Unit 1. Mobilization of the Peripheral Nervous System PDF

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Universidad CEU San Pablo

Arturo Pérez Gosálvez

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nervous system peripheral nervous system manual therapy anatomy and physiology

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These lecture notes cover the Mobilization of the Peripheral Nervous System, focusing on anatomy, physiology and mechanics. The document includes questions and discussions about the nervous system’s structure and function. It's a professional-level resource.

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MOBILIZATION OF THE PERIPHERAL NERVOUS SYSTEM UNIT 1. ANATOMY, PHYSIOLOGY AND MECHANICS Manual Therapy I Arturo Pérez Gosálvez CEU-Universidad San Pablo ANATOMY, PHYSIOLOGY AND MECHANICS OF THE NERVOUS SYSTEM • INTRODUCTION • GENERAL STRUCTURE OF THE NS. • PROTECTION SYSTEMS OF THE NS. • PHYSIOLO...

MOBILIZATION OF THE PERIPHERAL NERVOUS SYSTEM UNIT 1. ANATOMY, PHYSIOLOGY AND MECHANICS Manual Therapy I Arturo Pérez Gosálvez CEU-Universidad San Pablo ANATOMY, PHYSIOLOGY AND MECHANICS OF THE NERVOUS SYSTEM • INTRODUCTION • GENERAL STRUCTURE OF THE NS. • PROTECTION SYSTEMS OF THE NS. • PHYSIOLOGY • MECHANICAL FUNCTIONS OF THE NS • NERVOUS SYSTEM AS A WHOLE/SET 2 INTRODUCTION 3 INTRODUCTION • ¿Which are the main functions of the Nervous System? • ¿How the Nervous System is divided? • ¿Does/Has the Nervous System movement capability ? 4 INTRODUCTION • The NS is a continuous tissue: – Mechanical Continuity (dura- mater) – Electrical Continuity. – Chemical Continuity. • Any movement of a extremity has consequences in the NS. • Any movement of the PNS has consequences in the CNS. GENERAL STRUCTURE OF THE NS 6 GENERAL STRUCTURE OF THE NS GENERAL STRUCTURE OF THE NS • 1. CONTACT SURFACE / MECHANICAL INTERFACE: – “Tissue or material adjacent to the nervous system that can be moved independently of the system” (Butler 1991). – The mechanical interface acts as a container for the NS. (Shacklock 1995). – The NS must accommodate the tissues around it (interface). – The bio-pathological condition of these tissues can influence the NS by mechanical or inflammatory action. GENERAL STRUCTURE OF THE NS 2. NEURAL STRUCTURES: 2.1 Structures associated with nerve conduction. • Features that allow some mobility. – Neuroaxis (brain and spinal cord) – Nerve roots, dorsal root ganglion, peripheral nerve (axons). 2.2 Conjunctive structures associated. • Protection structures (meninges, endoneurium,...) • Features that allow some mobility. GENERAL STRUCTURE OF THE NS • 3. INNERVATED TISSUES: – Influence causal mechanisms (are the basis of some of them). – The NS interacts with the innervated tissues (afferent and efferent) – Allow mobilization and treatment (through them) of the nerve tissue. 10 PROTECTION SYSTEMS OF THE NS 11 PROTECTION SYSTEMS OF THE NS • 1. MENINGES: – ¿ What structures involve? – ¿What is their function? – Dura- mater. – Arachnoid. – Pia- Mater. PROTECTION SYSTEMS OF THE NS • 1.1 DURA- MATER: – More external. – Stringy/ fibrous, thick and rough. – Collagen and elastin. – It has little longitudinal deformation with capacity for crossadaptation. – Envelop loosely (not tightly) the NS. Parts: - Cranial Dura- Mater. - Spinal Dura- Mater. PROTECTION SYSTEMS OF THE NS • 1.1 DURA- MATER: – Anchores/ Attachment: • Central portions of the skull bones. • Foramen Magnum. • Lateral masses and posterior arch of the atlas and axis. • Sacrum (S2). • Dural ligaments and dorsomedial septums /partitions. PROTECTION SYSTEMS OF THE NS • 1.2 ARACHNOID MATER: – It is interposed between the two other meninges => Intermediate layer. – It is a translucent collagen membrane that envelop loosely the brain and spinal cord. – It is separated from the Dura- Mater by the subdural space. PROTECTION SYSTEMS OF THE NS • 1.3 PIA MATER: – It is the innermost membrane. – It is closely linked to nerve tissue, following its contours. – Microscopically thin and highly vascularized. – Between the pia -mater and arachnoid stands the subarachnoid space, through which circulates cerebrospinal fluid. 16 PROTECTION SYSTEMS OF THE NS • 2. WRAPS/ ENVELOPES OF THE PERIPHERAL NERVE: – Some fibers are coated with myelin and someone not. – Connective tissue sheaths, with longitudinal and oblique arrangement respect the axon. – Have more rigidity/stiffness near joints. – 20% of tissue is elastin (fibers). – May increase, between 15% to 20%, its resting length. PROTECTION SYSTEMS OF THE NS • 2. WRAPS/ ENVELOPES OF THE PERIPHERAL NERVE : – ¡ Both the connective tissue such as neural tissue are likely to respond to mechanical problems! 18 PROTECTION SYSTEMS OF THE NS • 2.1 ENDONEURIUM: – Envelopes the axon. – Formed by collagen matrix. – Maintains endoneurial space and the Cerebrospinal fluid pressure. – No lymphatic vessels, which causes…. that any edema interferes in the function. PROTECTION SYSTEMS OF THE NS • 2.2 PERINEURIUM: – Envelopes several axons and protects the endoneurial tubes. – It is the most resistant structure to the tension/ stress: ¡¡¡until 750 mmHg to be broken!!!!! PROTECTION SYSTEMS OF THE NS • 2.3 EPINEURIUM: - Envelopes the nerve. – Collagen and longitudinal elastic fibers (and may exist fat/grease among the nerve fascicles). – Internal epineurium: It facilitates the movement between the fascicles. Important in joint areas!!! – It allows the gliding, with respect to the mechanical interface. 