wbldb
home
|
authors
|
theses
Cheung, Jason Tak-Man
;
An, Kai-Nan
;
Zhang, Ming
Consequences of partial and total plantar fascia release: a finite element study
Foot Ankle Int
. 2006;27(2):125-132
Links
PubMed:
16487466
WoS:
000235483800011
Cited Works (13)
Year
Entry
2000
Gefen A, Megido-Ravid M, Itzchak Y, Arcan M. Biomechanical analysis of the three-dimensional foot structure during gait: a basic tool for clinical applications.
J Biomech Eng
. December 2000;122(6):630-639.
1997
Kitaoka HB, Luo ZP, An K-N. Mechanical behavior of the foot and ankle after plantar fascia release in the unstable foot.
Foot Ankle Int
. 1997;18(1):8-15.
2002
Gefen A. Stress analysis of the standing foot following surgical plantar fascia release.
J Biomech
. 2002;35(5):629-637.
1998
Athanasiou KA, Liu GT, Lavery LA, Lanctot DR, Schenck RC Jr. Biomechanical topography of human articular cartilage in the first metatarsophalangeal joint.
Clin Orthop Relat Res
. 1998;348:269-281.
2003
Crary JL, Hollis JM, Manoli A II. The effect of plantar fasci release on strain in the spring and long plantar ligaments.
Foot Ankle Int
. March 2003;24(3):245-250.
1993
Huang C-K, Kitaoka HB, An K-N, Chao EYS. Biomechanical evaluation of longitudinal arch stability.
Foot Ankle
. July–August 1993;14(6):353-357.
1964
Wright DG, Rennels DC. A study of the elastic properties of plantar fascia.
J Bone Joint Surg
. 1964;46A(3):482-492.
2000
Zheng YP, Choi YKC, Wong K, Chan S, Mak AFT. Biomechanical assessment of plantar foot tissue in diabetic patients using an ultrasound indentation system.
Ultrasound Med Biol
. 2000;26(3):451-456.
1999
Jacob S, Patil MK. Stress analysis in three-dimensional foot models of normal and diabetic neuropathy.
Front Med Biol Eng
. 1999;9(3):211-227.
2002
Camacho DLA, Ledoux WR, Rohr ES, Sangeorzan BJ, Ching RP. A three-dimensional, anatomically detailed foot model: a foundation for a finite element simulation and means of quantifying foot-bone position.
J Rehab Res Dev
. 2002;39(3):401-410.
2001
Chen W-P, Tang F-T, Ju C-W. Stress distribution of the foot during mid-stance to push-off in barefoot gait: a 3-D finite element analysis.
Clin Biomech
(Bristol, Avon). August 2001;16(7):614-620.
1998
Murphy GA, Pneumaticos SG, Kamaric E, Noble PC, Trevino SG, Baxter DE. Biomechanical consequences of sequential plantar fascia release.
Foot Ankle Int
. 1998;19(3):149-152.
1988
Siegler S, Block J, Schenck CD. The mechanical characteristics of the collateral ligaments of the human ankle joint.
Foot Ankle
. April 1988;8(5):234-242.
Cited By (18)
Year
Entry
2014
Feinblatt JS. Plantar fasciitis/faciosis. In: Philbin TM, ed.
Sports Injuries of the Foot: Evolving Diagnosis and Treatment
. New York, NY: Springer; 2014:129-150.
2012
Meyer EG, Wei F, Button K, Powell JW, Haut RC. Determination of ligament strain during high ankle sprains due to excessive external foot rotation in sports. In:
Proceedings of the 2012 International IRCOBI Conference on the Biomechanics of Injury
. September 12-14, 2012; Dublin, Ireland.277-287.
2011
Wei F, Hunley SC, Powell JW, Haut RC. Development and validation of a computational model to study the effect of foot constraint on ankle injury due to external rotation.
Ann Biomed Eng
. February 2011;39(2):756-765.
2017
Smolen C, Quenneville CE. A finite element model of the foot/ankle to evaluate injury risk in various postures.
Ann Biomed Eng
. August 2017;45(8):1993-2008.
2016
Morales-Orcajo E, Bayod J, Barbosa de Las Casas E. Computational foot modeling: scope and applications.
Arch Comput Methods Eng
. September 2016;23(3):389-416.
2010
Caravaggi P, Pataky T, Günther M, Savage R, Crompton R. Dynamics of longitudinal arch support in relation to walking speed: contribution of the plantar aponeurosis.
J Anat
. 2010;217(3):254-261.
2008
Cheng H-YK, Lin C-L, Wang H-W, Chou S-W. Finite element analysis of plantar fascia under stretch: the relative contribution of windlass mechanism and Achilles tendon force.
J Biomech
. 2008;41(9):1937-1944.
2007
Liacouras PC, Wayne JS. Computational modeling to predict mechanical function of joints: application to the lower leg with simulation of two cadaver studies.
J Biomech Eng
. 2007;129(6):811-817.
2009
García-Aznar JM, Bayod J, Rosas A, Larrainzar R, García-Bógalo R, Doblaré M, Llanos LF. Load transfer mechanism for different metatarsal geometries: a finite element study.
J Biomech Eng
. February 2009;131(2):021011.
2017
Nie B, Panzer MB, Mane A, Mait AR, Donlon J-P, Forman JL, Kent RW. Determination of the in situ mechanical behavior of ankle ligaments.
J Mech Behav Biomed Mater
. January 2017;65:502-512.
2007
Petre MT.
Investigating the Internal Stress/strain State of the Foot Using Magnetic Resonance Imaging and Finite Element Analysis
[PhD thesis]. Cleveland, OH: Case Western Reserve University; August 2007.
2020
Ellison MA.
Beam Theory and Finite Element Approaches to Modelling the Stresses in the Second Metatarsal During Running
[PhD thesis]. Exeter, UK: University of Exeter; March 2020.
2015
Smolen C.
Evaluation of the Load Path Through the Foot/ankle Complex in Various Postures Through Cadaveric and Finite Element Model Testing
[Master's thesis]. Hamilton, ON: McMaster University; September 2015.
2012
Wei F.
Biomechanical Investigations and Computational Modeling of the Human Ankle
[PhD thesis]. East Lansing, MI: Michigan State University; 2012.
2015
Button KD.
Biomechanical Response of the Ankle to Excessive External Rotation
[PhD thesis]. East Lansing, MI: Michigan State University; 2015.
2006
Liacouras PC.
Computational Modeling to Predict Mechanical Function of Joints: Validations and Applications of Lower Leg Simulations
[PhD thesis]. Richmond, VA: Virginia Commonwealth University; August 2006.
2010
Iaquinto JM.
The Design and Validation of a Novel Computational Simulation of the Leg for the Investigation of Injury, Disease, and Surgical Treatment
[PhD thesis]. Richmond, VA: Virginia Commonwealth University; May 2010.
2013
Spratley EM.
Patient-Specific Modeling of Adult Acquired Flatfoot Deformity Before and After Surgery
[PhD thesis]. Richmond, VA: Virginia Commonwealth University; 2013.