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Electromagnetic Biology and Medicine Volume 32, 2013 - Issue 4
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Exposure to extremely low-frequency magnetic field restores spinal cord injury-induced tonic pain and its related neurotransmitter concentration in the brain

Suneel KumarDepartment of Physiology, All India Institute of Medical Sciences, New Delhi, India
,
Suman JainDepartment of Physiology, All India Institute of Medical Sciences, New Delhi, India
,
Thirumurthy VelpandianDepartment of Ocular Pharmacy and Pharmacology, All India Institute of Medical Sciences, New Delhi, India
,
Yury Petrovich Gerasimenko
,
Valery D. AvelevMotor Physiology Laboratory, I.P. Pavlov Institute of Physiology, Russian Academy of Sciences, St Petersburg, Russia
,
Jitendra BehariSchool of Environmental Sciences, Jawaharlal Nehru University, New Delhi, India
,
Madhuri BehariDepartment of Neurology, All India Institute of Medical Sciences, New Delhi, India
&
Rashmi MathurDepartment of Physiology, All India Institute of Medical Sciences, New Delhi, IndiaCorrespondence[email protected]
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Pages 471-483 | Received 04 Mar 2012, Accepted 02 Sep 2012, Published online: 08 May 2013

Citations (11)

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Read on this site (3)

Henry Lai. (2022) Neurological effects of static and extremely-low frequency electromagnetic fields. Electromagnetic Biology and Medicine 41:2, pages 201-221.
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Soumil Dey, Samrat Bose, Suneel Kumar, Ravinder Rathore, Rashmi Mathur & Suman Jain. (2017) Extremely low frequency magnetic field protects injured spinal cord from the microglia- and iron-induced tissue damage. Electromagnetic Biology and Medicine 36:4, pages 330-340.
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Suneel Kumar, Soumil Dey & Suman Jain. (2017) Extremely low-frequency electromagnetic fields: A possible non-invasive therapeutic tool for spinal cord injury rehabilitation. Electromagnetic Biology and Medicine 36:1, pages 88-101.
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Articles from other publishers (8)

Arpita Chakraborty, Mehar Chand Sharma, Sreenivas Vishnubhatla & Suman Jain. (2022) Electromagnetic field stimulation facilitates motor neuron excitability, myogenesis and muscle contractility in spinal cord transected rats. Journal of Biosciences 47:4.
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Suneel Kumar, Ajay Pal, Suman Jain, Thirumurthy Velpandian & Rashmi Mathur. (2021) Electromagnetic Field Stimulation Attenuates Phasic Nociception after Complete Spinal Cord Injury in Rats. Brain Sciences 11:11, pages 1431.
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Jonghoon Kang, Steve S. Cho, Hee Young Kim, Bong Hyo Lee, Hee Jung Cho & Young S. Gwak. (2020) Regional Hyperexcitability and Chronic Neuropathic Pain Following Spinal Cord Injury. Cellular and Molecular Neurobiology 40:6, pages 861-878.
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Ying Ye, Ting-ting Feng, Yi-ran Peng, Shu-qun Hu & Tie Xu. (2018) The treatment of spinal cord injury in rats using bone marrow-derived neural-like cells induced by cerebrospinal fluid. Neuroscience Letters 666, pages 85-91.
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S Ambalayam, S Jain & R Mathur. (2016) Abnormal feeding behaviour in spinalised rats is mediated by hypothalamus: Restorative effect of exposure to extremely low frequency magnetic field. Spinal Cord 54:12, pages 1076-1087.
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Joshua A. Cohn, Melissa R. Kaufman, Roger R. Dmochowski, Casey G. Kowalik, Douglas F. Milam & W. Stuart Reynolds. (2016) Early Sacral Neuromodulation in Spinal Cord Injury—Can It Regenerate Nerves?. Current Bladder Dysfunction Reports 11:4, pages 350-355.
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Xiao Liu, Hongyan Zuo, Dewen Wang, Ruiyun Peng, Tao Song, Shuiming Wang, Xinping Xu, Yabing Gao, Yang Li, Shaoxia Wang, Lifeng Wang & Li Zhao. (2015) Improvement of Spatial Memory Disorder and Hippocampal Damage by Exposure to Electromagnetic Fields in an Alzheimer’s Disease Rat Model. PLOS ONE 10:5, pages e0126963.
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T. Saliev, Z. Mustapova, G. Kulsharova, D. Bulanin & S. Mikhalovsky. (2014) Therapeutic potential of electromagnetic fields for tissue engineering and wound healing. Cell Proliferation 47:6, pages 485-493.
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