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.
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. a prospective clinical study.
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.
The magnetic amplipulse therapy of vestibular dysfunctions of
vascular origin by using the Sedaton apparatus (experimental research).
[Article in Russian]
Mal’tsev AE.
The paper describes the results of combined utilization of magnetic
field (MF), sinusoidal modulated current (SMC) and galvanic current (GC)
generated by a specially devised unit “Sedaton”. This multimodality
physiotherapy was tested in chronic experiments on 25 cats with
experimental vascular and vestibular dysfunction. MF in combination with
SMC displayed greater efficacy than in monotherapy. Positive
physiological reactions were more pronounced.
Headache. 2010 Jul;50(7):1153-63. Epub 2010 Jun 10.
Transcranial magnetic stimulation for migraine: a safety review.
Dodick DW, Schembri CT, Helmuth M, Aurora SK.
Source
Mayo Clinic, Phoenix, AZ, USA.
Abstract
OBJECTIVE:
To review potential and theoretical safety concerns of transcranial
magnetic stimulation (TMS), as obtained from studies of single-pulse
(sTMS) and repetitive TMS (rTMS) and to discuss safety concerns
associated with sTMS in the context of its use as a migraine treatment.
METHODS:
The published literature was reviewed to identify adverse events
that have been reported during the use of TMS; to assess its potential
effects on brain tissue, the cardiovascular system, hormone levels,
cognition and psychomotor tests, and hearing; to identify the risk of
seizures associated with TMS; and to identify safety issues associated
with its use in patients with attached or implanted electronic
equipment or during pregnancy.
RESULTS:
Two decades of clinical experience with sTMS have shown it to be a
low risk technique with promise in the diagnosis, monitoring, and
treatment of neurological and psychiatric disease in adults. Tens of
thousands of subjects have undergone TMS for diagnostic, investigative,
and therapeutic intervention trial purposes with minimal adverse
events or side effects. No discernable evidence exists to suggest that
sTMS causes harm to humans. No changes in neurophysiological function
have been reported with sTMS use.
CONCLUSIONS:
The safety of sTMS in clinical practice, including as an acute
migraine headache treatment, is supported by biological, empirical, and
clinical trial evidence. Single-pulse TMS may offer a safe
nonpharmacologic, nonbehavioral therapeutic approach to the currently
prescribed drugs for patients who suffer from migraine.
Appl Psychophysiol Biofeedback. 2007 Dec;32(3-4):191-207. Epub 2007 Nov 2.
Headache treatment with pulsing electromagnetic fields: a literature review.
Vincent W, Andrasik F, Sherman R.
Department of Psychology, Georgia State University, PO Box 5010, Atlanta, GA 30302-5010, USA.
Abstract
Pulsing electromagnetic field (PEMF) therapy may be a viable form of
complementary and alternative medicine. Clinical applications include
the treatment of fractures, wounds, and heart disease. More recent
applications involve treatment of recurrent headache disorders. This
paper reviews available studies investigating PEMF for headache
management. Possible mechanisms for effects (neurochemical,
electrophysical, and cardiovascular) are discussed. The available data
suggest that PEMF treatment for headache merits further study.
Suggestions for future research are provided.
EEG EMG Z Elektroenzephalogr Elektromyogr Verwandte Geb. 1985 Dec;16(4):227-30.
Cerebral use of a pulsating field in neuropsychiatry patients with long-term headache.
[Article in German]
Grunner O.
A pulsed magnetic field (f = 260 Hz; t = 3 ms; induction B = 1.9 mT;
gradient = 0.5 mT/cm) was applied at 40 patients with headaches of
various etiology. The change of cephalea intensity was evaluated
according the patients statements. These statements were further
compared with the changes of the EEG. By means of frequency analysis of
the EEG significant changes in percentages of delta and alpha 1
activities (7.5-9.5/s) were stated after the application of the real
treatment regarding the sham treatment. Any treatment lasted one half
hour. The retreat of subjective difficulties as well as the amelioration
of EEG were stated accordingly at headaches, which were bounded with
cerebral arteriosclerosis, with states after cerebral concussion, with
depressive neurosis, or with tension headache. Pulsed magnetic field
could be applied only there, where the visual evaluation stated EEG as
physiological.
Headache: The Journal of Head and Face Pain
Volume 39 Issue 8 Page 567 – September 1999
doi:10.1046/j.1526-4610.1999.3908567.x
Treatment of Migraine With Pulsing Electromagnetic Fields: A Double-Blind, Placebo-Controlled Study
Richard A. Sherman, PhD; Nancy M. Acosta, BS; Linda Robson, BA
The effect of exposure to pulsing
electromagnetic fields on migraine activity was evaluated by having
42 subjects (34 women and 8 men), who met the International Headache
Society’s criteria for migraine, participate in a double-blind,
placebo-controlled study. Each subject kept a 1-month, pretreatment,
baseline log of headache activity prior to being randomized to having
either actual or placebo pulsing electromagnetic fields applied to
their inner thighs for 1 hour per day, 5 days per week, for 2 weeks.
After exposure, all subjects kept the log for at least 1 follow-up
month. During the first month of follow-up, 73% of those receiving
actual exposure reported decreased headaches (45% good decrease,
14% excellent decrease) compared to half of those receiving the
placebo (15% worse, 20% good, 0% excellent). Ten of the 22 subjects
who had actual exposure received 2 additional weeks of actual
exposure after their initial 1-month follow-up. All showed decreased
headache activity (50% good, 38% excellent). Thirteen subjects from
the actual exposure group elected not to receive additional exposure.
Twelve of them showed decreased headache activity by the second
month (29% good, 43% excellent). Eight of the subjects in the placebo
group elected to receive 2 weeks of actual exposure after the
initial 1-month follow-up with 75% showing decreased headache
activity (38% good, 38% excellent).
In conclusion, exposure of the inner thighs to pulsing
electromagnetic fields for at least 3 weeks is an effective,
short-term intervention for migraine, but not tension headaches.
Headache: The Journal of Head and Face Pain
Volume 38 Issue 3 Page 208 – March 1998
doi:10.1046/j.1526-4610.1998.3803208.x
Initial Exploration of Pulsing Electromagnetic Fields for Treatment of Migraine
Richard A. Sherman, PhD; Linda Robson, BA; Linda A. Marden, MD
Two studies were conducted during which
23 patients with chronic migraine were exposed to pulsing
electromagnetic fields over the inner thigh. In an open study, 11
subjects kept a 2-week headache log before and after 2 to 3 weeks of
exposure to pulsing electromagnetic fields for 1 hour per day, 5 days
per week. The number of headaches per week decreased from 4.03
during the baseline period to 0.43 during the initial 2-week
follow-up period and to 0.14 during the extended follow-up which
averaged 8.1 months. In a double-blind study, 9 subjects kept a
3-week log of headache activity and were randomly assigned to receive
2 weeks of real or placebo pulsing elactromagnetic field exposures
as described above. They were subsequently switched to 2 weeks of the
other mode, after which they kept a final 3-week log. Three
additional subjects in the blind study inadvertently received
half-power pulsing electromagnetic field exposures. The 6 subjects
exposed to the actual device first showed a change in headache
activity from 3.32 per week to 0.58 per week. The 3 subjects exposed
to only half the dose showed no change in headache activity. Large
controlled studies should be performed to determine whether this
intervention is actually effective
Curr Rev Pain. 1999;3(5):342-347.
Sphenopalatine Ganglion Analgesia.
Day M.
Texas Tech University Health Sciences Center, Department of
Anesthesiology, 3601 4th Street, Room 1C282, Lubbock, TX 79430, USA.
The sphenopalatine ganglion and its involvement in the
pathogenesis of pain has been the subject of debate for the last 90
years. The ganglion is a complex neural center composed of sensory,
motor, and autonomic nerves, which makes it difficult to determine
its pathophysiology. Current indications for blockade of the
sphenopalatine ganglion include sphenopalatine and trigeminal
neuralgia, migraine and cluster headaches, and atypical facial pain.
Methods of blockade use local anesthetics, steroids, phenol, and
conventional radiofrequency and electromagnetic field- pulsed
radiofrequency lesioning. The techniques for blockade range from
superficial to highly invasive. Efficacy studies, though few and
small, show promise in patients who have failed pharmacologic or
surgical therapies.
Anesth Pain Control Dent. 1992 Spring;1(2):85-9.
The management of craniofacial pain in a pain relief unit.
Hillman L, Burns MT, Chander A, Tai YM.
Russells Hall Hospital, Dudley, United Kingdom.
This paper reports the results of 34 craniofacial pain sufferers who
were treated at the Dudley Pain Relief Unit over a 1-year period. Most
of the patients were referred by their general medical practitioners.
They were adults representing all age groups, with a female-male ratio
of 4:1. The average history of pain was 5.5 years. Neuralgic pain (as
distinct from temporomandibular joint dysfunction syndrome, migrainous
disorders, and pain of iatrogenic origin) was most frequently seen. Oral
drug therapy, local injection of corticosteroids and analgesics,
peripheral neurolysis, magnetotherapy, hypnotherapy, and acupuncture
were the lines of management available. By the end of this study period,
pain had been relieved or eliminated in 30 of the patients (88%).
J Physiol Pharmacol. 2012 Sep;63(4):397-401.
Pulsating electromagnetic field stimulation of urothelial cells
induces apoptosis and diminishes necrosis: new insight to magnetic
therapy in urology.
Juszczak K, Kaszuba-Zwoinska J, Thor PJ.
Source
Department of Pathophysiology, Jagiellonian University, Medical College, Cracow, Poland. kajus13@poczta.onet.pl.
Abstract
The evidence of electromagnetic therapy (EMT) efficacy in stress
and/or urge urinary incontinence, as well as in detrusor overactivity is
generally lacking in the literature. The potential EMT action of
neuromuscular tissue depolarization has been described. Because there is
no data on the influence of pulsating electromagnetic fields (PEMF) on
the urothelium, we evaluated the effect of PEMF stimulation on rat
urothelial cultured cells (RUCC). In our study 15 Wistar rats were used
for RUCC preparation. RUCC were exposed to PEMF (50 Hz, 45±5 mT) three
times for 4 hours each with 24-hour intervals. The unexposed RUCC was in
the same incubator, but in a distance of 35 cm from the PEMF generator.
Annexin V-APC (AnV+) labelled was used to determine the percentage of
apoptotic cells and propidium iodide (PI+), as standard flow cytometric
viability probe to distinguish necrotic cells from viable ones. The
results are presented in percentage values. The flow cytometric analysis
was carried out on a FACS calibur flow cytometer using Cell-Quest
software. In PEMF-unstimulated RUCC, the percentage of AnV+, PI+, and
AnV+PI+ positive cells were 1.24±0.34%, 11.03±1.55%, and 12.43±1.96%,
respectively. The percentages of AnV+, PI+, and AnV+PI+ positive cells
obtained after PEMF stimulation were 1.45±0.16% (p=0.027), 7.03±1.76%
(p<0.001), and 9.48±3.40% (p=0.003), respectively. The PEMF
stimulation of RUCC induces apoptosis (increase of AnV+ cells) and
inhibits necrosis (decrease of PI+ cells) of urothelial cells. This
leads us to the conclusion that a low-frequency pulsating
electromagnetic field stimulation induces apoptosis and diminishes
necrosis of rat urothelial cells in culture.
Vopr Kurortol Fizioter Lech Fiz Kult. 2005 Jan-Feb;(1):26-8.
Efficacy of general magnetotherapy in conservative therapy of uterine myoma in women of reproductive age.
[Article in Russian]
Kulishova TV, Tabashnikova NA, Akker LV.
Sixty women of the reproductive age with uterine myoma were divided
into two groups. Thirty patients of the study group received combined
therapy plus general magnetotherapy (GMT). Patients of the control group
received only combined treatment. Ultrasound investigation registered a
reduction in the size of myoma nodes by 16.7% in the study group, while
in the controls myoma size did not change (p < 0.05). 1-year
follow-up data for the study group demonstrated no cases of the myoma
growth while 16.6% of the controls showed growth of myoma nodes, in 6.6%
of them supravaginal myoma amputation was made for rapidly growing
myoma.
Urologiia. 2004 Mar-Apr;(2):20-2.
Combined therapy of interstitial cystitis using the “Aeltis-Synchro-02-Iarilo” device.
[Article in Russian]
Kalinina SN, Molchanov AV, Rutskaia NS.
Multiple modality therapy of interstitial cystitis (IC)–the disease
characterized by nicturia, pelvic pains, imperative pollakiuria–is
considered. As IC nature is not well known, its treatment remains
empiric. Among the underlying causes, most probable are autoimmune,
allergic, infectious, neurological, vascular. Therefore, the treatment
should be multi-modality. Most usable now is combined chemotherapy.
