Tag: neurodynamics

Chapter 6: Planning the Physical Examination

This is a Chapter 6 summary of “Clinical Neurodynamics” by Michael Shacklock. Observe When assessing the patient, you must look at the following information: Symptom location, extent, quality, and behavior. Movement resistance. Range of motion. Compensatory patterns. Breathing quality. Tone of voice. Facial expression Protective muscle tone. Avoidance. When planning the exam, you can tier to what extent you ought to assess someone. Level 0: neurodynamics are contraindicated for physical or psychosocial reasons. Level 1: Limited exam where symptoms are minimally provoked. Full neurodynamic tests are not performed, and are tested separately from musculoskeletal structures. The neurodynamic tests are performed with relieving-based structural differentiation. Level 1 is indicated when… Symptoms are easily provoked and take a long time to settle after movement. Severe or latent pain is present. Potential pathology. Neurological deficit. Progressive worsening prior to exam. Level 2: Standard examination in which neurodynamics, interfaces, and innervated tissue are tested separately. Standard neurodynamic sequences are used and symptoms can more readily be brought on. Level 2 is indicated when… Less severe, latent, or easily provoked symptoms. Absent/minor neurological symptoms. Stable problem that is not rapidly deteriorating. Level 3: It’s gettin’ real. Here we see greater force localization and sequences that start at the problem. Sensitizers are often used as well. Level 3 is indicated when… Level 2 exam is normal or provides insufficient information. Symptoms are not severe or easily provoked. Problem is stable. No evidence of pathology. There are four examination types here: 3a) sensitizers are added. 3b) Begin

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Chapter 5: Diagnosis with Neurodynamic Tests

This is a Chapter 5 summary of “Clinical Neurodynamics” by Michael Shacklock. Neurodynamic Tests In neurodynamic tests, there are two movement types: 1)      Sensitizing: Increase force on neural structures. 2)      Differentiating: Emphasizing nervous system by moving the neural structure as opposed to musculoskeletal tissue. The reason why sensitizers are not considered differentiating structures is because they also move musculoskeletal structures. Examples of sensitizing movements include: Cervical or lumbar spine contralateral lateral flexion. Scapular depression Humeroglenoid (HG) horizontal extension HG external rotation Hip internal rotation Hip adduction Interpreting The ability to interpret neurodynamic findings is crucial when determining the nervous system’s involvement.  Findings such as asymmetry, symptoms, and increased sensitivity are all important. But to implicate neurodynamics, structural differentiation ought to be performed. Just because there is a positive test does not mean that it is relevant to the patient’s complaints. There are several ways to classify findings: Negative structural differentiation: Implicates musculoskeletal response. Positive structural differentiation: Implicates neurodynamic response. Neurodynamic responses can have different interpretations: Normal: Fits normal responses per literature. Abnormal: Differ from normal responses. Can be broken down further into… Overt abnormal responses: Symptoms reproduction. Covert abnormal response: No symptoms, but may have other subtle findings such as asymmetry, abnormal location, and/or different resistance. From here, one must determine if the findings are relevant or irrelevant to the condition in question. You may also come across subclinical findings, in which the neurodynamic test is related to a minor problem that may become major at some point.

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Course Notes: Mobilisation of the Nervous System

I Have an Addiction It seems the more and more that I read the more and more and read the more and more addicted I become to appreciating the nervous system and all its glory. To satisfy this addiction, I took Mobilisation of the Nervous System with my good friend Bob Johnson of the NOI Group. This was the second time I have taken this course in a year’s span and got so much more value this time around. I think the reason for this enrichment has been the fact that I have taken many of their courses prior and that I prepared by reading all the NOI Group’s books. A course is meant to clarify and expand on what you have already read. So if you are not reading the coursework prior, you are not maximizing your learning experience. What made this course so much more meaningful was being surrounded by a group of like-minded and intelligent individuals. As many of you know, I learned much of my training through Bill Hartman. Myself, Bill, the brilliant Eric Oetter and Matt Nickerson, my good friend Scott, and my current intern Stephanie, all attended. When you surround yourself with folks smarter than you, the course understanding becomes much greater. This course was so much more with the above individuals, so thank you. Try to attend courses with like-minded folks. Here are the highlights of what I learned. If you would like a more in-depth explanation of these concepts, check out my

