Tsai Tsung-Yuan, Dimitriou Dimitris, Liow Ming Han Lincoln, Rubash Harry E, Li Guoan, Kwon Young-Min
Department of Orthopaedic Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts.
Department of Orthopaedic Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts; Department of Orthopaedic Surgery, Singapore General Hospital, Singapore.
J Arthroplasty. 2016 May;31(5):1096-101. doi: 10.1016/j.arth.2015.11.027. Epub 2015 Nov 30.
Component malalignment in unicompartmental knee arthroplasty (UKA) has been associated with contact stress concentration and poor clinical outcomes. However, there is a paucity of data regarding UKA component alignment and in vivo articular contact in weight-bearing position. This study aims to (1) quantify three-dimensional UKA component alignment and (2) evaluate the association between the component alignment and in vivo articular contact in standing position.
Seventy-seven UKAs in 68 consecutive patients were imaged in standing position using a biplanar X-ray imaging acquisition system. The UKA models were imported into a virtual imaging environment and registered with component silhouette on X-ray image for determination of component position and contact location. Anatomic bony landmarks of the lower limb were digitized for quantification of the bone alignment.
The femoral component (FC) showed 1.6° ± 3.3° valgus, 6.5° ± 6.4° external rotation, and 2.4° ± 4.6° flexion. The tibial component (TC) showed 3.9° ± 4.5° varus, 4.4° ± 6.7° internal rotation, and 10.1° ± 4.6° tibial slope. The average contact point was located medially and posteriorly by 7.8 ± 7.6% and 0.7 ± 7.7% of TC dimensions to its center. Multiple regression analysis identified FC flexion as a significant variable affecting UKA anterior and/or posterior contact position (R = 0.549, P < .001).
This study demonstrated the highest variability of UKA component positioning in axial plane rotation for FC and TC. The association between FC flexion and anterior contact position suggests accurate implant positioning may be important in optimizing in vivo UKA contact behavior. Further studies are required to gain understanding of the influence of axial rotation variability on in vivo UKA contact kinematics during functional activities.
单髁膝关节置换术(UKA)中组件排列不齐与接触应力集中及临床效果不佳有关。然而,关于UKA组件排列及负重位体内关节接触的数据较少。本研究旨在:(1)量化UKA组件的三维排列;(2)评估组件排列与站立位体内关节接触之间的关联。
使用双平面X线成像采集系统对68例连续患者的77个UKA进行站立位成像。将UKA模型导入虚拟成像环境,并与X线图像上的组件轮廓配准,以确定组件位置和接触位置。对下肢的解剖骨性标志进行数字化处理,以量化骨骼排列。
股骨组件(FC)显示有1.6°±3.3°的外翻、6.5°±6.4°的外旋和2.4°±4.6°的屈曲。胫骨组件(TC)显示有3.9°±4.5°的内翻、4.4°±6.7°的内旋和10.1°±4.6°的胫骨坡度。平均接触点位于TC尺寸中心内侧和后方,分别占TC尺寸的7.8±7.6%和0.7±7.7%。多元回归分析确定FC屈曲是影响UKA前后接触位置的一个显著变量(R = 0.549,P <.001)。
本研究表明,FC和TC在轴向平面旋转中UKA组件定位的变异性最高。FC屈曲与前接触位置之间的关联表明,准确的植入物定位对于优化UKA体内接触行为可能很重要。需要进一步研究以了解轴向旋转变异性对功能活动期间UKA体内接触运动学的影响。