Perspective is also IC treatment with medicines in combination with
physiotherapy (electromagnetolaser AELTIS-SYNCHRO-02-YARILO”).
Endovesical electrophoresis can be also applied.
The effect of a low-frequency magnetic field on the
clinico-immunological indices of patients with chronic inflammatory
diseases of the organs of the female genital system.
Low-frequency magnetic field generated by the vaginal inductor used
in 120 females with chronic genital inflammation promoted a decrease in
leukocytosis, elevation of total population of T-lymphocytes, inhibition
of high proliferative activity in PHA test. However, marked
immunocorrection was not reached.
Eur J Surg Suppl. 1994;(574):83-6.
Electrochemical therapy of pelvic pain: effects of pulsed electromagnetic fields (PEMF) on tissue trauma.
Jorgensen WA, Frome BM, Wallach C.
International Pain Research Institute, Los Angeles, California.
Unusually effective and long-lasting relief of pelvic pain of
gynaecological origin has been obtained consistently by short exposures
of affected areas to the application of a magnetic induction device
producing short, sharp, magnetic-field pulses of a minimal amplitude to
initiate the electrochemical phenomenon of electroporation within a 25
cm2 focal area. Treatments are short, fasting-acting, economical and in
many instances have obviated surgery. This report describes typical
cases such as dysmenorrhoea, endometriosis, ruptured ovarian cyst, acute
lower urinary tract infection, post-operative haematoma, and persistent
dyspareunia in which pulsed magnetic field treatment has not, in most
cases, been supplemented by analgesic medication. Of 17 female patients
presenting with a total of 20 episodes of pelvic pain, of which 11
episodes were acute, seven chronic and two acute as well as chronic, 16
patients representing 18 episodes (90%) experienced marked, even
dramatic relief, while two patients representing two episodes reported
less than complete pain relief.
Urol Nefrol (Mosk). 1996 Sep-Oct;(5):10-4.
Magnetic-laser therapy in inflammatory and postraumatic lesions of the urinary system.
[Article in Russian]
Loran OB, Kaprin AD, Gazimagomedov GA.
The authors discuss disputable problem of renal and ureteral tissue
after trauma or inflammation. These cause irreversible morphological
changes in the tissue. Poor results of the standard therapy urged the
authors to try magnetic-laser therapy in urological clinic. The
technique has been developed on experimental animal models. The
resultant morphological characteristics of ureteral wall and parenchyma
support the validity of magnetic-laser therapy in urological practice.
A permanent magnetic field in the combined treatment of acute endometritis after an artificial abortion.
[Article in Russian]
Strugatskii VM, Strizhakov AN, Kovalenko MV, Istratov VG, Iakubovich DV.
117 patients with acute endometritis after induced abortion were
examined using markers of wound process phases and treated according to
the original method. This consists in combination of constant magnetic
field with other modalities. Application of the constant magnetic field
produced a significant clinical response and reduced the hospital stay
through positive effect on healing of the endometrial wound.
Zh Nevropatol Psikhiatr Im S S Korsakova. 1989;89(4):41-4.
Current methods of pathogenetic therapy of infectious-allergic polyradiculoneuritis.
[Article in Russian]
Neretin VIa, Ki’riakov VA, Sapfirova VA, Agafonov BV.
This is a survey of the experience in using corticosteroids,
plasmapheresis, immunodepressants, hyperbaric oxygenation, laser and
magnetotherapy in treating the infectious-allergic Guillain-Barre
polyradiculoneuritis. The indications and counter-indications to
individual techniques are presented as related to the character and
course of the disease. The principles of interrelation of these
techniques with other drug and physical therapies are discussed. The
authors infer that combination of plasmapheresis with corticosteroids is
the best for acute polyradiculoneuritis and prolonged use of
maintenance doses of corticosteroids and immunodepressants, physical
methods and gymnastics are recommended for chronic polyradiculoneuritis.
1
Siegfried Weller Institute for Trauma Research,
Eberhard-Karls-Universität Tübingen, Schnarrenbergstr. 95, D-72076,
Tübingen, Germany. sabrina.ehnert@med.uni-tuebingen.de.
2
Sachtleben GmbH, Hamburg, Spectrum UKE, Martinistraße 64, D-20251, Hamburg, Germany.
3
Siegfried Weller Institute for Trauma Research,
Eberhard-Karls-Universität Tübingen, Schnarrenbergstr. 95, D-72076,
Tübingen, Germany.
4
Wuhan Union Hospital, Tongji Medical College, Huazhong University of
Science and Technology, Jiefang Dadao 1277#, 430022, Wuhan, China.
Abstract
Recently, we identified a specific extremely low-frequency pulsed
electromagnetic field (ELF-PEMF) that supports human osteoblast (hOBs)
function in an ERK1/2-dependent manner, suggesting reactive oxygen
species (ROS) being key regulators in this process. Thus, this study
aimed at investigating how ELF-PEMF exposure can modulate hOBs function
via ROS. Our results show that single exposure to ELF-PEMF induced ROS
production in hOBs, without reducing intracellular glutathione.
Repetitive exposure (>3) to ELF-PEMF however reduced ROS-levels,
suggesting alterations in the cells antioxidative stress response. The
main ROS induced by ELF-PEMF were •O2– and H2O2,
therefore expression/activity of antioxidative enzymes related to these
ROS were further investigated. ELF-PEMF exposure induced expression of
GPX3, SOD2, CAT and GSR on mRNA, protein and enzyme activity level.
Scavenging •O2– and H2O2 diminished the ELF-PEMF effect on hOBs function (AP activity and mineralization). Challenging the hOBs with low amounts of H2O2 on
the other hand improved hOBs function. In summary, our data show that
ELF-PEMF treatment favors differentiation of hOBs by producing non-toxic
amounts of ROS, which induces antioxidative defense mechanisms in these
cells. Thus, ELF-PEMF treatment might represent an interesting adjunct
to conventional therapy supporting bone formation under oxidative stress
conditions, e.g. during fracture healing.
Med Pr. 2014;65(3):343-9.
Effect of extremely low frequency magnetic field on glutathione in rat muscles.
[Article in Polish]
Ciejka E, Jakubowska E, Zelechowska P, Huk-Kolega H, Kowalczyk A, Goraca A.
Abstract
BACKGROUND:
Free radicals (FR) are atoms,
molecules or their fragments. Their excess leads to the development of
oxidizing stress, the cause of many neoplastic, neurodegenerative and
inflammatory diseases, and aging of the organism. Industrial pollution,
tobacco smoke, ionizing radiation, ultrasound and magnetic field are the
major FR exogenous sources. The low frequency magnetic field is still
more commonly applied in the physical therapy. The aim of the presented
study was to evaluate the effect of extremely low frequency magnetic
field used in the magnetotherapy on the level of total glutathione,
oxidized and reduced, and the redox state of the skeletal muscle cells,
depending on the duration of exposure to magnetic field.
MATERIAL AND METHODS:
The male rats, weight of 280-300 g,
were randomly devided into 3 experimental groups: controls (group I) and
treatment groups exposed to extremely low frequency magnetic field
(ELF-MF) (group II exposed to 40 Hz, 7 mT for 0.5 h/day for 14 days and
group III exposed to 40 Hz, 7 mT for 1 h/day for 14 days). Control rats
were kept in a separate room not exposed to extremely low frequency
magnetic field. Immediately after the last exposure, part of muscles was
taken under pentobarbital anesthesia. Total glutathione, oxidized and
reduced, and the redox state in the muscle tissue of animals were
determined after exposure to magnetic fields.
RESULTS:
Exposure to low magnetic field: 40 Hz,
7 mT for 30 min/day and 60 min/day for 2 weeks significantly increased
the total glutathione levels in the skeletal muscle compared to the
control group (p < 0.001).
CONCLUSIONS:
Exposure to magnetic fields used in
the magnetic therapy plays an important role in the development of
adaptive mechanisms responsible for maintaining the oxidation-reduction
balance in the body and depends on exposure duration.
Long-standing research on electric
and electromagnetic field interactions with biological cells and their
subcellular structures has mainly focused on the low- and high-frequency
regimes. Biological effects at intermediate frequencies between 100 and
300 kHz have been recently discovered and applied to cancer cells as a
therapeutic modality called Tumor Treating Fields (TTFields). TTFields
are clinically applied to disrupt cell division, primarily for the
treatment of glioblastoma multiforme (GBM). In this review, we provide
an assessment of possible physical interactions between 100 kHz range
alternating electric fields and biological cells in general and their
nano-scale subcellular structures in particular. This is intended to
mechanistically elucidate the observed strong disruptive effects in
cancer cells. Computational models of isolated cells subject to TTFields
predict that for intermediate frequencies the intracellular electric
field strength significantly increases and that peak dielectrophoretic
forces develop in dividing cells. These findings are in agreement with
in vitro observations of TTFields’ disruptive effects on cellular
function. We conclude that the most likely candidates to provide a
quantitative explanation of these effects are ionic condensation waves
around microtubules as well as dielectrophoretic effects on the dipole
moments of microtubules. A less likely possibility is the involvement of
actin filaments or ion channels.Keywords: electric fields, biological cells, cancer cells, microtubules, ions, TTFields
1. Introduction
The effects of external electric fields
on biological cells have been extensively studied both in the direct
current (DC) and alternating current (AC) cases [1].
In order to elucidate possible impact of electric fields on cells,
various experimental assays as well as analytical and computational
models have been developed in the past. Experimentally obtained findings
were further translated into biomedical applications. While DC or
low-frequency AC fields are used to induce stimulation of excitable
cells through membrane depolarization or to promote wound healing,
high-frequency AC fields are associated with tissue heating and membrane
rupture, thus finding its application in diathermy or ablation
techniques.
Intermediate-frequency AC electric fields in the kHz to MHz
range were commonly assumed to lead to no significant biological
effects [1]. However, in a major breakthrough paper, Kirson et al. [2]
reported the discovery that low-intensity (1–3 V/cm), intermediate
frequency (100–300 kHz) electric fields have a profoundly inhibitory
effect on the growth rate of various mammalian tumor cell lines [2,3,4].
This discovery has been translated into a clinical application termed
Tumor Treating Fields (TTFields). Based on the results of a Phase III
clinical trial [5],
TTFields have been approved by the United States Food and Drug
Administration (FDA) in 2011 for the treatment of recurrent glioblastoma
multiforme (GBM) and their efficacy in treating other solid tumor types
is currently being investigated clinically [6]. In late 2015, TTFields were also approved for newly diagnosed GBM patients in combination therapy with temozolomide [7,8] due to significantly increased survival times.
It should be noted that electromagnetic (EM) fields may
affect the regulation of cellular growth and differentiation, including
the growth of tumors [9,10].
Both static magnetic and electric fields have altered the mitotic index
and cell cycle progression of a number of cell types in various species
[10].
EM low-frequency fields in the range of 50–75 Hz cause perturbations in
the mitotic activity of plant and animal cells and a significant
inhibitory effect on mitotic activity occurs early during exposure [11,12,13].
While the field amplitudes used are consistent with those of interest
to this report, the frequencies are orders of magnitude lower.
The reduction in the cell number due to an application of
TTFields was studied by in vitro experiments with various cancer cell
lines. A significant prolongation of mitosis was predicted, where
treated cells remain stationary at metaphase for several hours, which
was accompanied by abnormal mitotic figures as well as membrane rupture
and blebbing leading to apoptosis [2,3].
Furthermore, these experiments showed that the inhibitory effect
increases with an increasing electric field intensity, resulting in a
complete proliferation arrest of rat glioma cells after 24 h exposure to
a field intensity of 2.25 V/cm. Additionally, the effects of TTFields
have been shown to be frequency-dependent, with a cancer cell
line-specific peak frequency of the maximal inhibitory effect, e.g., 200
kHz for glioma cells [3]. Following these experimental results, two specific mechanisms of action of TTFields have been proposed [2,3,4] which we describe below.
Firstly, the applied field is expected to interfere with
proper microtubule (MT) formation preventing a functioning mitotic
spindle, due to the force of interactions with the large intrinsic
dipole moments of the tubulin dimers [14,15,16]
that make up MTs. It has been hypothesized that the tubulin dimers
might align parallel to the direction of the applied electric field,
rather than along the MT axis. Secondly, the cellular morphology during
cytokinesis gives rise to a non-uniform intracellular electric field,
with a high density at the cleavage furrow between the dividing cells.
This non-uniform field leads to the development of dielectrophoretic
(DEP) forces [17]
acting on polarizable macromolecules such as MTs, organelles and all
charged structures present in the cell, such as ions, proteins or DNA.
