echoplanar image acquisition and stimulation of right thumb
primary motor cortex with a nonferromagnetic TMS coil.
RESULTS: Significant (P< 0.001) response was observed in motor
cortex under the TMS coil during stimulation compared to rest, as well
in auditory cortex, the latter presumably due to the loud “snap” when
the coil was pulsed.
CONCLUSIONS: Concurrent TMS stimulation and echoplanar BOLD fMRI
imaging is possible. This method has potential for tracing neural
circuits with brain imaging, as well as investigating the effects of
TMS.
Int J Neurosci. 1998 May;94(1-2):41-54.
Transcranial AC pulsed applications of weak electromagnetic fields
reduces freezing and falling in progressive supranuclear palsy: a case
report.
Sandyk R.
Department of Neuroscience, Institute for Biomedical Engineering and
Rehabilitation Services, Touro College, Dix Hills, NY 11746, USA.
Freezing is a common and disabling symptom in patients with
Parkinsonism. It affects most commonly the gait in the form of start
hesitation and sudden immobility often resulting in falling. A higher
incidence of freezing occurs in patients with progressive supranuclear
palsy (PSP) which is characterized clinically by a constellation of
symptoms including supranuclear ophthalmoplegia, postural instability,
axial rigidity, dysarthria, Parkinsonism, and pseudobulbar palsy.
Pharmacologic therapy of PSP is currently disappointing and the disease
progresses relentlessly to a fatal outcome within the first decade after
onset. This report concerns a 67 year old woman with a diagnosis of PSP
in whom freezing and frequent falling were the most disabling symptoms
of the disease at the time of presentation. Both symptoms, which were
rated 4 on the Unified Parkinson Rating Scale (UPRS) which grades
Parkinsonian symptoms and signs from 0 to 4, with 0 being normal and 4
being severe symptoms, were resistant to treatment with dopaminergic
drugs such as levodopa, amantadine, selegiline and pergolide mesylate as
well as with the potent and highly selective noradrenergic reuptake
inhibitor nortriptyline. Weekly transcranial applications of AC pulsed
electromagnetic fields (EMFs) of picotesla flux density was associated
with approximately 50% reduction in the frequency of freezing and about
80-90% reduction in frequency of falling after a 6 months follow-up
period. At this point freezing was rated 2 while falling received a
score of 1 on the UPRS. In addition, this treatment was associated with
an improvement in Parkinsonian and pseudobulbar symptoms with the
difference between the pre-and post EMF treatment across 13 measures
being highly significant (p < .005; Sign test). These results suggest
that transcranial administration AC pulsed EMFs in the picotesla flux
density is efficacious in the treatment of PSP.
Int J Neurosci. 1997 Nov;92(1-2):63-72.
Speech impairment in Parkinson’s disease is improved by transcranial application of electromagnetic fields.
Sandyk R.
Department of Neuroscience, Touro College, Dix Hills, NY 11746, USA.
A 52 year old fully medicated physician with juvenile onset
Parkinsonism experienced 4 years ago severe “on-off” fluctuations in
motor disability and debilitating speech impairment with severe
stuttering which occurred predominantly during “on-off” periods. His
speech impairment improved 20%-30% when sertraline (75 mg/day), a
serotonin reuptake inhibitor, was added to his dopaminergic medications
which included levodopa, amantadine, selegiline and pergolide mesylate. A
more dramatic and consistent improvement in his speech occurred over
the past 4 years during which time the patient received, on a fairly
regular basis, weekly transcranial treatments with AC pulsed
electromagnetic fields (EMFs) of picotesla flux density. Recurrence of
speech impairment was observed on several occasions when regular
treatments with EMFs were temporarily discontinued. These findings
demonstrate that AC pulsed applications of picotesla flux density EMFs
may offer a nonpharmacologic approach to the management of speech
disturbances in Parkinsonism. Furthermore, this case implicates cerebral
serotonergic deficiency in the pathogenesis of Parkinsonian speech
impairment which affects more than 50% of patients. It is believed that
pulsed applications of EMFs improved this patient’s speech impairment
through the facilitation of serotonergic transmission which may have
occurred in part through a synergistic interaction with sertraline.
Int J Neurosci. 1997 Sep;91(1-2):57-68.
Reversal of cognitive in an elderly parkinsonian patient by transcranial application of picotesla electromagnetic fields.
Sandyk R.
Department of Neuroscience, Touro College, Dix Hills, NY 11746, USA.
A 74 year old retired building inspector with a 15 year history of
Parkinson’s disease (PD) presented with severe resting tremor in the
right hand, generalized bradykinesia, difficulties with the initiation
of gait with freezing, mental depression and generalized cognitive
impairment despite being fully medicated. Testing of constructional
abilities employing various drawing tasks demonstrated drawing
impairment compatible with severe left hemispheric dysfunction. After
receiving two successive transcranial applications, each of 20 minutes
duration, with AC pulsed electromagnetic fields (EMFs) of 7.5 picotesla
flux density and frequencies of 5Hz and 7Hz respectively, his tremor
remitted and there was dramatic improvement in his drawing performance.
Additional striking improvements in his drawing performance occurred
over the following two days after he continued to receive daily
treatments with EMFs. The patient’s drawings were subjected to a
Reliability Test in which 10 raters reported 100% correct assessment of
pre- and post drawings with all possible comparisons (mean 2 = 5.0; p
< .05). This case demonstrates in PD rapid reversal of drawing
impairment related to left hemispheric dysfunction by brief transcranial
applications of AC pulsed picotesla flux density EMFs and suggests that
cognitive deficits associated with Parkinsonism, which usually are
progressive and unaffected by dopamine replacement therapy, may be
partly reversed by administration of these EMFs. Treatment with
picotesla EMFs reflects a “cutting edge” approach to the management of
cognitive impairment in Parkinsonism.
OBJECTIVE: The aim of this study was to investigate if laser therapy
in combination with pulsed electromagnetic field therapy/repetitive
transcranial magnetic stimulation (rTMS) and the control of reactive
oxygen species (ROS) would lead to positive treatment results for
hyperacusis patients.
BACKGROUND DATA: Eight of the first ten patients treated for
tinnitus, who were also suffering from chronic hyperacusis, claimed
their hyperacusis improved. Based upon that, a prospective, unblinded,
uncontrolled clinical trial was planned and conducted. ROS and
hyperacusis pain thresholds were measured.
MATERIALS AND METHODS: Forty-eight patients were treated twice a week
with a combination of therapeutic laser, rTMS, and the control and
adjustment of ROS. A magnetic field of no more than 100 microT was
oriented behind the outer ear, in the area of the mastoid bone. ROS were
measured and controlled by administering different antioxidants. At
every treatment session, 177-504 J of laser light of two different
wavelengths was administered toward the inner ear via meatus acusticus.
RESULTS: The improvements were significantly better in the verum
group than in a placebo group, where 40% of the patients were expected
to have a positive treatment effect. The patients in the long-term
follow-up group received significantly greater improvements than the
patients in the short-term follow-up group.
CONCLUSION: The treatment is effective in treating chronic hyperacusis.
HNO. 2006 Jun;54(6):439-44.
Treatment of chronic tinnitus with neuronavigated repetitive Transcranial Magnetic Stimulation (rTMS).
BACKGROUND AND OBJECTIVE: Idiopathic tinnitus is a frequent and
debilitating disorder of largely unknown pathophysiology. Focal brain
activation in the auditory cortex has recently been demonstrated in
chronic tinnitus. Low-frequency rTMS can reduce cortical
hyperexcitability.
PATIENTS AND METHODS: In 12 patients with chronic tinnitus, fusion of
[18F]deoxyglucose-PET and structural MRI (T1, MPRAGE) scans allowed the
area of increased metabolic activity in the auditory cortex to be
exactly identified; this area was selected as the target for rTMS. A
neuronavigational system adapted for TMS positioning enabled the
relative positions of the figure-8 coil and the target area to be
monitored. Repetitive TMS (110% motor threshold; 1 Hz; 2000 stimuli per
day over 5 days) was performed using a placebo-controlled crossover
design. A sham coil system was used for the placebo stimulation.
Treatment outcome was assessed with a specific tinnitus questionnaire
(Goebel and Hiller).
RESULTS: In all 12 patients an asymmetrically increased metabolic
activation of the gyrus of Heschl was detected. The tinnitus score was
significantly improved after 5 days of active rTMS, an effect not seen
after placebo stimulation.
CONCLUSION: These preliminary results show that neuronavigated rTMS
may improve our understanding and treatment of chronic tinnitus.
HNO. 2005 Sep 17; [Epub ahead of print]
Treatment of chronic tinnitus with neuronavigated repetitive Transcranial Magnetic Stimulation (rTMS).
Klinik fur HNO-Heilkunde der Universitat Regensburg, .
BACKGROUND AND OBJECTIVE: Idiopathic tinnitus is a frequent and
debilitating disorder of largely unknown pathophysiology. Focal brain
activation in the auditory cortex has recently been demonstrated in
chronic tinnitus. Low-frequency rTMS can reduce cortical
hyperexcitability.
PATIENTS AND METHODS: In 12 patients with chronic tinnitus, fusion of
[(18)F]deoxyglucose-PET and structural MRI (T1, MPRAGE) scans allowed
the area of increased metabolic activity in the auditory cortex to be
exactly identified; this area was selected as the target for rTMS. A
neuronavigational system adapted for TMS positioning enabled the
relative positions of the figure-8 coil and the target area to be
monitored. Repetitive TMS (110% motor threshold; 1 Hz; 2000 stimuli per
day over 5 days) was performed using a placebo-controlled crossover
design. A sham coil system was used for the placebo stimulation.
Treatment outcome was assessed with a specific tinnitus questionnaire
(Goebel and Hiller).
RESULTS: In all 12 patients an asymmetrically increased metabolic
activation of the gyrus of Heschl was detected. The tinnitus score was
significantly improved after 5 days of active rTMS, an effect not seen
after placebo stimulation.
CONCLUSION: These preliminary results show that neuronavigated rTMS
may improve our understanding and treatment of chronic tinnitus.
Otol Neurotol. 2005 Jul;26(4):616-9.
Transcranial magnetic stimulation for tinnitus: influence of
tinnitus duration on stimulation parameter choice and maximal tinnitus
suppression.
De Ridder D, Verstraeten E, Van der Kelen K, De Mulder G, Sunaert S, Verlooy J, Van de Heyning P, Moller A.
Department of Neurosurgery and Otorhinolaryngology, University Hospital Antwerp, Belgium. dirk.de.ridder@uza.be
OBJECTIVE: Tinnitus is a distressing symptom for which few treatments
exist. It leads to an important decrease in quality of life in 2 to 3%
of the population. Tinnitus is considered a phantom sound, the result of
cortical reorganization. Transcranial magnetic stimulation (TMS) is a
noninvasive method to modulate cortical reorganization and has been
shown to be able to influence tinnitus perception.
STUDY DESIGN: Retrospective analysis.
SETTING: Tertiary referral center.
PATIENTS: The effect of TMS of the contralateral auditory cortex in
114 patients with unilateral tinnitus is investigated as one of the
selection criteria used for surgical implantation of electrodes on the
auditory cortex.
INTERVENTION: TMS is performed at 90% of motor threshold at 1, 3, 5,
10, and 20 Hz, with each stimulation session consisting of 200 pulses.
Results were classified as no effect (0-19% improvement), partial effect
(20-79% improvement), and good effect (80-100 suppression). MAIN
OUTCOME MEASURES: TMS had a good effect in 25% of the patients studied,
partial effect in 28% patients, and no effect in 47%.
RESULTS: TMS at 200 pulses is capable of tinnitus suppression for
seconds only. The results were influenced by tinnitus duration: the
longer the tinnitus exists, the lower the stimulation frequency that
yields maximal tinnitus suppression (p < 0.001). The maximal amount
of tinnitus suppression decreases in time (p < 0.01), resulting in a
2% decrease of potential tinnitus suppression per year.
CONCLUSION: TMS of the auditory cortex is capable of modifying
tinnitus perception for a very short time. The maximal amount of
suppression and best stimulation frequency depends on the tinnitus
duration.
Electromagnetic stimulation as a treatment of tinnitus: a pilot study.
Roland NJ, Hughes JB, Daley MB, Cook JA, Jones AS, McCormick MS.
Department of Otolaryngology, Royal Liverpool University Hospital, UK.
This paper reports the results of a study to determine whether pulsed
electromagnetic stimulation, applied over the mastoid bone, caused an
improvement in the level of tinnitus in long-standing tinnitus
sufferers. Fifty-eight patients from the Liverpool Tinnitus Association
volunteered to take part in a double-blind placebo controlled trial.
Active and placebo devices were randomly allocated to these patients on
their first visit. At the end of one week of treatment, each patient
noted whether their tinnitus had completely disappeared, was improved,
unchanged or made worse by the treatment Forty-five per cent of the
patients who completed the trial were improved by the active device, but
only 9% by placebo (P = 0.0013, Mann-Whitney test). We suggest that
electromagnetic stimulation may be an effective treatment in some
tinnitus sufferers.
Vestn Otorinolaringol. 2002;(1):11-4.
Electrophysical effects in combined treatment of neurosensory hypoacusis.
[Article in Russian]
Morenko VM, Enin IP.
The authors consider different methods of electrobiophysical impacts
on the body in the treatment of neurosensory hypoacusis: laser beam,
laser puncture, electrostimulation, magnetotherapy, magnetolasertherapy,
electrophoresis, etc. These methods find more and more intensive
application in modern medicine. Further success of physiotherapy for
neurosensory hypoacusis depends on adequate knowledge about mechanisms
of action of each physical method used and introduction of novel
techniques.
Vestn Otorinolaringol. 2001;(4):10-2.
Cerebral hemodynamics in patients with neurosensory hearing loss before and after magnetotherapy.
[Article in Russian]
Morenko VM, Enin IP.
Magnetotherapy effects on cerebral hemodynamics were studied using
rheoencephalography (REG). When the treatment results and changes in
cerebral hemodynamics were compared it was evident that normalization or
improvement of vascular status in vertebrobasilar and carotid
territories registered at REG results in better hearing. This confirms
the role of vascular factor in pathogenesis of neurosensory hypoacusis
of different etiology and effectiveness of magnetotherapy in such
patients.
Vestn Otorinolaringol. 1996 Nov-Dec;(6):23-6.
The treatment of hypoacusis in children by using a pulsed low-frequency electromagnetic field.
[Article in Russian]
Bogomil’skii MR, Sapozhnikov IaM, Zaslavskii AIu, Tarutin NP.
The authors provide specifications of the unit INFITA supplied with
ELEMAGS attachment of their own design; the technique of treating
hypoacusis in children with utilization of impulse low-frequency
electromagnetic field; the results of this treatment in 105 hypoacusis
children. The method was found highly effective and valuable for wide
practice.
Med Tekh. 1995 Mar-Apr;(2):40-1.
ELEMAGS apparatus and clinical experience in its use in the treatment of children with hypoacusis and otalgia.
To enhance effectiveness of magnetotherapy in the treatment of otic
diseases the authors propose to use impulse low-frequency
electromagnetic field in combination with constant magnetic field.
ELEMAGS equipment based on the above principles is introduced to treat
cochlear neuritis and neurosensory hypoacusis in children.
Klinik fur HNO-Heilkunde der Universitat Regensburg, .
BACKGROUND AND OBJECTIVE: Idiopathic tinnitus is a frequent and
debilitating disorder of largely unknown pathophysiology. Focal brain
activation in the auditory cortex has recently been demonstrated in
chronic tinnitus. Low-frequency rTMS can reduce cortical
hyperexcitability.
PATIENTS AND METHODS: In 12 patients with chronic tinnitus, fusion of
[(18)F]deoxyglucose-PET and structural MRI (T1, MPRAGE) scans allowed
the area of increased metabolic activity in the auditory cortex to be
exactly identified; this area was selected as the target for rTMS. A
neuronavigational system adapted for TMS positioning enabled the
relative positions of the figure-8 coil and the target area to be
monitored. Repetitive TMS (110% motor threshold; 1 Hz; 2000 stimuli per
day over 5 days) was performed using a placebo-controlled crossover
design. A sham coil system was used for the placebo stimulation.
Treatment outcome was assessed with a specific tinnitus questionnaire
(Goebel and Hiller).
RESULTS: In all 12 patients an asymmetrically increased metabolic
activation of the gyrus of Heschl was detected. The tinnitus score was
significantly improved after 5 days of active rTMS, an effect not seen
after placebo stimulation.
