Sage Journals: Discover world-class research

Abstract

This study investigates the use of an orthotic device for improving pathologic gait lacking a heel-strike and its effect on the joint loads. The orthosis is fabricated from 10-mm thick polypropylene sheets joined together using a bolted joint. The gait trials are recorded using a Qualisys motion capture system and Kistler’s force platform. The data recorded in this study comprise five male and five female participants, executing level ground gait under barefoot, shod and orthotic conditions. Computed tomography reconstructed foot bone–tissue model and computer-aided design model of the orthosis are used to predict the mechanical behaviour with and without orthosis under static loading. A one-way analysis of variance is conducted to compare the peak gait parameters in the early and late stance phase between the three walking conditions. The experimental results show that the orthosis reduces the peak joint forces and the rate of change of moment at the hip, knee and ankle joints. The finite element analysis results present a decrease in foot plantar pressure from 0.74 to 0.32 MPa with orthotic usage. The results of this study indicate that the orthosis can eliminate the heel-ground gap while retaining sufficient ankle motion and providing peak joint force reduction.

Keywords

Gait analysis kinetics kinematics rollover shape orthotic insert analysis of variance

Get full access to this article

View all access options for this article.

References

Pauk

Minta-Bielecka

A new classification of hemiplegia gait patterns based on bicluster analysis of joint moments. Acta Bioeng Biomech 2016; 18: 33–40.

Woolley

SM.

Characteristics of gait in hemiplegia. Topics Stroke Rehabilit 2001; 7: 1–18.

Keller

Weisberger

Ray

, et al. Relationship between vertical ground reaction force and speed during walking, slow jogging, and running. Clin Biomech 1996; 11: 253–259.

Verdejo

Mills

Heel–shoe interactions and the durability of EVA foam running-shoe midsoles. J Biomech 2004; 37: 1379–1386.

Gruber

Boyer

Derrick

, et al. Impact shock frequency components and attenuation in rearfoot and forefoot running. J Sport Health Sci 2014; 3: 113–121.

Curtze

Hof

van Keeken

, et al. Comparative biomechanics of prosthetic feet. Gait Post 2009; 30: 40–41.

Dabiri

Najarian

Eslami

, et al. A powered prosthetic knee joint inspired from musculoskeletal system. Biocybernet Biomed Eng 2013; 33: 118–124.

Meier

Tucker

Hansen

AH.

Development of inexpensive prosthetic feet for high-heeled shoes using simple shoe insole model. J Rehabilit Res Dev 2014; 51: 439–450.

Beitl

Noll

KH.

Postsurgical orthotic devices. Foot Ankle Clin 2001; 6: 297–314.

10.

Jena

Sudro

Reddy

, et al. The effect of transient loading on a foot-orthotic using temporal parameters of gait. J Mech Med Biol 2017; 17: 1750117.

11.

Majumdar

Laxton

Thuesen

, et al. Development and evaluation of prefabricated antipronation foot orthosis. J Rehabilit Res Dev 2014; 50: 1331–1342.

12.

Sinitski

Hansen

Wilken

JM.

Biomechanics of the ankle–foot system during stair ambulation: implications for design of advanced ankle–foot prostheses. J Biomech 2012; 45: 588–594.

13.

Vanicek

Strike

McNaughton

, et al. Biomechanical analysis of stair-climbing in transtibial amputees. J Biomech 2007; 40: 501.

14.

Segal

Yeates

Neptune

, et al. Foot and ankle joint biomechanical adaptations to an unpredictable coronally uneven surface. J Biomech Eng 2018; 140: 031004.

15.

Lewis

Garibay

EJ.

Effect of increased pushoff during gait on hip joint forces. J Biomech 2015; 48: 181–185.

16.

Koga

Three-dimensional motion analysis and its application in total knee arthroplasty: what we know, and what we should analyze. J Orthopaed Sci 2015; 20: 239–249.

17.

Mochizuki

Koga

Tanifuji

, et al. Effect on inclined medial proximal tibial articulation for varus alignment in advanced knee osteoarthritis. J Exp Orthopaed 2019; 6: 14.

18.

Hansen

Childress

DS.

Effects of shoe heel height on biologic rollover characteristics during walking. J Rehabilit Res Dev 2004; 41: 547–554.

19.

Ren

Howard

Ren

, et al. A generic analytical foot rollover model for predicting translational ankle kinematics in gait simulation studies. J Biomech 2010; 43: 194–202.

