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What sensation is probably the most important to test and why?

Podcast #99: How foot placement, the glutes and cross over gait all come together and make sense.

Topics: Plus, How foot placement, the glutes and cross over gait all come together and make sense. Plus, discussions on vibration,proprioception, cerebellum and movement.

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A. Link to our server: http://traffic.libsyn.com/thegaitguys/pod_99final.mp3

Podcast Direct Download: http://thegaitguys.libsyn.com/podcast-99-how-foot-placement-the-glutes-and-cross-over-gait-all-come-together-and-make-sense

Other Gait Guys stuff

B. iTunes link:
https://itunes.apple.com/us/podcast/the-gait-guys-podcast/id559864138
C. Gait Guys online /download store (National Shoe Fit Certification & more !)
http://store.payloadz.com/results/results.aspx?m=80204
D. other web based Gait Guys lectures:
Monthly lectures at : www.onlinece.com type in Dr. Waerlop or Dr. Allen, ”Biomechanics”

-Our Book: Pedographs and Gait Analysis and Clinical Case Studies
Electronic copies available here:

-Amazon/Kindle:
http://www.amazon.com/Pedographs-Gait-Analysis-Clinical-Studies-ebook/dp/B00AC18M3E

-Barnes and Noble / Nook Reader:
http://www.barnesandnoble.com/w/pedographs-and-gait-analysis-ivo-waerlop-and-shawn-allen/1112754833?ean=9781466953895

https://itunes.apple.com/us/book/pedographs-and-gait-analysis/id554516085?mt=11

-Hardcopy available from our publisher:
http://bookstore.trafford.com/Products/SKU-000155825/Pedographs-and-Gait-Analysis.aspx

Show notes:

Evaluating the Differential Electrophysiological Effects of the Focal Vibrator on the Tendon and Muscle Belly in Healthy People ARTICLE in ANNALS OF REHABILITATION MEDICINE · AUGUST 2014 DOI: 10.5535/arm.2014.38.4.494 · Source: PubMed

J Neurophysiol. 2014 Jul 15;112(2):374-83. doi: 10.1152/jn.00138.2014. Epub 2014 Apr 30. A neuromechanical strategy for mediolateral foot placement in walking humans.  Rankin BL

J Neurophysiol. 2015 Oct;114(4):2220-9. doi: 10.1152/jn.00551.2015. Epub 2015 Aug 19.

Hip proprioceptive feedback influences the control of mediolateral stability during human walking.

Roden-Reynolds DC1, Walker MH1, Wasserman CR1, Dean JC2.

Eur Spine J. 2015 May 26. [Epub ahead of print]
Prevalence of gluteus medius weakness in people with chronic low back pain compared to healthy controls.
Cooper NA1, Scavo KM, Strickland KJ, Tipayamongkol N, Nicholson JD, Bewyer DC, Sluka KA.

Prog Brain Res. 2004;143:353-66. Role of the cerebellum in the control and adaptation of gait in health and disease. Thach WT1, Bastian AJ.

You’d have to be smart to walk this lazy, and people are

Research suggests that humans are wired for laziness

http://www.sciencedaily.com/releases/2015/09/150910131451.htm#.VfWquNKaf3s.facebook

Jessica C. Selinger, Shawn M. O’Connor, Jeremy D. Wong, J. Maxwell Donelan. Humans Can Continuously Optimize Energetic Cost during Walking. Current Biology, 2015; DOI: 10.1016/j.cub.2015.08.016

Ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion

 
                                                                                                              
“The results provide strong evidence that the primary endings of ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion by providing information describing the movement of the body’s COM with respect to the support foot. Our results also provide supporting evidence for the proposal that there are context-dependent changes in muscle spindle sensitivity during human locomotion.”                                                                                    

  • This study tells us what we already know: The muscles surrounding the ankle, especially of the leg you are standing on (the “stance” phase leg) provide important information to the central nervous system about both that leg AND the leg not on the ground (The “swing” phase leg).  Remember the central integration of things like the Crossed Extensor Response we have talked about in prior podcasts ?
  • The implications are that if you have an ankle injury, this mechanism can be altered, resulting in loss of balance (or proprioception) as well as opening you up to greater (or additional) injury.
  • The other implication is that the whole ball of wax is “situationally dependent”; meaning plastic and adaptable. Pretty cool !
The Gait Guys. Bringing you the latest and greatest, each and every post.
                                                                                       
                                                                                                                
 SOURCE:
Exp Brain Res. 2002 Mar;143(1):24-34. Epub 2001 Dec 18.

The effects of human ankle muscle vibration on posture and balance during adaptive locomotion.

Source

Gait and Posture Laboratory, Department of Kinesiology, University of Waterloo, Ontario N2L 3G1, Canada.

