Force-velocity relationship models of nine skeletal muscles

## Abstract In previous work we developed and validated a mathematical model that predicted force output from skeletal muscles subjected to six‐pulse stimulation trains under isometric condition. The current study investigated the model's ability to predict force responses to longer stimulation tra

## Purpose: To test the feasibility of using real-time phase contrast (pc) magnetic resonance imaging (mri) to track velocities (1-20 cm/second) of skeletal muscle motion. ## Materials and methods: To do this we modified a fast real-time spiral pc pulse sequence to accommodate through-plane veloc

## Abstract We examined the influence of varying stimulation frequency on muscle output during isometric and dynamic contractions. Our findings demonstrate that the predictability of the force– and excursion–frequency relationships is extremely strong across stimulation intensities. There were no d

Maximal tetanic tension was elicited at 200, 150, and 150 Hz in control tibialis anterior muscles and at 150, 100, and 100 Hz in 14-day regenerating muscles of young (3 months), adult (18 months), and old (31 months) Fischer 344/Brown Norway F1 rats, respectively. In contrast to young rats, increasi