DIAGNOSTICS OF NERVE IMPULSES TRANSMISSION PATHOLOGY IN PATIENTS WITH SUSPECTED THORACIC OUTLET SYNDROME USING CLINICAL NEUROPHYSIOLOGY TESTS

Introduction Thoracic Outlet Syndrome (TOS) is a group of conditions characterized by compression of the nerves, arteries and veins in the lower neck and upper chest area. On average, six physicians of different specialities need 4.3 years to develop TOS diagnosis. Early detection of changes in transmission of nerve impulses within the brachial plexus may lead to faster and more effective treatment of patients. Aim The aim of the study is to present the scheme of diagnostic tests of clinical neurophysiology contributing to the objective diagnosis of TOS, as well as the positive results of tests in a group of sixteen patients with clinically confirmed pathological symptoms. Material and methods Sixteen patients with clinically diagnosed TOS and sixteen healthy people as a control group aged from 18 to 36 participated in this study. In both groups of subjects, bilateral clinical neurophysiological diagnostics tests were carried out: an examination of the sensory perception with von Frey’s filaments within C4-C8 dermatomes, examination of surface electromyography (sEMG) during maximal contractions when recordings from proximal and distal muscles of the upper extremities were performed, the electroneurographic transmission of nerve impulses in selected nerves of the upper extremities (ENG) and motor evoked potentials recordings induced with the magnetic field (MEP) following oververtebral C5 and C6 stimulation. Results Comparing to studies performed in a control group of healthy volunteers, more than 50% of patients with clinical symptoms of TOS had confirmed abnormalities in the diagnostic tests of clinical neurophysiology, unilaterally or bilaterally. Conclusions In the diagnosis of TOS, sEMG recordings from the distal muscles of upper extremities during maximal contractions after induction of ischemia (“hand-raised test”), ENG segmental examination of nerve impulses transmission in motor fibers after stimulation of the median and ulnar nerves, and MEP examination after oververtebral C5 and C6 stimulation are particularly useful. Confirmation of a relatively high percentage of positive TOS tests in patients requires a greater number of neurophysiological examinations. Keywords: Thoracic Outlet Syndrome, neurophysiological diagnostics, motor evoked potentials

Correction to: Statistical field theory of the transmission of nerve impulses

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Statistical field theory of the transmission of nerve impulses

Background Stochastic processes leading voltage-gated ion channel dynamics on the nerve cell membrane are a sufficient condition to describe membrane conductance through statistical mechanics of disordered and complex systems. Results Voltage-gated ion channels in the nerve cell membrane are described by the Ising model. Stochastic circuit elements called “Ising Neural Machines” are introduced. Action potentials are described as quasi-particles of a statistical field theory for the Ising system. Conclusions The particle description of action potentials is a new point of view and a powerful tool to describe the generation and propagation of nerve impulses, especially when classical electrophysiological models break down. The particle description of action potentials allows us to develop a new generation of devices to study neurodegenerative and demyelinating diseases as Multiple Sclerosis and Alzheimer’s disease, even integrated by connectomes. It is also suitable for the study of complex networks, quantum computing, artificial intelligence, machine and deep learning, cryptography, ultra-fast lines for entanglement experiments and many other applications of medical, physical and engineering interest.

OTTO LOEWI: ONE HUNDRED YEARS OF CONFIRMATION OF CHEMICAL NEUROTRANSMISSION

In 1921, Otto Loewi published an experimental study that gave rise to the birth of the chemical theory of nerve transmission, according to which, the nerve current causes, at the end of nerve fibers, the release of a chemical substance called a neurotransmitter. For his discoveries related to the chemical neurotransmission of nerve impulses, Loewi received the Nobel Prize in Physiology or Medicine in 1936.

Statistical field theory of the transmission of nerve impulses

Background Stochastic processes leading voltage-gated ion channel dynamics on the nerve cell membrane are a sufficient condition to describe membrane conductance through statistical mechanics of disordered and complex systems.Results Voltage-gated ion channels in the nerve cell membrane are described by the Ising model. Stochastic circuital elements called ”Ising machines” are introduced. Action potentials are described as quasi-particles of a statistical field theory for the Ising system.Conclusions The particle description of action potentials is a new powerful tool to describe the generation and propagation of nerve impulses. We thus have the opportunity to exploit another useful point of view to describe the generation and propagation of nerve impulses, especially when classical electrophysiological models break down. Moreover, the particle description allows us to develop new hardware and software devices based on general and theoretical physics to study neurodegenerative and demyelinating diseases as Multiple Sclerosis and Alzheimer’s disease, even integrated by connectomes. It is also suitable for the study of complex networks, quantum computing, artificial intelligence, machine and deep learning, cryptography, ultra-fast lines for entanglement experiments and many other applications of medical, physical and engineering interest.

Statistical field theory of the transmission of nerve impulses

Background: Stochastic processes leading voltage-gated ion channel dynamics on the nerve cell membrane are a sufficient condition to describe membrane conductance through statistical mechanics of disordered and complex systems. Results: Voltage-gated ion channels in the nerve cell membrane are described by the Ising model. Stochastic circuital elements called ”Ising machines” are introduced. Action potentials are described as quasi-particles of a statistical field theory for the Ising system. Conclusions: The particle description of action potentials is a powerful new tool for describing the generation and propagation of nerve impulses. We thus have the opportunity to exploit another useful point of view to describe the generation and propagation of nerve impulses, especially when classical electrophysiological models break down. Moreover, the corpuscular description allows us to develop new hardware and software devices based on particle physics to study neurodegenerative and demyelinating diseases (Multiple Sclerosis), even integrated by connectomes. It is also suitable for the study of complex networks, cryptography, machine learning, quantum computing and many other applications of medical, physical and engineering interest.

Abundant distinct types of solutions for the nervous biological fractional FitzHugh–Nagumo equation via three different sorts of schemes

The dynamical attitude of the transmission for the nerve impulses of a nervous system, which is mathematically formulated by the Atangana–Baleanu (AB) time-fractional FitzHugh–Nagumo (FN) equation, is computationally and numerically investigated via two distinct schemes. These schemes are the improved Riccati expansion method and B-spline schemes. Additionally, the stability behavior of the analytical evaluated solutions is illustrated based on the characteristics of the Hamiltonian to explain the applicability of them in the model’s applications. Also, the physical and dynamical behaviors of the gained solutions are clarified by sketching them in three different types of plots. The practical side and power of applied methods are shown to explain their ability to use on many other nonlinear evaluation equations.

Statistical field theory of the transmission of nerve impulses

Stochastic processes leading voltage-gated ion channel dynamics on the nerve cell membrane are a sufficient condition to describe membrane conductance through statistical mechanics of disordered and complex systems. Voltage-gated ion channels in the nerve cell membrane are described by the Ising model. Stochastic circuital elements called ”Ising machines” are introduced. Action potentials are described as quasi-particles of a statistical field theory for the Ising system. The particle description of action potentials is a powerful new tool for describing the generation and propagation of nerve impulses. We thus have the opportunity to exploit another useful point of view to describe the generation and propagation of nerve impulses, especially when classical electrophysiological models break down. Moreover, the corpuscular description allows us to develop new hardware and software devices based on particle physics to study neurodegenerative and demyelinating diseases (Multiple Sclerosis), even integrated by connectomes. It is also suitable for the study of complex networks, cryptography, machine learning, quantum computing and many other applications of medical, physical and engineering interest.