Skeletal Muscle of Molecular Motor and Its Application in Active Rehabilitation of Human Lower Limbs

Abstract

Nanotechnology is an innovative science and technology that has the most opportunity to be applied in the market, and its intrinsic value is immeasurable. Some developed countries have invested a lot in research activities. The purpose of this paper is to explore the biomechanical principle of the skeletal muscle of the molecular motor and its application in the active rehabilitation of the lower limbs. In this paper, based on the force generation mechanism and biomechanical model of skeletal muscle, and guided by the mechanical principle equation of skeletal muscle contraction of the collective operation mechanism of a molecular motor, and combined with the experiment of active rehabilitation design of human lower limbs, it is demonstrated in the results that the angle error after yaw angle fitting can be controlled within −1° − 1°, which has a strong effect, and in the rehabilitation effect in fruit, the swing phase accounts for about 40% and the support phase accounts for about 60%. It can be concluded that the accuracy of rehabilitation data collection and the effectiveness of gait parameters detection in the process of human rehabilitation, as well as the actual recognition effect of lower limb movement pattern recognition, is good and efficient. Molecular materials play an important role in biology or medicine. With the development of technology, they contribute to the recovery of skeletal muscle.