CONCLUSION: These preliminary results show that neuronavigated rTMS
may improve our understanding and treatment of chronic tinnitus.
Otol Neurotol. 2005 Jul;26(4):616-9.
Transcranial magnetic stimulation for tinnitus: influence of
tinnitus duration on stimulation parameter choice and maximal tinnitus
suppression.
De Ridder D, Verstraeten E, Van der Kelen K, De Mulder G, Sunaert S, Verlooy J, Van de Heyning P, Moller A.
Department of Neurosurgery and Otorhinolaryngology, University Hospital Antwerp, Belgium. dirk.de.ridder@uza.be
OBJECTIVE: Tinnitus is a distressing symptom for which few treatments
exist. It leads to an important decrease in quality of life in 2 to 3%
of the population. Tinnitus is considered a phantom sound, the result of
cortical reorganization. Transcranial magnetic stimulation (TMS) is a
noninvasive method to modulate cortical reorganization and has been
shown to be able to influence tinnitus perception.
STUDY DESIGN: Retrospective analysis. SETTING: Tertiary referral center.
PATIENTS: The effect of TMS of the contralateral auditory cortex in
114 patients with unilateral tinnitus is investigated as one of the
selection criteria used for surgical implantation of electrodes on the
auditory cortex.
INTERVENTION: TMS is performed at 90% of motor threshold at 1, 3, 5,
10, and 20 Hz, with each stimulation session consisting of 200 pulses.
Results were classified as no effect (0-19% improvement), partial effect
(20-79% improvement), and good effect (80-100 suppression).
MAIN OUTCOME MEASURES: TMS had a good effect in 25% of the patients
studied, partial effect in 28% patients, and no effect in 47%.
RESULTS: TMS at 200 pulses is capable of tinnitus suppression for
seconds only. The results were influenced by tinnitus duration: the
longer the tinnitus exists, the lower the stimulation frequency that
yields maximal tinnitus suppression (p < 0.001). The maximal amount
of tinnitus suppression decreases in time (p < 0.01), resulting in a
2% decrease of potential tinnitus suppression per year.
CONCLUSION: TMS of the auditory cortex is capable of modifying
tinnitus perception for a very short time. The maximal amount of
suppression and best stimulation frequency depends on the tinnitus
duration.
Electromagnetic stimulation as a treatment of tinnitus: a pilot study.
Roland NJ, Hughes JB, Daley MB, Cook JA, Jones AS, McCormick MS.
Department of Otolaryngology, Royal Liverpool University Hospital, UK.
This paper reports the results of a study to determine whether pulsed
electromagnetic stimulation, applied over the mastoid bone, caused an
improvement in the level of tinnitus in long-standing tinnitus
sufferers. Fifty-eight patients from the Liverpool Tinnitus Association
volunteered to take part in a double-blind placebo controlled trial.
Active and placebo devices were randomly allocated to these patients on
their first visit. At the end of one week of treatment, each patient
noted whether their tinnitus had completely disappeared, was improved,
unchanged or made worse by the treatment Forty-five per cent of the
patients who completed the trial were improved by the active device, but
only 9% by placebo (P = 0.0013, Mann-Whitney test). We suggest that
electromagnetic stimulation may be an effective treatment in some
tinnitus sufferers.
The effect of the siting of exposure to decimeter-range
electromagnetic waves on the function of the hypophyseal-thyroid and
adrenal systems in viral hepatitis.
[Article in Russian]
Mavrodi? VM.
Abstract
The author studied time course of changes in the thyroid and adrenal
systems as shown by the levels of T3, T4, T3/T4, TTH, hydrocortisone,
ACTH in response to exposure to decimetric microwaves (460 MHz, 30
mW/cm2). The microwaves were directed to the area of hepatic, thyroid,
adrenal projections and combinations thereof. An optimal effect was
achieved at the course exposure of the adrenal projection.
The promotion of the healing process
following musculoskeletal injuries comprises growth factor signalling,
migration, proliferation and apoptosis of cells. If these processes
could be modulated, the healing of tendon tissue may be markedly
enhanced. Here, we report the use of the Somagen™ device, which is
certified for medical use according to European laws. It generates
low-frequency pulsed electromagnetic fields that trigger effects of a
nature that are yet to be determined.
Methods
A 1.5-cm wide, linear scrape was
introduced into patellar tendon fibroblast cultures (N?=?5 donors).
Treatment was carried out every second day. The regimen was applied
three times in total with 30 minutes comprising pulsed electromagnetic
field packages with two fundamental frequencies (10 minutes of 33 Hz,
20 minutes of 7.8 Hz). Control cells remained untreated. All samples
were analyzed for gap closure time, proliferation and apoptosis one week
after induction of the scrape wound.
Results
The mean time for bridging the gap
in the nontreated cells was 5.05?±?0.33 days, and in treated cells, it
took 3.35?±?0.38 days (P <0.001). For cell cultures with
scrape wounds, a mean value for BrdU incorporation of OD?=?0.70?±?0.16
was found. Whereas low-frequency pulsed electromagnetic fields treated
samples showed OD?=?1.58?±?0.24 (P <0.001). However, the percentage of apoptotic cells did not differ between the two groups.
Conclusions
Our data demonstrate that low-frequency pulsed electromagnetic fields emitted by the Somagen™ device influences the in vitro wound healing of patellar tendon fibroblasts and, therefore, possibly increases wound healing potential.Keywords: wound healing, proliferation, apoptosis, low-frequency pulsed electromagnetic fields
Background
One of the most important advances in
promotion of the healing process following musculoskeletal injuries has
evolved from the insight that treatment of these injuries with prolonged
immobilization may delay recovery and adversely affect normal tissues.
Conversely, controlled early resumption of activity can promote
restoration of function. Experimental studies in the several past
decades confirm and help explain the deleterious effects of prolonged
immobilization and the beneficial effects of activity on the
musculoskeletal tissues [1,2].
At the beginning of the healing process, controlled motion and loading
of tendon and ligament repair tissue help align the regeneration of
cells and collagen fibers, stimulate collagen synthesis and increase
strength [3–6].
Early or excessive strain, however, can increase the inflammatory
reaction and may damage repair tissue, leading to failure of the healing
process [7].
However, not only mechanical loading or growth factor
signalling is important for healing processes. DNA activity concerning
transcription and translation, as well as cell cycle mechanisms, plays a
pivotal role. Those activities comprise proliferation, migration and
apoptosis of cells. If these processes could be modulated, the healing
of tendon tissue may be enhanced markedly. This modulation could prevent
the occurrence of excessive strain by accelerating tendon healing.
In order to study such processes in vitro,
wound-healing assays have been carried out in tissue cultures for many
years. These assays monitored cell behavior, including appraising the
migration and proliferative capacities of different cells under various
culture conditions. They generally involve growing cells to a confluent
monolayer as a first step. The layer is ‘wounded’ by a scraping device
(razor-blade, pipette tip, needle or cell-scraper). This penning in the
cell layer gets repopulated because the cells on the wound edge are no
longer contact-inhibited. At the cellular level, healing involves the
cells’ detachment from and attachment to the matrix adjacent to the
wound area, migration, and proliferation. This repopulation is
microscopically observed over a time course to assess the gap closure
time, the occupied area over time, or the rate of migration [8–10].
Moreover, proliferation and apoptosis are investigated regularly.
Depending on the cell type, the growth factors present, and the extent
of the wounded region, wound repair ranges from several hours to days.
Until the 1980s it was believed that biological information
within cell systems was being transferred not only chemically but also
physically via electromagnetic waves. Information of this nature
activates or inhibits biochemical processes [11,12].
Led by these findings in the early 1990s, Sachtleben GmbH,
Hamburg, Germany developed the Somagen™ device, which supposedly
stimulates the communication mechanisms of cells (Figure 1).
The low-frequency pulsed electromagnetic fields (PEMF) electromagnetic
signals have been described as affecting enzymes, cells, tissues and
whole organisms. Even though the effects exerted by PEMF could be
measured, the reasons for the reactions of the biological systems remain
unidentified. However, several theories exist to explain these effects,
for example the Larmor precession [13,14], the hypothesis of Gartzke and Lange [15] or radical pair mechanism [16–18] (for review see [19]). The application of the PEMF induces changes in cellular processes, among others, differentiation [20], apoptosis [21], DNA synthesis [22], protein expression [23], protein phosphorylation [24], anti-inflammatory effects [25] and hormone production [26].
Figure 1The low-frequency pulsed electromagnetic fields (PEMF) emitting Somagen™ device.
In this work, a specific ‘wound healing’ program lasting 30 minutes was
used. The applied program consisted of two PEMF signal packages of …
PEMF instruments like the Somagen™ device generate
low-frequency electromagnetic signals in order to accelerate, among
others, wound healing response. This enhances the regeneration potential
of the destroyed tissue, especially the stimulation of new formation of
connective tissue, something for which the vasodilatation and increased
cell division are likely responsible [27].
Furthermore, growth factor signalling, which is important for healing
processes, can be influenced by low-frequency electromagnetic signals.
Zhao et al. could demonstrate a stimulation of the VEGF
receptor signaling pathway by applying an electric field on vascular
endothelial cells [28]. Another study demonstrated an increased type I collagen expression in fibroblasts after exposure to pulsing electric fields [29]. Zhao et al.
summarized that electric fields polarize the activation of multiple
signalling pathways, including the PI3 kinases/Pten, membrane growth
factor receptors and integrins, both key players in the wound healing
processes [30].
However, the effect of low-frequency PEMF
emitted by the Somagen™ device on fibroblasts as key players in wound
healing remains to be investigated. Therefore, this study focuses on the
effects of PEMF on the healing process of tendon fibroblasts in an in vitro
wound healing model. Our findings may be helpful in the field of
ligament tissue engineering and may support the development of new
strategies for ligament repair.
Methods
Cell culture
Fibroblasts were isolated from five
patients undergoing surgical treatment of the knee joint. The study
protocol is in accordance with the standards of the Declaration of
Helsinki. Following approval by the ethical committee of Hannover
Medical School, written informed consent was obtained from the patients.
The specimens of approximately 4?×?2 mm were aseptically collected from
the patellar tendon. The obtained patellar tendon specimen was divided
into 0.5 mm2 pieces and transferred into petri dishes with a
roughened bottom. Dulbecco’s Modified Eagle’s Medium (DMEM) was used as
culture medium containing 10% fetal calf serum, 1% gentamicin and 1%
amphotericin B (Biochrom, Berlin, Germany). Tissue specimens were
cultured in a humidified environment with 5% CO2 at 37°C.
Medium was replenished every second day. After six to eight days,
fibroblasts started to grow out of the patellar tendon specimens. After
another three to four weeks, the cells reached 80 to 90% confluence. The
cells were trypsinized and subcultured in 75 cm2 flasks (13?×?103 cells/cm2).
Concomitantly, they were counted and an overall viability of more than
90% was observed using the trypan blue exclusion test. This procedure
was repeated once. Cells in the second passage were harvested and
1.5?×?105 fibroblasts were transferred into six-well tissue culture plates (Corning, Vienna, Austria).
Induction of the scrape wound
Scrape wounds were performed in
confluent monolayer cultures of the patellar tendon fibroblasts. A
1.5 cm wide, linear scrape was introduced with a cell scraper over the
entire diameter of the well. The wound area was marked with three black
ink dots on each side of the wound for reference. Cultures were rinsed
with culture medium to remove floating cellular debris, and fresh
culture medium was added.
Cell cultures were treated every second
day, three times in total, with a registered and certified Somagen™
device, according to company’s protocol (Sachtleben GmbH, Hamburg) In
this work, a specific “wound healing” program was used. The applied
program consisted of two PEMF signal packages of 10 minutes at a
fundamental frequency of 33 Hz and 20 minutes at 7.8 Hz. This ‘wound
healing’ program was developed by Sachtleben GmbH in cooperation with
different dermatology clinics and has been successfully used before in a
clinical setting [31].
The signals have the shape of spike pulses with varying send/pause
intervals. Thereby, a magnetic flux density of 0.25 ?T up to 3.16 ?T
emerged. At a 5-mm distance from the applicator, electric field strength
up to 6.3 mV/cm was measurable (Additional file 1).
Applicators attached to the Somagen™ device were placed in the
incubator. The six-well tissue culture dishes were put directly on top
of the applicators, thereby having a distance to the fibroblast
monolayer of approximately 1 to 2 mm. Control cells were also put on the
applicator without starting the program and were cultivated in a
separate incubator to avoid interactions between the stimulated and
nonstimulated cells.
In order to measure any deviation between
the treated versus the control cell cultures, time to closure of the
gap, proliferation and apoptosis were determined.
Time to closure
The wound was microscopically examined daily for repopulation of the wound area (Figure 2A).
The end point of observation was the complete bridging of the scrape
wound. Therefore, before the scratch was initiated, a photograph as
control with a 20× magnification was captured with the microscope
(Zeiss). Afterwards, a photograph with the same magnification was made
every day. For quantification, the free area was highlighted, calculated
and compared to the control with the software ImageJ 1.42q (National
Institute of Health, Maryland, USA). Three independent calculations of
each donor were made.
Figure 2The use of low-frequency pulsed electromagnetic fields (PEMF) lead to a significantly lower time to closure. Scrape wound of patellar tendon fibroblasts caused by a cell scraper (A), magnification 60×. For the analysis of the time to closure, …
Proliferation
The analysis of cell proliferation
was performed one week after induction of the scrape wound using a
standard BrdU kit for spectrophotometry (Roche, Mannheim, Germany). BrdU
is a thymidine analog that is incorporated into the DNA during the
synthesis phase (S1) of the cell cycle. At 0, 6 and 12 hours after
application of BrdU, the amount of inserted BrdU was analyzed according
to a modified protocol for the larger dishes. To remove non-incorporated
BrdU, cells were washed twice with DMEM. Washed cells were fixed with
70% ethanol in 0.5 M HCl at -20°C for 30 min and washed three more times
with DMEM. Nucleases were added to the cells at 37°C for 30 min to
increase the accessibility of the incorporated BrdU for detection by
anti-BrdU Fab-fragment. This incubation was performed in a buffer
containing 66 mM Tris, 0.66 mM MgCl2, and 1 mM
2-mercaptoethanol to permeate the cells and disintegrate disulphide
bonds. After washing the cells three times with DMEM, a mouse monoclonal
Fab-fragment against BrdU conjugated with horse-radish peroxidase was
added to the cells together with 10 mg/ml BSA in phosphate-buffered
saline. The cells were incubated at 37°C for 30 min and subsequently
washed three times with DMEM. The bound conjugate was visualized using
1 mg/ml of the soluble chromogenic substrate 2,2′-Acinobis
[3-ethylbenzthiazoline-sulfonic acid] (ABTS). The signal was increased
by adding 1 mg/ml of ABTS-substrate enhancer. The optical density of
each sample was measured at 405 nm and 490 nm.
Apoptosis rate
Analysis of apoptosis was performed
one week after induction of the scrape wound according to the protocol
provided by the manufacturer (Bender Med systems, Vienna, Austria).
Briefly, adherent cells were detached from the cell culture dishes by
carefully scratching with a cell scraper. The cells were centrifuged at
1500?×?g and 4°C; afterwards, the pellet was carefully resuspended in
100 ?l binding buffer (10 mM HEPES, pH 7.4; 140 mM NaCl; 5 mM CaCl2)
and stained with 6 ?l recombinant human annexin-V-FITC and 6 ?l of
propidium iodide for discrimination of living, apoptotic and necrotic
cells (Bender Med Systems, Vienna, Austria). After incubation for 20 min
at 4°C in darkness, the cells were centrifuged and resuspended in
100 ?l binding buffer. Flow cytometry was carried out on a FACS-calibur
(Becton-Dickinson, Heidelberg, Germany). The software Cellquest-pro V1.1
from Becton-Dickinson was used for data analysis.
Statistical analysis
All experiments were performed in
duplicates for each of the five patients. Furthermore, cells of each
donor were divided into two groups: treated and nontreated. Data are
presented as mean?±?standard deviation. Differences between the treated
and nontreated patellar tendon fibroblasts were analyzed using Student’s
t-test. A P value of less than 0.05 was considered statistically significant.
Results
Characterization of the patellar tendon fibroblasts
Patellar tendon fibroblasts were used for cell culture. Characterization of the cells was carried out as described before [32].
