A total of 8 fresh-frozen human cadaver legs were subject to biomechanical testing, the specimens were thawed to room temperature (24ºC) . The mean age of the cadavers was 71.4 (7.4) years old. X-rays were obtained for each specimen and none of them had malalignment of the tibia, hindfoot, nor preexisting subtalar joint osteoarthritis. All specimens had a normal motion of both ankle and subtalar joints. The specimens were tested under two circumstances, the subtalar joint was intact and fused. We tested the change in ankle pressure with tibia varus and valgus at different angles.
The anterior soft tissue (including skin, subcutaneous tissue, anterior joint capsule, tendons and neurovascular bundles) of the ankle joint were dissected to access the ankle joint. Both the medial and lateral ankle ligaments were well preserved. The tibia and fibula were cut at 20cm above the ankle joint. For each specimen, the proximal tibia and fibula were potted securely into a custom-made shell, and then mounted on a custom-made fixture. The tibia and fibula were embedded and securely fixed into the shell using dental gypsum. The load was applied to the tibia and fibula via the custom-made shell. Each specimen must be potted in a neutral position, no plantarflexion or dorsiflexion of the ankle joint in the sagittal plane, and no varus or valgus malalignment of the hindfoot in the coronal and no internal or external rotation of the foot in a horizontal plane.
The custom-designed fixture was subjected to testing. Spirit levels were utilized to make sure both the working table and the top plate were horizontal throughout the testing process.
The malalignment of tibia (0º,5º,10º,15º,20º of tibial varus and valgus) was simulated using a custom-made apparatus. Each hole on the apparatus represented a specific angle. A bolt was used to fix the specimen at a desired angle.
The four threaded polyethylene pillars were used to connect the top plate, the compressive forces were exerted via the four pillars. Sensor cells were placed in each pillar, a monitor was connected to each sensor cell, displaying the real-time force. Springs were placed right above each force sensor, then followed by nuts, compressive forces could be generated by twisting the nut on the spring.
The sensor pads (Model 6900, TekScan, Inc., South Boston, MA), with each pad measuring 14*14mm, each pad had 121 senels (11*11 sensels), the column and row spacing were 1.3mm, resulting in a spatial resolution of 0.62 mm2 per sensel. Two pads were put side by side within the ankle joint to measure the ankle joint pressure. The sensor pads were inserted into the ankle joint from anterior and secured by thumbtacks to the distal tibial metaphysis and the foot to avoid sensor motion during testing. The sensor pads were connected to the handle that could be further connected to a personal computer, data including pressure, a force was collected using I-Scan software.
Situation A: when the subtalar joint was intact
The baseline ankle joint pressure distribution was initially collected for each specimen. The specimen was fixed at 0º of tibial varus by inserting a bolt, and the foot was then placed onto the floor freely. A compressive force was generated through the 4 pillars by twisting the nuts. Make sure that the top plate is maintained horizontally throughout the testing. A 600N compressive force was applied to simulate the normal load within the ankle joint during ambulation. Both the medial and lateral ankle joint pressure data were collected. Then, the tibial was fixed to 5º, 10º, 15º, 20º valgus and varus, and the corresponding pressure within the ankle joint was measure and recorded.
Situation B: When the subtalar joint was fused
The foot and ankle specimens are naturally placed in the loading device, and 10N force is applied to correctly fix the foot and ankle. Two metal screws are used to fix the subtalar joint from the anterior talus neck to the calcaneus. After fixation, CT scans were performed to confirm the screws position to ensure the subtalar joints were stable and fixed. Then, the tests were carried out the same as when the subtalar joint was intact, and the corresponding medial and lateral pressures of the ankle joint under different working conditions were recorded.
Statistical analysis
SPSS V.23 software (IBM Inc., New York) was used for the data analysis. Paired student t-test was employed to determine the significant differences for pressure differences. The level of significance was set to a p-value < 0.05.