Farrell Brad J, Prilutsky Boris I, Kistenberg Robert S, Dalton John F, Pitkin Mark
School of Applied Physiology, Center for Human Movement Science, Georgia Institute of Technology, Atlanta, GA, USA.
School of Applied Physiology, Center for Human Movement Science, Georgia Institute of Technology, Atlanta, GA, USA.
Clin Biomech (Bristol). 2014 Mar;29(3):336-49. doi: 10.1016/j.clinbiomech.2013.12.014. Epub 2013 Dec 23.
Despite the number of advantages of bone-anchored prostheses, their use in patients is limited due to the lack of complete skin-implant integration. The objective of the present study was to develop an animal model that would permit both detailed investigations of gait with a bone-anchored limb prosthesis and histological analysis of the skin-implant-bone interface after physiological loading of the implant during standing and walking.
Full-body mechanics of walking in two cats were recorded and analyzed before and after implantation of a percutaneous porous titanium pylon into the right tibia and attachment of a prosthesis. The rehabilitation procedures included initial limb casting, progressively increasing loading on the implant, and standing and locomotor training. Detailed histological analysis of bone and skin ingrowth into implant was performed at the end of the study.
The two animals adopted the bone-anchored prosthesis for standing and locomotion, although loads on the prosthetic limb during walking decreased by 22% and 62%, respectively, 4months after implantation. The animals shifted body weight to the contralateral side and increased propulsion forces by the contralateral hindlimb. Histological analysis of the limb implants demonstrated bone and skin ingrowth.
The developed animal model to study prosthetic gait and tissue integration with the implant demonstrated that porous titanium implants may permit bone and skin integration and prosthetic gait with a bone-anchored prosthesis. Future studies with this model will help optimize the implant and prosthesis properties.
尽管骨锚式假体有诸多优点,但由于皮肤与植入物缺乏完全整合,其在患者中的应用受到限制。本研究的目的是建立一种动物模型,以便在站立和行走过程中对植入物进行生理负荷后,既能详细研究骨锚式肢体假体的步态,又能对皮肤 - 植入物 - 骨界面进行组织学分析。
在两只猫的右胫骨植入经皮多孔钛柱并连接假体之前和之后,记录并分析其行走时的全身力学情况。康复程序包括最初的肢体石膏固定、逐渐增加植入物上的负荷以及站立和运动训练。在研究结束时,对植入物内的骨生长和皮肤向内生长进行详细的组织学分析。
两只动物都采用骨锚式假体进行站立和运动,尽管植入后4个月,行走时假肢肢体上的负荷分别下降了22%和62%。动物将体重转移到对侧,并增加对侧后肢的推进力。对肢体植入物的组织学分析显示有骨生长和皮肤向内生长。
所建立的用于研究假体步态和与植入物组织整合的动物模型表明,多孔钛植入物可能允许骨和皮肤整合以及使用骨锚式假体的假体步态。使用该模型的未来研究将有助于优化植入物和假体的性能。