Time to closure
A uniform 1.5-cm-wide scrape wound
was observed in every well of the six-well tissue culture plates. The
edges of the wounds were sharply delineated. Damaged cells were observed
in the edges that still adhered to the bottom of the well. On the
consecutive days, the wound area was occupied by fibroblasts. The mean
time for bridging the gap in the nontreated cells was 5.05?±?0.33 days
(Figure 2B).
Treatment with the specific ‘wound healing’ program emitted by Somagen™
device significantly accelerated the bridging time to 3.35?±?0.38 days (P <0.001).
Apoptosis rate
The percentage of Annexin-V positive
cells did not differ between the two groups (nontreated 38.5?±?6.5%
versus Somagen™ device-treated 38.7?±?7.7%) as depicted in Figure 3A.
Figure 3The low-frequency pulsed electromagnetic fields (PEMF) did
not affect the apoptotic rate but significantly increased the
proliferation. Apoptosis level in patellar tendon fibroblasts in the scrape wound after 1 week (B). Apoptosis was measured …
Proliferation
Proliferation was determined by
BrdU incorporation. The obtained values are optical density values
corrected for unspecific backgrounds (Figure 3B).
Untreated cell cultures with scrape wounds showed a mean value of
0.70?±?0.16. A significant increase was observed after application of
the specific ‘wound healing’ program emitted by Somagen™ device
(1.58?±?0.24, P <0.001).
Discussion
We investigated that certain low-frequency PEMF sequences influence in vitro
wound healing of patellar tendon fibroblasts possibly via increasing
the proliferation rate. In a similar model of scrape wounding of human
foreskin fibroblasts, the 0.8-mm-wide gap was closed within 36 hours due
to a preassembled matrix-containing fibrinogen. Moreover, this
accelerated closure of the gap was associated with an 8-fold increase in
3H-thymidine incorporation, indicating a high proliferation rate [10]. Rodemann et al.,
who treated skin fibroblasts with electromagnetic fields, could detect a
significant increase of the collagen synthesis and the protein content [33].
The proliferation capacity of the cells probably plays a role in the
secondary wound healing phase. As noted in similar models using
intestinal epithelial cells or endothelial cells, the rate of cell
proliferation, determined by BrdU incorporation, did not differ between
migrating and stationary cells over the initial 24-h period [34–36].
This indicates that early epithelial and endothelial restitution is
independent of proliferation. After the migration phase that allows
cells to go beyond the wound edges, cells have to proliferate in order
to repopulate the wound area.
These processes are modulated by signal transduction pathways. The second messenger Ca2+ seems to be involved, as brief treatment with increased extracellular Ca2+ during scrape wounding accelerated wound area closure rates by 50% [37,38].
In our study, the tendon fibroblasts display 30% better wound area
closure rates by low-frequency PEMF treatment. The differences may be
due to the different cell origin, namely skin fibroblasts in the
literature and tendon fibroblasts in our study. Furthermore, the
multi-functional signal transducer NF-?B was activated as soon as
30 minutes after scrape wounding [35].
Especially at the wound edges, the subunit p65 was found. Within
5 minutes after wounding, ERK activation was evident. Again, this
activation was particularly prominent in cells residing at the scrape
edge [9].
These signal transduction molecules are important during adaptation and
healing processes of tendon fibroblasts. This has been observed using
cyclic, longitudinal strain in patellar tendon fibroblasts. Fifteen
minutes of strain elicit NF-?B binding to DNA and is associated with
increased proliferation [39,40]. c-fos and JNK are also activated [41]. Therefore, low-frequency PEMF may activate these signal transduction pathways.
These signal transduction pathways are not only involved
in proliferation but also in apoptosis. In our model, 30 to 40%
apoptosis of patellar tendon fibroblasts was observed. This is in
concert with earlier observations using the same type of cells [41].
Treatment with the specific ‘wound healing’ low-frequency PEMF program
did not result in any changes in apoptosis rates. Epithelial cells
showed induction of apoptosis originating at the wound edges, but this
apoptotic effect subsequently spread over a 24-hour period to encompass
areas not originally damaged [42].
Our study included only five replicates; therefore, more
studies are necessary to further investigate the positive effect of
low-frequency PEMF in a larger cohort of samples. Additionally, in vivo studies should confirm these results in a whole organism with tendon pathology.
Nevertheless, the treatment with low-frequency PEMF enhances the wound healing potential of patellar tendon fibroblasts in vitro.
The incidence of tendon and ligament injuries grows due to the
increasingly sports-oriented society. Treatment of such injuries is
still a challenge to orthopedic trauma surgeons as a restitutio ad integrim
can hardly be achieved. Therefore, new modes of treatment are
investigated to improve the outcome of such pathologies. Low-frequency
PEMF seems to have no adverse effects when applied in the human
situation [31]. Furthermore, it is non-invasive, easy to handle, and has a short application time.
Conclusions
These results may be extrapolated
to wound-healing phenomena in other soft tissues, for example skin and
muscle. Wound healing is a complex process involving many different cell
types and coordinated signalling responses, but fibroblasts, as a part
of this complexity, support the healing process and in our study show an
improved wound area closure rate under the influence of low-frequency
PEMF. Thus, low-frequency electromagnetic signals could be an
interesting new treatment option for wound-healing processes in vivo by accelerating closure of the wounds. Based on the positive results, further in vivo studies using low-frequency PEMF generated by the Somagen™ device for modulating wound healing
The authors declare that they have
no competing interests. Sachtleben GmbH provided the Somagen™ device for
this project free of charge. Jens Sachtleben and Karsten Falldorf are
both managing directors of Sachtleben GmbH.
Authors’ contributions
CS and MvG conceived and designed
the study. CS and MvG performed the experiments and analyzed the data.
KF and JS provided data on the device and reviewed the manuscript. All
authors read and approved the final manuscript.
The authors would sincerely like to
thank Sachtleben GmbH for providing the Somagen™ device for this
project. We would also like to thank Fritz Seidl, M.A. Interpreting and
Translating, for proofreading this paper.
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Low frequency pulsed electromagnetic field
(PEMF) has proven to be effective in the modulation of bone and
cartilage tissue functional responsiveness, but its effect on tendon
tissue and tendon cells (TCs) is still underinvestigated. PEMF treatment
(1.5 mT, 75 Hz) was assessed on primary TCs, harvested from
semitendinosus and gracilis tendons of
eight patients, under different experimental conditions (4, 8, 12 h).
Quantitative PCR analyses were conducted to identify the possible effect
of PEMF on tendon-specific gene transcription (scleraxis, SCX and type I
collagen, COL1A1); the release of pro- and anti-inflammatory cytokines
and of vascular endothelial growth factor (VEGF) was also assessed. Our
findings show that PEMF exposure is not cytotoxic and is able to
stimulate TCs’ proliferation. The increase of SCX and COL1A1 in
PEMF-treated cells was positively correlated to the treatment length.
The release of anti-inflammatory cytokines in TCs treated with PEMF for 8
and 12 h was significantly higher in comparison with untreated cells,
while the production of pro-inflammatory cytokines was not affected. A
dramatically higher increase of VEGF-A mRNA transcription and of its
related protein was observed after PEMF exposure. Our data demonstrated
that PEMF positively influence, in a dose-dependent manner, the
proliferation, tendon-specific marker expression, and release of
anti-inflammatory cytokines and angiogenic factor in a healthy human TCs
culture model.
Knee Surg Sports Traumatol Arthrosc. 2008 Jun; 16(6): 595–601.
Published online 2008 Apr 2. doi: 10.1007/s00167-008-0519-9
PMCID: PMC2413121
Effects of biophysical stimulation in patients
undergoing arthroscopic reconstruction of anterior cruciate ligament:
prospective, randomized and double blind study
Francesco Benazzo,1 Giacomo Zanon,1 Luigi Pederzini,2 Fulvio Modonesi,2 Carlo Cardile,3 Francesco Falez,4 Luigi Ciolli,4 Filippo La Cava,4 Sandro Giannini,5 Roberto Buda,5 Stefania Setti,
6 Gaetano Caruso,7 and Leo Massari71IRCCS Foundation, Orthopaedic and Traumatology Department, S. Matteo Hospital Institute, University of Pavia, Pavia, Italy
2Orthopaedic Department of Nuovo Ospedale di Sassuolo, Modena, Italy
3Orthopaedic Department of University of Milano – Bicocca, San Gerardo Hospital, Monza, Italy
4Orthopaedic Department of S. Spirito Hospital Institute, Roma, Italy
5Orthopaedic Department of Rizzoli Orthopaedic Institute, Bologna, Italy
6IGEA, Clinical Biophysics, Via Parmenide 10/A, 41012 Carpi (Mo), Italy
7Department of Biomedical Science and Advanced Therapy, University of Ferrara, Ferrara, Italy
Stefania Setti, Phone: +39-059699600, Fax: +39-059695778, Email: moc.lacidemaegi@ittes.s.
Pre-clinical studies have shown that
treatment by pulsed electromagnetic fields (PEMFs) can limit the
catabolic effects of pro-inflammatory cytokines on articular cartilage
and favour the anabolic activity of the chondrocytes. Anterior cruciate
ligament (ACL) reconstruction is usually performed by arthroscopic
procedure that, even if minimally invasive, may elicit an inflammatory
joint reaction detrimental to articular cartilage. In this study the
effect of I-ONE PEMFs treatment in patients undergoing ACL
reconstruction was investigated. The study end-points were (1)
evaluation of patients’ functional recovery by International Knee
Documentation Committee (IKDC) Form; (2) use of non-steroidal
anti-inflammatory drugs (NSAIDs), necessary to control joint pain and
inflammation. The study design was prospective, randomized and double
blind. Sixty-nine patients were included in the study at baseline.
Follow-up visits were scheduled at 30, 60 and 180 days, followed by
2-year follow-up interview. Patients were evaluated by IKDC Form and
were asked to report on the use of NSAIDs. Patients were randomized to
active or placebo treatments; active device generated a magnetic field
of 1.5 mT at 75 Hz. Patients were instructed to use the stimulator
(I-ONE) for 4 h per day for 60 days. All patients underwent ACL
reconstruction with use of quadruple hamstrings semitendinosus and
gracilis technique. At baseline there were no differences in the IKDC
scores between the two groups. At follow-up visits the SF-36 Health
Survey score showed a statistically significant faster recovery in the
group of patients treated with I-ONE stimulator (P < 0.05). NSAIDs use was less frequent among active patients than controls (P < 0.05). Joint swelling resolution and return to normal range of motion occurred faster in the active treated group (P < 0.05)
too. The 2-year follow-up did not shown statistically significant
difference between the two groups. Furthermore for longitudinal analysis
the generalized linear mixed effects model was applied to calculate the
group × time interaction coefficient; this interaction showed a
significant difference (P < 0.0001) between the active and
placebo groups for all investigated variables: SF-36 Health Survey, IKDC
Subjective Knee Evaluation and VAS. Twenty-nine patients (15 in the
active group; 14 in the placebo group) underwent both ACL reconstruction
and meniscectomy; when they were analysed separately the differences in
SF-36 Health Survey scores between the two groups were larger then what
observed in the whole study group (P < 0.05). The results
of this study show that patient’s functional recovery occurs earlier in
the active group. No side effects were observed and the treatment was
well tolerated. The use of I-ONE should always be considered after ACL
reconstruction, particularly in professional athletes, to shorten the
recovery time, to limit joint inflammatory reaction and its catabolic
effects on articular cartilage and ultimately for joint preservation.Keywords: Anterior cruciate ligament, Chondroprotection, Biophysical stimuli, Pulsed electromagnetic fields, Joint preservation
Introduction
Articular cartilage performs mechanical
functions absorbing the different loads applied to a joint in the course
of daily activity [19].
Homeostasis and mechanical competence of cartilage are regulated by the
activity of the chondrocytes that maintain the function and the
integrity of the extracellular matrix, proteoglycans and collagen.
In consideration of the scant repairability of the
cartilage, even modest damages resulting from trauma or inflammation may
be the starting point for cartilage degeneration leading over time to
extensive lesions that deepen into the thickness of the cartilage
itself, ultimately exposing the subchondral bone tissue [3, 17].
Joint injury may involve synovial tissue, cartilage and
subchondral bone leading to joint inflammation, swelling and pain.
Surgical interventions must certainly be included among the triggers of
inflammatory reaction in a joint [12].
The development of arthroscopic procedures has undoubtedly limited
joint damage associated to surgery for reconstruction of ligaments;
nevertheless, it does not avoid the inflammatory response. Thus, while
arthroscopic procedures make surgery less invasive, the inflammatory
response at the joint remains and the release of pro-inflammatory
cytokines in the synovial fluid is associated with an increase in the
aggrecanase activities that lead to a degradation of the cartilage
matrix, and also inhibit proteoglycan synthesis [11, 15, 18].
To prevent cartilage damage, current pharmacological therapies aim to
control the catabolic effects of the pro-inflammatory cytokines and
enhance anabolic activity, proteoglycan synthesis and proliferation of
chondrocytes. Drugs that combine the above effects are called
chondroprotectors; in this category should be included drugs with A2A
adenosine receptor agonist activity, able to stimulate the
physiological pathways that control inflammation and promote chondrocyte
anabolic activities. Nevertheless, these drugs are in early stages of
clinical testing [5].
Pre-clinical studies have shown that pulsed electromagnetic fields (PEMFs) in vitro favour the proliferation of chondrocytes [6, 16], stimulate proteoglycan synthesis [7] and demonstrate an A2A adenosine receptor agonist activity [20, 21].
Electromagnetic fields in vivo prevent degeneration of articular
cartilage and down-regulate the synthesis and release of
pro-inflammatory cytokines in the synovial fluid [2, 4, 8, 9].
These findings suggest that electromagnetic fields may be used to
control joint inflammation and to stimulate cartilage anabolic
activities, finally resulting in chondroprotection.
A clinical study performed in patients undergoing
arthroscopic treatment for cartilage lesions showed that biophysical
treatment with PEMFs was well tolerated by the patients and led to a
decrease in the use of non-steroidal anti-inflammatory drugs (NSAIDs)
and to an early functional recovery; the positive effect of the
treatment was maintained at a 3-year follow-up [22].
Arthroscopic reconstruction is the
treatment of choice following anterior cruciate ligament (ACL) rupture;
although minimally invasive, the procedure is associated with joint
reaction involving the synovia and it is expected to lead to an increase
of pro-inflammatory cytokines in the synovial fluid with catabolic
effect on articular cartilage. In this study, we evaluated whether the
treatment with PEMFs could be used to control joint inflammatory
response in patients undergoing ACL reconstruction. The end points of
the study were: (1) patients’ functional recovery evaluated by
International Knee Documentation Committee (IKDC) form; (2) use of
NSAIDs, necessary to control joint pain and inflammation.
Materials and methods
Patients and study design
In 2004–2005, 84 patients undergoing ACL
reconstruction were evaluated for inclusion in the study at five
clinical centres. Of these, 69 gave their informed consent to
participate in the study. The prospective randomized and double-blind
study was approved by the local ethical committees. Inclusion criteria
were the following: age between 18 and 45 years, ACL complete lesion
following acute trauma or consequence of ligament chronic degeneration.
All lesions were documented by MRI and confirmed during the
intervention. The following were the exclusion criteria: osteonecrosis
of the femoral condyle, rheumatoid arthritis, autoimmune disease,
systemic disease and patients requiring meniscus repair.
The patients were assigned to the active or placebo group
according to the following randomization criteria: age (18–30 or 31–45),
sex, smoking status, origin of ACL rupture (traumatic or degenerative).
For randomization of patients, a computer-generated schedule was
prepared by a biostatistician. In this process, a random number seed was
entered into the computer to generate a list that assigned equal
numbers of active and placebo stimulators. The minimum number of
patients per group required was calculated by power analysis taking into
account the results of a previous study [22].
Of the 69 patients included, two never
started the therapy, two dropped out within 2 weeks of therapy, and five
did not return at follow-up visits; a total of 60 patients were
therefore available for subsequent analysis. The ACL rupture occurred
during sports activity in 49 patients (24 active and 25 placebo), daily
activity in eight patients (four active and four placebo) and traffic
accident in three patients (three active). At the time of ACL
reconstruction 29 patients underwent also meniscectomy: 15 in the active
group and 14 in the placebo.
Clinical evaluation
The patients were evaluated by IKDC Form
before the intervention and at 30, 60 and 180 days afterwards. The
different parts of the questionnaire, IKDC Current Health Assessment
Form (SF-36 Health Survey), IKDC Subjective Knee Evaluation Form and
IKDC Knee Examination Form were analysed separately. As regards the
scores of the questionnaires, for each subject we considered the changes
at follow-up visits with respect to the values recorded at baseline,
before surgery.
