Prediction of human gait parameters from temporal measures of foot-ground contact

Investigation of the influence of human physical activity on bone functional adaptation requires long-term histories of gait-related ground reaction force (GRF). Towards a simpler portable GRF measurement, we hypothesized that: 1) the reciprocal of foot-ground contact time (1/t(c)); or 2) the reciprocal of stride-period-normalized contact time (T/t(c)) predict peak vertical and horizontal GRF, loading rates, and horizontal speed juring gait. GRF data were collected from 24 subjects while they walked and ran at a variety of speeds. Linear regression and ANCOVA determined the dependence of gait parameters on 1/t(c) and T/t(c), and prediction SE. All parameters were significantly correlated to 1/t(c) and T/t(c). The closest pooled relationship existed between peak running vertical GRF and T/t(c) (r(2) = 0.896; SE = 3.6%) and improved with subject-specific regression (r(2) = 0.970; SE = 2.2%). We conclude that temporal measures can predict force parameters of gait and may represent an alternative to direct GRF measurements for determining daily histories of habitual lower limb loading quantities necessary to quantify a bone remodeling stimulus.