Chen Wang M D, Geng Xiang, Wang Shaobai, Xin Ma M D, Xu Wang M D, Jiazhang Huang M D, Chao Zhang M D, Li Chen M S, Yang Junsheng, Wang Kan
Department of Orthopedics, Huashan Hospital, Fudan University, Shanghai, China.
Harvard Medical School, Boston, MA, USA; Key Laboratory of Exercise and Health Science, Ministry of Education, Shanghai University of Sport, Shanghai, China.
Gait Posture. 2016 Sep;49:54-60. doi: 10.1016/j.gaitpost.2016.06.009. Epub 2016 Jun 10.
The tarsal bones articulate with each other and demonstrate complicated kinematic characteristics. The in vivo motions of these tarsal joints during normal gait are still unclear. Seven healthy subjects were recruited and fourteen feet in total were tested in the current study. Three dimensional models of the tarsal bones were first created using CT scanning. Corresponding local 3D coordinate systems of each tarsal bone was subsequently established for 6DOF motion decompositions. The fluoroscopy system captured the lateral fluoroscopic images of the targeted tarsal region whilst the subject was walking. Seven key pose images during the stance phase were selected and 3D to 2D bone model registrations were performed on each image to determine joint positions. The 6DOF motions of each tarsal joint during gait were then obtained by connecting these positions together. The TNJ (talo-navicular joint) exhibited the largest ROMs (range of motion) on all rotational directions with 7.39±2.75°of dorsi/plantarflexion, 21.12±4.68°of inversion/eversion, and 16.11±4.44°of internal/external rotation. From heel strike to midstance, the TNJ, STJ (subtalar joint), and CCJ (calcaneao-cuboid joint) were associated with 5.97°, 5.04°, and 3.93°of dorsiflexion; 15.46°, 8.21°, and 5.82°of eversion; and 9.75°, 7.6°, and 4.99°of external rotation, respectively. Likewise, from midstance to heel off, the TNJ, STJ, and CCJ were associated with 6.39, 6.19°, and 4.47°of plantarflexion; 18.57°, 11.86°, and 6.32°of inversion and 13.95°, 9.66°, and 7.58°of internal rotation, respectively. In conclusion, among the tarsal joints, the TNJ exhibited the greatest rotational mobility. Synchronous and homodromous rotational motions were detected for TNJ, STJ, and CCJ during the stance phase.
跗骨相互连接,呈现出复杂的运动学特征。这些跗骨关节在正常步态中的体内运动仍不清楚。本研究招募了7名健康受试者,共测试了14只脚。首先使用CT扫描创建跗骨的三维模型。随后为每个跗骨建立相应的局部三维坐标系,用于六自由度运动分解。透视系统在受试者行走时捕捉目标跗骨区域的侧位透视图像。选择站立阶段的7张关键姿势图像,并在每张图像上进行三维到二维骨模型配准,以确定关节位置。然后通过将这些位置连接在一起,获得每个跗骨关节在步态中的六自由度运动。距舟关节(TNJ)在所有旋转方向上表现出最大的运动范围(ROM),背屈/跖屈为7.39±2.75°,内翻/外翻为21.12±4.68°,内旋/外旋为16.11±4.44°。从足跟触地到站立中期,距舟关节、距下关节(STJ)和跟骰关节(CCJ)的背屈分别为5.97°、5.04°和3.93°;外翻分别为15.46°、8.21°和5.82°;外旋分别为9.75°、7.6°和4.99°。同样,从站立中期到足跟离地,距舟关节、距下关节和跟骰关节的跖屈分别为6.39°、6.19°和4.47°;内翻分别为18.57°、11.86°和6.32°;内旋分别为13.95°、9.66°和7.58°。总之,在跗骨关节中,距舟关节表现出最大的旋转灵活性。在站立阶段,距舟关节、距下关节和跟骰关节检测到同步和同向的旋转运动。