Pain intensity was evaluated by visual analogue scale
(VAS) of 10-cm length: 0 cm no pain, 10 cm maximum pain. The patients
were allowed to use NSAIDs to control knee pain when present and had to
report doing so.
A 2-year follow-up telephone interview
was conducted and the patients were asked: (a) if they had undergone
further surgery at the knee, (b) if they had pain at the knee, (c) if
they had functional limitation in daily activity, (d) if they returned
to previous sport activity level.
Surgical technique
ACL arthroscopic repair was
performed by quadruple hamstrings semitendinosus and gracilis technique.
Tendons were harvested with the tendons stripper through a 2–3 cm
vertical incision on the antero-medial tibial area. Diameter of the
quadruple hamstrings semitendinosus and gracilis tendons was measured,
while the tibial tunnel and same size femoral tunnel (30 mm length) were
prepared. The graft was pulled up through the tibial tunnel with the
knee at 90° of flexion and suspended on the external femoral cortex
(Endobutton, Smith and Nephew, London, UK). Distally, the graft was
fixed with an interference absorbable screw at the tibia at 10° of
flexion.
Rehabilitation
All the patients underwent standard
rehabilitation using passive knee flexion daily. Exercises started
within the third post-operative day with isometric quadriceps
contractions and then progressed to active closed-chain exercises by
4–6 weeks postoperatively. During the first 20 days patients were
instructed to use two crutches and then progressive weight bearing until
the end of the second month.
Biophysical stimulation
The patients were treated with active or
placebo devices. The active stimulators (I-ONE; IGEA, Carpi, Italy)
generated a magnetic field of peak intensity of 1.5 mT at a frequency of
75 Hz; no heat or vibration was felt by the patient during treatment
(Fig. 1).
Fig. 1Left I-ONE PEMFs generator. Right wave form of magnetic field, 1.5 mT peak value (top); electric field induced in a standard coil probe made of 50 turns (0.5 cm ?) of copper wire (0.2 mm ?), peak value 3 mV/cm …
The patients were instructed to use the
stimulator for 4 h per day, not necessarily consecutively, for 60 days.
Treatment started within 7 days from the surgery. Each device contained a
clock to monitor the hours of use.
Statistical analysis
The results were analysed with SPSS 13.0
(Statistical Packages for Social Sciences Inc, Chicago, IL, USA).
Comparison among the continuous variables in the two groups was
performed with Student’s heteroschedastic t test; comparison of continuous variables within each group during follow-up was performed with Student’s paired t test.
Binomial and categorical variables were compared by
contingency tables applying the chi-square test for 2 × 2 tables and the
Cochran Mantel Haenszel test for larger size tables.
Generalized linear mixed effects model was applied to the
SF-36 Health Survey, IKDC Subjective Knee Evaluation and VAS data to
test if a different trend between the two groups was present during
follow-up by correcting for the following covariates: sex, age, weight,
height, hours of treatment, smoking status, use of NSAIDs. In this
analysis, a mathematical model is built which takes into account the
trend over time of individual patients belonging to each group
(Group × Time interaction) and determines if a statistical difference
exists between the groups during the follow-up [10].
The minimum significance level for all the statistical tests was set at P < 0.05.
Results
At baseline, the two groups of study
were homogeneous for age, weight, height, VAS, SF-36 Health Survey and
IKDC Subjective Knee Evaluation score (Table 1).
Average daily treatment was the same in both groups:
3.92 ± 0.5 h/die versus 3.13 ± 0.3 h/die in the I-ONE group and the
placebo group, respectively (P = n.s.).
The average pain was modest and almost absent at 6 months’
follow-up: 0.7 ± 0.2 cm among placebo and 0.9 ± 0.2 cm among active. At
30 days, less patients in the active group used NSAIDs: 8% in the I-ONE
group versus 27% in the placebo group (P < 0.05).
The SF-36 Health Survey score decreased significantly at 30 days, in both groups (P < 0.0005).
At 60 days the mean SF-36 Health Survey score in the I-ONE patients
already exceeded the initial value (by 3.2 points), whereas in the
patients of the placebo group SF-36 Health Survey score was slightly
below the initial mean value (by ?0.7 units). At 6 months a significant (P < 0.005)
increase was observed for SF-36 Health Survey average values in both
groups; the patients of the I-ONE group were above the initial values by
10.1 units, while the placebo group exceeds the baseline value by 7.2
units. The mean changes of SF-36 Health Survey score in the I-ONE group
are systematically higher with respect to placebo during follow-up, P < 0.05 (Fig. 2).
Fig. 2
Mean changes of SF-36 Health Survey (±SE) versus baseline in the two groups (P < 0.05)
The IKDC Subjective Knee Evaluation score increased over
6 months and did not show significant differences between the two groups
at any follow-up visit.
The IKDC Knee Examination Form outlined both groups
including subjects with joint swelling before surgery (one in placebo
and two in I-ONE group, P = n.s.) and at 30 days’ follow-up (five in placebo and six in I-ONE group, P = n.s.).
On day 60, joint swelling was observed in the placebo group (two
patients) only. Joint swelling was not observed any more at 6 months’
follow-up. Limitation in the passive range of motion of the knee was
more frequent in the placebo group than in the I-ONE group (P < 0.05) (Fig. 3).
Fig. 3
Patients with limitation in passive range of motion in the two groups, P < 0.05
Finally, the generalized linear mixed effects analysis revealed a significantly different trend (group × time interaction, P < 0.0001)
between the two groups for SF-36 Health Survey score, IKDC Subjective
Knee Evaluation score and for VAS, showing a positive effect of I-ONE
treatment. The estimate coefficients and significance of independent
variables for three models are displayed in Table 2.
Table 2
Generalized linear mixed effects models in which the dependent
variables considered are: SF-36 Health Survey score, IKDC Subjective
Knee Evaluation score and VAS, respectively
At the 2-year follow-up interview 86% of the
patients in the I-ONE group and 75% in the placebo group reported
complete functional recovery, no knee pain and return to sport activity.
ACL reconstruction and meniscectomy
When the cohort of patients, undergoing
both ACL reconstruction and meniscectomy, was analysed separately, the
SF-36 Health Survey score confirmed the faster recovery trend among
I-ONE treated patients compared to placebo, P < 0.05 (Fig. 4). At 6 months, SF-36 Health Survey average score increase was 11.4 in the I-ONE group (P < 0.005 vs. baseline) and 7.1 in placebo group (P = ns
vs. baseline). Further, the average values of SF-36 Health Survey were
significantly higher in the I-ONE group compared to the placebo
(45.2 ± 1.5 vs. 37 ± 2.7, P < 0.05).
Fig. 4
Patients undergoing ACL and meniscectomy: mean changes of SF-36 Health Survey (±SE) versus baseline in the two groups (P < 0.05)
The percent of patients with limitation
in the passive range of motion was lower in the I-ONE group compared to
the placebo one (34% I-ONE vs. 50% placebo at day 30 and 4% I-ONE vs.
17% placebo at day 60, P < 0.05).
Discussion
Arthroscopic surgery has gained a large
success and led to a significant increase in its use: about 650,000
procedures are performed in the USA each year [14].
However, the access into the joint space is always associated to an
inflammatory reaction that may jeopardize the benefits expected from
surgery. Joint inflammation has a catabolic effect on extracellular
matrix and inhibits chondrocyte activity; thus, all means capable of
locally controlling the inflammation should be adopted to prevent the
onset and limit the progression of cartilage damage. Furthermore, unlike
bone tissue after damage, the cartilage will not completely recover its
competence: once lost, the articular cartilage does not reform [13].
Many efforts are made to develop strategies able to
control joint inflammation and to favour the anabolic activities of
chondrocytes; these are challenging objectives, and up to now the
pharmacological approaches based on the use of drugs, whether by
systemic or by local route, have not yet been able to demonstrate a
genuine chondroprotective effect in humans [19].
Pre-clinical studies have shown PEMFs to have a
chondroprotective effect, mediated by the control of inflammation and by
the stimulation of chondrocyte activity; thus, we hypothesized that
after arthroscopic surgery PEMFs treatment can be used for articular
cartilage protection and ultimately joint preservation.
This prospective, randomized and double-blind study
investigated whether and to what extent the employment of I-ONE, by
controlling joint reaction to arthroscopy, could accelerate functional
recovery in patients undergoing ACL reconstruction. The I-ONE treatment
was well tolerated by the patients and no adverse side effects were
observed. The results show that, at 30 days after surgery, in I-ONE
group significantly fewer patients used NSAIDs to control pain, compared
to patients in the placebo group; afterwards, the use of NSAIDs was not
necessary in either group.
When IKDC Subjective Knee Evaluation average scores were
analysed, we found no statistically significant difference between the
I-ONE and placebo group; this is in agreement with the findings of other
authors who reported that this parameter does not correlate with the
other clinical information collected using the SF-36 Health Survey form [1].
However, when the results of the two groups were analysed by
generalized linear mixed effects model, which takes into account the
trend of each patient in both groups and the effect of confounding
factors, we could evidence a positive significant effect of I-ONE
treatment also in the Subjective Knee Evaluation (Table 2).
The SF-36 Health Survey average scores at baseline were
the same in the I-ONE and placebo groups; however, the high standard
deviation testify the large distribution of initial score values. To
monitor patient’s recovery after ACL reconstruction, we considered the
SF-36 Health Survey score changes with respect to baseline for each
individual subject. At 2 and 6 months SF-36 Health Survey increase is
undoubtedly higher in I-ONE group than in the placebo group. This result
indicates a faster recovery in the treated patients. This positive
effect of I-ONE treatment is confirmed by the generalized linear mixed
effects analysis. Further, when the cohort of patients who underwent
both ACL reconstruction and meniscectomy was analysed, we observed that
the average increase of SF-36 Health Survey at 60 days in the I-ONE
group was the same as that of placebo group at 6 months (6.0 vs. 7.1, P = n.s.).
The IKDC Knee Examination Form showed how in the placebo
group the resolution of joint swelling and the recovery of complete
range of motion occur later compared to the I-ONE group; no significant
difference in scoring was observed among centres.
The study end-points were thus demonstrated: fewer
patients in the I-ONE group required the use of NSAIDs and their
functional recovery was faster.
At 2-year follow-up no statistically significant
difference was observed between two groups, although the percent of
patients with complete recovery was slightly higher in the I-ONE group.
In this study we applied a statistical analysis
specifically developed for longitudinal studies that allows to calculate
the group × time interaction. This test, that considers individual
patient’s score at different time points and the possible influence of
confounding factors, supports the positive effect of I-ONE treatment on
the recovery of patients undergoing ACL reconstruction.
Our data confirm the results reported by Zorzi et al. [22]
in a group of patients treated with I-ONE following an arthroscopic
treatment for cartilage lesions. To the authors’ knowledge, there are no
other reports of use of biophysical stimulation after surgical
procedures of the knee.
Biophysical stimulation allows treating individual joints,
permeating the whole cartilage surface and thickness, the synovia and
the subchondral bone. The effectiveness of biophysical stimulation is
not limited by considerations such as diffusion ability and
concentration gradient, which are present and important in the dynamic
of a pharmacological intervention; joint tissues are paramagnetic, they
do not attenuate the biophysical signal and thus are all homogenously
exposed to the treatment efficacy. Biophysical stimulation is an
effective therapeutic intervention to control the detrimental
consequences of the inflammation over articular cartilage in the absence
of negative side effects.
I-ONE should always be considered after
ACL reconstruction, particularly in professional athletes, to shorten
the recovery time, to limit joint inflammatory reaction and ultimately
for joint preservation.
Acknowledgments
Supported by Igea through a grant of Research funding of
Regione Emilia Romagna. Setti is Igea employ; the other authors have no
conflict of interest.
Open Access This article is distributed
under the terms of the Creative Commons Attribution Noncommercial
License which permits any noncommercial use, distribution, and
reproduction in any medium, provided the original author(s) and source
are credited.
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Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2008 Nov;22(11):1318-22.
Effects of decimeter wave and sodium hyaluronate product on postoperative adhesions in flexor tendon.
[Article in Chinese]
Tian D, Luo J, Zhang Q, Zhang Y, Liu K, Yu K, Han J, Han J.
Department of Hand Surgery, Third Hospital of Hebei Medical University, Shijiazhuang Hebei 050051, PR China.
Abstract
OBJECTIVE: To compare the effect of decimeter wave with sodium
hyaluronate product (SHP) on preventing and treating peritendinous
adhesion and promoting tendon healing.
METHODS: Totally 96 healthy male white 6-month-old Leghorn chickens
weighing (2.24 +/- 0.07) kg were randomized into group A (decimeter wave
therapy group, n = 32), in which decimeter wave therapy was applied 1
to 21 days after operation at a frequency of 915 MHz, a power of 8 W,
radiation distance of 10 cm, for 10 minutes once per day; group B (SHP
group, n = 32), in which 5 mL and 1.2% SHP was applied; and group C
(control group, n = 32), in which injury received no treatment. The III
and IV toes of left feet of all chickens were made into tendon injury
model. The general condition of animal was observed after operation;
gross and histological observations were made 7, 10, 14, 18, 21 and 28
days after operation, and the biomechanical analysis was done 14 and 28
days after operation.
RESULTS: Operative incision healed well, no infection and death
occurred. Peritendinous adhesions in groups A, B were looser, and tendon
healing was better than that of group C 14 and 28 days after operation.
More fibroblasts with active metabolism and more collagen formation in
groups A, B than that in group C. The Pmax of group A was better than
that of group B 14 and 28 days after operation (P < 0.05); the delta
max of group A was better than that of group B 18 and 21 days after
operation (P < 0.05), and the W0 of group A was better than that of
group B 18, 21 and 28 days after operation (P < 0.05). There was no
significant difference between group A and group B at the other time
points.
CONCLUSION: Topical decimeter wave therapy and application of SHP
after flexor tendon repair can promote intrinsic healing, meanwhile they
can prevent the adhesion of tendon and reduce extrinsic healing.
Decimeter wave therapy can improve the qualities of tendon’s wound
healing.
J Hand Surg Am. 2006 Sep;31(7):1131-5.
Pulsed magnetic field therapy increases tensile strength in a rat Achilles’ tendon repair model.
Department of Plastic and Reconstructive Surgery, Albert Einstein
College of Medicine, Montefiore Medical Center, Bronx, NY 10461, USA. bstrauch@montefiore.org
Abstract
PURPOSE: To examine the effect of pulsing electromagnetic fields on
the biomechanic strength of rat Achilles’ tendons at 3 weeks after
transection and repair.
METHODS: This noninvasive modality was tested in a prospective,
randomized, double-blinded, placebo-controlled study to evaluate the
effect of a specific noninvasive radiofrequency pulsed electromagnetic
field signal on tendon tensile strength at 21 days post transection in a
rat model.
RESULTS: In the animals receiving PMF exposure, an increase in
tensile strength of up to 69% was noted at the repair site of the rat
Achilles’ tendon at 3 weeks after transection and repair compared with
nonstimulated control animals.
CONCLUSIONS: The application of electromagnetic fields, configured to
enhance Ca(2+) binding in the growth factor cascades involved in tissue
healing, achieved a marked increase of tensile strength at the repair
site in this animal model. If similar effects occur in humans,
rehabilitation could begin earlier and the risk of developing adhesions
or rupturing the tendon in the early postoperative period could be
reduced.
Radiologe. 2004 Jun;44(6):597-603.
Conservative treatment and rehabilitation of shoulder problems.
The shoulder joint has an important influence on arm- and hand
function. Therefore, activities of daily living, working and leisure
time can be negatively influenced by diseases of the shoulder joint.
Problems of the shoulder joint can be induced by muscular dysbalance and
poor body posture. There is a strong relationship between shoulder
function and body posture. Conservative treatment and rehabilitation of
the shoulder joint aims at improving the local dysfunction of the
shoulder joint as well as at improving function and social
participation. Antiinflammatory and pain medication, exercise,
occupational, electro-, ultrasound and shock wave therapy, massage,
thermotherapy and pulsed electromagnetic fields are used as conservative
treatments. Exercise therapy aims at improving muscular performance,
joint mobility and body posture. Occupational therapy aims at improving
functional movements for daily living and work. Electrotherapy is
primarily used to relieve pain. Shock wave and ultrasound therapy proved
to be an effective treatment for patients with calcific tendinitis. The
subacromial impingement syndrome can be effectively treated by
conservative therapy.