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Chapter 4: Diagnosis of Specific Dysfunctions

This is a Chapter 4 summary of “Clinical Neurodynamics” by Michael Shacklock. Mechanical Interface Dysfunction In early stages of closing dysfunctions, symptoms present as aches and pains. This presentation is due to the musculoskeletal tissues being more affected than the neural tissue. As severity increases, neurological symptoms such as pins and needles, tingling, and burning are more likely to occur. The severest end of the spectrum includes numbness and weakness; indicating further compromise to the neurovascular structures. Interface dysfunctions behave with changes in posture and movement. Oftentimes cardinal signs of inflammation can be present, along with night pain/morning stiffness. Typically you will see a painful arc throughout movement. During the physical exam, patients will show an inability to move in opening or closing directions. You can also find altered pain production, soft tissue thickening, or hypermobility/instability. Neurological changes will usually be present only in severe interface dysfunction. There are four basic types of interface dysfunctions 1)      Reduced closing 2)      Excessive closing 3)      Reduced opening 4)      Excessive opening In reduced closing dysfunction, closing movements such as squeezing or cervical extension provoke symptoms. Assessment may show a protective deformity developing in the opening direction so pressure is reduced on the nervous system. Symptoms will often not be reproduced unless neurodynamic testing is combined with interface testing. Excessive closing is when, well, interfaces are closing too much. An example of this dysfunction is excessive lumbar lordosis present with low back pain that increases with standing, walking, and running. A patient’s history will often show

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Chapter 3: General Neuropathodynamics

This is a Chapter 3 summary of “Clinical Neurodynamics” by Michael Shacklock. What it is General neuropathodynamics are abnormalities consistent throughout the nervous system, with specific referring to local abnormalities. These changes may lead to a neurogenic pain experience, in which pain is initiated by a primary lesion, dysfunction, or transitory perturbation in the nervous system. This definition means that dysfunction in the nervous system, it’s surrounding tissues, and innervated tissues can all be related to neurogenic pain. Definitions of Clinical Problems When discussing dysfunction, there are several descriptors: 1)      Optimal/desirable: When the neuromusculoskeletal system behaves well and does not create symptoms in situations of high stress. 2)      Suboptimal: Imperfect neuromusculoskeletal behavior which results in potential symptom increasing if an adequate trigger occurs. 3)      Normal: Function of neuromusculoskeletal system is within normal values. 4)      Abnormal: Neuromusculoskeletal system is outside of the normal range. 5)      Relevant: When pathodynamics are linked to the clinical problem. 6)      Irrelevant: When pathodynamics are not linked to the clinical problem. You will oftentimes have multiple of these components in a clinical situation. Mechanical Interface Dysfunction These dysfunctions deal with abnormal or undesirable forces on the nervous system. There are two main categories with their own subcategories. 1)      Closing dysfunctions – Altered closing mechanisms of the movement complex. Can be reduced (protective response) or excessive (hypermobility/instability). 2)      Opening dysfunctions – Altered opening mechanisms of the movement complex. Can be reduced which creates impaired pressure reduction, or excessive leading to tissue traction. Pathoanatomical Dysfunction This type of dysfunction is

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Chapter 2: Specific Neurodynamics

