Introduction. The arch of the foot has been described as a truss where the plantar fascia (PF) acts as the tensile element. Its role in maintaining the arch has likely been underestimated because it only rarely torn in patients with progressive collapsing foot deformity (PCFD). We hypothesized that elongation of the plantar fascia would be a necessary and sufficient precursor of arch collapse. Method. We used a validated finite element model of the foot reconstructed from CT scan of a female cadaver. Isolated and combined simulated ligament transection models were created for each combination of the ligaments. A collapsed foot model was created by simulated transection of all the arch supporting ligaments and unloading of the posterior tibial tendon. Foot alignment angles, changes in force and displacement within each of the ligaments were compared between the intact, isolated ligament transection, and complete collapse conditions. Result. Isolated release of the PF did not cause deformity, but lead to increased force in the long (142%) and short plantar (156%), deltoid (45%), and spring ligaments (60%). The PF was the structure most able to prevent arch collapse and played a secondary role in preventing hindfoot valgus and forefoot abduction deformities. Arch collapse was associated with substantial attenuation of the spring (strain= 41%) and interosseous talocalcaneal ligaments (strain= 27%), but only a small amount in the plantar fascia (strain= 10%). Conclusion. Isolated PF release did not cause arch collapse, but arch collapse could not occur without at least 10% elongation of the PF. Simulated transection of the PF led to substantial increase in the force in the other arch supporting ligaments, putting the foot at risk of arch collapse over time. Chronic degeneration of the PF leading to plantar fasciitis may be an early sign of impending PCFD

A medializing calcaneal osteotomy (MCO) is one of the key inframalleolar osteotomies to correct progressive collapsing foot deformity (PCFD). While many studies were able to determine the hind- and midfoot alignment after PCFD correction, the subtalar joint remained obscured by superposition on plain radiography. Therefore, we aimed to perform a 3D measurement assessment of the hind- and subtalar joint alignment pre- compared to post-operatively using weightbearing CT (WBCT) imaging. Fifteen patients with a mean age of 44,3 years (range 17-65yrs) were retrospectively analyzed in a pre-post study design. Inclusion criteria consisted of PCFD deformity correct by MCO and imaged by WBCT. Exclusion criteria were patients who had concomitant midfoot fusions or hindfoot coalitions. Image data were used to generate 3D models and compute the hindfoot - and talocalcaneal angle as well as distance maps. Pre-operative radiographic parameters of the hindfoot and subtalar joint alignment improved significantly relative to the post-operative position (HA, MA. Sa. , and MA. Co. ). The post-operative talus showed significant inversion, abduction, and dorsiflexion of the talus (2.79° ±1.72, 1.32° ±1.98, 2.11°±1.47) compared to the pre-operative position. The talus shifted significantly different from 0 in the posterior and superior direction (0.62mm ±0.52 and 0.35mm ±0.32). The distance between the talus and calcaneum at the sinus tarsi increased significantly (0.64mm ±0.44). This study found pre-dominantly changes in the sagittal, axial and coronal plane alignment of the subtalar joint, which corresponded to a decompression of the sinus tarsi. These findings demonstrate the amount of alternation in the subtalar joint alignment that can be expected after MCO. However, further studies are needed to determine at what stage a calcaneal lengthening osteotomy or corrective arthrodesis is indicated to obtain a higher degree of subtalar joint alignment correction