Biomed Sci Instrum. 2002;38:157-62.
Quantitative characterization of rat tendinitis to evaluate the efficacy of therapeutic interventions.
Wetzel BJ, Nindl G, Swez JA, Johnson MT.
Terre Haute Center for Medical Education, Indiana University School
of Medicine, Indiana State University, Terre Haute, IN 47809, USA.
Abstract
Tendinitis is a painful soft tissue pathology that accounts for
almost half of all occupational injuries in the United States. It is
often caused by repeated movements and may result in loss of work and
income. Current treatments for tendinitis are aimed at reducing
inflammation, the major cause of the pain. Although anti-inflammatory
drugs and various alternative therapies are capable of improving
tendinitis, there are no quantitative scientific data available
regarding their impact on inflammation. The objective of this study is
to determine the time course for healing of rat tendinitis without
intervention to be able to assess the efficacy of tendinitis treatments.
We are interested in evaluating the therapeutic use of pulsed
electromagnetic fields (PEMFs), a therapeutic modality that has been
found to be beneficial for healing soft tissue injuries. Tendinitis was
induced in Harlan Sprague Dawley rats by collagenase injections into the
Achilles tendon, and tendons were collected for four weeks post-injury.
To determine the amount of edema, we used caliper measurements of the
rat ankles and quantified the tendon water content. To determine the
extent of inflammation, we estimated the number of inflammatory cells on
histological sections applying stereological methods. The data reveal
that edema is maximal 24 hours after injury accompanied by a massive
infiltration of inflammatory cells. Inflammatory cells are then
gradually replaced by fibroblasts, which are responsible for correcting
damage to the extracellular matrix. This natural time course of tendon
healing will be used to evaluate the use of PEMFs as a possible
therapeutic modality.
Arch Phys Med Rehabil. 1997 Apr;78(4):399-404.
Pulsed magnetic and electromagnetic fields in experimental achilles tendonitis in the rat: a prospective randomized study.
Lee EW, Maffulli N, Li CK, Chan KM.
Department of Orthopaedics and Traumatology, Chinese University of
Hong Kong, Prince of Wales Hospital, Shatin, New Territories, Hong Kong.
OBJECTIVE: To investigate the effects of pulsed magnetic fields (PMF)
and pulsed electromagnetic fields (PEMF) on healing in experimental
Achilles tendon inflammation in the rat.
DESIGN: Prospective randomized trial.
SETTING: University medical school.
METHODS: Exposure of the Achilles tendon and injury by a weight of
98.24 g falling from a height of 35cm in 180 male Sprague-Dawley rats.
INTERVENTION: A daily 15-minute session with PMF of 17Hz or 50Hz, or PEMF of 15Hz or 46Hz, or a sham session.
OUTCOME MEASURES: Random sacrifice 2 hours after the operation, and
at 1, 3, 7, 14, or 28 days. Assessment of water content, weight, and
histological appearance of the tendons.
RESULTS: The time from injury and the various treatment modalities
exerted a significant influence on the water content of the tendon after
the injury (two-way ANOVA, p = .02). At day 3, the water content of the
PEMF 46Hz group was significantly higher than in the other groups,
decreasing sharply by day 7, and being similar to the other groups
thereafter. By the end of the experiment, the PEMF 15Hz group was not
significantly different from the control group. At day 7, the PMF 50Hz
group showed significantly lower water content than the control group (p
= .03), but at 14 days the PMF 50Hz group was not significantly
different from the control group. PMF 50Hz suppressed the extravascular
edema during early inflammation. PMF 17Hz showed a similar initial
trend, producing a consistent lower water content throughout the
experiment, reaching statistical significance by the end of treatment.
By the end of the experiment, the collagen fibers had nearly regained
their normal alignment in all groups, with a more physiological
alignment seen in the PEMF 17Hz group.
CONCLUSIONS: The tendon returned to histological normality in all
groups, but the PMF 17Hz group showed better collagen alignment by the
end of the study. PMF 17Hz resulted in a greater reduction of
inflammation, with a better return of the tendon to histological
normality. Different PMF and PEMF could be applied according to when
treatment is started after the injury. If there is no delay between
injury and beginning of pulsed magnetic treatment, PMF 17 should be
used.
Lancet. 1984 Mar 31;1(8379):695-8.
Pulsed electromagnetic field therapy of persistent rotator cuff tendinitis. A double-blind controlled assessment.
Binder A, Parr G, Hazleman B, Fitton-Jackson S.
The value of pulsed electromagnetic fields (PEMF) for the treatment
of persistent rotator cuff tendinitis was tested in a double-blind
controlled study in 29 patients whose symptoms were refractory to
steroid injection and other conventional conservative measures. The
treated group (15 patients) had a significant benefit compared with the
control group (14 patients) during the first 4 weeks of the study, when
the control group received a placebo. In the second 4 weeks, when all
patients were on active coils, no significant differences were noted
between the groups. This lack of difference persisted over the third
phase, when neither group received any treatment for 8 weeks. At the end
of the study 19 (65%) of the 29 patients were symptomless and 5 others
much improved. PEMF therapy may thus be useful in the treatment of
severe and persistent rotator cuff and possibly other chronic tendon
lesions.
Oxid Med Cell Longev. 2017; 2017: 2181942.
Published online 2017 Sep 12. doi: 10.1155/2017/2181942
PMCID: PMC5613626
Benign Effect of Extremely Low-Frequency
Electromagnetic Field on Brain Plasticity Assessed by Nitric Oxide
Metabolism during Poststroke Rehabilitation
Natalia Cicho,
1 Piotr Czarny, 2 Micha? Bijak, 1 El?bieta Miller, 3 , 4 Tomasz liwiski, 5 Janusz Szemraj, 2 and Joanna Saluk-Bijak 11Department of General
Biochemistry, Faculty of Biology and Environmental Protection,
University of Lodz, Pomorska 141/143, Lodz, Poland
2Department of Medical Biochemistry, Medical University of Lodz, Mazowiecka 6/8, Lodz, Poland
3Department of Physical Medicine, Medical University of Lodz, Pl. Hallera 1, Lodz, Poland
4Neurorehabilitation Ward, III General Hospital in Lodz, Milionowa 14, Lodz, Poland
5Department of Molecular
Genetics, Laboratory of Medical Genetics, Faculty of Biology and
Environmental Protection, University of Lodz, Lodz, Pomorska 141/143,
Lodz, Poland
Nitric oxide (NO) is one of the most
important signal molecules, involved in both physiological and
pathological processes. As a neurotransmitter in the central nervous
system, NO regulates cerebral blood flow, neurogenesis, and synaptic
plasticity. The aim of our study was to investigate the effect of the
extremely low-frequency electromagnetic field (ELF-EMF) on generation
and metabolism of NO, as a neurotransmitter, in the rehabilitation of
poststroke patients. Forty-eight patients were divided into two groups:
ELF-EMF and non-ELF-EMF. Both groups underwent the same 4-week
rehabilitation program. Additionally, the ELF-EMF group was exposed to
an extremely low-frequency electromagnetic field of 40Hz, 7mT, for
15min/day. Levels of 3-nitrotyrosine, nitrate/nitrite, and TNF? in
plasma samples were measured, and NOS2 expression was determined in
whole blood samples. Functional status was evaluated before and after a
series of treatments, using the Activity Daily Living, Geriatric
Depression Scale, and Mini-Mental State Examination. We observed that
application of ELF-EMF significantly increased 3-nitrotyrosine and
nitrate/nitrite levels, while expression of NOS2 was insignificantly
decreased in both groups. The results also show that ELF-EMF treatments
improved functional and mental status. We conclude that ELF-EMF therapy
is capable of promoting recovery in poststroke patients.
1. Introduction
Cardiovascular diseases, including
ischemic stroke (IS), are a serious problem of the modern age, killing 4
million people each year in Europe [1].
Stroke is caused by ischemia of brain tissue. Brain structure damage
occurring during ischemia/reperfusion is due to the generation of
significant amounts of reactive oxygen species and inflammatory
mediators [2].
Damage to brain tissue as a result of a stroke cannot be undone.
However, the most important part of poststroke therapy is immediate and
long-term rehabilitation, considering the enormous plasticity of the
brain [3].
Although extremely low-frequency electromagnetic field (ELF-EMF)
therapy is not a standard treatment in the poststroke rehabilitation,
some authors suggest its increased positive effect on patients [4].
ELF-EMF treatment is based on regeneration, osteogenesis, analgesics,
and anti-inflammatory action. Its biological effect is related to
processes of ion transport, cell proliferation, apoptosis, protein
synthesis, and changes in the transmission of cellular signals [5].
The regenerative and cytoprotective effect of ELF-EMF is based on
mechanism associated with nitric oxide induction, collateral blood flow,
opioids, and heat shock proteins [6].
Nitric oxide (NO) is an unstable, colourless, water-soluble
gas with a short half-life (3–6?sec). The compound has one unpaired
electron, which makes it a highly reactive free radical. It is
characterized by the multiplicity of action in the body, in both
physiological and pathological conditions [7].
Synthesis of NO in the organism is catalysed by nitric oxide synthase
(NOS), occurring in three isoforms: neuronal (nNOS), inducible (iNOS),
and endothelial (eNOS), encoded by different genes whose expression is
subject to varying regulation. The constituent isoforms of NOS are eNOS
and nNOS, whose activity is associated with concentration of calcium
ions and the level of calmodulin in a cell, as well as with hypoxia,
physical activity, and the level of certain hormones, that is,
oestrogens [8].
In contrast, because it is closely related with the calmodulin, iNOS
does not require a high concentration of calcium ions but is regulated
by various endogenous and exogenous proinflammatory factors [9].
The two-stage synthesis of NO consists of the oxidation of
L-arginine to N-hydroxy-L-arginine and, under the influence of NOS and
oxygen, formation of L-citrulline and release of NO. All isoforms of NOS
require the same cofactors: nicotinamide adenine dinucleotide phosphate
(NADPH), flavin mononucleotide (FMN), flavin adenine dinucleotide
(FAD), tetrahydrobiopterin (BH4), iron protoporphyrin IX (heme), and O2[7].
Nitric oxide is one of the most important signal molecules,
involved in both physiological and pathological processes. One of the
major functions of NO is as a potent vasodilation, increasing the blood
flow and regulation of blood pressure, which has been used in clinical
practice for many years. Deficiency of this compound is observed in
various disorders of many systems: cardiovascular, gastrointestinal,
respiratory, and genitourinary [10].
The beneficial effects of NO lie in its platelet inhibition, macrophage
cytotoxicity (antibacterial, antiviral, and antiparasitic), and
protection of the mucosal lining of the digestive system. On the other
hand, excessive expression of iNOS can be disadvantageous, for example,
during sepsis. The adverse action of NO is associated with the
production of superoxide anions and subsequent generation of
peroxynitrite and hydroxyl radicals, which are highly toxic [11].
In the central nervous system, NO as a neurotransmitter
regulates cerebral blood flow, as well as neurogenesis and synaptic
plasticity. Furthermore, neuronal death is caused by high concentrations
of NO by caspase-dependent apoptosis process and promotion of
inflammation. Elevated levels of nitric oxide promote necrosis by energy
depletion. On the basis of these mechanisms, NO is involved in the
etiology of many neurological diseases, such as major depression,
schizophrenia, epilepsy, anxiety, and drug addiction [12].
Our study was designed to investigate the
effect of ELF-EMF on the metabolism of NO, as a signal molecule in the
central nervous system, in the rehabilitation of acute poststroke
patients.
2. Materials and Methods
2.1. Blood Sample Collection
Blood samples were collected into CPDA1-containing
tubes (Sarstedt, Nümbrecht, Germany). Immediately upon doing so, a
portion of the sample was frozen at ?80°C and the rest of the samples
centrifuged to isolate the plasma (15?min, 1500g) at 25°C.
Blood samples were collected twice, at an interval of 14 days before and
after a standard 10 sessions of therapy. For additional analysis of
3-nitrotyrosine levels, the blood samples were collected three times, at
an interval of 28 days: before treatment, after 10 treatments, and
after 20 treatments. All blood samples were taken in the morning
(between 7am and 9am) under patient fasting condition and stored using
the same protocol.
2.2. Subject Presentation
Forty-eight poststroke patients were enrolled in the study. Participants were randomly divided into two groups: ELF-EMF (n = 25) and non-ELF-EMF (n =
23). Patients with metal and/or electronic implants (pacemakers, etc.)
were excluded from the ELF-EMF group, for safety reasons. The ELF-EMF
group had already undergone ELF-EMF therapy with specific parameters
(40Hz frequency, magnetic induction of 5mT (B), rectangular and bipolar waveforms) (Figure 1),
which was conducted using a Magnetronic MF10 generator (EiE Elektronika
i Elektromedycyna, Otwock, Poland). The parameters were selected on the
basis of the fact that low-intensity stimuli improve the vital
functions of the body. In addition, rectangular pulses are more intense
than sinusoidal and trapezoid, while bipolar pulses show more range of
changes than unipolar pulses [13].
The ELF-EMF and non-ELF-EMF groups were treated for the same amount of
time (15minutes). The non-ELF-EMF subjects were given only sham
exposure. The pelvic girdle of the patients was exposed to the
electromagnetic field, because exposure of the head to ELF-EMF can
affect the activation of the epilepsy focus in the brain. The same
therapeutic program was used for both subject groups. This consisted of
aerobic exercise (30min), neurophysiological routines (60?min), and
psychological therapy (15?min). Poststroke patients with moderate stroke
severity according to NIHSS scores of 4.9 ±3.1 in the ELF-EMF group
(aged 48.8 ±7.7) and 5.4 ±2.9 (aged 44.8 ±8.0) in the non-ELF-EMF group
were enrolled in the study. Table 1 shows
the clinical and demographic characteristics. Participants with
haemorrhagic stroke, dementia, chronic or significant acute inflammatory
factors, decreased consciousness, and/or neurological illness other
than stroke in their medical prestroke history were excluded. The
subjects had undergone neurorehabilitation for 4 weeks in
Neurorehabilitation Ward III of the General Hospital in Lodz, Poland, as
well as internal and neurological examinations. The Bioethics Committee
of the Faculty of Biology and Environmental Protection of The
University of Lodz, Poland, approved the protocol with resolution
numbers 28/KBBN-U/II/2015 and 13/KBBN-U/II/2016. All participants
provided written informed consent prior to participation. Depression was
screened in both groups using the Geriatric Depression Scale (GDS).
Cognitive status was estimated in a Mini-Mental State Examination
(MMSE), and functional status using the Barthel Index of Activities of
Daily Living (ADL). The GDS, ADL, and MMSE were administered either on
the same day as the blood sampling or on the afternoon before.
ELF-EMF therapy was performed by a
Magnetronic MF10 generator as per accepted guidelines. This device is
able to produce pulses in rectangular, trapezoid, and sinusoidal shapes.
The pulses were applied using an AS-550 applicator (EiE, Otwock,
Poland), which has the following properties: 550 mm in diameter, 270mm
in length, and 5 layers of 187 turns of 1.45mm twin-parallel wires.
Magnetic induction was set at 5mT. The electromagnetic field intensity
was not uniformed; its distribution is vertical, while the induction
coils are set horizontally. Induction of the electromagnetic field of
5mT is present at the geometric center of the applicator, and the value
increases in the proximity to the surface about 7mT. Other factors that
could affect EMF were eliminated (electronic measuring instruments
occurring in rehabilitation room and other electronic equipment).
2.4. Immunodetection of 3-Nitrotyrosine by c-ELISA
Levels of 3-NT-containing proteins in plasma were determined using a modified c-ELISA method, as described by Khan et al. [14].
96-well microtiter plates were coated with nitro-fibrinogen (nitro-Fg)
(1mg/mL) and kept overnight at 4°C. Concentrations of nitrated proteins
inhibiting the binding of anti-nitrotyrosine antibodies were assessed
from the standard curve (10–100nM nitro-Fg equivalents) and expressed as
nitro-Fg equivalents [15].
2.5. Nitrate/Nitrite Estimation
Plasma samples were diluted twice
before the measurement of nitrate/nitrite concentration using a
Nitrate/Nitrite Colorimetric Assay Kit (Cayman Chemical Company, USA),
based on the two-step Griess method. In the first step, the nitrate is
converted to nitrite with nitrate reductase, while in the second step,
after addition of the Griess reagent, the nitrite is converted to a deep
purple azo compound. The absorbance measurement was performed at 540nm
in a 96-well microplate reader (SPECTROstarNano, BMG Labtech, Ortenberg,
Germany) [16].