Thus, TTFields are considered to be suitable as a novel
anti-mitotic cancer treatment modality. In fact, it has been suggested
by numerous researchers that endogenous electric fields may play a key
role during mitosis. Similar to Cooper [18], Pohl et al. [19]
proposed that the onset of mitosis is associated with a ferroelectric
phase transition, which establishes an axis of oscillation for the
cellular polarization wave. The mitotic spindle apparatus would
delineate the polarization field with MTs lined up along the electric
field lines. The poles are expected to experience the highest field
intensities while the equatorial plane is likely to provide a nodal
manifold for the fields. Consequently, the chromosome condensation
during this transformation was predicted to be induced by the static
dielectric polarization of the chromatin complex as a result of the
cellular ferroelectric phase transition. These conclusions have been
supported by experimental evidence for peak EM activity during mitosis [20,21]
and by physical modeling of the electrostatic forces generated by MTs
which generate mechanical force required for chromosome segregation
during mitosis and influence chromosomal motion [15,16,22]. A detailed review of this aspect can be found elsewhere [1].
Put together, there is reasonable evidence that especially
during mitosis, electric field effects are relevant for the functioning
of a dividing cell, especially in the creation of the mitotic spindle.
However, to date a rigorous quantitative analysis of the magnitude of
these effects within cells exposed to TTFields has not been performed.
Furthermore, an analysis of how TTFields might interact with subcellular
structures has also never been reported. In a quantitative model, which
attempts to explain these effects, an energetic constraint, both from
below and above, must be kept in mind. Firstly, for an effect to be of
significance at a molecular level, its interaction energy must exceed
thermal energy, i.e., kT per degree of freedom (i.e., 4 × 10?21 J).
Otherwise, thermal fluctuations will disrupt the action of electric
fields. Secondly, it must not produce so much thermal energy as to
seriously increase the temperature of the cell. In terms of practical
comparisons, a cell generates approximately 3 × 10?12 W of power (3 × 10?12 J/s),
much of which is used to maintain a constant physiological temperature.
This is found from a simple estimate of energy production by the human
body which is 100 W divided by the number of cells in the body which is
approximately 3 × 1013 [23].
In terms of subcellular forces at work, a minimal amount of useful
force at a nanometer scale is 1 pN. Motor proteins generate forces on
the order of several pN. A force of 1 pN applied to a tip of a
microtubule may be used to bend it by as much as 1 µm [24]. Below, we review electric conduction effects for subcellular structures of interest.
The paper is structured as follows. In Section 2,
we review what is known about the shape and intensity of the electric
field within cells exposed to externally applied electric fields,
focusing on cells during mitosis. As a preparation for following
sections, Section 3 offers a general introduction to subcellular electrical conduction and electrostatics. Section 4 and Section 5 are
devoted to a comprehensive review of the literature concerned with the
effects of electric fields on biopolymers, and with the identification
of additional mechanisms by which TTFields might interact with cells. Section 4 covers electric field interactions with the cell membrane and the cytosol, whereas the focus of Section 5 penetrates
deeper into the cell, shedding light on the electric field effects on
subcellular structures of interest, i.e., microtubules (MTs), actin
filaments (AFs), ionic charges and DNA. Finally, in Section 6,
we present a discussion about the significance of our findings and
about future directions of research that should be undertaken in this
area. We hope this paper will set a solid theoretical foundation for
future studies into the biophysics of TTFields.
2. Induced Electric Fields within Biological Cells in Mitosis
The topic of induced electric fields in
and around biological cells subject to DC or AC fields has been
investigated for decades. The preliminary and most popular studies on
the analytical description of steady-state trans-membrane potential
induced on spherical cells go back to the work of H.P. Schwan and
colleagues [25].
Arguments were presented to account for the influence of the membrane
conductance, surface admittance and spatial charge effects [25], as well as for the geometric and material properties of the cell and the surrounding medium [26].
The impact of external electric fields on a living cell significantly
depends on the cell’s shape. Concerning analytical solutions for
non-spherical cell shapes, many authors proposed appropriate adaption of
the governing equations going back to the work presented in Reference [27].
Later models aimed to study electric polarization effects on oblate and
prolate homogeneous and single-shell spheroids have been developed [28]. They were later extended to arbitrarily oriented cells of the general ellipsoidal shape [29].
Importantly, the induced electric field inside a spherical cell is
uniform, whereas increasing non-uniformities are predicted for
deviations of the regular shape.
Another important aspect is the frequency-dependency of
the induced trans-membrane voltage and thus also the intracellular field
strength, as predicted by the above-mentioned studies and additional
research reported elsewhere [30,31,32,33,34].
For low frequencies, the intracellular space is shielded to a large
degree from extracellular electric fields. For example, the electric
field strength inside a typical spherical cell is approximately five
orders of magnitude lower than that outside the cell [35,36].
However, as the frequency of the field increases, the high membrane
field gain diminishes, allowing for higher field intensities to
penetrate into the cell.
Recently, Wenger et al. [37]
developed a computational model to study the application of TTFields to
isolated cells during mitosis, specifically during metaphase and at
different stages of cytokinesis. Comsol Multiphysics (www.comsol.com) was used to solve for the scalar electric potential V for
frequency ranges between 60 Hz and 10 GHz. With voltages of opposite
signs set as boundary conditions, a uniform field of 1 V/cm was induced
in the model domain. Following 3D confocal microscopy findings [38,39],
the metaphase cell was represented by a sphere with a 10 µm radius and
three different stages of cytokinesis were modeled with increased
distance between the elliptical mother and daughter cell (see Figure 1,
left panel). Three model domains, the extracellular space, the
cytoplasm and the membrane, were assigned typical dielectric properties,
electrical conductivity and relative permittivity [37].
Figure 1
(Left) Schematic diagrams of the cell geometries
for metaphase and three stages of cytokinesis. Black lines indicate the
electric field contours. (Right) The maximum intracellular electric field strength in V/cm plotted as a function of field frequency …
For a spherical cell during metaphase, the modeling
results predict that for frequencies lower than 10 kHz only small
changes of the field are detected and the intracellular field strength, Ei, almost equals zero. A first significant increase of Ei is observed at approximately 200 kHz, and Ei increases rapidly as the frequencies increase above this value. This can be seen in the inset of the right panel in Figure 1,
which shows a zoomed view of the blue M-phase cell. This transition
region depends on the dielectric properties of the cell and its
membrane. Nonetheless, above 1 MHz electric current is shunted across
the membrane and the impedance is dominated by the cytoplasm. Thus, for
an increasing frequency, the electric field inside the cell is augmented
and at 1 GHz the cellular structure becomes ‘‘electrically invisible’’
as previously reported [33]. The directions of the electrical field near the cell membrane resemble already predicted results [40].
The model further showed that within the dividing cell the
intracellular electric field distribution is non-uniform with highest
field intensities at the cleavage plane (black lines in the left panel
of Figure 1).
These maximum intensities are much higher than the applied field and
appear for frequencies in the range 100–500 kHz depending on the stage
of cytokinesis, i.e., how far the cell division has already progressed.
The corresponding curves are plotted in the right panel of Figure 1, where the highest maximum intracellular field strength of ~22 V/cm is observed for the cell in late cytokinesis.
Due to the inhomogeneity in the electric field
distribution, significant dielectrophoretic (DEP) forces are expected to
develop within the cell and these DEP forces are thought to be
important factors in the mechanism of action of TTFields [41].
This DEP force causes the motion of polarizable particles as a result
of the interaction of a non-uniform electric field with their induced
dipole moment F=p??E [42]. The DEP force is proportional to the volume of the particle v, its effective polarizability ? and the square of the gradient of the electric field according to: ?F DEP?=1/2?v?Re[?(E˜??)E˜?] using complex phasor notation [42,43].
Thus, the magnitude of the DEP force component is proportional to the
magnitude of the gradient of the squared electric field, |F|????|E|2?? in (V2/m3).
The DEP force component showed well-defined peak frequencies at 500,
200, and 100 kHz, respectively, for the three stages considered, from
the earliest to the latest stage [37]. This coincides with the peaks of the maximum electric field inside the cell, which are presented in the right panel of Figure 1.
Apart form testing different field intesities, the
computational study tested another aspect of TTFields. Namely, it has
been shown that the optimal frequency for the inhibitory effect of
TTFields is inversely related to cell size [2,44] and that cell volume is increased in almost all cell lines treated with TTFields [45].
The simulation results predicted that the above-mentioned peak
frequencies decrease and converge as a function of an increasing cell
radius. The corresponding maximum values of the DEP force component also
decrease with an increasing cell size with equal decay rates for all
cytokinesis stages [37].
In summary, these results obtained by computational
modeling confirmed several predicted outcomes of the application of
TTFields to biological cells. During metaphase a uniform non-zero Ei is
induced. Depending on cell properties, the frequency window of the
predicted transition range might be shifted. During cytokinesis, a
non-uniform Eiis induced with a substantially
increased strength at the cleavage furrow. Frequency-, cell size-, and
field-intensity dependences were confirmed.
Experimental validation of the predicted
induced field strength values would be of great interest. Electric field
strengths have typically only been able to be measured inside membranes
with voltage dye and patch-clamp techniques. A promising technique by
Tyner et al. [46]
reported the generation of a nanovoltmeter that can report local
electric fields in the cell and its use would be ideal to calibrate the
strength and local distribution of electric fields in the presence of
externally applied AC electric fields.
3. Subcellular Electrical Conduction and Electrostatics
3.1. Protein Conduction
Biological polymers are made up of
various proteins, such as actin and tubulin, or nucleic acids as is the
case of DNA and RNA. These structures have uncompensated electrical
charges when immersed in water but ionic solutions such as the cytoplasm
provide a bath of counter-ions that at least partially neutralize the
net electric charge. This, however, results in dipolar and higher-moment
electric field distributions complicating the situation greatly.
Biological water is also believed to create structures with ordered
dipole moments and complex dynamics at multiple scales [47],
which adds to the complexity of subcellular electric field effects.
Additionally, free ions endow the cell with conducting properties along
well-defined polymeric pathways as well as in a diffusive way. Membranes
support strong electric fields (on the order of 105 V/cm),
which, due to counter-ion attraction to charged surfaces in solution,
result in Debye screening. This causes an exponential decay of these
electric fields on a nm scale [48] but not their complete disappearance when measured in the cell interior (hence a field strength of 105 V/cm decreases to approximately 0.01 V/cm over 100 nm).
The idea that proteins in organisms may have semiconducting properties dates back many decades [49,50] but protein conductivity has been found to be strongly dependent on the hydration state of proteins [51]. Electrical properties of cells and their components were promoted by Szent-Györgyi [52,53],
but significant experimental challenges of measuring electric fields
and currents at a sub-cellular level impeded progress in this field. The
development of more precise experimental tools in the area of
nanotechnology holds great promise for rapid progress in the near future
[54,55]. Owing to the fact that there have been many previous reviews of electromagnetic effects in biology [1,56,57,58],
here we mainly focus on the electrical properties of MTs, actin AFs,
ion channels, cytoplasmic ions and DNA with special interest into
dynamical electrical properties involving AC fields in the range of 100
kHz. A crucial role of water in the transmission of electrical pulses
due to the structure imparted by hydrophilic surfaces [59]
is also worth noting. Charge carriers related to protein
semi-conduction have largely been electrons, protons as well as ions
surrounding proteins in physiological solution. AFs and MTs have been
implicated in facilitating numerous electrical processes involving ionic
and electronic conduction [60,61] and have been theorized to support dipolar and/or ionic kink-like soliton waves traveling at speeds in the 2–100 m/s range [14,62].
Due to strong coupling between electrical and mechanical degrees of
freedom in proteins, mechano-electric vibrations of MTs have been
modeled both analytically and computationally [63,64]. Electric fields generated by MTs have been modeled extensively and reviewed recently [65,66,67], although experimental measurement of these fields remains extremely difficult, especially in a live cellular environment.
3.2. Electrostatic Interactions Involving Charges and Dipoles of Tubulin
The net charge on a tubulin dimer depends on pH and changes from +5 at pH 4.5 to 0 at pH 5 and drops to ?30 at pH 8 [68].
However, in the cytoplasm, a vast majority of electrostatic charges are
screened over the distances greater than the Debye length (which varies
between 0.6 and 1.5 nm depending on the ionic strength). Therefore,
calculating the force due to an electric field of a static electric
field with a strength of 1 V/cm acting on a 10 µm-long microtubule, we
find from F = qE, with q = 10?13 C for unscreened charges, that results in F =
10 pN assuming the field is largely undiminished when penetrating a
cell, which is in general a major oversimplification. This latter issue
will be addressed at the end of this review. Even if the force is
essentially unchanged, the Debye screening of electrostatic charges
means that less than 5% of the charge remains exposed to the field
resulting in a net force of at most 0.5 pN, most likely insufficient to
exert a major influence on the cytoskeleton. If the field oscillates
rapidly, the net force would cancel out over the period of these
oscillations, i.e., on a time scale of microseconds or less.