Background. A calcaneal medial osteotomy (CMO) is a surgical procedure frequently performed to correct a valgus alignment of the hindfoot. However currently little is known on its accurate influence on hindfoot alignment (HA). Aim. To assess the influence of a CMO on HA in both 2D and 3D measurements using weightbearing CT (WBCT). Methods. Twelve patients with a mean age of 49,4 years (range 18–67yrs) were prospectively included. Indications for surgical correction by a CMO with a solitary translation of the calcaneus consisted of an adult acquired flat foot stage II (N=10) and a talocalcaneal coalition (N=2). Fixation of the osteotomy was performed either using a step plate or double screw. A WBCT was obtained pre- and post-operative. HA was assessed by an angle between the anatomical tibia axis and the axis connecting the inferior calcaneus point and the middle of the talus in the coronal plane (HA. 2D. ) using Curvebeam® software. The tibia in the HA was separately assessed by the anatomical tibia axis (TA. X 2D. ). The same method was translated in 3D using 3-Matic® software with a Cartesian coordinate system originating in the inferior point of the calcaneus (HA. 3D. and TA. x 3D. ). Results. Both the mean pre-op HA. 2D. =12.8°± 4.5 and HA. 3D. =21.1°± 8.4 of valgus improved significantly post-operatively to a HA. 2D. =4.2°±4.5 and a HA. 3D. =11,9°± 6.1 (P < 0.001). Additionally, the mean pre-op TA. X 2D. = 4°± 2.6 and TA. X 3D. = 7,2 °± 3.2 showed a significant improvement to a TA. X 2D. = 3.1°± 2.7 and a TA. X 3D. = 6.1 °± 3.4 post-operatively (P < 0.05). The inter-rater reliability of the 2D measurement method with a mean ICC. HA2D. =0.74 and a mean ICC. TA2D. = 0.77 showed to be lower when compared to the 3D measurement method with a mean ICC. HA3D. =0.94 and a mean ICC. TA3D. =0.89. Conclusion. This study shows an effective correction of the valgus position from the calcaneus measured both in 2D and 3D when using a surgical CMO. The novelty is the marked influence on the tibia, which could now be accurately assessed using a weightbearing CT and additional 3D measurements. This resulted in 10% of the achieved HA correction, when analyzed both in 2D and 3D. This information could be of use when performing a pre-operative planning of a hindfoot deformity

Subtalar arthrodesis known as talocalcaneal fusion is an end-stage treatment for adult hind foot pathologies. The goal of the arthrodesis is to restrict the relative motion between bones of the subtalar joints, aiming to reduce pain and improve function for the patient. However, the change of the subtalar structures through the fusion is considered a disturbance to the joint biomechanics, which have been suggested to affect the biomechanics of the adjacent joints. However, no quantitative data are available to document this phenomenon. The purpose of the current study was to quantify the effects of subtalar arthrodesis on the laxity and stiffness of the talocrural joint in vitro using a robot-based joint testing system (RJTS) during anterioposterior (A/P) drawer test. Six fresh frozen ankle specimens were used in this study. The lateral tissues of the specimens were removed but the anterior and posterior talofibular ligaments and calcaneofibular ligament were kept intact. A/P drawer tests were performed on each of the specimens at neutral position, 5° and 10° of dorsiflexion, and 5?and 10?of plantarflexion using a robot-based joint testing system (RJTS), before and after subtalar arthrodesis. The RJTS enabled unconstrained A/P drawer testing at the prescribed ankle position while keeping the proximal/distal and lateral/medial forces, and varus/valgus and internal/external moments to be zero. This was achieved via a force-position hybrid control method with force and moment control, which has been shown to be more accurate than other existing force-position hybrid control methods. The target A/P force applied during the A/P drawer test was 100N in both anterior and posterior directions. The stiffness and laxity were calculated from the measured force and displacement data. The anterior and posterior stiffness of the talocrural joint were defined as the slope beyond 30% of the target A/P force, and the peak displacements quantified the laxity of the joint. Comparisons of laxity and stiffness between the intact and fusion ankle specimens were performed using Wilcoxon signed rank test (SPSS 19.0, IBM, USA) and a significance level of 0.05 was set. Subtalar arthrodesis did not lead to significant changes in the stiffness and laxity in both anterior and posterior directions (P>0.05). The mean anterior stiffness before arthrodesis was 9.54±1.17 N/mm and was 10.35±2.40 N/mm after arthrodesis. The mean anterior displacements before and after arthrodesis were 9.68±0.94 mm and 8.97±1.42 mm, respectively. Subtalar arthrodesis did not show significant effects on the A/P laxity and stiffness of the talocrural joint in both anterior and posterior directions. This may imply that the motion of the subtalar joints do not have significant effects on the A/P stability of the talocrural joint, which is the main joint of the ankle complex. This agrees with the anatomical roles of the subtalar joints which provide mainly the varus/valgus motions for the ankle complex. The current study provides a basis for further studies needed to evaluate the effects subtalar arthrodesis on the varus/valgus stability