2.6. Determination of NOS2 Expression in Whole Blood Samples
RNA was isolated from the frozen
whole blood samples (?80°C), in accordance with the manufacturer’s
protocol using TRI Reagent® (Sigma-Aldrich, USA). The aqueous phase was
purified in accordance with the manufacturer’s protocol using an
InviTrap Spin Universal RNA Mini Kit (Stratec Biomedical Systems,
Germany). The purity and quantity of isolated RNA were assessed using a
Synergy HTX Multi-Mode Microplate Reader equipped with a Take3
Micro-Volume Plate and connected to a PC running Gen5 Software (BioTek
Instruments Inc., Winooski, VT, USA). Isolated RNA (20ng/L) was
transcribed onto cDNA with a High-Capacity cDNA Reverse Transcription
Kit (Applied Biosystems™, Waltham, MA, USA). Quantitative assays were
executed using a TaqMan Hs01075529_m1 probe for human NOS2 genes and an Hs02786624_g1 for endogenous control, which was GAPDH (Life
Technologies). Reactions were carried out using a TaqMan Universal
Master Mix II, without UNG (Life Technologies) in a BioRad CFX96
real-time PCR system (BioRad Laboratories, Hercules, CA, USA), all in
accordance with the manufacturers’ protocols. Relative expression of NOS2 was obtained using the equation 2Ct, where Ct is the threshold cycle (Ct) value for the target gene minus Ct values obtained for the housekeeping gene GAPDH [17].
2.7. Determination of TNF?
Measurements of human tumour
necrosis factor alpha (TNF?) in plasma samples were made with a Human
TNF? ELISA development kit (MABTECH, Cincinnati, OH, USA), in accordance
with the manufacturer’s protocol. The combination of two coating
antibodies (TNF3 and TNF4) were used for the analysis. The absorbance
was measured at 450nm, and TNF? concentration was expressed as pg/mL [18].
2.8. Data Analysis
Biochemical and clinical data were
expressed as mean ±SD. All measurements were executed in duplicate.
Output value (100%) was determined for each measured parameter of each
patient before treatment. Data from tests performed on the same study
subjects after therapy constituted a percentage of the output value.
Percentage values were presented as mean ± SD. Statistical analyses were
performed using the Statistica 12 statistical software (StaftSoft
Inc.). A Shapiro-Wilk test was used to analyse for normality. A paired
Student t-test was used to the calculate differences between
the values obtained for subjects before and after therapy, whereas
unpaired Student t-test or Mann–Whitney U tests were used to determine differences between the ELF-EMF and non-ELF-EMF groups. p values of 0.05 were accepted as statistically significant for all analyses.
3. Results
Our comparative analysis demonstrated an increased level of 3-nitrotyrosine (3-NT) (p< 0.05) (Figure 2) and an elevated nitrate/nitrite concentration (p < 0.01) (Figure 3)
in the plasma of patients from the ELF-EMF group. The gain in the 3-NT
level was significantly higher with an increased amount of sessions (Figure 2).
In the non-ELF-EMF group, we saw that the effect of rehabilitation on
nitrative stress was largely weaker and not statistically significant (p > 0.05) (Figures (Figures22 and and3).3). The 3-NT level increased more in the ELF-EMF group than in the non-ELF-EMF after 10 treatments (68% versus 17%, p < 0.05) (Figure 2).
The level of nitrate/nitrite in the non-ELF-EMF group even decreased
after 10 treatments (although not statistically significantly) (Figure 3).
Figure 2
The comparison of 3-NT levels in plasma proteins obtained from the
ELF-EMF group versus those from the non-ELF-EMF group. Statistical
significance between the ELF-EMF and non-ELF-EMF groups: B versus D (p < 0.05).
Figure 3
The comparison of nitrate/nitrite levels in plasma proteins
obtained from the ELF-EMF group versus those from the non-ELF-EMF group.
Statistical significance between ELF-EMF and non-ELF-EMF groups: B
versus D (p < 0.05).
In the next set of experiments, we determined the effect of magnetotherapy on gene expression in the whole blood samples of NOS2 mRNA.
Its expression was unmeasurable in 35% of subjects from both the
ELF-EMF and non-ELF-EMF groups. We observed a statistically
insignificant decrease in the level of NOS2 mRNA expression after treatment in both the ELF-EMF and non-ELF-EMF groups (Figure 4).
Figure 4
The comparison of NOS2 mRNA expression obtained from the ELF-EMF group versus that from the non-ELF-EMF group.
Subsequently, we determined the concentration of proinflammatory cytokine TNF?.
We found that the concentration of TNF? was comparable before treatment
in both the ELF-EMF and non-ELF-EMF-groups. The cytokine level did not
change in either groups after rehabilitation (Figure 5).
Figure 5
The comparison of TNF? levels in plasma proteins obtained from the ELF-EMF group versus those from the non-ELF-EMF group.
The ADL, MMSE, and GDS were used to evaluate the
functional and mental status of poststroke patients undergoing
rehabilitation. We demonstrated that treatment using ELF-EMF improves
their clinical parameters, particularly in cognitive and psychosomatic
functions.
Motor abilities estimated by ADL score changed at similar
levels in both groups, with the observed improvement being statistically
significant in all rehabilitated patients (p < 0.001) (Table 2).
Table 2
Clinical parameters: ADL, MMSE, and GDS measured in the ELF-EMF and
non-ELF-EMF groups. Data presented as the delta of a clinimetric scale
before and after the standard series of treatments ADL=the increase of
ADL; MMSE= the …
The baseline MMSE values before treatment in both groups were comparable, but statistically different (p < 0.05) after rehabilitation. After 2 weeks of rehabilitation, MMSE parameters improved markedly in the ELF-EMF group (p = 0.002), while a small increase in the non-ELF-EMF group was not statistically significant (p = 0.2) (Table 2).
Depression syndrome expressed by GDS
improved significantly in both groups after rehabilitation. However, the
GDS value reached about a 60% lower result in the ELF-EMF group than in
the non-ELF-EMF group (p = 0.018), starting from a similar base level in both groups (p > 0.05) (Table 2).
4. Discussion
In this study, we provide the evidence
that application of extremely low-frequency electromagnetic field
increases nitric oxide generation and its metabolism, as well as
improving the effectiveness of poststroke ischemic patients’ treatments.
Ischemic stroke is one of the major causes of morbidity
and mortality in the world’s population and is one of the main causes of
long-term disability. The mechanisms of neurological function recovery
after brain injury associated with neuroplasticity (cortical
reorganization) are still insufficiently understood. Poststroke
neurorehabilitation is designed to provide external stimuli, improving
the effectiveness of compensatory plasticity [19].
In the central nervous system, NO is both a pre- and
postsynaptic signal molecule. The activity of NO is associated with a
cGMP-mediated signalling cascade. The presynaptic excitatory action of
NO is related to the phosphorylation of synaptophysin by the
cGMP-dependent protein kinase G (PKG) pathway and the subsequent
potentates of glutamatergic neurotransmission [20].
On the other hand, NO causes a neurotransmission inhibition through
gamma-aminobutyric acid- (GABA-) ergic synaptic communication. It is
associated with ion exchange and regulation of membrane excitation [21, 22].
Moreover, NO as an important vasodilation factor mediates neurovascular
coupling. The enlargement of vessel diameter is caused by increasing
metabolic consumption as a result of neuronal activity. Neurovascular
coupling maintains functional and structural brain integrity [23].
This study was designed to investigate the impact of
ELF-EMF on the metabolism of nitric oxide in the rehabilitation of acute
poststroke patients.
In our study, we demonstrate that poststroke
rehabilitation increases the level of 3-NT and nitrate/nitrite
concentrations. Due to its vasodilating and proangiogenic effects, NO
serves as a protective function during cerebral ischemia. Su et al.
investigated the role of simvastatin-regulated TRPV1 receptors
(transient receptor potential vanilloid type 1) in NO bioavailability,
activation of eNOS, and angiogenesis in mice. They demonstrated that
simvastatin causes an influx of calcium ions through the TRPV1-TRPA1
(transient receptor potential ankyrin 1) pathway, which then causes
activation of CaMKII (Ca2+/calmodulin-dependent protein
kinase II). This then enhances the formation of the TRPV1-eNOS complex,
which also includes CaMKII, AMPK (5AMP-activated protein kinase), and
Akt (protein kinase B), which leads to activation of eNOS, production of
NO, and thus the promotion of endothelial angiogenesis [24]. There have been numerous reports of the protective effects of NO against inflammation and oxidative stress [25].
Transgenic eNOS-deficient mice demonstrated a more extensive infarct of
the middle cerebral artery (MCA), compared to controls [26].
NO effects on the regulation of endothelial integrity,
anti-inflammatory and anti-apoptotic effects, as well as maintenance of
cerebral blood flow, inhibition of platelet aggregation, and reduction
of leukocyte adhesion [25, 27].
Khan et al. studied structurally different NO donors as agents of
cerebrovascular protection in experimentally induced stroke in rats.
They showed that NO donors promote cerebral blood flow through
S-nitrosylation and may be an effective drug for acute stroke [28, 29].
Furthermore, Greco et al. proved the protective effect of
nitroglycerin (donors of NO) on cerebral damage induced by MCA occlusion
in Wistar rats. They observed a significant reduction in stroke volume
in preinjected rats compared to their control group, which confirms the
protective effect of nitroglycerin in vivo. They speculated
that the mechanism of action is associated with the generation of a
complex chain of phenomena, triggering activation of apoptosis and
subsequent activation of antiapoptotic responses [30].
The biological action of ELF-EMF is still being
investigated. It is suggested that ELF-EMF has an impact on the
physicochemical properties of water, the liquid crystal structure
generated by cholesterol, and its derivatives [31, 32].
Changes in ion balance caused by ELF-EMF appeal to the structure of
tissue with piezoelectric and magnetostrictive properties, free
radicals, diamagnetic molecules, and uncompensated magnetic spins of
paramagnetic elements [33]. Therefore, ELF-EMF causes depolarization of cells having the ability to spontaneously depolarize, predominantly through Ca2+ influx [34].
In our previous study, we investigated the effect of ELF-EMF on
oxidative stress in patients after ischemic stroke. We demonstrated that
ELF-EMF causes activation of antioxidant enzymes [35], which leads to reduction of the oxidative modification of plasma protein (this is detailed in an article published in Advances in Clinical and Experimental Medicine).
As a highly reactive molecule, NO can also regulate the level of
oxidative stress. Through the covalent interaction, NO influences the
activity of various enzymes. Mechanisms of this modulation can be
varied: NO reacts with coenzymes and active centers containing metal
ions and interacts with cysteine residues of proteins [36].
In the current study, we observed that in the ELF-EMF group, the level of plasma 3-NT was increased (Figure 2). The formation of 3-NT in protein molecules occurs in vivo by
the action of nitrating agents on the polypeptide chain. The formation
of 3-NT is mainly attributed to NO and superoxide anions (O2??), which react rapidly to form peroxynitrite (ONOO?). This is one of the major oxidizing and nitrating agents produced in vivo in
acute and chronic inflammation, as well as in ischemia/reperfusion.
Endothelial cells, macrophages, and neutrophils release large amounts of
NO and O2?. Thus, increased amounts of NO contribute to the creation of 3-NT [37].
To investigate the effect of ELF-EMF on NO metabolism, we
determined nitrate/nitrite concentrations in plasma. We showed that in
the ELF-EMF group, the level of nitrate/nitrite compounds in plasma
increased after treatment (Figure 3), and these results correspond with the data presented by Chung et al. [38].
The authors investigated the effects of ELF-EMF (60Hz, 2mT) on the
level of NO, biogenic amines, and amino acid neurotransmitters in the
hippocampus, cortex, thalamus, cerebellum, and striatum in rats. They
found a significant increase in NO concentration in the hippocampus,
thalamus, and striatum. Moreover, ELF-EMF also caused a change in the
level of biogenic amines and amino acid neurotransmitters in the brain.
However, the observed effect and range were different, depending on the
brain area. Balind et al. determined the effect of ELF-EMF (50Hz, 0.5mT)
on oxidative stress in gerbils with induced cerebral ischemia. They
measured the level of NO using the Griess reagent and showed an
increased level of NO, provoked by electromagnetic fields. Moreover,
ELF-EMF reduces oxidative stress generated during cerebral ischemia,
thus leading to a decrease in the damaged brain tissue [39].
NO is produced from L-arginine with the involvement of
nitric oxide synthase. Three NOS isoforms are expressed in different
tissues. Although, in the blood, only NOS2 is expressed, in 35% of the
subjects in both the ELF-EMF and non-ELF-EMF groups, mRNA expression of NOS2 was under detection. In the remaining patients, the expression of NOS2 had
not significantly changed after treatment. The NOS2 gene in fact
encodes for iNOS, which is primarily activated during inflammation. In
order to exclude deeper inflammation, we measured the concentration of
TNF?, one of the main proinflammatory cytokines. TNF? is a
pleiotropic cytokine that is involved in nearly all phenomena of
inflammatory responses: initiating chemokine synthesis, promoting the
expression of adhesion molecules, promoting the maturation of dendritic
cells, and inducing the production of inflammatory mediators and other
proinflammatory cytokines [40].
TNF? stimulates collagenase synthesis in synovial fibroblasts and
synovial cartilage chondrocytes and activates osteoclasts, leading to
joint cartilage damage, hypertrophy, bone resorption and erosion, and
angiogenesis. It also activates monocytes and macrophages, enhancing
their cytotoxicity and stimulating cytokine production. Chemokines and
growth factors are responsible for T cell proliferation, proliferation
and differentiation of B lymphocytes, and the release of inflammatory
cytokines by the lymphocytes. Moreover, in the hypothalamus, TNF?
stimulates prostaglandin E and IL-1 synthesis [41].
Pena-Philippides et al. investigated the effect of pulsed
electromagnetic fields on injury size and neuroinflammation in mice
after middle cerebral artery occlusion (MCAO). They found, using
magnetic resonance imaging (MRI), that EMF reduced infarct size, as well
as changed expression of genes encoding pro- and anti-inflammatory
cytokines in the hemisphere with ischemic injury. After EMF exposure,
genes encoding IL-1 and TNF superfamily were downregulated, while IL-10 expression
was upregulated. Thus, the authors suggested that application of EMF to
poststroke patients could have been beneficial through
anti-inflammatory effect and reduction of injury size [42].
On the basis of our results, we suggest that the observed
increase in NO level is associated with nNOS and/or eNOS activities, but
not with iNOS expression. Our research is consistent with evidence
shown by Cho et al., who established that ELF-EMF (60Hz, 2mT) increased
the expression and activation of nNOS in rat brains [43].
The activities of nNOS and eNOS depend on calcium ions.
There are many reports that the biological effect of ELF-EMF is related
to the control of calcium channels [44–48].
In view of these findings, the observed mechanism of increased NO
generation and metabolism may be associated with calcium-ion flux.
Additionally, we noticed that ELF-EMF treatment enhances the effectiveness of poststroke rehabilitation (Table 2).
Some researchers suggest that electromagnetic fields have a beneficial
effect on ischemic/reperfusion injury, and in some places, therapeutic
programs using ELF-EMF are considered to be standard therapy for
poststroke patients [49, 50].
The beneficial effects of ELF-EMF include the following: improvement in
the transport of cellular and mitochondrial membranes; normalization of
blood rheological values; counteraction of tissue oxidation;
intensification of regenerative processes; stimulation of axon growth in
undamaged neurons; intensification of neuronal dissociation and
differentiation; reduction of stress-induced emotional reactions and
free radicals; acceleration of the return of fibre function in
functional disorders; reduction of periapical scarring; and increase of
the level of energetic substances in the brain tissue and erythrocytes [48–53].
Grant et al. estimated the impact of low-frequency pulsed
electromagnetic field on cerebral ischemia in rabbit. They observed
using MRI that exposure to electromagnetic field caused extenuation of
cortical ischemia oedema and reduction of neuronal injury in cortical
area [54].
In conclusion, ELF-EMF therapy increases
the metabolism and generation of NO, which has both neuroprotective and
cytotoxic properties. An increase in NO level is probably associated
with nNOS and/or eNOS activities, but not with iNOS expression, which
increases mainly during inflammation. We suggested that in poststroke
patients, NO demonstrated a protective effect due to significant
improvement in patient functional status. Thus, our studies promote the
validity of this method in poststroke rehabilitation therapy.