The next aspect of MT electrostatics is the effect on the
dipole moments of tubulin dimers and of entire MTs. The dipole moment of
tubulin (excluding the very flexible and dynamic C-termini which we
discuss separately below) has been estimated to be between 566 debye for
the ?-monomer and 1714 for the ?-monomer [69].
However, this is also strongly tubulin-isotype dependent, so these
numbers vary a lot between various tubulin isotypes from 500 to 4000
debye [70]. Note that 1 debye is a unit of electric polarization and is equal to 3.33 × 10?30 Cm. Therefore, taking the dipole moment of a free tubulin dimer as p = 3000 debye as a representative number, we find the interaction energy U with an electric field of E = 1 V/cm, and obtain U= ?pE, and hence U = 10?24 J. This is clearly too small (4000 times smaller than thermal energy kT)
to affect the dynamics of an individual tubulin dimer. However, a
single MT contains 1625 dimers per 1 µm of its length, so it could
eventually accumulate enough net dipole strength to be significantly
affected by the field. Unfortunately, this is very unlikely because of
the almost perfect radial symmetry of tubulin dipole arrangements in an
MT, which has been predicted by a computer simulation [70].
The individual dipole moments of constituent dimers will almost
perfectly cancel out in the radial arrangement of an MT cylinder. There
is a small non-cancellation effect along the MT axis but this amounts to
less than 10% of the next dipole moment, hence it is doubtful that an
entire MT can be aligned in electric fields with intensities lower than
10 V/cm. Unless one uses time-dependent fields (e.g., those used in
Reference [71]), much stronger fields are needed for static effects. To put it another way, the torque ? between a dipole moment of an MT, p, and an external electric field, E, is proportional to their vector product: ? = pxE.
For the force to have a meaningful effect on a microtubule, it should
exceed 1 pN for lever arm on the order of 1 µm giving a torque of 10?18 Nm.
With fields on the order of 1 V/cm, and a dipole moment of 3000 debye
per tubulin dimer, even if these dipoles were perfectly aligned, it
would result in a 1 µm MT only experiencing a torque of 10?21 Nm, which is approximately 1000 times too low to be of relevance.
Various special situations involving electrostatic effects on MTs were calculated earlier [68]. Note that a force between a charge and an electric field is given by F = qE(x) where E(x)
is screened exponentially over the Debye length, which is approximately
1 nm. Hence, a test charge of +5e a distance of 5 nm from the MT
surface for a 10-µm MT, experiences a force of 12 pN in water and 1 pN
in ionic solution. A tubulin dimer with a dipole of 3000 debye in the
vicinity of a microtubule experiences an electrostatic energy of 3 meV.
MT-MT interactions due to their net charges with Debye screening
accounted for lead to a net force of 9 pN when separated by 40 nm
resulting in net repulsion between them. However, at longer distances
attractive forces prevail and the corresponding dipole-dipole attraction
at 90 nm is only 0.08 pN. The authors of the references [15,16,22] estimated the maximum electrostatic force in the mitotic plate, which was given as F = 6n2 pN per MT where n is the number of elementary charges on each protofilament. Since F is
estimated to be 1–74 pN for a typical MT, the estimate is 0.4–3.5
uncompensated elementary charges per protofilament. The range of values
of the forces involved is certainly within the realm of possible force
requirements for chromosome segregation (about 700 pN per chromosome).
3.3. MT Conductivity
The building block of an MT is a tubulin
dimer, containing approximately 900 amino acid residues with a combined
mass of 110 kDa (1 Da is the atomic unit of mass, 1 Da = 1.7 × 10?27 kg).
Each tubulin dimer in an MT has a length of 8 nm, along the MT cylinder
axis, a width of about 6.5 nm and the radial dimension of 4.6 nm. The
inner core of the cylinder, known as the lumen, is approximately 15 nm
in diameter. MTs have been predicted to exhibit intrinsic electronic
conductivity as well as ionic conductivity along their length [72].
MTs have a highly electro-negatively charged outer surface as well as
C-terminal tails (TTs), resulting in a cloud of counter-ions surrounding
them. Experiment and theory demonstrate that ionic waves are amplified
along MTs [72,73].
Since MTs form a cylinder with a hollow inner volume (lumen), MTs have
also been theorized to have special conducting properties involving the
lumen [55]
but there has been no direct experimental determination of the electric
properties of the MT lumen. Many diverse experiments were performed to
date in order to measure the various conductivities of MTs, with a range
of results largely dependent on the experimental method, and this has
been reviewed elsewhere [74].
Interestingly, Sahu et al. [75,76]
measured conductivity along the periphery of MTs, where the DC
intrinsic conductivities of MTs, from a 200 nm gap, were found to be
approximately 10?1 to 102 S/m. Unexpectedly, MTs
at certain specific AC frequencies (in several frequency ranges) were
found to be approximately 1000 times more conductive, exhibiting
astonishing values for the MT conductivities in the range of 103to 105 S/m [55,76].
Some resonance peaks for solubilized tubulin dimers were reported as:
37, 46, 91, 137, 176, 281, and 430 MHz; 9, 19, 78, 160, and 224 GHz; and
28, 88, 127, and 340 THz. However, for MTs, the corresponding resonance
peaks were given as: 120, 240, and 320 kHz; 12, 20, 22, 30, 101, 113,
185, and 204 MHz; and 3, 7, 13, and 18 GHz. Therefore, for MTs there is
some overlap with the 100 kHz range indicating a possible independent
confirmation of the sensitivity of MT AC conductivity to this electric
field frequency range. These authors showed experimental evidence that
the high conductivity of the MT at specific AC frequencies only occurred
when the water channel inside the lumen of the MT remained intact [55].
Electro-orientation experiments involving MTs have shown
an increased ionic conductivity (0.150 S/m) compared to the buffer
solution free of tubulin by as much as 15-fold [77]. MTs exposed to low frequency AC fields (f <
10 kHz) exhibit a flow motion due to ionic convection. However, for
frequencies above 10 kHz this convection effect is absent. Electric
fields with intensities above 500 V/cm and frequencies in the range of
10 kHz–5 MHz, are able to orient MTs in solution. As a point of
interest, this frequency range overlaps with the range used by Kirson et
al. [2]. However, the intensities of the electric fields used are substantially higher. For instance, a 900 V/cm field with f = 1 MHz was able to align MTs within several seconds [77]. Impedance spectroscopy enabled the measurements of the dielectric constant of tubulin as ? = 8.41 [78]. Uppalapati et al. [79]
exposed taxol-stabilized MT’s in solution to an AC field, which
exhibited electro-osmotic and electro-thermal flow, in addition to MT
dielectrophoresis effects. Interestingly above f = 5 MHz, electro-hydrodynamic flows were virtually eliminated, and the conductivity of MTs was estimated at 0.25 S/m.
Priel et al. demonstrated MTs’ ability to amplify ionic
charge conductivity, with current transmission increasing by 69% along
MTs [60],
which was explained by the highly negative surface charge density of
MTs that creates a counter-ionic cloud subjected to amplification along
the MT axis [60]. From Priel et al.’s conductance data, the approximate ionic conductivity of MTs is found to be an astonishing 367 S/m [74].
Below, in the second part of this review, we quantitatively assess AC
electric fields on these ionic conductivity experiments, which are
expected to be sensitive to the electric field frequencies in the 100
kHz to 1 MHz range.
The multiple mechanisms of MT conductance
provide ample possibility to explain the varied reports on MT
conductivity in the literature. Ionic conductivity along the outer edge
of the MT, intrinsic conductivity through the MT itself, and possible
proton jump conduction and conductivity through the inner MT lumen have
all been suggested. It is conceivable that TTFields may affect ionic
conductivities along MTs as is argued below.
4. Collective Effects in the Membrane and Cytoplasm
4.1. Membrane Depolymerization Effects
The electric field across the membrane is on the order of 105 V/cm
(0.1 V over 8–10 nm), which is 4–5 orders of magnitude greater than
TTFields’ amplitude. Therefore, a direct effect of TTFields on cancer
cells’ membrane potential is expected to be very minor.
4.2. Ion Channel Conduction Effects
Liu et al. [80] reported activation of a Na+ pumping
mode with an oscillating electric field with a strength of 20 V/cm,
which is comparable to the fields of interest in this review, but at a
much higher frequency (1.0 MHz) than those of interest. Moreover,
neither K+ efflux nor Na+ influx was stimulated by
the applied field in the frequency range from 1 Hz to 10 MHz. These
results indicate that only those transport modes that require ATP
splitting under the physiological condition were affected by the applied
electric fields, although the field-stimulated K+ influx and Na+ efflux
did not depend on the cellular ATP concentration in the range 5 to 800
µM. Computer simulation of a four-state enzyme electro-conformationally
coupled to an alternating electric field [81,82] reproduced the main features of the above results.
Channel densities strongly vary among different neuronal
phenotypes reflecting different stabilities of resting potentials and
signal reliabilities. In model cell types such as in mammalian medial
enthorinal cortex cells, modeled and experimental results match best for
an average of 5 × 105 fast conductance Na+ and delayed rectifier K+ channels per neuron [83]. In unmyelinated squid axons counts can reach up to 108 channels per cell. In model channels such as the bacterial KcsA channel one K+ ion crosses the channel per 10–20 ns under physiological conductances of roughly 80–100 pS [84],
which is consistent with the frequencies of external electric
stimulation mentioned above. This allows for a maximum conduction rate
of about 108 ions/s. Estimating the distances between the
center of the channel pore and the membrane surface to scale along 5 nm
and assuming the simplest watery-hole and continuum electro-diffusion
model of channels, this would provide an average speed of 0.5 m/s per
ion. Ion transition occurs through a sequence of stable multi-ion
configurations through the filter region of the channels, which allows
rapid and ion-selective conduction [85].
The motion of ions within the filter was intensively studied applying
classical molecular dynamics (MD) methods (for a summary see Reference [86]) and density functional studies (e.g., [87]). MD methods used in these simulations solve Newton’s equations of motion for the trajectory of ions.
Time scales for the processes in ion channels can be estimated by the time for translocations (ttr) between two filter sites separated by ~0.3 nm, i.e., 5 × 10?10 s [88] and 5 × 10?11 s [87]. Transition rates (from potential mean force maps and the Kramer transition rate model [89]
are consistent with these numbers. Changes between a non-conductive and
a conductive state in the KcsA occur at a rate of 7.1 × 103 s?1, giving a life-time of the non-conducting state of 0.14 ms (~10?4 s) [89]. As the duration of the rather (stable) non-conducting state scales in the range 10?3–10?4 s and the within filter translocation time is on the order of 10?11 s, we can expect about 107 filter state changes during a non-conducting state and about 1010 switches
per second (10 GHz). Consequently, these time scales are incompatible
with those resulting from the effects of 100 kHz electric fields (10
?s).
4.3. Electric Field Effects on Cytoplasmic Ions
The cytoplasm provides a medium in which
fundamental biophysical processes, e.g., cellular respiration, take
place. Most biological cells maintain a neutral pH (7.25–7.35) and their
dry matter is composed of at least 50% of protein). The remaining dry
material is composed of nucleic acids, trace ions, lipids, and
carbohydrates. Most of the trace ions are positively charged. A few
metallic ions are found which are required for incorporation into
metallo-proteins, e.g., Fe2+, typically at nanomolar concentrations. In Table 1, we summarize the composition of the cytoplasm regarding the most abundant and important components.
Based on the above, we can estimate the net force on the total charge in the cytoplasm as F = qE, q = 4 × 1011 e and E =
1 V/cm, so the total force is approximately 6 µN, which is sufficient
to cause major perturbations in the cell interior. As discussed above,
this is strongly depended on the ability of the electric field to
penetrate into the cell’s interior, which is easier in the case of
non-spherical cells. The net outcome of these ionic oscillations away
and towards attractively interacting protein surfaces inside the
cytoplasm can be a concomitant series of oscillations of the structures
affected by the ionic clouds as schematically shown below.
The viscosity of cytoplasm is approximately ? = 0.002 Pa·s [90], hence we can estimate the friction coefficient for an ion in solution as ? = 6??r where r is the ionic radius (hydration shell radius) and find ? = 2 × 10?12 Pa·s·m. In an oscillating electric field of amplitude 1 V/cm and a frequency f = 200 kHz, an ion’s position will follow periodic motion given by: x(t) = 0.1·A·sin(2?ft),
i.e., will execute harmonic motion out of phase with the field, with
the same frequency and an amplitude A approximately 10% of the radius.
