Barefoot and shod walking in virtual reality environment with Oxford foot model

Craig R. Childs, Vicki Cameron, Andrew J. Murphy

Research output: Contribution to conferencePoster

Abstract

Introduction and Objectives: The Oxford Foot Model (OFM) [1] was developed to get accurate measurement of foot movement during gait as the bone pin method [2] is not practical for most clinical situations. It has been validated in adults [3] and children [4]. However, since barefoot walking on a treadmill is not recommended there is a question over whether the OFM can be usefully applied in facilities such as the Motek CAREN (Computer Assisted Rehabilitation Environment - motekmedical.com). Consequently, there is an interest to see if applying OFM markers to shoes can give useful results when measuring human walking on treadmills. This study looks at the differences in measurements using the OFM between walking over-ground (barefoot and with shoes) and on a treadmill (with shoes). Methods: Nine boys (mean age 13.5±0.5yrs, height 1.59±0.09m, mass 47.8±8.3kg) were recruited. Retro-reflective markers were attached bilaterally following the Plug-in-Gait lower limb and OFM models. The over-ground (barefoot and with shoes) trials were recorded in a standard gait laboratory (12 camera Vicon T-Series). Barefoot trials were performed first to minimise the need to reattach markers. The treadmill walking trials were recorded in the CAREN immediately after the over-ground trials (12 camera Vicon Bonita10). The treadmill speed was set to match the speed of over-ground walking in the gait laboratory. Gait events were determined from force plate contacts. All the boys wore light indoor training shoes. Data was captured using Vicon Nexus 1.8.5 and processed using Plug in Gait and OFM models in Nexus 2.1. Results: There was no difference in ankle kinematics between over-ground (barefoot and with shoes) and on a treadmill (with shoes). Although Forefoot-Hindfoot angles were comparable to the literature in the barefoot condition, this was not the case with shoes (Table 1). Barefoot, there was a steady dorsiflexing motion throughout stance until push off which was signified by a rapid plantar-flexing motion. With shoes on, the same model segments show rapid dorsiflexion, then plantar flexion during early stance followed by neutral position held until push-off. Conclusion: Reinschmidt and colleagues [2] reported that the shape of the calcaneal motion curves was similar for shoe mounted markers and bone markers, but that the shoe-mounted markers overestimated joint angles. In this study, the shape of the curves was quite different.

Conference

ConferenceXXV Congress International Society of Biomechanics
Abbreviated titleISB 2015
CountryUnited Kingdom
CityGlasgow
Period12/07/1516/07/15
Internet address

Fingerprint

Shoes
Virtual reality
Walking
Foot
Exercise equipment
Gait
Bone
Cameras
Bone Nails
Patient rehabilitation
Kinematics
Biomechanical Phenomena
Ankle
Wear of materials
Lower Extremity
Rehabilitation
Joints

Keywords

  • walking
  • biomechanics
  • barefoot
  • virtual reality

Cite this

Childs, C. R., Cameron, V., & Murphy, A. J. (2015). Barefoot and shod walking in virtual reality environment with Oxford foot model. Poster session presented at XXV Congress International Society of Biomechanics, Glasgow, United Kingdom.
Childs, Craig R. ; Cameron, Vicki ; Murphy, Andrew J. / Barefoot and shod walking in virtual reality environment with Oxford foot model. Poster session presented at XXV Congress International Society of Biomechanics, Glasgow, United Kingdom.
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Childs, CR, Cameron, V & Murphy, AJ 2015, 'Barefoot and shod walking in virtual reality environment with Oxford foot model' XXV Congress International Society of Biomechanics, Glasgow, United Kingdom, 12/07/15 - 16/07/15, .

Barefoot and shod walking in virtual reality environment with Oxford foot model. / Childs, Craig R.; Cameron, Vicki; Murphy, Andrew J.

2015. Poster session presented at XXV Congress International Society of Biomechanics, Glasgow, United Kingdom.

Research output: Contribution to conferencePoster

TY - CONF

T1 - Barefoot and shod walking in virtual reality environment with Oxford foot model

AU - Childs, Craig R.

AU - Cameron, Vicki

AU - Murphy, Andrew J.

