The Foundation of Biomechanical Evaluation
Clinical Monograph 9
By R. C. Schafer, DC, PhD, FICC
The study of human biomechanics includes the mechanical principles involved, the physiologic considerations of muscle length-tension relations, and an understanding of the controlling neuromotor mechanisms and the sensory feedback apparatus, reflecting both locomotor activity and cerebral function. Applied biomechanics is the application of the practical principles of mechanics (the study of forces and their effects) to the body in movement and at rest.
The more biomechanics are understood, the better musculoskeletal disorders in sports and the workplace can be appreciated. The same can be said of physical work and recreational activities. The athlete is constantly attempting to improve performance by applying biomechanical principles to specific movements. The same is true for ergonomics in the workplace. From the viewpoint of the doctor, knowledge of the mechanisms involved in an injury is necessary to evaluate an injury accurately.
From a pure musculoskeletal standpoint, the human body is a mechanical device. All mechanical devices are subject to wear during use that reflects their history of destructive forces. Unique to living tissue is its ability to heal, adapt, and strengthen, which provides a dialogue between catabolic and anabolic forces. While machines convert thermal or chemical energy into mechanical energy, muscle tissue transforms nutrients directly into mechanical energy without a thermal intermediary. Body energy enables it to overcome resistance to motion, to produce a physical effect, and to accomplish work.
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