However, these ions are simultaneously subjected to the Brownian motion
due to their collisions with the molecules of the solvent.
To estimate the effect of an oscillating external electric
field on the diffusion of a single biomolecular particle (protein, DNA,
simple ion, etc.), the Langevin equation can be written down and
solved. In the Ito interpretation [91], the position Xt of such a particle is given as a function of time by [92]:
dXt= F(Xt)?dt+2kBT???????dWt
(1)
where ? is the friction coefficient of the particle, T=310 ? is the temperature and kB is the Boltzmann constant. The first term on the RHS of Equation (1) accounts for the influence of deterministic forces F(Xt). Assuming there is no interaction other than the coupling with an external electric field E(Xt), we can write F(Xt)=qE(Xt) where q is
the net charge of the particle. At intermediate frequencies, i.e.,
around 100–200 kHz, the wavelength is around 1000 m, which is obviously
much larger than the size of a typical cell. Thus, assuming no important
changes due to the dissipation of the field, E can be considered almost constant in a cellular environment: F(Xt)=qE(t).
The second term on the RHS represents the random motion, which is due
to the many kicks with the surrounding water molecules. Hence, dWt is usually given by [91]:
dWt~dt1/2 ?(t)
(2)
where ?(t) is
a random number, which follows a normal distribution with a mean equal
to 0 and a variance equal to 1. Since the Brownian motion is
proportional to dt1/2, an estimate of dt is needed to evaluate the influence of the external electric field over the thermal noise. The time step dt can
be estimated by the time interval between two series of collisions with
water molecules, each series being the sum of enough collisions so that
the outcome is approximately Gaussian. In other words, one can assume dt=dx/vH2O, where dx is the typical separation between two water molecules, i.e., dx=mH2O/?H2O??????????3 where mH2O is the mass of one water molecule and ?H2O is the mass density of water. Here, vH2O is the velocity of water molecules given by vH2O=3kBT/mH2O???????????. The use of the above parameters leads to a typical time step of dt~5.0×10?13 s.
The two terms in the RHS of Equation (1) above can be
compared to estimate the effect of an electric field over the thermal
noise. In the case of a spherical particle, we can assume ?=6??r, where the hydrodynamic radius is r=1.8 ? and the viscosity of the cytoplasm is ?=0.002 Pa·s [90]. By taking q=1 e (a single ion) and E=E0cos2?ft with E0=1 V/cm, it turns out that the amplitude of the coupling term associated with the electric field is qE0/?=2.36 × 10?6 m/s. On the other hand, the noise coefficient is 2kBT/???????? (dt)?1/2=50.2 m/s when the estimate obtained above is used: dt~5.0×10?13 s, which is much larger than the deterministic term. Even in the case of less frequent Brownian collisions, e.g., dt~10?6 s,
the noise coefficient is 0.035 m/s which is still much larger than the
coupling with the electric field, meaning that an electric field of
amplitude 1 V/cmhas an exceedingly small probability to influence the diffusion of a single Brownian particle even if the net charge q is 100–1000 times larger as in the case of a protein.
Alternatively, it can be shown that an oscillating electric field at intermediate frequencies with an amplitude of 1 V/cm has
no direct sizable effect on the diffusion of biomolecules by
considering an ensemble of molecules instead of a single Brownian
particle. Assuming a constant electric field E, the distribution of particles as a function of time is given by [93]:
P(x,t)= 12Dt????exp?????(x –x0?qEt?)22Dt????
(3)
Here, D=kBT/? is
the diffusion coefficient for one particle. From the above equation, a
typical time when the particles start to be drifted away because of the
electric field is t=2(kBT)?/(qE)2. For a single ion (q=1 e, r=1.8 ?), t=226.1 s, whereas for a typical globular protein (q~100 e, r~1.0 nm), t=0.13 s, which is much larger than the period of an electric field oscillating at hundreds of kHz.
For the sake of simplicity, we have not
discussed here how an electric field could induce conformational changes
in biomolecular structures, which would affect their charge
distributions and dipolar spectra, which, in turn, could modify their
diffusion by inducing new interactions with the surrounding molecules.
An estimate of such indirect effects would require careful
investigations of the studied system based on realistic MD simulations.
In this case, the external electric field can be either computationally
modeled by initializing the system with added kinetic energy in the
directions of the normal modes or by adding an extra coupling term to
the force field [94].
5. AC Electric Field Effects on Subcellular Structures
5.1. Electric Field Effects on MTs
Several experimental efforts were made aimed at measuring the electric field around MTs. Vassilev et al. [71]
observed alignment of MTs in parallel arrays due to the application of
electric fields with intensities of 0.025 V/cm and of pulsed shape. In
cell division, coherent polarization waves have been implicated as
playing the key role in chromosome alignment and their subsequent
separation [18,19]. Electric fields in the range of 3 V/cm were applied by Stracke et al. [75]
to suspended MTs, which moved at pH 6.8 from the negative electrode to
the positive one indicating a negative net charge, and an
electrophoretic mobility of about 2.6 × 10?4 cm2·V?1·s?1. The work of Uppalapati et al. [79]
covers the range of frequencies overlapping with TTFields, although the
amplitudes are much larger due to the voltage bias of 40 V across a
20-µm gap giving an electric field of 2 × 104 V/cm as opposed to 1 V/cm). Below 500 kHz, MTs flow toward the centerline of electrodes. The electro-osmotic force causes
the movement of the fluid in a vortex-like manner. This represents the
Coulomb force experienced by the ionic fluid due to the applied voltage.
The fluid flow velocity ? is proportional to the tangential component of the electric field Et, surface charge density ?, the solution’s viscosity ? and the inverse Debye length ? such that: ? = Et ?/??.
At lower frequencies, flow velocity is larger. On the other hand, due
to strong heating effects of the AC field, the electro-thermal force
causes motion of MTs along the length of the electrodes. Above 500 kHz
MTs flow toward the gap between the electrodes due to dielectrophoresis.
The DEP force experienced by MTs in a non-uniform electric field is
given by:
?FDEP?=14??m[?2?m(?p??m)+?m(?p??m)?2?2m+?2m]?|E|2
(4)
where the symbols with subscript “m” refer to the medium and “p”
to the particle. Hence, this process is largely driven by the
difference between the conductivities and permittivities of the MTs and
the medium, (?p ? ?m) and (?p ? ?m),
respectively. We predict that lowering the pH of the solution to the
isoelectric point of MTs around pH 5 should substantially reduce this
effect and additionally lowering the frequency will reduce it further
due to the dependence of the first term on the square of the frequency.
At ~5 MHz, the electro-osmotic and electro-thermal flow balance each
other out with the flow of MTs being solely due to dielectrophoresis. It
is important to compare the dielectrophoretic force to Brownian motion
in order to determine whether or not electric fields are sufficiently
strong to overcome random motion, i.e., to find out if the dielectric
potential exceeds the thermal energy, i.e.,
?r3?m[(?p??m)(?p+2?m)]E2>kT
(5)
where ?m is the dielectric constant of the medium and ?p is the dielectric constant of the particle. E is the electric field strength and r the
radius of the particle. Taking as an example a tubulin dimer in
solution and the corresponding values of the dielectric constants, one
finds that E must exceed 0.25 V/cm for the
field to be effective in orienting polarizable tubulin dimers.
Similarly, for a 10-µm long MT we replace the factor ?r3 with ?r2L, where r is the radius of a MT (12.5 nm) and L its length, to obtain a condition that E >
0.01 V/cm. Clearly, the electric field values of 1 V/cm (even if they
are screened by a large factor inside the cell) are sufficient to exert
electrophoretic effects on tubulin and MTs. The longer the MT, the more
pronounced the dielectrophoretic effect is predicted to occur.
Recently, Isozaki et al. [95]
used MTs labeled with dsDNA to manipulate the amount of net charge and
observe the mobility of these hybrid structures compared to control
where MTs where only labeled fluorescently with two different tags. It
was found for control MTs that the electrophoretic mobility is
approximately: 2 × 10?8 m2·V?1·s?1which is consistent with Stracke et al. [75].
For field strengths of approximately 1 V/cm, one can estimate the
average velocity of MT translocations as 2 µm/s. They also stated ?D = 0.74 nm as the Debye length, ? = 8.90 × 10?4 kg·m?1·s?1 and ? = 6.93 × 10?10C·V?1·m?1 as
the viscosity and dielectric constant of the buffer, respectively.
Importantly, they estimated the effective charges of the TAMRA- and
AlexaFluor 488-tagged tubulin dimer as 10 e? and 9.7 e?,
which obviously is only a fraction (approximately 20%–30%) of the
vacuum values but much larger than earlier experimental estimates.
Electrophoresis experiments were also performed by van den Heuvel et al.
[96], with electric field strengths of 40 V/cm, yielding MT electrophoretic mobility in the range of 2.6 × 10?8 m2·V?1·s?1, in line with previous reports. They found the effective charge of a tubulin dimer to be approximately 23 e?.
5.2. Tubulin’s C-Termini Dynamics and AC Electric Fields
Computer simulations demonstrate
that ionic waves can trigger C-termini to change from upright to
downward conformations initiating propagation of a travelling wave [97]. This wave is predicted to travel as a “kink” solitary wave with a phase velocity of vph = 2 nm/ps [97].
A typical time scale for C-termini motion is 100 ps, which is too fast
for the 100 kHz frequency range of TTFields. However, C-termini being
very flexible and highly charged (with approximately 40% of the
tubulin’s charge located there) are likely to dynamically respond to
electric fields as local changes of pH are correlated with positive and
negative electric field’s polarities, respectively. This effect can
cause MT instability as well as interference with motor protein
transport as discussed below. A stable dimer conformation is predicted
to have C-termini cross-linked between the monomers as shown in Figure 2.
Figure 2
A cross-linked conformation of C-termini stabilizes a straight
orientation of a tubulin dimer. A disruption of this conformation can
cause MT instability.
5.3. Ionic Waves along MTs and AC Electric Fields
Manning [98]
postulated that polyelectrolytes may have condensed ions in their
surroundings if a sufficiently high linear charge density is present on
the polymer’s surface [99]. The Bjerrum length, ?B,
is defined as the distance at which thermal fluctuations are equally
strong as the electrostatic interactions between charges in solution
whose dielectric constant is ? at a given temperature T in Kelvin. Here, ?0denotes the permittivity of the vacuum and kB is the Boltzmann constant. Counter-ion condensation occurs when the average distance between charges, b, is such that ?B/b = S>
1. In this case, the cylindrical volume of space depleted of ions
outside the counter-ion cloud surrounding the polymer functions as an
electrical shield. The “cable-like” electro-conducting behavior of such a
structure is supported by the polymer itself and the “adsorbed”
counter-ions, which are “bound” to the polymer in the form of an ionic
cloud (IC). Tuszynski et al. [68]
calculated an electrostatic potential around tubulin and extended this
to an MT, which demonstrated non-uniformity of the potential along the
MT radius with periodically repeating peaks and troughs along the MT
axis. Consequently, MTs have been viewed as “conducting cables” composed
of 13 parallel currents of ionic flux (corresponding to 13
protofilaments of MTs) and attracting an IC of positive counter-ions
close to its surface and along tubulin C-terminal tails (TT), while
negative ions of the cytosol are repelled away from the MT surface. The
thickness of the negative ion depleted area corresponds to the Bjerrum
length. An estimate of the respective condensate thickness ? of the
counter-ion sheath for the tubulin dimer (?TD) and C-termini (?TT) is ?TD = 2.5 nm and ?TT = 1.1 nm, as analyzed in [61]. Using a Poisson–Boltzmann approach, the capacitance of an elementary ring of an MT consisting of 13 dimers is found as [100]:
C0=2??0?lln(1+lBRIC)
(6)
where l stands for the length of a polymer unit and RIC = ?TD + ?TT for the outer radius of an IC. For a tubulin dimer: CTD = 1.4 × 10?16 F and for an extended TT: CTT = 0.26 × 10?16 F. Hence:
C0=C0+2×C0=1.92×10?16 F
(7)
Estimating the electrical resistance for a complete tubulin ring gives R0 = 6.2 × 107 ? [60,100].
Including the conductance of both nanopores through an MT surface
accounts for the leakage of IC cations into the lumen area and gives a
conductance G0, of a ring as G0 = ?1 + ?2 = (2.93 + 7.8) nS = 10.7 nS and the corresponding resistivity as R = 1/G0= 93 M?.
A simple equivalent periodic electric circuit simulating
one protofilament of an MT consists of a long ladder network composed of
elementary circuit units as shown in Figure 3 [61].
