Sage Journals: Discover world-class research

Abstract

Using voltage-time-dependent negative resistance characteristics of Voltage-Current curves of excitable cell membranes estimated without using artificial voltage clamp method, the author made a quantitative analysis of excitability of cell membranes and different conditions of transmembrane action potentials as a bias voltage to the negative resistance of the excitable cell membrane. The pacemaker cells were classified as “Astable Oscillators” and nonpacemaker excitable cells as “Monostable Oscillators,” and application of a rapidly changing electromagnetic field to the cells was analyzed as a means of stimulating the cells. The understanding of the 10 essential electrical parameters is highly desirable for safe and effective electrical stimulation. Among these, emphasis was placed on the often neglected, important electrical parameters of “output impedance” of stimulation pulse wave complexes for + and − polarity components, as well as the importance of capacitive current ( $I_{c} = c . \frac{d v}{d t}$ ) which depends on rise time as well as fall time of the stimulation pulse wave, and undesirable side effects of electrolysis phenomena due to excessive D.C. current. The difference and similarity between TENS (Transcutaneous Nerve Stimulation) and TES (Transcutaneous Electrical Stimulation), TENMS (Transcutaneous Electrical Nerve and Muscle Stimulation) or TMS (Transcutaneous Muscle Stimulation) was discussed. The author’s clinical study indicated that effective TES (TENMS)--characterized by effective muscle contraction without creating pain with a pulse repetition rate approximately the same as the heart rate of the individual--can often give superior beneficial effects in improvement of micro-circulation and subsequent relief of pain and other symptoms compared with TENS that creates stimulation of large diameter sensory nerve fibers without creating significant muscle contraction. Such improvement is often accompanied by the abolishment of the pain with disappearance of local substance P and increase in local serotonin with disappearance of local L-tryptophan.

Keywords

Safe electrical stimulation TES TENMS (or TEMS)TENS Electromagnetic field stimulation Electrolysis phenomena Basic electrical parameters Capacitive current Threshold Potential for Tingling sensation Muscle contraction and Pain Substance P Serotonin L-Tryptophan Neurotransmitters Diabetic gangrene

Get full access to this article

View all access options for this article.

References

1. Omura

Herter

Van Dyke

, Voltage- time-dependent negative resistance characteristics in V-I curves of excitable cardiac cell membranes, Fed. Proc. , Vol. 242, p. 137, 1965.

2. Omura

Welsh

, Voltage-time-dependent negative resistance characteristics of excitable cardiac cell membrane as a switching and oscillating element, Proc. 2nd International Biophysics Congress, Sept., 5-9, 1966, at the University of Vienna, Austria, p. 418, 1966.

3. Omura

Lehr

, Semiquantitative estimation of the voltage-current curve of excitable cell membrane without using a non-physiologic voltage clamp method, Digest of the 7th International Conference on Medical and Biological Engineering, Stockholm, Sweden, p. 361, 1967.

4. Omura

, The relationship between the transmembrane action potential and the voltage-time-dependent, negative resistance characteristics of the voltage-current curves of excitable pacemaker and nonpacemaker cell membranes, Transactions of the New York Academy of Sciences , Series II, Vol. 33, No. 5, pp. 467-518, 1971.

5. Omura

Lee

Jeronimo

, The stimulation of excitable cell membranes by capacitive current (I_c) and rapidly-changing electromagnetic field (R-C EMF) without direct contact between electrodes and the cells, Federation Proceedings , Vol. 31(2), p. 298, 1972.

6. Bassett

CAL

Mitchell

Gaston

, Treatment of ununited tibial diaphyseal fractures with pulsing electromagnetic fields, J. Bone and Joint Surgery , Vol. 63A, pp. 511-523, 1981.

7. Korenstein

Somjen

Fischler

Binderman

, Capacitive pulsed electric stimulation of bone cells; induction of cyclic-AMP changes and DNA synthesis, Biochem, Biophvs, Acta. , Vol. 803, pp. 302-307, 1984.