PY - 2015/7/12

Y1 - 2015/7/12

N2 - Introduction and Objectives: The Oxford Foot Model (OFM) [1] was developed to get accurate measurement of foot movement during gait as the bone pin method [2] is not practical for most clinical situations. It has been validated in adults [3] and children [4]. However, since barefoot walking on a treadmill is not recommended there is a question over whether the OFM can be usefully applied in facilities such as the Motek CAREN (Computer Assisted Rehabilitation Environment - motekmedical.com). Consequently, there is an interest to see if applying OFM markers to shoes can give useful results when measuring human walking on treadmills. This study looks at the differences in measurements using the OFM between walking over-ground (barefoot and with shoes) and on a treadmill (with shoes). Methods: Nine boys (mean age 13.5±0.5yrs, height 1.59±0.09m, mass 47.8±8.3kg) were recruited. Retro-reflective markers were attached bilaterally following the Plug-in-Gait lower limb and OFM models. The over-ground (barefoot and with shoes) trials were recorded in a standard gait laboratory (12 camera Vicon T-Series). Barefoot trials were performed first to minimise the need to reattach markers. The treadmill walking trials were recorded in the CAREN immediately after the over-ground trials (12 camera Vicon Bonita10). The treadmill speed was set to match the speed of over-ground walking in the gait laboratory. Gait events were determined from force plate contacts. All the boys wore light indoor training shoes. Data was captured using Vicon Nexus 1.8.5 and processed using Plug in Gait and OFM models in Nexus 2.1. Results: There was no difference in ankle kinematics between over-ground (barefoot and with shoes) and on a treadmill (with shoes). Although Forefoot-Hindfoot angles were comparable to the literature in the barefoot condition, this was not the case with shoes (Table 1). Barefoot, there was a steady dorsiflexing motion throughout stance until push off which was signified by a rapid plantar-flexing motion. With shoes on, the same model segments show rapid dorsiflexion, then plantar flexion during early stance followed by neutral position held until push-off. Conclusion: Reinschmidt and colleagues [2] reported that the shape of the calcaneal motion curves was similar for shoe mounted markers and bone markers, but that the shoe-mounted markers overestimated joint angles. In this study, the shape of the curves was quite different.

AB - Introduction and Objectives: The Oxford Foot Model (OFM) [1] was developed to get accurate measurement of foot movement during gait as the bone pin method [2] is not practical for most clinical situations. It has been validated in adults [3] and children [4]. However, since barefoot walking on a treadmill is not recommended there is a question over whether the OFM can be usefully applied in facilities such as the Motek CAREN (Computer Assisted Rehabilitation Environment - motekmedical.com). Consequently, there is an interest to see if applying OFM markers to shoes can give useful results when measuring human walking on treadmills. This study looks at the differences in measurements using the OFM between walking over-ground (barefoot and with shoes) and on a treadmill (with shoes). Methods: Nine boys (mean age 13.5±0.5yrs, height 1.59±0.09m, mass 47.8±8.3kg) were recruited. Retro-reflective markers were attached bilaterally following the Plug-in-Gait lower limb and OFM models. The over-ground (barefoot and with shoes) trials were recorded in a standard gait laboratory (12 camera Vicon T-Series). Barefoot trials were performed first to minimise the need to reattach markers. The treadmill walking trials were recorded in the CAREN immediately after the over-ground trials (12 camera Vicon Bonita10). The treadmill speed was set to match the speed of over-ground walking in the gait laboratory. Gait events were determined from force plate contacts. All the boys wore light indoor training shoes. Data was captured using Vicon Nexus 1.8.5 and processed using Plug in Gait and OFM models in Nexus 2.1. Results: There was no difference in ankle kinematics between over-ground (barefoot and with shoes) and on a treadmill (with shoes). Although Forefoot-Hindfoot angles were comparable to the literature in the barefoot condition, this was not the case with shoes (Table 1). Barefoot, there was a steady dorsiflexing motion throughout stance until push off which was signified by a rapid plantar-flexing motion. With shoes on, the same model segments show rapid dorsiflexion, then plantar flexion during early stance followed by neutral position held until push-off. Conclusion: Reinschmidt and colleagues [2] reported that the shape of the calcaneal motion curves was similar for shoe mounted markers and bone markers, but that the shoe-mounted markers overestimated joint angles. In this study, the shape of the curves was quite different.

KW - walking

KW - biomechanics

KW - barefoot

KW - virtual reality

UR - https://isbweb.org/activities/congresses

M3 - Poster

ER -

Childs CR, Cameron V, Murphy AJ. Barefoot and shod walking in virtual reality environment with Oxford foot model. 2015. Poster session presented at XXV Congress International Society of Biomechanics, Glasgow, United Kingdom.