Abstract

This study investigated the contribution of ankle muscle proprioception to the control of dynamic stability and lower limb kinematics during adaptive locomotion, by using mechanical vibration to alter the muscle spindle output of individuals’ stance limbs. It was hypothesised that muscle length information from the ankle of the stance limb provides information describing location as well as acceleration of the centre of mass (COM) with respect to the support foot during the swing phase of locomotion. Our prediction, based on this hypothesis was that ankle muscle vibration would cause changes to the position and acceleration of the COM and/or compensatory postural responses. Vibrators were attached to both the stance limb ankle plantarflexors (at the Achilles tendon) and the opposing dorsiflexor muscle group (over tibialis anterior). Participants were required to walk along a 9-m travel path and step over any obstacles placed in their way. There were three task conditions: (1) an obstacle (15 cm in height) was positioned at the midpoint of the walkway prior to the start of the trial, (2) the same obstacle was triggered to appear unexpectedly one step in front of the participant at the walkway midpoint and (3) the subjects’ walking path remained clear. The participants’ starting position was manipulated so that the first step over the obstacle (when present) was always performed with their right leg. For each obstacle condition participants experienced the following vibration conditions: no vibration, vibration of the left leg calf muscles or vibration of the anterior compartment muscles of the lower left leg. Vibration began one step before the obstacle at left leg heel contact and continued for 1 s. Vibrating the ankle muscles of the stance limb during the step over an obstacle resulted in significant changes to COM behaviour [measured as displacement, acceleration and position with respect to the centre of pressure (COP)] in both the medial/lateral (M/L) and anterior/posterior planes. There were also significant task-specific changes in stepping behaviour associated with COM control (measured as peak M/L acceleration, M/L foot displacement and COP position under the stance foot during the step over the obstacle). The results provide strong evidence that the primary endings of ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion by providing information describing the movement of the body’s COM with respect to the support foot. Our results also provide supporting evidence for the proposal that there are context-dependent changes in muscle spindle sensitivity during human locomotion.

Ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion

 
                                                                                                              
“The results provide strong evidence that the primary endings of ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion by providing information describing the movement of the body’s COM with respect to the support foot. Our results also provide supporting evidence for the proposal that there are context-dependent changes in muscle spindle sensitivity during human locomotion.”                                                                                    

  • This study tells us what we already know: The muscles surrounding the ankle, especially of the leg you are standing on (the “stance” phase leg) provide important information to the central nervous system about both that leg AND the leg not on the ground (The “swing” phase leg).  Remember the central integration of things like the Crossed Extensor Response we have talked about in prior podcasts ?
  • The implications are that if you have an ankle injury, this mechanism can be altered, resulting in loss of balance (or proprioception) as well as opening you up to greater (or additional) injury.
  • The other implication is that the whole ball of wax is “situationally dependent”; meaning plastic and adaptable. Pretty cool !
The Gait Guys. Bringing you the latest and greatest, each and every post.
                                                                                       
                                                                                                                
 SOURCE:
Exp Brain Res. 2002 Mar;143(1):24-34. Epub 2001 Dec 18.

The effects of human ankle muscle vibration on posture and balance during adaptive locomotion.

Source

Gait and Posture Laboratory, Department of Kinesiology, University of Waterloo, Ontario N2L 3G1, Canada.

Abstract

This study investigated the contribution of ankle muscle proprioception to the control of dynamic stability and lower limb kinematics during adaptive locomotion, by using mechanical vibration to alter the muscle spindle output of individuals’ stance limbs. It was hypothesised that muscle length information from the ankle of the stance limb provides information describing location as well as acceleration of the centre of mass (COM) with respect to the support foot during the swing phase of locomotion. Our prediction, based on this hypothesis was that ankle muscle vibration would cause changes to the position and acceleration of the COM and/or compensatory postural responses. Vibrators were attached to both the stance limb ankle plantarflexors (at the Achilles tendon) and the opposing dorsiflexor muscle group (over tibialis anterior). Participants were required to walk along a 9-m travel path and step over any obstacles placed in their way. There were three task conditions: (1) an obstacle (15 cm in height) was positioned at the midpoint of the walkway prior to the start of the trial, (2) the same obstacle was triggered to appear unexpectedly one step in front of the participant at the walkway midpoint and (3) the subjects’ walking path remained clear. The participants’ starting position was manipulated so that the first step over the obstacle (when present) was always performed with their right leg. For each obstacle condition participants experienced the following vibration conditions: no vibration, vibration of the left leg calf muscles or vibration of the anterior compartment muscles of the lower left leg. Vibration began one step before the obstacle at left leg heel contact and continued for 1 s. Vibrating the ankle muscles of the stance limb during the step over an obstacle resulted in significant changes to COM behaviour [measured as displacement, acceleration and position with respect to the centre of pressure (COP)] in both the medial/lateral (M/L) and anterior/posterior planes. There were also significant task-specific changes in stepping behaviour associated with COM control (measured as peak M/L acceleration, M/L foot displacement and COP position under the stance foot during the step over the obstacle). The results provide strong evidence that the primary endings of ankle muscle spindles play a significant role in the control of posture and balance during the swing phase of locomotion by providing information describing the movement of the body’s COM with respect to the support foot. Our results also provide supporting evidence for the proposal that there are context-dependent changes in muscle spindle sensitivity during human locomotion.