Fig. 1 Finite element analysis models of ( a ) intact foot, ( b ) loading conditions, ( c ) TTR foot and design of oversized TTPs; TTR, total talar replacement; TTP, total talar prosthesis More about this image found in Finite element analysis models of ( a ) intact foot, ( b ) loading conditio...

Fig. 2 Measuring talus inclination angle in ( a ) inversion and ( b ) eversion numerical experiments. ( c ) Measurement of anterior drawer distance. TTP, total talar prosthesis; Ti, tibia; Fi, fibula; Na, navicular; Ca, calcaneus; Pre, pre-analysis; Post, postanalysis. More about this image found in Measuring talus inclination angle in ( a ) inversion and ( b ) eversion num...

Fig. 3 Comparison of the talar tilt angle between experimental measurement and FEA prediction in ( a ) inversion and ( b ) eversion numerical experiments. Data in the experimental group are from Sato et al. [ 18 ]. More about this image found in Comparison of the talar tilt angle between experimental measurement and FEA...

Fig. 4 Comparison of the talar tilt angle between intact and TTP models in ( a ) inversion and ( b ) eversion numerical experiments. ( c ) Comparison of the anterior drawer distance between intact and TTP models in anterior drawer numerical experiment. More about this image found in Comparison of the talar tilt angle between intact and TTP models in ( a ) i...

Fig. 5 Comparison of the stress on the inferior articular surface of the tibia between intact and TTP models in inversion numerical experiment (varus force = 150N) More about this image found in Comparison of the stress on the inferior articular surface of the tibia bet...

Fig. 6 Comparison of the stress on the inferior articular surface of the fibula between intact and TTP models in inversion numerical experiment (varus force = 150N) More about this image found in Comparison of the stress on the inferior articular surface of the fibula be...

Fig. 7 Comparison of the stress on the tibial cartilage surface between intact and TTP models in eversion numerical experiment (valgus force = 150N) More about this image found in Comparison of the stress on the tibial cartilage surface between intact and...

Fig. 8 Comparison of the stress on the fibular cartilage surface between intact and TTP models in eversion numerical experiment (valgus force = 150N) More about this image found in Comparison of the stress on the fibular cartilage surface between intact an...

Fig. 9 Comparison of the stress on the inferior articular surface of the tibia between intact and TTP models in anterior drawer numerical experiment (anterior drawer force = 150N) More about this image found in Comparison of the stress on the inferior articular surface of the tibia bet...

Fig. 10 Comparison of oversized TTPs and TTP0 regarding percentage change in ( a ) talar tilt angle in the inversion numerical experiment, ( b ) talar tilt angle in the eversion numerical experiment, and ( c ) anterior drawer distance in the anterior drawer numerical experiment More about this image found in Comparison of oversized TTPs and TTP0 regarding percentage change in ( a ) ...

Fig. 1 Flow diagram of SSM construction and application More about this image found in Flow diagram of SSM construction and application

Fig. 2 Flow diagram of SSM construction More about this image found in Flow diagram of SSM construction

Fig. 3 Architecture of automatic measurement system More about this image found in Architecture of automatic measurement system

Fig. 4 First five modes of variation for lumbar spine SSM at ±3 standard deviations, with the impacts of human features on the prediction model: ( a ) single vertebral SSMs L1–L5 and ( b ) entire lumbar spine SSM More about this image found in First five modes of variation for lumbar spine SSM at ±3 standard deviation...

Fig. 5 Individual and cumulative variation explained by modes 1–10 of the lumbar spine SSM More about this image found in Individual and cumulative variation explained by modes 1–10 of the lumbar s...