This is a Chapter 2 summary of “Clinical Neurodynamics” by Michael Shacklock. Intro Specific neurodynamics include local effects of body movements on the nervous system. So today we will go through each body region discussing these. The Spine Here are some interesting tidbits regarding the spine and neurodynamics. When we flex the spine, the spinal canal elongates by about 9 cm. Neck flexion creates significant tension to the lumbosacral nerve roots. Neural structures slide relative to the bony interface differently depending on the location and the movement used. Flexion increases tension, but reduces compression. Extension adds compression, but reduces tension. Lateral flexion increases tension on the convex/contralateral side of the spine. This situation occurs by interface and neural tissue elongation and increased distance between the spine and periphery. Rotation closes on the ipsilateral side and opens on the contralateral side. The spinal cord tends to move towards various specific segments. These areas are termed zones of convergence, and these areas include C5-6 and L4-5.  For example, tissues above C5-6 will slide toward this zone, as will tissues below this segment. The midpoint at which tissues diverge is at T6. At this point, tissues below T6 will converge towards L4-5, and tissues above T-6 will converge to C5-6. Gravity can also play a role in neurodynamics. For example, if you perform a SLR in sidelying, the downward side usually has less mobility.  This difference occurs because the neural contents are convex on the downward side and convex on the upper side,

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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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The Sensitive Nervous System Chapter V: Neurodynamics

This is a summary of Chapter V of “The Sensitive Nervous System” by David Butler. Intro Neurodynamics is the study and relationship of nervous system mechanics and physiology. The testing protocols for neurodynamics assess the nervous system’s ability to lengthen, glide, and change amongst interfacing structures. When discussing neurodynamics, it is important to think of the nervous system as a continuum. Mechanical, electrical, and chemical changes in one part of the nervous system affect other related parts. Gross Movements and Dynamics When having a nervous system, the following qualities, movements, and buffering capabilities are necessary: Slide, glide, strain. Elongate (think gymnasts) and return from elongated position. Compress (ulnar nerve during elbow flexion). Stength (kicking a field goal). Jolting (whiplash). Repetitive forces Bending Fluid/chemical selectivity. Neural Connective Tissue These include the meninges, nerve root complex, and peripheral nerve structures. Broken down as follows: Meninges Dura mater (outer, tougher) Arachnoid mater Pia mater (inner, thinner) Nerve root complex Root Sleeve Dorsal and ventral roots DRG Spinal nerve. Peripheral nerves Epineurium Perineurium Endoneurium Mesoneurium – Sheath that surrounds a nerve. Contracts like an accordion to glide along adjacent tissues. Can become fibrotic with injury. Important Attachments Meningovertebral ligaments – anchor down to spinal canal, which could become symptomatic. Rectus capitus posterior is connected to the dura mater between the occiput and atlas; helping the dura fold. Makes you wonder what you are truly doing when you release this structure. The sympathetic trunk’s proximity to the spinal column makes it susceptible to increased loads

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The Sensitive Nervous System Chapter I: Painting a Bigger Canvas

This is a summary of Chapter I of The Sensitive Nervous System. This book is an all-encompassing manual regarding neurodynamics. This concept is defined as the physical and related physiological abilities of the nervous system. Before delving into neurodynamic nitty-gritty, a brief history of physical therapy is laid out via a very cool brachial plexus design (you have to get the book to see it). There are three different progressions in physical therapy history: manual therapy, exercise, and neurological manual therapy. The first time PTs learned manipulation was in 1916 at St. Thomas Hospital in London. The thought process of the time, as well as most early manual therapy, was predominantly biomechanically joint-centric. Eventually, muscle and other tissues were targeted. These approaches were championed by Geoffrey Maitland’s signs and symptoms approach and Graves’ pathological model. Concomitant with manual therapy has been exercise, which had moved from nonspecific (aerobics, tai chi) to specific movements a la Vladimir Janda and Shirley Sahrmann. On the other side of orthopedic manual therapy were manual techniques from the likes of Bobath’s NDT and PNF. What is sad about these techniques is that they have not interacted much during manual therapy’s development. Butler makes arguably one of the most important statements in the book by saying our patients are ultimately all neurological. We will all meet at the brain. Aside from various manual approaches, recent techniques have been developed including psychology, counseling, exercise physiology, and acupuncture. Butler feels these are nice adjuncts to the plan of

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