TY - JOUR
T1 - The mechanism of plantar unloading in total contact casts
T2 - Implications for design and clinical use
AU - Shaw, Jonathan E.
AU - Hsi, Wei Li
AU - Ulbrecht, Jan S.
AU - Norkitis, Arleen
AU - Becker, Mary B.
AU - Cavanagh, Peter R.
N1 - Funding Information:
We would like to acknowledge the assistance of Esther Boone in the preparation of the manuscript, and Juan C. Garbalosa, Ph.D., for statistical advice. Dr. Shaw was supported as a visiting scholar at Penn State by an NHS Research and Development Initiative and by the Central Manchester Endowments Fund (U.K.). We would like to thank Novel Electronics, Inc., USA, who supported the color reproduction in this paper.
PY - 1997/12
Y1 - 1997/12
N2 - Although the total contact cast (TCC) has been shown to be an extremely effective treatment for the healing of plantar ulcers in diabetic patients, little is known about the biomechanics of its action. In this study, plantar pressure and ground reaction force measurements were obtained from over 750 foot contacts as five subjects with known elevated plantar forefoot pressures walked barefoot, in a padded cast shoe, and a TCC. Peak plantar pressures in the forefoot were markedly reduced in the cast compared with both barefoot and shoe walking (reductions of 75% and 86% respectively, P < 0.05). Peak plantar pressures in the heel were not, however, significantly different between the shoe and the TCC, and the longer duration of heel loading resulted in an impulse that was more than twice as great in the cast compared with the shoe (P < 0.05). An analysis of load distribution indicated that the mechanisms by which the TCC achieves forefoot unloading are (1) transfer of approximately 30% of the load from the leg directly to the cast wall, (2) greater proportionate load sharing by the heel, and (3) removal of a load- bearing surface from the metatarsal heeds because of the 'cavity' created by the soft foam covering the forefoot. These results point out some of the 'essential design features' of the TCC (which are different from what had been previously supposed), support the use of the TCC for healing plantar ulcers in the forefoot, but raise questions about its utility in the healing of plantar ulcers on the heel.
AB - Although the total contact cast (TCC) has been shown to be an extremely effective treatment for the healing of plantar ulcers in diabetic patients, little is known about the biomechanics of its action. In this study, plantar pressure and ground reaction force measurements were obtained from over 750 foot contacts as five subjects with known elevated plantar forefoot pressures walked barefoot, in a padded cast shoe, and a TCC. Peak plantar pressures in the forefoot were markedly reduced in the cast compared with both barefoot and shoe walking (reductions of 75% and 86% respectively, P < 0.05). Peak plantar pressures in the heel were not, however, significantly different between the shoe and the TCC, and the longer duration of heel loading resulted in an impulse that was more than twice as great in the cast compared with the shoe (P < 0.05). An analysis of load distribution indicated that the mechanisms by which the TCC achieves forefoot unloading are (1) transfer of approximately 30% of the load from the leg directly to the cast wall, (2) greater proportionate load sharing by the heel, and (3) removal of a load- bearing surface from the metatarsal heeds because of the 'cavity' created by the soft foam covering the forefoot. These results point out some of the 'essential design features' of the TCC (which are different from what had been previously supposed), support the use of the TCC for healing plantar ulcers in the forefoot, but raise questions about its utility in the healing of plantar ulcers on the heel.
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U2 - 10.1177/107110079701801210
DO - 10.1177/107110079701801210
M3 - Article
C2 - 9429884
AN - SCOPUS:0031457281
SN - 1071-1007
VL - 18
SP - 809
EP - 817
JO - Foot and Ankle International
JF - Foot and Ankle International
IS - 12
ER -