Lower extremity prosthesis fit results from a complex biomechanical interaction at the interface between the residuum and socket. The quality of fit determines subject comfort, acceptance, and potential for ambulation. The long term goal of this research is comprehensive assessment of lower limb prosthesis fit that is highly correlated with subjective metrics and has high predictive value for complications and functional outcome. In situ static 3D determination of prosthesis socket fit by a valid, repeatable, practical, and comprehensive method is sought to aid prosthesis design and evaluation, and to improve outcome. Volumetric imaging based on x-ray spiral CT will be used for static in situ lower limb prosthesis evaluation with and without axial loading. From these image volume data sets, tissue composition volume fractions (fat, muscle, bone, skin, other) will be extracted, mass properties estimated, and shape information mapped onto a 3D display. Shape and fit will be visualized by 3D. The measurement methods will be validated in vitro with phantom test objects and cadaver parts, and in vivo with adult amputees. Tissue composition estimates will be tested on extremity remnants phantoms, and on cadaver limbs. Prediction of the biomechanical characteristics for a given socket and limb remnant will be achieved by mathematical modeling. Using the CT volume data, we will synthesize polynomial version (p-version) finite element models that are static, fully 3--dimensional, incorporate separate tissue compartment (bone, muscle/fascia, fat, skin, and prosthesis), anisotropic, and nonlinear with large deformations. The models will be validated experimentally and used to predict the quality of socket fit. Measurements using x-rat spiral CT imaging and finite element tools will be used in a logistic regression model to determine the biomechanical characteristics associated with good and poor fitting prostheses. The feasibility of diagnostic fit evaluation using x-ray spiral CT and finite element mapping methods will be determined through ROC and repeatability analysis. Image-derived fit measures will be tested for correlation with subjective reports corrected for covariation due to age, gender, race, nutritional status, diabetes, smoking, amputation characteristics (stump length, reason for amputation), and other factors known to influence fit. On completion, this project will provide a valid and repeatable practical comprehensive volumetric image-based method to aid lower limb prosthesis design and evaluation. Prediction of the biomechanical characteristics of a given socket and limb remnant by p-version finite element modeling will be developed and tested.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Research Project (R01)
Project #
5R01HD030169-07
Application #
2673709
Study Section
Special Emphasis Panel (ZRG4-GRM (01))
Project Start
1992-09-30
Project End
2000-08-31
Budget Start
1998-09-01
Budget End
2000-08-31
Support Year
7
Fiscal Year
1998
Total Cost
Indirect Cost
Name
University of Iowa
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
041294109
City
Iowa City
State
IA
Country
United States
Zip Code
52242
Madsen, M T; Haller, J; Commean, P K et al. (2000) A device for applying static loads to prosthetic limbs of transtibial amputees during spiral CT examination. J Rehabil Res Dev 37:383-7
Wang, G; Frei, T; Vannier, M W (2000) Fast iterative algorithm for metal artifact reduction in X-ray CT. Acad Radiol 7:607-14
Commean, P K; Brunsden, B S; Smith, K E et al. (1998) Below-knee residual limb shape change measurement and visualization. Arch Phys Med Rehabil 79:772-82
Commean, P K; Smith, K E; Vannier, M W (1997) Lower extremity residual limb slippage within the prosthesis. Arch Phys Med Rehabil 78:476-85
Commean, P K; Smith, K E; Vannier, M W et al. (1997) Finite element modeling and experimental verification of lower extremity shape change under load. J Biomech 30:531-6
Commean, P K; Smith, K E; Vannier, M W (1996) Design of a 3-D surface scanner for lower limb prosthetics: a technical note. J Rehabil Res Dev 33:267-78
Commean, P K; Smith, K E; Cheverud, J M et al. (1996) Precision of surface measurements for below-knee residua. Arch Phys Med Rehabil 77:477-86
Smith, K E; Commean, P K; Vannier, M W (1996) Residual-limb shape change: three-dimensional CT scan measurement and depiction in vivo. Radiology 200:843-50
Kohn, L A; Cheverud, J M; Bhatia, G et al. (1995) Anthropometric optical surface imaging system repeatability, precision, and validation. Ann Plast Surg 34:362-71
Smith, K E; Commean, P K; Bhatia, G et al. (1995) Validation of spiral CT and optical surface scanning for lower limb stump volumetry. Prosthet Orthot Int 19:97-107