21 PROTECTION SYSTEMS OF THE NS • 3. WRAPS/ ENVELOPES OF THE NERVE ROOTS: – They are similar to pia mater and arachnoid. – Have structures which allow transmit tension and movement: • Exist anchors of the roots to neighbour structures. • They have possibility to deploy themselves. WRAPS/ ENVELOPES OF THE NERVE ROOTS 23 PHYSIOLOGY 24 PHYSIOLOGY • 1. AXONAL TRANSPORT: – Anterograde: • Fast (400 mm/day): vesicles and neurotransmitters. • Slow (1-6 mm/day): material of the cytoskeleton. – Retrograde: • 200 mm/day. • Recycled vesicles and extracellular material which promotes the neurite growth. ¡¡¡¡Compression may affect these transports!!!! PHYSIOLOGY • 2. BLOOD CIRCULATION: – The NS consumes the 20% of the oxygen. – Irrigation of the CNS: the Circle of Willis. – Irrigation of the spinal cord: vertebral and radicular arteries. PHYSIOLOGY • 2. BLOOD CIRCULATION – Irrigation of the nerve roots: radicular (proximal and distal) artery. – Irrigation of the peripheral nerve: Intrinsic vascular system very extensive, due to can not afford to lack of blood supply. PHYSIOLOGY • 2. BLOOD CIRCULATION: – Decreased blood flow begins with a stretch of 8%, stopping when the stretch is 15%. – Also affects time: 6% stretch for one hour reduces the conduction by 70%. – Compression effects: the threshold is between 30-50 mmHg. – Compression and tension have acumulative effects. PHYSIOLOGY • 3. INERVATION: – Peripheral nerve is inervated by the “nervi nervorum”. – Effects of the sympathetic fibers about the peripheral nerve circulation : vasoconstriction. – Effects of the nociceptors about the peripheral nerve circulation: vasodilation. MECHANICAL FUNCTIONS OF THE NS 30 MECHANICAL FUNCTIONS OF THE NS • Any body movement is going to be transmitted to NS, not only locally. • The body mechanics of the NS must allow pain-free movements without altering the primary function of the SN (transmission of electrochemical impulses) • NS has mechanisms to prevent injuries. MECHANICAL FUNCTIONS OF THE NS • Mechanical interface moves and can produce changes in the NS: - Physiologic mechanical interface. - Pathological mechanical interface • The normality in the movement of the SN depends of its neuro-biomechanical capacity: - Withstand tension. - Slip(slide) into your container. - Be able to compress MECHANICAL FUNCTIONS OF THE NS • 1. TENSION: – Nerves are attached to the ends of the container. – The lengthening of the container "lengthens" the nerve. – The tension increases “intraneural pressure”. – Perineurium is a key protective structure: dense connective tissue. – They can withstand between 18-22% of tension: sciatic nerve (up to 50 kg.) MECHANICAL FUNCTIONS OF THE NS • 2. SLIDING: – “Movement between the neural tissue and mechanical interface”. – Longitudinal Sliding: • Nerves move according to the tension gradient (towards the points of maximum tension and towards the area where the lengthening begins). • Without sliding, neural ischemia would occur. • Add other movements increases tension. MECHANICAL FUNCTIONS OF THE NS – Transverse Sliding: • Find the shortest path when apply tension. * Helps dissipate tension / pressure on nerves • It responds to lateral pressure of adjacent structures. – Permitted by the epineurium. MECHANICAL FUNCTIONS OF THE NS • 3. COMPRESSION: – Possibility of deformation. – Epineurium is which protects from excessive compression. – It has sufficient elasticity to return to the initial position when the pressure is removed. NERVOUS SYSTEM AS A WHOLE/SET 37 NERVOUS SYSTEM AS A WHOLE/SET • NS as a complex system: – Local movements can cause distance changes. • During movement, the tension in the NS is initially located in the local area. • The transmission of forces facilitates that can produce side/ secondary effects in another area. • The spread of the tension and movement is nonuniform. • If pressure is higher in an area, the greater the distance and the mechanisms of adaptation to other areas. NERVOUS SYSTEM AS A WHOLE/SET • Response to movement: – At the beginning, a movement of the NS is produced locally. Then it spreads to distal. – In the medium-haul (path), a very fast neural slip/ glide occurs. – In the end- haul (path), appears a tension in the NS, due to the ability of gliding has decreased. NERVOUS SYSTEM AS A WHOLE/SET – The first part that moves is the one that will be subjected to more stress. – Load receiving in the NS is determined by joint position. Lengthens on the convex side of the joints and shortens on the concave side 40 NERVOUS SYSTEM AS A WHOLE/SET • Structural differentation: – NS continuity allows manual differentiation of the structures involved in the problem. – It is performed by moving the neural structures without moving the musculoskeletal structures in the same area. – It can be done in all neurodynamic tests. BIBLIOGRAPHY • Butler DS. Mobilisation of the Nervous System. Editorial Paidotribo. • Shacklock M. Clinical Neurodynamics: A New System of Musculoskeletal Treatment. Editorial Elsevier. • López Cubas,C. Neurodinámica en la Práctica Clínica. Editorial Zerapi.

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