Our aim with this proposal is to better understand how in-shoe foot orthoses achieve improvements in foot and ankle function for people with ankle osteoarthritis (OA) and/or adult acquired flatfoot resulting from posterior tibial tendon dysfunction (PTTD). We also aim to be able to predict what the optimal, personalized orthotic device is for each patient is. These are common, painful, and often highly debilitating conditions, with ankle OA estimated to affect around 6% of the adult population and adult acquired flat foot around 3.3% percent of females. It has been shown that foot orthoses can be an effective conservative intervention for these conditions, and can help to postpone or negate surgery. However, for a significant proportion of patients foot orthoses are unsuccessful, and there is evidence that this may be a result of significant inter-individual variability in joint movement and loading response to the intervention. This may be due to a number of factors, including foot bone shape, muscle strength, and/or joint range of motion. In addition, the design of foot orthoses is often inconsistent between suppliers, largely because of the manual approach that is used to design and manufacture them. A further complicating factor is that prescriptions for foot orthoses are often vaguely written. Improving our understanding of different foot and ankle responses to variation in foot orthotic design is essential if we are to improve how these devices function at the level of the individual patient. To measure how the individual bones of the foot move using traditional techniques is, however, very difficult. Such methods rely on skin-mounted markers that are tracked in space to determine foot and ankle kinematics. However the size and position of the foot and ankle bones means that it is not possible to measure them all of them individually. Moreover, the movement between the skin and the underlying bones, known as soft tissue artifact, introduces significant errors into the measurements. This is further complicated by the need to wear shoes for orthoses to function properly. Our group has developed a biplane fluoroscopy system that is tailored to address the unique issues of measuring foot kinematics. This system has the additional advantage of being able to measure the effects of foot orthotics in unmodified shoes. To achieve our objective of understanding and being able to predict the effects of orthoses, our specific aims are: [1]: To collect, via biplane fluoroscopy, kinematic dat describing the effect of varying the angle of hindfoot posting in foot orthotics. These data will b obtained from 90 participants: 30 with ankle OA; 30 with symptomatic PTTD; and 30 healthy controls. [2]: Using the data from SA1, carry out a regression analysis to identify factors obtained from biplane fluoroscopy and clinical exam that significantly influence an individual's response (i.e., hindfoot kinematics) to the orthotic intervention. These factors include: foot type bone geometry, static foot posture, joint axis location, range of motion, and muscle strength. [3]: Using the data from SA1, generate a musculoskeletal model of the foot that allows detailed analysis of the muscles and ligaments controlling ankle movement. This will be developed in the OpenSim modeling platform and made freely available upon project completion. [4]: To compare the kinematic responses to orthotic devices prescribed using standard methods and those prescribed using algorithms and insight from SA2 and SA3 in a separate group of participants. Biplane fluoroscopy will be used to collect kinematic data from 10 patients with ankle OA and 10 with PTTD to compare the performance of the three pairs (one traditional, one from SA2 and one from SA3) of orthotics. This data will also be used to validate the predictions resulting from SA2 and SA3. This proposed research project will improve our understanding of how foot orthotics work and will help us to prescribe more effective devices to patients. This will benefit the large number of people in the population with ankle osteoarthritis and adult acquired flat foot.
This study will investigate the effect of foot orthoses on two common conditions (ankle osteoarthritis and symptomatic adult onset flat feet) by using a custom biplane X-ray system our group has developed to very accurately and precisely quantify foot bone motion. We will vary the design of the orthoses and subjects will be examined to find out which are most effective at improving function. It has recently been shown that veterans have a significantly higher prevalence of foot problems, including arthritis and flatfoot, than non-veterans. In 2010, there were 308 million Americans, of which 21.8 million were veterans, including 9 million who were 65 or older. Demographically, most foot problems are more prevalent in older populations. The prevalence of diabetes is also higher in older populations. Therefore, veterans, in particular older veterans, are likely to suffer from foot problems such as arthritis, flatfoot or diabetes related tissue changes, at a higher prevalence than the general population, and as such, they stand to benefit from the research that our group is proposing.
Iaquinto, Joseph M; Kindig, Matthew W; Haynor, David R et al. (2018) Model-based tracking of the bones of the foot: A biplane fluoroscopy validation study. Comput Biol Med 92:118-127 |