Figure 3
An effective circuit diagram for the n-th unit with characteristic
elements for Kirchhoff’s laws applied to a microtubule as an ionic cable
[61].
The longitudinal ionic current encounters a series of Ohmic resistors R0 for each ionic conduction unit (an MT ring). The nonlinear capacity with the charge Qn for the n-th site of the ladder is in parallel with the total conductance G0 of the two TTs of a dimer. Then using Kirchhoff’s law:
in?in+1=?Qn?t+G0?n,
(8)
?n?1??n=R0in,
(9)
we find the equations for the voltage propagation:
?Qn?t=C0??n?t?C0?0??n?C0?0?(t?t0)??n?t?2b0C0?n??n?t
(10)
Introducing an auxiliary function u(x, t) unifying the voltage and its accompanying IC current as:
un=Z1/2in=Z?1/2?n
(11)
with the characteristic impedance defined as:
Z=1?C0,
(12)
leads in the continuum limit to the electric signal propagation equation:
?2?u?x?l23?3u?x3?ZC0l?u?t+ZC0?0?l(t?t0)?u?t+2Z3/2b0C0lu?u?t?1l(ZG0+Z?1R0?ZC0?0?)u=0
(13)
The characteristic charging (discharging) time of an elementary unit capacitor C0through the resistance R0 is given by T0 = R0C0 with an estimate for T0 = 1.2 × 10?8 s and the characteristic propagation velocity of the ionic wave: v=l/T0 as v0 = 0.67 m/s. A standard travelling-wave with speed v, for the normalized function u(x, t), can
be used as a solution of the propagation equation, which is a soliton
that preserves its width but its amplitude decays over the length of
about 400 units corresponding to 3.2 µm, which is of the order of the MT
length. Interestingly, a characteristic time for this excitation can
readily be estimated as 1.2 × 10?5 s whose inverse, the frequency, f, is very close to the TTField value, i.e., 90 kHz. The maximum frequency allowed in this model is 68 MHz.
To summarize, ionic conduction along and away from charged
protein filaments such as MTs involves cable equations resulting from
equivalent RLC circuits surrounding each protein unit in the network.
Conduction along the filaments experiences resistance due to viscosity
in the ionic fluid. Capacitance is caused by charge separation forming a
double layer between the MT surface and ions with a distance separating
them comparable to the Bjerrum length. Inductance is caused by helical
nature of the MT surface and consequently, solenoidal flows of the ionic
fluid along and around the MT. The key numerical estimates of the RLC
circuit components are as follows [60]. For a single dimer: C = 6.6 × 10?16 F, R1 = 6 × 106 ? (along the MT), R2 = 1.2 × 106 ? (perpendicular to the MT) and L = 2 × 10?12 H.
These numbers can be used to estimate characteristic time scales for
the oscillations (LC) and exponential decay (RC) taking place in this
equivalent circuit. We obtain for decay times (? = RC) the following values: (a) ?1 = 10?8 s along the MT length and (b) ?2 = 10?9 s away from the MT surface. However, due a low value of inductance L, the corresponding time for electromagnetic oscillations is found using ?0 = (LC)1/2 as ?0 = 0.2 × 10?12 s
= 0.2 ps. Clearly, the oscillation times are too short for potential
effects with 100 kHz-range fields (the time of TTFields oscillations is
on the order of 5–10 µs). The decay times are much closer so we will
focus on these parameters. Repeating these calculations for a
microtubule of length l, we note that R1 scales with length of a microtubule, while R2 is length independent. The corresponding capacitance in both cases scales with length, therefore ?1 scales with length squared (l2) while ?2 scales
with length. To obtain actual values, we need to multiply the values
for a single ring by the number of rings in an MT. We use the values
found for a single ring, i.e., ?1 = 10?8 s and ?2 = 2 × 10?9 s
and scale them accordingly to estimate the length of MTs that could
experience resonant effects in terms of ionic currents along and away
from their surface. This way we find the scaling factor that leads to
the characteristic times on the order of 10 µs. Therefore, for
longitudinal effects, on the order of 50 rings, MTs only 400 nm long
would respond to 100 kHz stimulation. On the other hand, for ionic flows
pulsating radially around an MT, a 20-µm long MT would be required.
These results are very sensitive regarding the choice of parameter
values, especially the resistivity where diverse estimates can be found
in the literature. In general, there is strong overlap between the time
scales of ionic wave propagation and electric field stimulation. It is
conceivable that both effects play a role depending on the orientation
of the field vis a vis the geometry of mitotic spindles and the
MTs forming them. It appears that short MTs would be more sensitive to
the longitudinal wave generation by TTFields while long MTs should lead
to perpendicular wave generation.
Current densities should also be briefly discussed in relation to previously reported endogenous current densities, j, in cells, which range from 0.2 to 60 µA/ cm2 [101]. This translates into 0.002 < j < 0.6 A/m2. Since j = ?E where E =
1 V/cm and ? of the cytoplasm has a large range of values reported
between 0.1 and 100, we see that even taking the lower limit of 0.1
would result in ionic currents along MTs that would overwhelm the
intrinsic ion flows in a dividing cell. It is possible that these
externally stimulated currents cause a major disruption of the process
of mitosis and associated intra-cellular effects.
It is also worth mentioning that recently metabolic
oscillations in cells with a period of approximately 10 to 12 s, were
measured in vivo [102]
which is many orders of magnitude slower than any AC electric field
effects discussed here. Hence, it is safe to assume that there is a very
unlikely possibility of electric field effects in the 100 kHz range to
interfere with cellular metabolism.
Finally, it is interesting to address the
issue of the power dissipated due to a current flowing along an MT.
Again, we take as an example a 10 µm-long MT, and we estimate the
average power drain as:
?P?=(1/2)V20[R/(R2+X2c)],
(14)
where Xc= 1/?C is the capacitive resistance. Substituting the relevant numbers we obtain the power dissipated to be in the 10?11 W
range which is comparable to the power generated by the cell in
metabolic processes (100 W of power generation in the body/3 × 1013 cells
in the body). Consequently, additional heat generated by these
processes may be disruptive to living cells although there is no
experimentally detected thermal effect of TTFields.
5.4. Resonance Effects on MTs
Cosic et al. [103,104]
reported EM resonances in biological molecules (proteins, DNA and RNA)
in THz, GHz, MHz and kHz ranges. They proposed the so-called resonant
recognition model (RRM) based on the distribution of energy of
delocalized proteins in a biological system and charge transfer under
resonance with a velocity of 7.87 × 105m/s and covering distances of 3.8 Å between amino acids, giving a characteristic frequency between 1013 and 1015 Hz.
Then they state a variety of charge transfer velocities yielding
different resonant frequencies. Of particular interest to this review is
the velocity v = 0.0005 m/s which produces EMF in the range of
108–325 kHz for TERT, TERT mRNA and Telomere. This velocity corresponds
the propagation of solitons on ?-helices. For tubulin and MTs, three
specific ranges of resonant frequencies have been predicted by the RRM
approach: 97–101 THz, 340–350 THz and 445–470 THz, none of which
overlaps with TTField frequencies.
H-bond strength in MTs has been recently computationally estimated [105]
as ranging from 11.9 k/mol for the weakest bond to 42.2 kJ/mol for the
strongest one and a total of 462 kJ/mol for the ?-tubulin/?-tubulin
interactions and 472 kJ/mol for the ?-tubulin/?-tubulin interactions,
which based on the Planck relationship between frequency and energy
translates into a range of frequency values between 0.3 × 1014 Hz and 1.3 × 1015Hz.
Again, these frequencies are much too high to be affected by TTFields.
Therefore, we do not expect TTFields to be capable of disrupting the MT
structure.
Furthermore, Pizzi et al. [106]
measured microwave resonance effects in MTs and found a resonant
frequency at 1.510 GHz. This may not correspond to bond-breaking between
tubulin dimers but simply to some specific electro-mechanical
oscillations. Finally, Preto et al. [92]
re-evaluated the Froehlich mechanism for long-range interactions and
concluded that classical electromagnetic dipole-dipole interactions at
high enough frequencies can lead to attraction between oscillating
dipoles over distances comparable to the size of the cell. However, even
including a coherently coupled layer of water molecules around a
protein, this would require frequencies in the THz range or higher.
Consequently, almost all of the resonant frequencies listed above fall
well outside the range of potential overlap with the 100 kHz frequencies
of TTFields.
5.5. Ionic Wave Conductivity along Actin Filaments and AC Fields
AFs are approximately 7 nm in diameter,
with a periodic helical structure repeating every 37 nm. Actin filaments
are arranged from actin monomers resulting in an alternating
distribution of electric dipole moments along the length of each
filament [107]. They are characterized by a high electrostatic charge density [108,109] resulting in ionic current conductivity involving the counter-ions surrounding them [109], which is very similar to the effects observed for MTs [60]. The observed wave patterns in electrically-stimulated AFs [30] were very similar to the solitary waveforms recorded for electrically-stimulated non-linear transmission lines [110]. In these experiments [30,42],
an input voltage pulse was applied with an amplitude of 200 mV for a
duration of 800 ms. Electrical signals were measured at the opposite end
of the AF demonstrating that AFs support axial non-linear ionic
currents. Since AFs produce a spatially-dependent electric field
arranged in peaks and troughs [111]
with an average pitch ~35–40 nm, they can be modeled as an electrical
circuit with the following non-linear components: (a) a non-linear
capacitor associated with the spatial charge distribution between the
ions located in the outer and inner areas of the polymer; (b) an
inductor; and (c) a resistor, similar to the model described above
developed for MTs. A helical distribution of ions winding around the
filament at an approximate distance of one Bjerrum length to the
filament corresponds to a solenoid in which an ionic current flows due
to the voltage gradient between the two ends. For an AF with n monomers, its effective resistance, inductance, and capacitance are, respectively:
Reff=(?ni=11R2,1)?1+?ni=1R1,i,
(15)
Leff=?ni=1Li,
(16)
Ceff=?ni=1C0,i,
(17)
where R1,i = 6.11 × 106 ?, and R2,i = 0.9 × 106 ?, such that R1,i = 7R2,i [112]. Hence, for a 1-µm length of an AF we find that Reff = 1.2 × 109 ?, Leff = 340 × 10?12 H and Ceff = 0.02 × 10?12 F.
The electrical model of an AF is an application of Kirchhoff’s laws to
one section of the effective electrical circuit that is coupled to
neighboring monomers. In the continuum limit [112] the following equation describes the spatio-temporal behavior of the electric potential propagating along the actin filament:
LC0?2V?t2=a2(?xxV)+ R2C0??t(a2(?xxV))? R1C0?V?t+R1C02bV?V?t.
(18)
Solitary ionic waves have been described as the solutions of the above nonlinear partial differential equation [112] with an estimated velocity of propagation between 1 and 100 m/s [72]. This model has been recently updated with a more plausible estimation of model parameters [100]. Like MTs [96], AFs can be manipulated by external electric fields [113].
In a similar manner to our analysis of the time scales for MTs as ionic
conduction cables with RLC components, we estimate similar time scales
for actin and AFs. We readily find for a single actin monomer, that the
time scale for LC oscillations is very fast, namely ?0 = (LC)1/2 and ?0 = 6 × 10?14 s. Secondly, the decay time for longitudinal ionic waves is ?1 = R1C = 6 × 10?10 s while the corresponding time for radial waves is ?2 = R2C = 0.9 × 10?10 s.
All of the above time scales are not compatible with interactions
involving electric fields in the 100 kHz range. However, the situation
changes drastically for AFs where there is a similar scaling with the
length of the filament as described above for MTs. Taking as an example a
1-µm AF, we find ?0 = 10?11 s, which is still too short but ?1 = R1C = 2.4 × 10?5 s
which is in the correct range of time for interactions with AC electric
fields in the 100 kHz range. It should be noted that AFs have been
found sensitive to AC fields under experimental conditions [114].
5.6. Electric Field Effects on DNA
Anderson and Record [115]
described ionic distribution around DNA in great detail. During
interphase, DNA contents present in the nucleus are expected to be
protected from external fields due to being enclosed in the nearly
spherical nuclear membrane [78].
In addition to the screening effects of being shielded both by the cell
membrane and the nuclear wall, the irregular geometry of the DNA
strands and their short persistence length indicate that while highly
charged, DNA is unlikely to participate in ionic conduction effects
shown either for AFs or MTs, both of which have very large persistence
lengths.
However, at the beginning of mitosis, the
nuclear membrane breaks down, thus potentially not shielding the DNA
any longer which would allow for the action of electric fields on
chromosomes.
5.7. Electric Field Effects on Motor Proteins
Kinesin participates in mass transport along MTs and propagates at a maximum speed of 10?6 m/s.