Acknowledgments
This study was supported by the Department of General
Biochemistry, Faculty of Biology and Environmental Protection,
University of Lodz (no. 506/1136), and Laboratory of Medical Genetics,
Faculty of Biology and Environmental Protection, University of Lodz (no.
B161100000004601), and Grants for Young Scientists and PhD Students,
Faculty of Biology and Environmental Protection, University of Lodz
(B1611000001145.02).
Conflicts of Interest
The authors declare that there is no conflict of interest regarding the publication of this article.
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Neurosci Behav Physiol. 2010 Oct;40(8):920-5.
The potential of transcranial magnetotherapy in color and rhythm therapy in the rehabilitation of ischemic stroke.
Sholomov II, Cherevashchenko LA, Suprunov OV, Raigorodskii YM.
Saratov State Medical University, Saratov, Russia.
Abstract
A total of 116 patients with ischemic stroke were studied during the
early recovery period. The patients were divided into four groups –
three experimental groups and one control group. Of these, 87 patients
in the first three groups received transcranial magneto- and/or color
and rhythm therapy (TcMT, CRT) along with traditional treatment, while
the 29 patients of the control group received basal treatment only. TcMT
was performed using a bitemporal method, with a running field regime
with a modulation frequency of 1-10 Hz. CRT consisted of an alternating
scheme of stimulation of the left and right eyes with green and/or blue
light with a period of 2-4 sec and an on time of 1 sec. Each of the
three experimental groups (group 1 received TcMT, group 2 received CRT,
and group 3 received TcMT + CRT) received two courses of treatment
separated by 1.5 months. After treatment, all experimental groups,
particularly group 3, showed more marked improvements than the control
group. Regression of neurological symptomatology on the Lindmark scale
in group 3 was 9.5% greater than that in controls; improvements in
impairments to activity and self-care ability on the Barthel scale were
greater by 8.8%; memory and intellectual changes were also seen on the
MMSE and the Luriya and Schulte tests. Rheography and
electroencephalography demonstrated significant improvements in
hemodynamics and alpha-rhythm differentiation and a 14.6% reduction in
the proportion of patients with dysrhythmia in group 3 compared with the
control group. The best result on all measures were obtained in
patients given the combination of TcMT and CRT; TcMT had the greater
influence on hemodynamics, while CRT had the greater effect on
psychoemotional status. Both treatments were well tolerated and produced
no side effects.
Clin Neurophysiol. 2010 Mar;121(3):441-7. Epub 2010 Jan 13.
Reduced motor cortex plasticity following inhibitory rTMS in older adults.
Todd G, Kimber TE, Ridding MC, Semmler JG.
Discipline of Physiology, School of Molecular and Biomedical Science, The University of Adelaide, Adelaide, SA, Australia. gabrielle.todd@adelaide.edu.au
Abstract
OBJECTIVE: Ageing is accompanied by diminished practice-dependent
plasticity. We investigated the effect of age on another plasticity
inducing paradigm, repetitive transcranial magnetic stimulation (rTMS).
METHODS: Healthy young (n=15; 25+/-4 years) and old (n=15; 67+/-5
years) adults participated in two experiments. Motor evoked potentials
(MEPs) were measured in the target muscle (first dorsal interosseus,
FDI) and a remote muscle (abductor digiti minimi) during a set of single
stimuli. Subjects then received real or sham inhibitory rTMS
(intermittent subthreshold trains of 6Hz stimulation for 10min). MEPs
were measured for 30min after rTMS.
RESULTS: In young adults, MEPs in the target FDI muscle were
approximately 15% smaller in the real rTMS experiment than in the sham
rTMS experiment (P<0.026). In old adults, FDI MEP size did not differ
between experiments.
CONCLUSIONS: Advancing age is associated with reduced efficacy of inhibitory rTMS.
SIGNIFICANCE: This work has important implications for the potential therapeutic use of rTMS in stroke and neurological disease.
Zh Nevrol Psikhiatr Im S S Korsakova. 2009;109(7):23-8.
Possibilities of transcranial magnetic therapy and color and rhythm therapy in rehabilitation of ischemic stroke.
[Article in Russian]
Sholomov II, Cherevashchenko LA, Suprunov OV, Ra?gorondski? IuM.
Abstract
One hundred and sixteen post-stroke patients were studied in the
early rehabilitation period. All patients were divided into 4 groups: 3
main and 1 control groups. Three main groups (87 patients) received
transcranial magnetic therapy (TMT) and/or color and rhythm therapy
(CRT) along with traditional treatment and the control group (29
patients) received only basic therapy. TMT was conducted using
bitemporal technique, running regime with modulation frequency 1-10 Hz.
In CRT, the alternating stimulation of the right and left eye with green
and/or blue color with a period of 2-4 s and duration of luminescence
1s was applied. Each of 3 main groups received 2 treatment sessions with
an interval of 1,5 month (1st – TMT, 2nd – CRT, 3rd – TMT + CRT). After
the treatment, the marked positive changes were seen in all main
groups, in particular in group 3. The improvement of neurologic symptoms
on the B. Lindmark scale was higher by 9,5% in group 3 compared to the
control one, on the Barthel index – by 8,8%, on MMSE and A. Luria and
Schulte test – by 5,4 and 14,3%, respectively. Rheographic and
encephalographic study revealed the significant improvement of
hemodynamics and alpha-rhythm differentiation, decrease of patients with
dysrhythmia by 14,6% in group 3 as compared to the control group. The
best results were seen in the combination of TMT and CRT, TMT exerted a
higher effect on the hemodynamics and CRT – on the psychoemotional
state. Both therapies were well tolerated and had no side-effects.
Stroke. 2009 Jan;40(1):309-12. Epub 2008 Oct 9.
Safety and behavioral effects of high-frequency repetitive transcranial magnetic stimulation in stroke.
Yozbatiran N, Alonso-Alonso M, See J, Demirtas-Tatlidede A, Luu D, Motiwala RR, Pascual-Leone A, Cramer SC.
Abstract
BACKGROUND AND PURPOSE: Electromagnetic brain stimulation might have
value to reduce motor deficits after stroke. Safety and behavioral
effects of higher frequencies of repetitive transcranial magnetic
stimulation (rTMS) require detailed assessment.
METHODS: Using an active treatment-only, unblinded, 2-center study
design, patients with chronic stroke received 20 minutes of 20 Hz rTMS
to the ipsilesional primary motor cortex hand area. Patients were
assessed before, during the hour after, and 1 week after rTMS.
RESULTS: The 12 patients were 4.7+/-4.9 years poststroke (mean+/-SD)
with moderate-severe arm motor deficits. In terms of safety, rTMS was
well tolerated and did not cause new symptoms; systolic blood pressure
increased from pre- to immediately post-rTMS by 7 mm Hg (P=0.043); and
none of the behavioral measures showed a decrement. In terms of
behavioral effects, modest improvements were seen, for example, in grip
strength, range of motion, and pegboard performance, up to 1 week after
rTMS. The strongest predictor of these motor gains was lower patient
age.
CONCLUSIONS: A single session of high-frequency rTMS to the motor
cortex was safe. These results require verification with addition of a
placebo group and thus blinded assessments across a wide spectrum of
poststroke deficits and with larger doses of 20 Hz rTMS.
Lancet Neurol. 2008 Jun;7(6):507-13. Epub 2008 May 1.
Contralesional repetitive transcranial magnetic stimulation for
chronic hemiparesis in subcortical paediatric stroke: a randomised
trial.
Kirton A, Chen R, Friefeld S, Gunraj C, Pontigon AM, Deveber G.
Division of Neurology, Department of Pediatrics, Alberta Children’s Hospital, University of Calgary, Calgary, Canada. adam.kirton@calgaryhealthregion.ca
Abstract
BACKGROUND: Arterial ischaemic stroke (AIS) can cause disabling
hemiparesis in children. We aimed to test whether contralesional,
inhibitory repetitive transcranial magnetic stimulation (rTMS) could
affect interhemispheric inhibition to improve hand function in chronic
subcortical paediatric AIS.
METHODS: Patients were eligible for this parallel, randomised trial
if they were in the SickKids Children’s Stroke Program and had
subcortical AIS more than 2 years previously, had transcallosal sparing,
were more than 7 years of age, had hand motor impairment, had no
seizures or dyskinesia, and were taking no drugs that alter cortical
excitability. Patients were paired for age and weakness and were
randomised within each pair to sham treatment or inhibitory,
low-frequency rTMS over contralesional motor cortex (20 min, 1200
stimuli) once per day for 8 days. An occupational therapist did
standardised tests of hand function at days 1 (baseline), 5, 10, and 17
(1 week post-treatment), and the primary outcomes were changes in grip
strength and the Melbourne assessment of upper extremity function
(MAUEF) between baseline and day 10. Patients, parents, and occupational
therapists were blinded to treatment allocation. Analysis was per
protocol.
FINDINGS: Ten patients with paediatric stroke were enrolled (median
age 13.25 [IQR 10.08-16.78] years, mean time post-stroke 6.33 [SD 3.56]
years): four with mild weakness, two with moderate weakness, and four
with severe weakness. A repeated-measures ANOVA showed a significant
interaction between time and the effect of treatment on grip strength
(p=0.03). At day 10, grip strength was 2.28 (SD 1.01) kg greater than
baseline in the rTMS group and 2.92 (1.20) kg less than baseline in the
sham group (p=0.009). Benefits in mean grip strength persisted at day 17
(2.63 [0.56] kg greater than baseline with rTMS and 1.00 [0.70] kg less
than baseline with sham treatment; p=0.01). Day 10 MAUEF score improved
by more in the rTMS group than in the sham group (7.25 [3.8] vs 0.79
[1.3] points greater than baseline; p=0.002), but this benefit did not
persist to day 17. Function of the unaffected hand remained stable. rTMS
was well tolerated with no serious adverse events.
INTERPRETATION: Contralesional inhibitory rTMS was safe and feasible
for patients with paediatric subcortical AIS, and seemed to improve hand
function in patients with hemiparesis. Further studies are required to
confirm the potential role of rTMS in paediatric neurorehabilitation.
FUNDING: Canadian Stroke Consortium; Canadian Institutes of Health
Research; American Academy of Neurology Foundation; Alberta Heritage
Foundation for Medical Research.
Arch Neurol. 2008 Jun;65(6):741-7.
Effects of low-frequency repetitive transcranial magnetic
stimulation of the contralesional primary motor cortex on movement
kinematics and neural activity in subcortical stroke.
Nowak DA, Grefkes C, Dafotakis M, Eickhoff S, Küst J, Karbe H, Fink GR.
Department of Neurology, University Hospital Cologne, University of Cologne, Kerpener Strasse 62, D-50924 Cologne, Germany. dennis.nowak@uk-koeln.de
Abstract
BACKGROUND: Following the concept of interhemispheric competition,
downregulation of the contralesional primary motor cortex (M1) may
improve the dexterity of the affected hand after stroke.
OBJECTIVE: To determine the effects of 1-Hz repetitive transcranial
magnetic stimulation (rTMS) of the contralesional M1 on movement
kinematics and neural activation within the motor system in the subacute
phase after subcortical stroke.
DESIGN: Crossover investigation.
SETTING: A university hospital.
METHODS: Fifteen right-handed patients with impaired dexterity due to
subcortical middle cerebral artery stroke received 1-Hz rTMS for 10
minutes applied to the vertex (control stimulation) and contralesional
M1. For behavioral testing, patients performed finger and grasp
movements with both hands at 2 baseline conditions, separated by 1 week,
and following each rTMS application. For functional magnetic resonance
imaging, patients performed hand grip movements with their affected or
unaffected hand before and after each rTMS application.
RESULTS: Application of rTMS to the contralesional M1 improved the
kinematics of finger and grasp movements in the affected hand. At the
neural level, rTMS applied to the contralesional M1 reduced overactivity
in the contralesional primary and nonprimary motor areas. There was no
significant correlation between the rTMS-induced reduction in blood
oxygen level-dependent responses within the contralesional M1 and the
degree of behavioral improvement of the affected hand. Overactivity of
the contralesional dorsal premotor cortex, contralesional parietal
operculum, and ipsilesional mesial frontal cortex at baseline predicted
improvement of movement kinematics with the affected hand after rTMS of
the contralesional M1.
CONCLUSION: The functional magnetic resonance imaging data suggest
that rTMS of the contralesional M1 may normalize neural activation
within the cortical motor network after subcortical stroke. Identifying
patients suitable for rTMS intervention based on individual patterns of
cortical activation may help to implement rTMS in motor rehabilitation
after stroke.
Przegl Lek. 2007;64(2):74-7.
Effect of low frequency magnetic fields used in magnetotherapy and
magnetostimulation on the rehabilitation results of patients after
ischemic stroke.
New methods of rehabilitation should be introduced in order to reduce
disability resulting from stroke. During the twelve months of
follow-up, effect of low frequency magnetic field (If mf) on the course
of patient rehabilitation following ischemic stroke was evaluated on
in-patient (acute and subacute period of the stroke) and outpatient
(chronic period) basis with the use of Mathew et al’s and Barthel’s
scales. Lf mf (20 procedures of 20-min. duration) of magnetotherapy (I
group–placebo, II–group 5.6 mT induction, 10 Hz frequency and sinusoidal
shape, III group–2.8 mT induction, 10 Hz frequency and sinusoidal
shape) and magnetostimulation (IV group–M1P1 program of Viofor JPS
system, 16 min a day) was applied as early as in the subacute period of
the stroke (1-8 weeks). The data obtained were presented in the form of
percentage changes in the pain levels as well as in the form of the
arithmetical mean and standard deviation (X +/- SD). The ANOVA test was
used for a statistical evaluation of the data obtained in the tests. The
results obtained indicate beneficial effects of If mf in the III and IV
group of patients in the Barthel’s scale and Mathew scale, which were
observed during the examination 12 months after the stroke. The
recommended doses of If mf seem to be adequate to obtain therapeutic
effects and may be used in the early period of rehabilitation. The
neurological and functional improvement persisted for a long-period of
the out-patient treatment, which was confirmed during the control
examination 12 months after the ischemic stroke. As no adverse effects
(which could be attributed to If mf), were observed, this method of
physical therapy can be recognized as a safe one and worth making
popular in clinical practice.
Restor Neurol Neurosci. 2007;25(5-6):461-5.
Improvement of dexterity by single session low-frequency repetitive
transcranial magnetic stimulation over the contralesional motor cortex
in acute stroke: a double-blind placebo-controlled crossover trial.
PURPOSE: Increasing evidence suggests that the contralesional motor
cortex (M1) inhibits the ipsilesional M1 in stroke patients. This
inhibition could impair motor function of the affected hand. We
investigated if inhibitory 1~Hz repetitive transcranial magnetic
stimulation (rTMS) over the contralesional M1 improved motor performance
of the affected hand in acute stroke.
METHODS: A double-blind study of real versus placebo rTMS was
conducted. Twelve patients early after subcortical stroke (mean: 7 days)
received 1200 stimuli of real and placebo rTMS in a crossover design.
The sequence of stimulations was counterbalanced across subjects.
Stimulus intensity was subthreshold (90% of motor threshold at rest).
Motor function was tested by grip strength recordings and Nine Hole Peg
Test (NHPT) executions before and after each rTMS session.
RESULTS: Compared to sham stimulation, real rTMS improved NHPT
results but not grip strength in the affected hand. No change of
performance was observed for the unaffected hand. NHPT baseline
repetitions in a subgroup of patients indicated stable motor performance
prior to the rTMS sessions.
CONCLUSIONS: The study suggests that therapeutic rTMS applications
over the contralesional hemisphere are feasible in acute stroke patients
and can transiently improve dexterity of the affected hand. RTMS may
become an additional tool for early neurorehabilitation.
Prog Brain Res. 2005;150:527-35.
Neural plasticity and recovery of function.
Ward NS.
Wellcome Department of Imaging Neuroscience, Institute of Neurology,
University College London, 12 Queen Square, London WC1N 3BG, UK.
