Li Chaodi, Schmid Steven, Mason James
Department of Aerospace and Mechanical Engineering, University of Notre Dame, Notre Dame, IN 46556, USA.
Med Eng Phys. 2003 Sep;25(7):559-64. doi: 10.1016/s1350-4533(03)00054-7.
Numerical studies were performed to investigate bone cement polymerization, temperature history and thermal osteonecrosis in cemented hip replacements with finite element methods. In this paper, the effects of pre-cooling and pre-heating of the prosthesis and/or the cement prior to implantation were simulated. It was found that the cement polymerization initiated near the bone-cement interface and progressed toward the prosthesis when both the cement and prosthesis were initially at room temperature. When the prosthesis and/or cement were pre-cooled, a reduction of the peak temperature at the bone-cement interface resulted, and this may reduce thermal osteonecrosis. However, this also slowed the polymerization process, and may result in a weaker bone cement. If the prosthesis was significantly initially heated, bone cement polymerization reversed reaction direction, started from the cement-prosthesis interface and proceeded toward the bone. Such polymerization direction may reduce or eliminate the formation of voids at the cement-prosthesis interface. Numerical results also showed that pre-heating seemed unlikely to produce significant thermal damage to the bone. The method of pre-heating the prosthesis prior to implantation may decrease the likelihood of cement-prosthesis loosening and increase the life of total hip arthroplasty.
采用有限元方法进行了数值研究,以探讨骨水泥聚合、温度历程以及骨水泥型髋关节置换术中的热致骨坏死情况。在本文中,模拟了植入前对假体和/或骨水泥进行预冷和预热的效果。研究发现,当骨水泥和假体最初均处于室温时,骨水泥聚合在骨-水泥界面附近开始,并向假体方向推进。当假体和/或骨水泥被预冷时,骨-水泥界面处的峰值温度降低,这可能会减少热致骨坏死。然而,这也会减缓聚合过程,并可能导致骨水泥强度降低。如果假体最初被显著加热,骨水泥聚合反应方向会反转,从骨水泥-假体界面开始并向骨推进。这种聚合方向可能会减少或消除骨水泥-假体界面处孔隙的形成。数值结果还表明,预热似乎不太可能对骨骼产生显著的热损伤。植入前对假体进行预热的方法可能会降低骨水泥-假体松动的可能性,并延长全髋关节置换术的使用寿命。