This value depends on the concentration of ATP and the ionic
concentrations in the medium. In the case of MTs, kinesin transports
various crucial cargo and for actin filaments, dynein does the same at
similar speeds. Hence each step of a motor protein takes place over the
period of a few ms, which is much longer than the period of AC field
oscillations. However, kinesin binds to MTs through C-termini, which are
very sensitive to electric field fluctuations and hence it is possible
that kinesin transport would be very strongly disrupted by these rapid
oscillations of C-termini. This aspect merits careful experimental
verification.
Another potential member of the cytoskeleton that has been found affected by TTFields [2]
is the protein called septin, which are GTP-binding like tubulin but
form oligomeric hetero-complexes including rings and filaments. There is
no information at the present time that could shed light on the
mechanism of TTField effects with septin-based structures.
6. Discussion
The cytoskeleton and especially, MTs,
may participate in numerous interactions with electromagnetic forces due
to the complex charge distribution in and around these protein
filaments surrounded by poly-ionic solutions. First of all, there are
large net charges on tubulin, which are largely but not completely
screened by counter-ions. Secondly, some of the charges are localized on
C-termini, which are very flexible leading to oscillating charge
configurations. Then, there are ions surrounding the protein that can be
partially condensed and susceptible to collective oscillations.
Moreover, there are large dipole moments on tubulin and microtubules
whose geometric organization importantly affects their response to
external fields. Finally, there can be induced dipole moments especially
in the presence of electric field gradients. Disentangling the relative
importance of the various effects under different conditions is not
trivial and requires careful examination.
Depending on the orientation of the electric fields with
the cell axis and in particular with the MT axis (however, they fan out
from centrosomes in mitotic cells, so there will be at different angles
to any field), there could in general be three types of ionic waves
generated:
Longitudinal waves propagating along the MT surface. In this case
each protofilament of a microtubule acts like a cable with its inherent
resistance r, so the resistance of an entire microtubule would be R = r/13 since all these cables are in parallel to each other.
Helical waves propagating around and along each microtubule, there
could be three or five such waves propagating simultaneously mimicking
the three-start or five-start geometry of a microtubule. The effective
resistance of such cables would be the individual resistance divided by
the number of cables in parallel.
Radial waves propagating perpendicularly to the microtubule surface.
If a field is oriented at an angle to the MT axis, it is
expected that all these wave types may be generated simultaneously. Once
AC fields generate oscillating ionic flows, these can in turn:
Interfere with ion flows in the cleavage area of dividing cells.
Interfere with motor protein motion and MAP-MT interactions.
May to a lesser degree affect ion channel dynamics.
May in general affect the net charge of the cytoplasm.
Finally, Kirson et al. [2]
mention intracellular charged and polar entities such as cytoplasmic
organelles as being potentially most directly affected by TTFields. This
is not specifically addressed in this paper due to size and scope
limitations as well as the scarcity of data in this regard. It has been
argued [2]
that inhomogeneity in field intensity may exert a uni-directional
electric force on all intracellular charged and polar entities, pulling
them toward the furrow (regardless of field polarity). It was determined
that cytoplasmic organelles are electrically polarized by the field
within dividing cells. As a consequence, the TTField-generated forces
acting on these organelles may reach values up to 60 pN resulting in
their movement toward the cleavage furrow. These organelles can move at
velocities up to 30 ?m/s and, as a result, they could pile up at the
cleavage furrow within a few minutes, interfering with cytokinesis,
which may lead to cell destruction. This aspect needs detailed
experimental investigation.
Some measurable heating effects in the
cytoplasm might also be expected. These fields are not expected to
affect permanent dipoles of proteins such as tubulin and actin. Although
TTField effects have not been specifically assessed for AFs, an earlier
paper [114]
investigated exposure of cells to AC electric fields in a low frequency
range of 1–120 Hz and found significant induced alterations in the AF
structure, which were both frequency- and amplitude dependent. An
application of 1–10 Hz AC fields caused AF reorganization from
continuous, aligned cable structures to discontinuous globular patches.
Cells exposed to 20–120 Hz electric fields were not visibly affected.
The extent of AF reorganization increased nonlinearly with the electric
field strength. The characteristic time for AF reorganization in cells
exposed to a 1 Hz, 20 V/cm electric field was approximately 5 min.
Importantly, applied AC electric fields were shown to initiate signal
transduction cascades, which in turn cause reorganization of
cytoskeletal structures. Therefore, in addition to direct effects of
TTFields, there may be indirect, down-stream interactions.
7. Conclusions
Based on the extensive analysis of the
various possible effects AC electric fields can have on living cells, we
conclude the following. Electric field gradients, especially in
dividing cells, cause substantial DEP forces on tubulin dimers and MTs.
The longer the MT, the more pronounced the effect. Additionally, another
likely scenario is that ionic current flows along and perpendicular to
MT surfaces (as well as actin filaments, but less likely) take place,
which can be generated by AC field oscillations in the 100–300 kHz
range. The specific frequency selection depends critically on the length
of each filament.
Identification of the strength, cause,
and function of intracellular electric fields has only recently been
experimentally accessible, although speculations in this area have
existed for over a decade. These insights may also assist in devising
and optimizing ways and means of affecting cells, especially cancer
cells, by the application of external electric fields. With the advent
of nanoprobe technology, which has shown promise in measuring these
fields at a subcellular level, it is very timely to explore the various
physical properties of the cytoplasmic environment including the
cytoskeleton and the ionic contents of the cytoplasm. This research
promises to contribute to our understanding of the cytoplasm in live
cells and the role of microtubules and mitochondria in creating dynamic
and structural order in healthy functioning cells. It will also be of
help to identify biophysical differences in cancer cells that lead to
increased metastatic behavior. Such an understanding may lead to
optimized therapies and the identification of specific targets to halt
metastatic transformation, as well as insights into the mechanism of
action of current electromagnetic cancer therapies that are FDA approved
and are in development.
Acknowledgments
Cornelia Wenger was supported by Novocure. Douglas E.
Friesen was supported by Novocure. Douglas E. Friesen also gratefully
acknowledges support from Alberta Innovates Health Solutions and the
Alberta Cancer Foundation. The funding for J.A.T.’s research comes from
the Natural Sciences and Engineering Research Council of Canada.
Abbreviations
The following abbreviations are used in this manuscript:
DC
direct current
AC
alternating current
TTFields
Tumor Treating Fields
GBM
glioblastoma multiforme
EM
electromagnetic
MT
microtubule
DEP
dielectrophoretic
AF
actin filament
TT
C-terminal tail
MAP
microtubule associated protein
Author Contributions
Jack A. Tuszynski produced the first draft of the
manuscript. Cornelia Wenger performed the computational studies and
contributed to editing the paper. Douglas E. Friesen helped conceive the
ideas presented in the paper and contributed to editing the paper.
Jordane Preto contributed the analysis of ion motion in electric fields.
Conflicts of Interest
Novocure had no role in the design of the study; in the
collection, analyses, or interpretation of data; in the writing of the
manuscript, and in the decision to publish the results.
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Vestn Oftalmol. 2000 Jul-Aug;116(4):3-5.
Differentiated approaches to the treatment of nonstabilized primary
open-angle glaucoma with normalized intraocular pressure considering
its pathogenic features.
[Article in Russian]
Egorov VV, Sorokin EL, Smoliakova GP.
Clinical efficiency of dedystrophic treatments for nonstabilized
primary open-angle glaucoma (POAG) in the presence of normalized
intraocular pressure is compared in 168 patients (246 eyes). In one
group of patients ischemic angiopathy and hyperreactivity of optic
vessel adrenoreceptors associated with hypokinetic central hemodynamics
and constitutional metabolic status of the organism was corrected by
cinnarisin and riboxin. Patients with predominating congestive
angiopathy symptoms, hyper- or eukinetic circulation and “slow”
acetylation were treated by pantothenic acid, endotelon, and hyperbaric
oxygenation. In both groups epithalamine, eiconol, and magnetic laser
therapy were used, if indicated. This helped stabilize the process in
91% patients with initial POAG, in 87.5% with well-developed condition
vs. 66.1% and 38.2% patients treated by traditional therapy (period of
observation 3 years).
Vestn Oftalmol. 1996 Jan-Mar;112(1):6-8.
Possibilities of magnetotherapy in stabilization of visual function in patients with glaucoma.
[Article in Russian]
Bisvas Shutanto Kumar, Listopadova NA.
Courses of magnetotherapy (MT) using ATOS device with 33 mT magnetic
field induction were administered to 31 patients (43 eyes) with primary
open-angle glaucoma with compensated intraocular pressure. The
operation mode was intermittent, with 1.0 to 1.5 Hz field rotation
frequency by 6 radii. The procedure is administered to a patient in a
sitting posture with magnetic inductor held before the eye. The
duration of a session is 10 min, a course consists of 10 sessions.
Untreated eyes (n = 15) of the same patients were examined for control.
The patients were examined before and 4 to 5 months after MT course.
Vision acuity improved by 0.16 diopters, on an average, in 29 eyes
(96.7%) out of 30 with vision acuity below 1.0 before treatment.
Visocontrastometry was carried out using Visokontrastometer-DT device
with spatial frequency range from 0.4 to 19 cycle/degree (12
frequencies) and 125 x 125 monitor. The orientation of lattices was
horizontal and vertical. The contrasts ranged from 0.03 to 0.9 (12
levels). MT brought about an improvement of spatial contrast
sensitivity by at least 7 values of 12 levels in 22 (84.6%) out of 26
eyes and was unchanged in 4 eyes. Visual field was examined using
Humphry automated analyzer. A 120-point threshold test was used. After a
course of MT, visual field deficit decreased by at least 10% in 31
(72%) out of 43 eyes, increased in 3, and was unchanged in 9 eyes; on
an average, visual field deficit decreased by 22.4% vs. the initial
value. After 4 to 5 months the changes in the vision acuity and visual
field deficit were negligible. In controls these parameters did not
appreciably change over the entire follow-up period.
Oftalmol Zh. 1990;(3):154-7.
The effect of a pulsed electromagnetic field on the hemodynamics of eyes with glaucoma.
[Article in Russian]
Tsisel’skii IuV, Kashintseva LT, Skrinnik AV.
The influence of pulse electromagnetic field (PEMF) on hemodynamics
of the eye in open-angle glaucoma has been studied by means of a method
and a device proposed at the Filatov Institute. The PEMF
characteristics are: impulse frequency–50 Hz, exposition–0,02 sec.,
impulse shape–square, rate of impulse rise–4.10(4) c rate of magnetic
induction rise–2.10(4) mT/c, amplitude value of magnetic induction at
the impulse height–9.0–8.5 mT, duration of the procedure–7 min., a
course–10 sessions. Observations over 150 patients (283 eyes) with
latent, initial and advanced glaucoma have shown a positive influence
of PEMF on hemodynamics of a glaucomatous eye: a rise of rheographic
coefficient and relative volume pulse in 87,99 and 81,63%,
respectively. The degree of the rise and restoration frequency of
rheographic values of the glaucomatous eye under the influence of PEMF
to the age norm was more expressed at initial stages of the
glaucomatous process (latent and initial glaucoma).
Oftalmol Zh. 1990;(3):154-7.
The effect of a pulsed electromagnetic field on the hemodynamics of eyes with glaucoma.
[Article in Russian]
Tsisel’skii IuV, Kashintseva LT, Skrinnik AV.
The influence of pulse electromagnetic field (PEMF) on hemodynamics
of the eye in open-angle glaucoma has been studied by means of a method
and a device proposed at the Filatov Institute. The PEMF characteristics
are: impulse frequency–50 Hz, exposition–0,02 sec., impulse
shape–square, rate of impulse rise–4.10(4) c rate of magnetic induction
rise–2.10(4) mT/c, amplitude value of magnetic induction at the impulse
height–9.0–8.5 mT, duration of the procedure–7 min., a course–10
sessions. Observations over 150 patients (283 eyes) with latent, initial
and advanced glaucoma have shown a positive influence of PEMF on
hemodynamics of a glaucomatous eye: a rise of rheographic coefficient
and relative volume pulse in 87,99 and 81,63%, respectively. The degree
of the rise and restoration frequency of rheographic values of the
glaucomatous eye under the influence of PEMF to the age norm was more
expressed at initial stages of the glaucomatous process (latent and
initial glaucoma).
Oftalmol Zh. 1990;(2):89-92.
The effect of a pulsed electromagnetic field on ocular hydrodynamics in open-angle glaucoma.
[Article in Russian]
Tsisel’skii IuV.
