Remote multi-wave radioneuroengineering: An innovative technology for non-contact radio restoration of damaged nervous tissue of the human brain and spinal cord
Andrey S. Bryukhovetskiy1,2,3, Igor S. Bryukhovetskiy2,4
1 Federal Research Center for Specialized Types of Medical Assistance and Medical Technologies of FMBA of Russia, Moscow, Russia;
2 School of Biomedicine, Far Eastern Federal University, Vladivostok, Russia;
3 NeuroVita Clinic of Restorative and Interventional Neurology and Therapy, Moscow, Russia;
4 Zhirmunskiy Institute of Sea Biology of the Russian Academy of Sciences, Vladivostok, Russia
Remote multi-wave radioneuroengineering: An innovative technology for non-contact radio restoration of damaged nervous tissue of the human brain and spinal cord
Andrey S. Bryukhovetskiy1,2,3, Igor S. Bryukhovetskiy2,4
1 Federal Research Center for Specialized Types of Medical Assistance and Medical Technologies of FMBA of Russia, Moscow, Russia;
2 School of Biomedicine, Far Eastern Federal University, Vladivostok, Russia;
3 NeuroVita Clinic of Restorative and Interventional Neurology and Therapy, Moscow, Russia;
4 Zhirmunskiy Institute of Sea Biology of the Russian Academy of Sciences, Vladivostok, Russia
摘要 Objectives: Objectives: Significant advances in neurosciences will result from research focused on the non-contact treatment of the nervous tissue (NT). The objective of the article is to describe a novel non-contact method of restoration of damaged NT of the human brain and spinal cord that was termed multi-wave neuro-bioengineering. Methods: The method includes a purposeful complex program of different therapeutic ionizing and non-ionizing electromagnetic radiation effects on the damaged NT, which is approved for clinical practice. Exposure of the human brain to a stepwise algorithmized combination of different ionizing and non-ionizing radiations and simultaneous application of various types of electromagnetic radiation at the specific site of restoration considerably reduce the adverse effects of all types of radiation on NT. Results: The technology for non-contact restoration of the injured tissue of brain or spinal cord was appiled in 30 cases of neurological disorders using the stereotaxic system, structural resonance therapy, radiotherapy and focused ultrasound. The applied methods are approved for humans and theorem programmed combination opens new perspective for the treatment of brain and spinal cord disorders. Conclusions: The approach provides quick restoration of the disordered function of damaged brain tissue and establishes a new paradigm of radio non-contact neurorestoration of the brain and spinal cord.
Abstract: Objectives: Objectives: Significant advances in neurosciences will result from research focused on the non-contact treatment of the nervous tissue (NT). The objective of the article is to describe a novel non-contact method of restoration of damaged NT of the human brain and spinal cord that was termed multi-wave neuro-bioengineering. Methods: The method includes a purposeful complex program of different therapeutic ionizing and non-ionizing electromagnetic radiation effects on the damaged NT, which is approved for clinical practice. Exposure of the human brain to a stepwise algorithmized combination of different ionizing and non-ionizing radiations and simultaneous application of various types of electromagnetic radiation at the specific site of restoration considerably reduce the adverse effects of all types of radiation on NT. Results: The technology for non-contact restoration of the injured tissue of brain or spinal cord was appiled in 30 cases of neurological disorders using the stereotaxic system, structural resonance therapy, radiotherapy and focused ultrasound. The applied methods are approved for humans and theorem programmed combination opens new perspective for the treatment of brain and spinal cord disorders. Conclusions: The approach provides quick restoration of the disordered function of damaged brain tissue and establishes a new paradigm of radio non-contact neurorestoration of the brain and spinal cord.
通讯作者:
Andrey S. Bryukhovetskiy, E-mail: neurovitaclinic@gmail.com
E-mail: neurovitaclinic@gmail.com
引用本文:
Andrey S. Bryukhovetskiy, Igor S. Bryukhovetskiy. Remote multi-wave radioneuroengineering: An innovative technology for non-contact radio restoration of damaged nervous tissue of the human brain and spinal cord[J]. 临床转化神经科学, 2015, 1(1): 31-59.
Andrey S. Bryukhovetskiy, Igor S. Bryukhovetskiy. Remote multi-wave radioneuroengineering: An innovative technology for non-contact radio restoration of damaged nervous tissue of the human brain and spinal cord. Translational Neuroscience and Clinics, 2015, 1(1): 31-59.
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