Recovery of the function after stroke is a consequence of many
factors including resolution of oedema and survival of the ischaemic
penumbra. In addition there is a growing interest in the role of central
nervous system (CNS) reorganization. Much of the evidence supporting
this comes from animal models of focal brain injury, but non-invasive
techniques such as functional magnetic resonance imaging, transcranial
magnetic stimulation, electroencephalography and magnetoencephalography
now allow the study of the working human brain. Using these techniques
it is apparent that the motor system of the brain adapts to damage in a
way that attempts to preserve motor function. This has been demonstrated
after stroke, as part of the ageing process, and even after disruption
of normal motor cortex with repetitive transcranial magnetic
stimulation. The result of this reorganization is a new functional
architecture, one which will vary from patient to patient depending on
the anatomy of the damage, the biological age of the patient and lastly
the chronicity of the lesion. The success of any given therapeutic
intervention will depend on how well it interacts with this new
functional architecture. Thus it is crucial that the study of novel
therapeutic strategies for treating motor impairment after stroke take
account of this. This review maps out the attempts to describe
functionally relevant adaptive changes in the human brain following
focal damage. A greater understanding of how these changes are related
to the recovery process will allow not only the development of novel
therapeutic techniques that are based on neurobiological principles and
designed to minimize impairment in patients suffering from stroke, but
also to target these therapies at the appropriate patients.
Neurology. 2005 Aug 9;65(3):466-8.
Therapeutic trial of repetitive transcranial magnetic stimulation after acute ischemic stroke.
Khedr EM, Ahmed MA, Fathy N, Rothwell JC.
Department of Neurology, Assiut University Hospital, Assiut, Egypt. emankhedr99@yahoo.com
Repetitive transcranial magnetic stimulation (rTMS) or sham
stimulation was given over the motor cortex daily for 10 days to two
randomly assigned groups of 26 patients with acute ischemic stroke.
Patients otherwise continued their normal treatment. Disability scales
measured before rTMS, at the end of the last rTMS session, and 10 days
later showed that real rTMS improved patients’ scores more than sham.
Stroke. 2005 Oct 27; [Epub ahead of print]
Repetitive Transcranial Magnetic Stimulation of Contralesional Primary Motor Cortex Improves Hand Function After Stroke.
Takeuchi N, Chuma T, Matsuo Y, Watanabe I, Ikoma K.
From the Department of Rehabilitation Medicine, Hokkaido University Graduate School of Medicine, Sapporo 060-0814, Japan.
BACKGROUND AND PURPOSE: A recent report has demonstrated that the
contralesional primary motor cortex (M1) inhibited the ipsilesional M1
via an abnormal transcallosal inhibition (TCI) in stroke patients. We
studied whether a decreased excitability of the contralesional M1
induced by 1 Hz repetitive transcranial magnetic stimulation (rTMS)
caused an improved motor performance of the affected hand in stroke
patients by releasing the TCI.
METHODS: We conducted a double-blind study of real versus sham rTMS
in stroke patients. After patients had well- performed motor training to
minimize the possibility of motor training during the motor
measurement, they were randomly assigned to receive a subthreshold rTMS
at the contralesional M1 (1 Hz, 25 minutes) or sham stimulation.
RESULTS: When compared with sham stimulation, rTMS reduced the
amplitude of motor-evoked potentials in contralesional M1 and the TCI
duration, and rTMS immediately induced an improvement in pinch
acceleration of the affected hand, although a plateau in motor
performance had been reached by the previous motor training. This
improvement in motor function after rTMS was significantly correlated
with a reduced TCI duration.
CONCLUSIONS: We have demonstrated that a disruption of the TCI by the
contralesional M1 virtual lesion caused a paradoxical functional
facilitation of the affected hand in stroke patients; this suggests a
new neurorehabilitative strategy for stroke patients.
Stroke. 2005 Nov 3; [Epub ahead of print]
Motor Strokes. The Lesion Location Determines Motor Excitability Changes.
Liepert J, Restemeyer C, Kucinski T, Zittel S, Weiller C.
From the Departments of Neurology and Neuroradiology, University
Medical Center Eppendorf, Hamburg, and Department of Neurology,
University Hospital, Freiburg, Germany.
BACKGROUND AND PURPOSE: The purpose of this research was to
investigate the impact of lesion location on motor excitability and
motor performance.
METHODS: We studied patients with pure motor strokes in 4 different
brain areas: motor cortex lesions (n=7), striatocapsular lesions (n=13),
lacunar lesions of the internal capsule (n=13), and paramedian pontine
lesions (n=10). Motor performance tests included the 9-hole-peg test and
grip strength recordings. Motor excitability was determined by
transcranial magnetic stimulation. Motor thresholds, stimulus-response
curves, silent periods, motor cortical inhibition, and facilitation were
investigated.
RESULTS: The 4 groups were clinically similar but showed major
differences in motor excitability. Only motor cortex lesions had a loss
of intracortical inhibition in the affected hemisphere. In the internal
capsule lesion group and the pontine lesion group, stimulus-response
curves were depressed on the affected side. All of the subcortical
lesions showed a prolongation of the silent period in the paretic side.
Motor thresholds were predominantly elevated in the lesioned hemisphere
of patients with internal capsule or pontine lesions. Motor performance
was correlated with silent period duration in internal capsule lesions
and with motor thresholds in internal capsule and pontine lesions.
CONCLUSIONS: Motor cortex lesions exhibited deficient inhibitory
properties. In contrast, subcortical lesions displayed an enhancement of
inhibition. Internal capsule and pontine lesions affecting the
corticospinal tract on different levels particularly impaired neuronal
recruitment. Our results suggest that the lesion location determines a
specific pattern of motor excitability changes.
i Yi Jun Yi Da Xue Xue Bao. 2004 Aug;24(8):946-9, 952.
Effect of power-frequency electromagnetic fields on stroke during rehabilitation.
[Article in Chinese]
Deng AW, Yuang XG, Wei D, Zhang JH, Ran CF, Wang M.
Department of Rehabilitation, Longgang center Hospital of Shenzhen City, Shenzhen 518116, China. aiwen@fimmu.com
Abstract
OBJECTIVE: To explore the effects and mechanism of power-frequency
electromagnetic fields on lipoprotein metabolism and homodynamic during
stroke rehabilitation.
METHODS: One hundred fifteen patients with stroke were divided into 2
groups, 55 cases of them were treated by exposure to power-frequency
electromagnetic fields, 60 cases were treated as control group. Barthel
index and Functional Independence Measure (FIM) were used to evaluate
rehabilitation outcome. The lipoprotein and its subclasses, homodynamic
parameters were compared at pre- and post-rehabilitation.
RESULTS: The treatment group showed a statistically significant
better prognosis compared with the control group(P<0.01). The score
of Barthel index also increased after treatment(P<0.001). Total
cholesterol(Tc), triglycerides(TG), low-density lipoprotein
cholesterol(LDL-c) levels dropped and high-density lipoprotein
cholesterol(HDL-c) increased significantly. The Tc/HDL-c, LDL-c/HDL-c
ratio along with the blood and plasma viscosity decreased significantly
compared with the controls (P<0.01). The ratio of stroke recurrence
decreased significantly after the treatment compared with the control
group (P<0.05).
CONCLUSION: The power-frequency electromagnetic fields can improve
lipoprotein metabolism and homodynamic parameters. It can improve the
ADL and FIM of stroke patients, which may have significant implications
for stroke patients.
Magnetic and laser therapy of acute ischemic stroke.
[Article in Russian]
Samosiuk NI.
The paper presents the technique of frequency-modulated magnetolaser
therapy (FMMLT) used in combined treatment of 121 patients with ischemic
stroke in acute period. The results were compared with those in the
control group of 30 patients who received conventional drug treatment.
The results of the comparison allowed the author to recommend FMMLT in
ischemic stroke especially in the period of “therapeutic window”.
Magnet therappy in rehabilitation of patients with cerabral ischemia.
[Article in Russian]
Provotorov VM, Putilina MV.
Abstract
Basing on the results of clinical examination and treatment of 420
patients with aftereffects of acute circulatory disturbance, the authors
propose a pathogenetically grounded approach to correction of the
residual phenomena following stroke. The method proposed includes three
courses of impulse electromagnetotherapy used in combination with either
standard chemotherapy or massage and therapeutic exercise
The use of extremely high frequency electromagnetic fields during acute period of ischemic stroke.
[Article in Russian]
Podoliako VA, Makarchik AV.
Abstract
The rheological, coagulatory and clinical examination of 70 patients
with acute ischemic stroke has demonstrated that EHF therapy (53.53 GHz)
improves rheological and coagulatory parameters in such patients, has a
positive effect on hemostasis and clinical course of acute ischemic
stroke. The technique and doses are presented.
Stroke. 2000 Jun;31(6):1210-6.
Treatment-induced cortical reorganization after stroke in humans.
Liepert J, Bauder H, Wolfgang HR, Miltner WH, Taub E, Weiller C.
BACKGROUND AND PURPOSE: Injury-induced cortical reorganization is a
widely recognized phenomenon. In contrast, there is almost no
information on treatment-induced plastic changes in the human brain. The
aim of the present study was to evaluate reorganization in the motor
cortex of stroke patients that was induced with an efficacious
rehabilitation treatment.
METHODS: We used focal transcranial magnetic stimulation to map the
cortical motor output area of a hand muscle on both sides in 13 stroke
patients in the chronic stage of their illness before and after a
12-day-period of constraint-induced movement therapy.
RESULTS: Before treatment, the cortical representation area of the
affected hand muscle was significantly smaller than the contralateral
side. After treatment, the muscle output area size in the affected
hemisphere was significantly enlarged, corresponding to a greatly
improved motor performance of the paretic limb. Shifts of the center of
the output map in the affected hemisphere suggested the recruitment of
adjacent brain areas. In follow-up examinations up to 6 months after
treatment, motor performance remained at a high level, whereas the
cortical area sizes in the 2 hemispheres became almost identical,
representing a return of the balance of excitability between the 2
hemispheres toward a normal condition.
CONCLUSIONS: This is the first demonstration in humans of a long-term
alteration in brain function associated with a therapy-induced
improvement in the rehabilitation of movement after neurological injury.
Magnetotherapy and laser therapy were used in complex and
complex-combined regimens in 75 patients after cerebral ischemic or
hemorrhagic stroke starting on the poststroke week 4-5.
Clinico-neurologic, neurophysiological and cerebrohemodynamic findings
evidence for the highest effectiveness of neurorehabilitation including
complex magneto-laser therapy in hemispheric ischemic and hemorrhagic
stroke of subcortical location in the absence of marked
clinico-tomographic signs of dyscirculatory encephalopathy.
Complex-combined magneto-laser therapy is more effective for correction
of spastic dystonia. Mutual potentiation of magnetotherapy and laser
therapy results in maximal development of collateral circulation and
cerebral hemodynamic reserve (84% of the patients). Complex effects
manifest in arteriodilating and venotonic effects. Complex magneto-laser
therapy is accompanied by reduction of hyperthrombocythemia and
hyperfibrinogenemia.
Motor hand recovery after stroke. Prognostic yield of early transcranial magnetic stimulation.
Cruz Martínez A, Tejada J, Díez Tejedor E.
Unidad de Electromiografía, Hospital La Luz, Madrid, Spain.
Abstract
Transcranial magnetic stimulation (TMS) was performed in 20 patients
within the first days after stroke. Motor evoked potentials (MEPs) were
bilaterally recorded over thenar eminence muscles, and central motor
conduction time (CMCT), amplitude of the MEPs (A%M) and threshold
intensity compared between both sides. Six months later the patients
were reexamined. Within the first days after stroke the obtention of
MEPs at rest or during voluntary muscle activation have a favorable
prognostic value. All patients with early response by TMS reached a good
motor function in the following months. The follow-up showed that the
electrophysiological improvement was closely related to clinical
recovery of the hand function. However, even in cases with a good
recovery, the CMCT and, mainly, the A%M, may be significantly different
related to those in normal hand. TMS may be an early and valuable
prognostic indicator of hand function recovery after stroke, and their
prognostic yield is higher than clinical evaluation and CT study. TMS is
a quantifiable method of motor disability and may have practical
application in the management and rehabilitation therapy in stroke
patients.
The effect of combined transcerebral magnetic and electric impulse
therapy on the cerebral and central hemodynamic status of stroke
patients in the early rehabilitation period.
[Article in Russian]
Gorbunov FE, Orekhova EM, Isaev SV, Bugaev SA.
75 clinical cases of acute impairment of cerebral circulation treated
with sinusoidal modulated currents in combination with transcerebral
magnetic field have been analysed. Functional and clinical findings
indicate that the above combination is much more effective than magnetic
field and sinusoidal modulated currents alone: 62% against 35% and 33%,
respectively.
Zh Nevrol Psikhiatr Im S S Korsakova. 1997;97(9):41-3.
Magnetic and electrical stimulation in the rehabilitative treatment of patients with organic nervous system lesions.
[Article in Russian]
Tyshkevich TG, Nikitina VV.
89 patients with organic damages of nervous system with paralyses and
pareses as the main symptoms in clinical pattern were treated. Their
treatment was complex with application of impulse magnetic field and
electrostimulation which permitted to achieve multilevel
electrostimulation. The control group was formed by 49 patients with
analogous diseases which were treated by sinusoidal current
electrostimulation only. Combined application of magnetic stimulation
and electrostimulation was more effective. That was confirmed by data of
roentgenographic and electromyographic studies.
Bioelectromagnetics. 1994;15(3):205-16.
Protection against focal cerebral ischemia following exposure to a pulsed electromagnetic field.
Grant G, Cadossi R, Steinberg G.
Department of Neurosurgery, Stanford University, California 94305.
There is evidence that electromagnetic stimulation may accelerate the
healing of tissue damage following ischemia. We undertook this study to
investigate the effects of low frequency pulsed electromagnetic field
(PEMF) exposure on cerebral injury in a rabbit model of transient focal
ischemia (2 h occlusion followed by 4 h of reperfusion). PEMF exposure
(280 V, 75 Hz, IGEA Stimulator) was initiated 10 min after the onset of
ischemia and continued throughout reperfusion (six exposed, six
controls). Magnetic resonance imaging (MRI) and histology were used to
measure the degree of ischemic injury. Exposure to pulsed
electromagnetic field attenuated cortical ischemia edema on MRI at the
most anterior coronal level by 65% (P < 0.001). On histologic
examination, PEMF exposure reduced ischemic neuronal damage in this same
cortical area by 69% (P < 0.01) and by 43% (P < 0.05) in the
striatum. Preliminary data suggest that exposure to a PEMF of short
duration may have implications for the treatment of acute stroke.
Zh Nevropatol Psikhiatr Im S S Korsakova. 1992;92(1):63-7.
Magnetotherapy of initial manifestations of cerebrovascular disorders in hypertension.
[Article in Russian]
Miasnikov IG.
The paper is concerned with the data on 147 subjects who underwent
magnetotherapy with the unit “Magniter-AMT-01” applied to the cervical
area. The main group included 102 subjects, 45 person served as control.
The purpose of the work was to base the application of MT under
inpatient and home conditions with the use of the above-indicated unit.
In view of this fact, a study was made of cerebral hemo- and
thermodynamics with the aid of rheoencephalography and
encephaloradiothermography under the action of different modes of the
functioning of the unit “Magniter-AMT-01” (pulse and variable magnet
induction fields 12-15 mTl and 30-35 mTl). A method of measuring
magnetosensitivity of patients depending on the temperature reaction of
the brain to a single MT session was elaborated. The greatest clinical
effect was attained with the use of pulse magnetic field 15 mTl.
Magnetotherapy with the use of the unit “Magniter-AMT-01” provided good
results under inpatient and home conditions. The magnetosensitive
patients demonstrated the highest effect.
J Cell Biochem. 1993 Apr;51(4):387-93.
Beneficial effects of electromagnetic fields.
Bassett CA.
Bioelectric Research Center, Columbia University, Riverdale, New York 10463.
Selective control of cell function by applying specifically
configured, weak, time-varying magnetic fields has added a new, exciting
dimension to biology and medicine. Field parameters for therapeutic,
pulsed electromagnetic field (PEMFs) were designed to induce voltages
similar to those produced, normally, during dynamic mechanical
deformation of connective tissues. As a result, a wide variety of
challenging musculoskeletal disorders have been treated successfully
over the past two decades. More than a quarter million patients with
chronically ununited fractures have benefitted, worldwide, from this
surgically non-invasive method, without risk, discomfort, or the high
costs of operative repair. Many of the athermal bioresponses, at the
cellular and subcellular levels, have been identified and found
appropriate to correct or modify the pathologic processes for which
PEMFs have been used. Not only is efficacy supported by these basic
studies but by a number of double-blind trials. As understanding of
mechanisms expands, specific requirements for field energetics are being
defined and the range of treatable ills broadened. These include nerve
regeneration, wound healing, graft behavior, diabetes, and myocardial
and cerebral ischemia (heart attack and stroke), among other conditions.
Preliminary data even suggest possible benefits in controlling
malignancy.