Chapter 1: General Neurodynamics

This is a Chapter 1 summary of “Clinical Neurodynamics” by Michael Shacklock.  Concepts When we first started working with the nervous system, oftentimes we called pathological processes adverse neural tension. The problem with this name was that it left out nervous system physiology; it was mere mechanical concepts. Hence, we call the movement and physiology of the nervous system neurodynamics. General neurodynamics account for whole body fundamental mechanisms, regardless of region. Specific neurodynamics, on the other hand, applies to particular body regions to account for local anatomical and biomechanical idiosyncrasies. The System There are three parts to the neurodynamic structure: 1)      The mechanical interface 2)      The neural structures 3)      The innervated tissues The mechanical interface is that which is near the nervous system. It consists of materials such as tendon, muscle, bone, intervertebral discs, ligaments, fascia, and blood vessels. The neural structures are those which make up the nervous system. These structures include the connective tissues that forms the meninges (pia, arachnoid, and dura mater) and peripheral nervous system (mesoneurium, epineurium, epineurium, and endoneurium). The nervous system has mechanical functions of tension, movement, and compression. It also has physiological functions to include intraneural blood flow, impulse conduction, axonal transport, inflammation, and mechanosensitivity. The innervated tissues are simply any tissues that are innervated by the nervous system. They provide causal mechanisms for patient complaints, and are able to create nerve motion. When we have neural problems, sometimes the best treatment is to these structures. You must treat everything affected. Mechanical Functions

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Movement Chapter 8: SFMA Assessment Breakout Descriptions and Flowcharts

This is a chapter 8 summary of the book “Movement” by Gray Cook. What to Look For The SFMA breakouts are utilized to determine if one’s movement deficiencies have a mobility or stability origin. There are further possibilities in each of these categories. It Could Be a Mobility Problem There are two subsets of mobility problems that include tissue extensibility dysfunction (TED) and joint mobility dysfunction (JMD). From here, we can break it down even further in each subset. Here are some potential TEDs Active/passive muscle insufficiency Limited neurodynamics (they said neural tension; come on Gray!) Fascial tension Muscle shortening Hypertrophy Trigger points Scarring/fibrosis And here are some potential JMDs Osteoarthritis/arthrosis Single-joint muscle spasm/guarding Fusion Subluxation Adhesive capsulitis Dislocation It could be a Stability Problem These issues are also known as stability or motor control dysfunction (SMCD). Most conventional therapies would treat these complaints by strengthening the stabilizers, but this is problematic. When something works reflexively, how can we train something volitionally and expect changes? To train these muscles we must focus on proprioceptive and timing-based training. There are several examples of SMCD problems. Motor control dysfunction. High threshold strategy. Local muscle dysfunction/asymmetry. Mechanical breathing dysfunction. Prime mover or global muscle compensation behavior or asymmetry. Poor static stability, alignment, postural control, asymmetry, and structural integrity. Poor dynamic stability, alignment, postural control, asymmetry, and structural integrity. Relatedness Mobility and stability can influence one another. If I were to lose mobility at one segment, motor control can be distorted at nearby segments.

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