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http://dx.doi.org/10.15616/BSL.2021.27.2.99

Anti-inflammatory Effects of Low-frequency Stimulator using Superposition of Alternating Microcurrent Wave in the Animal Models  

Kim, Yoo-Jeong (Department of Clinical Laboratory Science, Catholic University of Pusan)
Lee, Seong gwang (Department of Clinical Laboratory Science, Catholic University of Pusan)
Go, Shin Jee (Department of Clinical Laboratory Science, Catholic University of Pusan)
An, Suyeon (Department of Clinical Laboratory Science, Catholic University of Pusan)
Kim, Ye eun (Department of Clinical Laboratory Science, Catholic University of Pusan)
Kim, Ye in (Department of Clinical Laboratory Science, Catholic University of Pusan)
Hyun, Kyung-Yae (Department of Clinical Laboratory Science, Dong-Eui University)
Cho, Dong Shik (Natural Well Tech. Co. Ltd)
Choi, Go-Eun (Department of Clinical Laboratory Science, Catholic University of Pusan)
Publication Information
Biomedical Science Letters / v.27, no.2, 2021 , pp. 99-104 More about this Journal
Abstract
Treatment techniques that affect homeostasis by non-invasive regulation in peripheral organs will advance disease research. Here, we demonstrate a non-invasive method of conditioning within an organ using a low-frequency stimulator superposition of alternating microcurrent wave in stages. It is first applied to the inflammatory response in H3N2-infected sinusitis mice. To check the progress of the treatment, mice were sacrificed every week for 3 weeks, nasal tissue was removed, and the inflammatory response was investigated through H & E staining. The low-frequency stimulation treatment group was found to alleviate the proliferation of epithelial cells and invasion of inflammatory cells compared to the control group as the passage of treatment time. The reduction of inflammatory cytokines in the nasal lavage fluid was observed in H3N2-infected sinusitis mice treated with of low-frequency stimulation using superposition of alternating microcurrent wave compared to H3N2-infected sinusitis mice after 3 weeks. These data demonstrate that low-frequency stimulation device in the form of using alternating current wave superposition on within organs provides a new method to regulate specific physiological functions. Therefore, it is necessary to prove the inhibitory effect of low-frequency stimulation using alternating current wave superposition on inflammatory diseases by various methods through further studies and clinical studies.
Keywords
Microcurrent; Low-frequency stimulator; Superposition of alternating microcurrent wave; Animal model; Inflammation; Influenza A (H3N2) virus;
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  • Reference
1 Becker RO. The Body Electric. New York, William Morrow and Co. 1985.
2 Bolger WE, Leonard D, Dick EJ Jr, Stierna P. Gram negative sinusitis: a bacteriologic and histologic study in rabbits. American Journal of Rhinology & Allergy. 1997. 11: 15-25.   DOI
3 Frick A, McCauley D. Microcurrent electrical therapy. Microcurrent Electrical therapy. 2005. 25: 418-422.
4 Seidman MD, Gurgel RK, Lin SY, Schwartz SR, Baroody FM, Bonner JR, et al. Clinical practice guideline: allergic rhinitis. Otolaryngology-Head and Neck Surgery. 2015. 152: S1-43.
5 Yennurajalingam S, Kang DH, Hwu WJ, Padhye NS, Masino C, Dibai SS, Liu D D, Williams L, Lu Z, Bruera E. Cranial Electrotherapy Stimulation for the Management of Depression, Anxiety, Sleep Disturbance, and Pain in Patients With Advanced Cancer: A Preliminary Study. Journal of Pain and Symptom Management. 2018. 55: 198-206.   DOI
6 Yi D, Lim H, Yim J. Effect of microcurrent stimulation on pain, shoulder function, and grip strength in early post-operative phase after rotator cuff repair. Medicina. 2021. 57: 491.   DOI
7 Yu C, Hu ZQ, Peng RY. Effects and mechanisms of a microcurrent dressing on skin wound healing: a review. Military Medical Research. 2014. 1.
8 Childs A, Crismon ML. The use of cranial electrotherapy stimulation in post-traumatic amnesia: a report of two cases. Brain Injury. 1988. 2: 243-247.   DOI
9 Blackwell DL, Villarroel MA. Tables of summary health statistics for U.S. adults: 2016 National health interview survey. National Center for Health Statistics. 2018.
10 Cheng N, Van Hoof H, Bockx E, Hoogmartens MJ, Michel J, Mulier JC, De Dijcker FJ, et al. The effects of electric currents on ATP generation, protein synthesis, and membrane transport of rat skin. Clinical Orthopaedics and Related Research. 1982. 171: 264-272.
11 Goldsobel AB, Prabhakar N, Gurfein BT. Correction to: Prospective trial examining safety and efficacy of microcurrent stimulation for the treatment of sinus pain and congestion. Bioelectronic Medicine. 2020. 6: 2.   DOI
12 Jin J. Nonsteroidal Anti-inflammatory Drugs. JAMA. 2015. 314: 1084.   DOI
13 Lambert MI, Marcus P, Burgess T, Noakes TD. Electro-membrane microcurrent therapy reduces signs and symptoms of muscle damage. Medicine & Science in Sports & Exercise. 2002. 34: 602-607.   DOI
14 Koh JO. Effects of Self-microcurrent massage on delayed onset muscle soreness (DOMS) and sit and reach: a preliminary study. Journal of Sport and Leisure Studies. 2019. 73: 463-470.   DOI
15 McMakin CR, Gregory WM, Phillips TM. Cytokine changes with microcurrent treatment of fibromyalgia associated with cervical spine trauma. Journal of Bodywork and Movement Therapies. 2005. 9: 169-176.   DOI
16 Lawson D, Lee KH, Kang HB, Yang N, Llewellyn T, Takamatsu S. Efficacy of microcurrent therapy for treatment of acute knee pain: A randomized double-blinded controlled clinical trial. Clinical Rehabilitation. 2021. 35: 390-398.   DOI
17 Lee SB, Song JA, Choi GE, Kim HS, Jang YJ. Rhinovirus infection in murine chronic allergic sinusitis model. International Forum of Allergy & Rhinology. 2016. 6: 1131-1138.   DOI
18 Maul XA, Borchard NA, Hwang PH, Nayak JV. Microcurrent technology for rapid relief of sinus pain: a randomized, placebo-controlled, double-blinded clinical trial. International Forum of Allergy & Rhinology. 2019. 9: 352-356.   DOI
19 Oh HJ, Kim JY, Park RJ. The effects of microcurrent stimulation on recovery of function and pain in chronic low back pain. The Journal of the Korean Society of Physical Medicine. 2008. 3: 47-56.
20 Piras A, Zini L, Trofe A, Campa F, Raffi M. Effects of Acute Microcurrent Electrical Stimulation on Muscle Function and Subsequent Recovery Strategy. International Journal of Environmental Research and Public Health. 2021. 18: 4597.   DOI
21 Ramey JT, Bailen E, Lockey RF. Rhinitis medicamentosa. Journal of Investigational Allergology and Clinical Immunology. 2006. 16: 148-155.
22 Rosenfeld RM, Piccirillo JF, Chandrasekhar SS, Brook I, Ashok Kumar K, Kramper M, et al. Clinical practice guideline (update): adult sinusitis. Otolaryngology-Head and Neck Surgery. 2015. 152: S1-S39.
23 Park RJ, Kim JS, Lee IH, Park JH, Han DU. Effects of Electrotherapy on Blood Velocity of Cranial Artery in Tension-Type Headache subjects. The Korean Society of Physical Therapy. 2000. 12: 349-359.