The influence of pulse electromagnetic field on the hydrodynamics of
the eye in open-angle glaucoma has been studied using the method and the
device suggested at the Filatov Institute. The characteristics of the
action were: impulse frequency–50 Hz, duration–0.02 sec., pulse
form–rectangular, rate of pulse rise–4/10(-4) sec., rate of magnetic
induction rise–2/10(-4) mT/sec., amplitude value of magnetic induction
at the pulse level–8.0-8.5 mT, duration of the procedure–7 min. Ten
session in a total. Observations over 150 patients (283 eyes) with
latent, initial and advanced glaucoma have shown that the usage of pulse
electromagnetic field exerts influence on the hydrodynamics of the eye
in open-angle glaucoma; stimulates the rise of aqueous outflow and
production, the reduction of the Becker’s coefficient. At the latent
stage of the disease, normalization of outflow was recorded in 25% of
cases, at the initial and advanced stages–in 17.8% and 16.0% of cases,
respectively. The investigations carried out allow to recommend the
mentioned method for a complex treatment of open-angle glaucoma.
Vestn Oftalmol. 1994 Apr-Jun;110(2):5-7.
The effect of noninvasive electrostimulation of the optic nerve and
retina on visual functions in patients with primary open-angle glaucoma.
[Article in Russian]
Kumar BSh, Nesterov AP.
Electrostimulation courses with OEC-2 Ophthalmologic
Electrostimulator were administered to 30 patients (36 eyes) with
primary open-angle glaucoma and normal intraocular pressure. An active
electrode was placed on the upper lid, an indifferent one on the
forearm. Electric pulses (150-900 mcA) were grouped in several sessions,
30 sec each, divided by 30-45 sec intervals. Total duration of a
procedure was 16 min, the course consisting of 10 procedures. Control
group included 24 eyes of the same patients. The patients were examined
before, immediately, and 4-5 months after the treatment. Noticeable
changes in vision acuity and visual field were detected. Visual field
was examined using Humphrey Field Analyzer and 120-point threshold
related test. The treatment resulted in reduction of visual field
deficit by 10% or more in 28 (78%) of 36 eyes, in its increase in 2
eyes, and in no changes in 2 cases. Visual field deficit decreased by
25% on an average as against the initial value. Four to five months
after the treatment the changes in this parameter were negligible.
Vision acuity increased after the treatment in 31 of 36 eyes by 0.17
diopters on an average; 4 to 5 months later no changes occurred. In
control eyes no changes were detected either in vision acuity or visual
field during and after the treatment.
Low-frequency pulsed electromagnetic field therapy in fibromyalgia: a randomized, double-blind, sham-controlled clinical study.
Sutbeyaz ST, Sezer N, Koseoglu F, Kibar S.
Fourth Physical Medicine and Rehabilitation Clinic, Ankara Physical
Medicine and Rehabilitation Education and Research Hospital, Ankara,
Turkey. ssutbeyaz@yahoo.com
Abstract
OBJECTIVE: To evaluate the clinical effectiveness of low-frequency
pulsed electromagnetic field (PEMF) therapy for women with fibromyalgia
(FM).
METHODS: Fifty-six women with FM, aged 18 to 60 years, were randomly
assigned to either PEMF or sham therapy. Both the PEMF group (n=28) and
the sham group (n=28) participated in therapy, 30 minutes per session,
twice a day for 3 weeks. Treatment outcomes were assessed by the
fibromyalgia Impact questionnaire (FIQ), visual analog scale (VAS),
patient global assessment of response to therapy, Beck Depression
Inventory (BDI), and Short-Form 36 health survey (SF-36), after
treatment (at 4 wk) and follow-up (at 12 wk).
RESULTS: The PEMF group showed significant improvements in FIQ, VAS
pain, BDI score, and SF-36 scale in all domains at the end of therapy.
These improvements in FIQ, VAS pain, and SF-36 pain score during
follow-up. The sham group also showed improvement were maintained on all
outcome measures except total FIQ scores after treatment. At 12 weeks
follow-up, only improvements in the BDI and SF-36 scores were present in
the sham group.
CONCLUSION: Low-frequency PEMF therapy might improve function, pain, fatigue, and global status in FM patients.
Aesthetic Plast Surg. 2008 Jul;32(4):660-6. Epub 2008 May 28.
Effects of pulsed electromagnetic fields on postoperative pain: a
double-blind randomized pilot study in breast augmentation patients.
Hedén P, Pilla AA.
Department of Plastic Surgery, Akademikliniken, Storängsvägen 10, 115 42, Stockholm, Sweden. per.heden@ak.se
Abstract
BACKGROUND: Postoperative pain may be experienced after breast
augmentation surgery despite advances in surgical techniques which
minimize trauma. The use of pharmacologic analgesics and narcotics may
have undesirable side effects that can add to patient morbidity. This
study reports the use of a portable and disposable noninvasive pulsed
electromagnetic field (PEMF) device in a double-blind, randomized,
placebo-controlled pilot study. This study was undertaken to determine
if PEMF could provide pain control after breast augmentation.
METHODS: Forty-two healthy females undergoing breast augmentation for
aesthetic reasons entered the study. They were separated into three
cohorts, one group (n = 14) received bilateral PEMF treatment, the
second group (n = 14) received bilateral sham devices, and in the third
group (n = 14) one of the breasts had an active device and the other a
sham device. A total of 80 breasts were available for final analysis.
Postoperative pain data were obtained using a visual analog scale (VAS)
and pain recordings were obtained twice daily through postoperative day
(POD) 7. Postoperative analgesic medication use was also followed.
RESULTS: VAS data showed that pain had decreased in the active cohort
by nearly a factor of three times that for the sham cohort by POD 3 (p
< 0.001), and persisted at this level to POD 7. Patient use of
postoperative pain medication correspondingly also decreased nearly
three times faster in the active versus the sham cohorts by POD 3 (p
< 0.001).
CONCLUSION: Pulsed electromagnetic field therapy, adjunctive to
standard of care, can provide pain control with a noninvasive modality
and reduce morbidity due to pain medication after breast augmentation
surgery.
Pain Res Manag. 2007 Winter;12(4):249-58.
A randomized, double-blind, placebo-controlled clinical trial using a
low-frequency magnetic field in the treatment of musculoskeletal
chronic pain.
Thomas AW, Graham K, Prato FS, McKay J, Forster PM, Moulin DE, Chari S.
Bioelectromagnetics, Imaging Program, Lawson Health Research
Institute, Department of Medical Biophysics, Schulich School of Medicine
and Dentistry, University of Western Ontario, London, Canada. athomas@lawsonimaging.ca
Abstract
Exposure to a specific pulsed electromagnetic field (PEMF) has been
shown to produce analgesic (antinociceptive) effects in many organisms.
In a randomized, double-blind, sham-controlled clinical trial, patients
with either chronic generalized pain from fibromyalgia (FM) or chronic
localized musculoskeletal or inflammatory pain were exposed to a PEMF
(400 microT) through a portable device fitted to their head during
twice-daily 40 min treatments over seven days. The effect of this PEMF
on pain reduction was recorded using a visual analogue scale. A
differential effect of PEMF over sham treatment was noticed in patients
with FM, which approached statistical significance (P=0.06) despite low
numbers (n=17); this effect was not evident in those without FM (P=0.93;
n=15). PEMF may be a novel, safe and effective therapeutic tool for use
in at least certain subsets of patients with chronic, nonmalignant
pain. Clearly, however, a larger randomized, double-blind clinical trial
with just FM patients is warranted.
Pain Res Manag. 2006 Summer;11(2):85-90.
Exposure to a specific pulsed low-frequency magnetic field: a
double-blind placebo-controlled study of effects on pain ratings in
rheumatoid arthritis and fibromyalgia patients.
Lawson Health Research Institute, St. Joseph’s Health Care, London, Ontario N6A 4V2.
Abstract
BACKGROUND: Specific pulsed electromagnetic fields (PEMFs) have been
shown to induce analgesia (antinociception) in snails, rodents and
healthy human volunteers.
OBJECTIVE: The effect of specific PEMF exposure on pain and anxiety ratings was investigated in two patient populations.
DESIGN: A double-blind, randomized, placebo-controlled parallel design was used.
METHOD: The present study investigated the effects of an acute 30 min
magnetic field exposure (less than or equal to 400 microTpk; less than 3
kHz) on pain (McGill Pain Questionnaire [MPQ], visual analogue scale
[VAS]) and anxiety (VAS) ratings in female rheumatoid arthritis (RA)
(n=13; mean age 52 years) and fibromyalgia (FM) patients (n=18; mean age
51 years) who received either the PEMF or sham exposure treatment.
RESULTS: A repeated measures analysis revealed a significant
pre-post-testing by condition interaction for the MPQ Pain Rating Index
total for the RA patients, F(1,11)=5.09, P<0.05, estimate of effect
size = 0.32, power = 0.54. A significant pre-post-effect for the same
variable was present for the FM patients, F(1,15)=16.2, P<0.01,
estimate of effect size = 0.52, power =0.96. Similar findings were found
for MPQ subcomponents and the VAS (pain). There was no significant
reduction in VAS anxiety ratings pre- to post-exposure for either the RA
or FM patients.
CONCLUSION: These findings provide some initial support for the use
of PEMF exposure in reducing pain in chronic pain populations and
warrants continued investigation into the use of PEMF exposure for
short-term pain relief.
Neurosci Lett. 2001 Aug 17;309(1):17-20.
A comparison of rheumatoid arthritis and fibromyalgia patients and
health controls exposed to a pulsed (200 microT) magnetic field: effects
on normal standing balance.
Thomas AW, White KP, Drost DJ, Cook CM, Prato FS.
The Lawson Health Research Institute, Department of Nuclear Medicine
& MR, St. Joseph’s Health Care, 268 Grosvenor Street, London, N6A
4V2, Ontario, Canada. athomas@lawsonimaging.ca
Specific weak time varying pulsed magnetic fields (MF) have been
shown to alter animal and human behaviors, including pain perception and
postural sway. Here we demonstrate an objective assessment of exposure
to pulsed MF’s on Rheumatoid Arthritis (RA) and Fibromyalgia (FM)
patients and healthy controls using standing balance. 15 RA and 15 FM
patients were recruited from a university hospital outpatient
Rheumatology Clinic and 15 healthy controls from university students and
personnel. Each subject stood on the center of a 3-D forceplate to
record postural sway within three square orthogonal coil pairs (2 m,
1.75 m, 1.5 m) which generated a spatially uniform MF centered at head
level. Four 2-min exposure conditions (eyes open/eyes closed, sham/MF)
were applied in a random order. With eyes open and during sham exposure,
FM patients and controls appeared to have similar standing balance,
with RA patients worse. With eyes closed, postural sway worsened for all
three groups, but more for RA and FM patients than controls. The
Romberg Quotient (eyes closed/eyes open) was highest among FM patients.
Mixed design analysis of variance on the center of pressure (COP)
movements showed a significant interaction of eyes open/closed and
sham/MF conditions [F=8.78(1,42), P<0.006]. Romberg Quotients of COP
movements improved significantly with MF exposure [F=9.5(1,42),
P<0.005] and COP path length showed an interaction approaching
significance with clinical diagnosis [F=3.2(1,28), P<0.09]. Therefore
RA and FM patients, and healthy controls, have significantly different
postural sway in response to a specific pulsed MF.
Efficacy of general magnetotherapy in conservative therapy of uterine myoma in women of reproductive age.
[Article in Russian]
Kulishova TV, Tabashnikova NA, Akker LV.
Sixty women of the reproductive age with uterine myoma were divided
into two groups. Thirty patients of the study group received combined
therapy plus general magnetotherapy (GMT). Patients of the control group
received only combined treatment. Ultrasound investigation registered a
reduction in the size of myoma nodes by 16.7% in the study group, while
in the controls myoma size did not change (p < 0.05). 1-year
follow-up data for the study group demonstrated no cases of the myoma
growth while 16.6% of the controls showed growth of myoma nodes, in 6.6%
of them supravaginal myoma amputation was made for rapidly growing
myoma.
[Corrective action of the microwave electromagnetic field on
progeny development in rats with impared uteroplacental circulation]
[Article in Russian] Lysaia TN, Sheveleva GA, Strugatskii VM.
The experiment on 71 non-inbred white pregnant rats, 316 fetuses and
placentas, 323 first progeny in experimental chronic impairment of
uteroplacental circulation in females with pregnancy in the ploid period
has found that decimetric waves (DW) in a weak heat dose (40 mW/cm2)
prevents hypotrophy and disorders of fetal and placental development.
Also, DW accelerate formation of motorsensory reflexes in the progeny in
an early neonatal period and normalize their behavioral reactions at a
mature age. The findings may serve experimental-theoretical grounds for
application of weak heat DW radiation in obstetric practice in various
general and regional hemocirculation.