8. Binderman

Somjen

Shimshoni

Levy

Fischler

Korenstein

, Stimulation of skeletal-derived cell cultures by different electric field intensities is cell-specific, Biochem. Biophys. Acta. , Vol. 844, pp. 273-279, 1985.

9. Polk

Postow

, Handbook of Biological Effects of Electromagnetic Fields , CRC Press, Inc., Boca Raton, Fla., pp. 1-503, 1986.

10.

10. Becker

, The Body Electric; Electromagnetism and the Foundation of Life , William Morrow and Co. Inc., N.Y., 1985.

11.

11. Melzack

Wall

, Pain mechanisms: A new theory. Science, N.Y., Vol. 150, pp 971-979, 1965.

12.

12. Omura

, Pathophysiology of acupuncture treatment: effects of acupuncture on cardiovascular and nervous systems, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 1, pp. 51-141, 1975.

13.

13. Omura

, Electro-acupuncture: its electrophysiological basis and criteria for effectiveness and safety--Part 1, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 1, pp. 157-181, 1975.

14.

14. Omura

, Editorial: Critical evaluation of the methods of measurement of “Tingling Threshold”, “Pain Threshold”, and “Pain Tolerance” by electrical stimulation, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 2, No. 3 & 4, pp. 161-236, 1977.

15.

15. Omura

, Editorial: Non-invasive circulatory evaluation and electro-acupuncture & TES treatment of diseases difficult to treat in Western medicine: 1) abnormal brain circulation and blood pressure: cephalic hypertension or cephalic hypotension syndromes and their related conditions--headache, insomnia, blindness due to macular degeneration & retinitis pigmentosa, and some psychiatric problems; 2) severe lower extremity circulatory disturbances, with intractable pain, intermittent claudication, ulceration and/or severe diabetic neuropathy, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 8, pp. 177-255, 1983.

16.

16. Omura

, Electro Acupuntura v Acupuntura Manual; Bases Biofisicas Y Boiguimicas , (187 page Spanish book) Published by EDAD S.A. Apdo.15065, Maracaibo, Venezuela, 1984.

17.

17. Omura

, Electrical parameters for safe and effective electro-acupuncture and transcutaneous electrical stimulation: threshold potentials for tingling, muscle contraction and pain; and how to prevent adverse effects of electro-therapy--Part 1, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 10, pp. 335-337, 1985.

18.

18. Omura

, Simple and Quick Non-invasive Evaluation of Circulatory Condition of Cerebral Arteries by Clinical Applications of the “Bi-Digital O-Ring Test”, Acupuncture & Electro-Therapeutics Research, Int. J. , Vol. 10, pp. 139-161, 1985.

19.

19. Omura

, Editorial: Effects of an electrical field and its polarity on an abnormal part of the body or organ representation point associated with a diseased internal organ, and its influence on the “Bi-Digital O-Ring Test” (simple, non-invasive dysfunction localization method) & drug compatibility test--Part 1, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 7, pp. 209-246, 1982.

20.

20. Omura

, Electro-Magnetic Resonance Phenomenon as a Mechanism Related to the “Bi-Digital O-Ring Test Molecular Identification and Localization Method”, Acupuncture & Electro-Therapeutics Research. Int. J. , Vol. 11, pp. 127-145, 1986.

BASIC ELECTRICAL PARAMETERS FOR SAFE AND EFFECTIVE ELECTRO-THERAPEUTICS [ELECTRO-ACUPUNCTURE,TES,TENMS (OR TEMS),TENS AND ELECTRO-MAGNETIC FIELD STIMULATION WITH OR WITHOUT DRUG FIELD] FOR PAIN,NEUROMUSCULAR SKELETAL PROBLEMS,AND CIRCULATORY DISTURBANCES

Abstract

Keywords

Get full access to this article

References