20.

Curtze

Hof

van Keeken

, et al. Comparative roll-over analysis of prosthetic feet. J Biomech 2009; 42: 1746–1753.

21.

Curtze

Otten

Hof

, et al. Determining asymmetry of roll-over shapes in prosthetic walking. J Rehabilit Res Dev 2011; 48: 1249–1260.

22.

Hansen

Childress

DS.

Investigations of roll-over shape: implications for design, alignment, and evaluation of ankle-foot prostheses and orthoses. Disabil Rehabilit 2010; 32: 2201–2209.

23.

Hansen

Childress

Knox

EH.

Roll-over shapes of human locomotor systems: effects of walking speed. Clin Biomech 2004; 19: 407–414.

24.

Hansen

Meier

Sam

, et al. Alignment of trans-tibial prostheses based on roll-over shape principles. Prosthet Orthot Int 2003; 27: 89–99.

25.

Hansen

Wang

CC.

Effect of rocker shoe radius on oxygen consumption rate in young able-bodied persons. J Biomech 2011; 44: 1021–1024.

26.

Hansen

Childress

Knox

Prosthetic foot rollover shapes with implications for alignment of transtibial prostheses. Prosthet Orthot Int 2000; 24: 205–215.

27.

Hansen

Meier

MR.

Roll-over shapes of the ankle–foot and knee–ankle–foot systems of able-bodied children. Clin Biomech 2010; 25: 248–255.

28.

Vattanasilp

Ada

Crosbie

Contribution of thixotropy, spasticity, and contracture to ankle stiffness after stroke. J Neurol Neurosurg Psychiatry 2000; 69: 34–39.

29.

Bressel

McNair

PJ.

The effect of prolonged static and cyclic stretching on ankle joint stiffness, torque relaxation, and gait in people with stroke. Phys Ther 2002; 82: 880–887.

30.

Sinclair

Isherwood

Taylor

PJ.

The effects of orthotic intervention on multisegment foot kinematics and plantar fascia strain in recreational runners. J Appl Biomech 2015; 31: 28–34.

31.

Daryabor

Saeedi

Ghasemi

, et al. Influence of heel design in an orthopedic shoe on ground reaction forces during walking. Prosthet Orthot Int 2016; 40: 598–605.

32.

Miller

Kaufman

Kingsbury

, et al. Mechanical testing for three-dimensional motion analysis reliability. Gait Post 2016; 50: 116–119.

33.

Rutherford

Kozey

Three-dimensional motion analysis: relevant concepts in physiotherapy movement dysfunction management. J Novel Physiother 2014; 4: 214.

34.

Tajino

Ito

Tanima

, et al. Three-dimensional motion analysis for comprehensive understanding of gait characteristics after sciatic nerve lesion in rodents. Sci Rep 2018; 8: 13585.

35.

C-motion. https://www.c-motion.com/v3dwiki/index.php/Tutorial:_Building_a_Conventional_Gait_Model

36.

C-motion. https://www.c-motion.com/v3dwiki/index.php?title=Inverse_Dynamics, 2019.

37.

Lin

S-Y

K-C

Chang

C-H

. Reverse engineering of CT-based rocker sole model – finite element analysis. In: 2013 international conference on orange technologies (ICOT), Tainan, Taiwan, 12–16 March 2013, pp.35–38. New York: IEEE.

38.

Qiu

T-X

Teo

E-C

Yan

Y-B

, et al. Finite element modeling of a 3D coupled foot–boot model. Med Eng Phys 2011; 33: 1228–1233.

39.

Mirzaali

Schwiedrzik

Thaiwichai

, et al. Mechanical properties of cortical bone and their relationships with age, gender, composition and microindentation properties in the elderly. Bone 2016; 93: 196–211.

40.

Peter

ANSYS theory reference manual (Release 5.6). Canonsburg, PA: ANSYS, 1994.

41.

Damavandi

Dixon

Pearsall

DJ.

Ground reaction force adaptations during cross-slope walking and running. Human Move Sci 2012; 31: 182–189.

42.

Kerrigan

Johansson

Bryant

, et al. Moderate-heeled shoes and knee joint torques relevant to the development and progression of knee osteoarthritis. Arch Phys Med Rehabilit 2005; 86: 871–875.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

1.05 MB

Experimental and numerical investigation of a polypropylene orthotic device for assistance in level ground walking

Abstract

Keywords

Get full access to this article

References

Supplementary Material