Biomechanical modeling

Anatomy and Physiology: The study of the structure and function of the human body, which is essential to understanding biomechanics.

Kinematics: The study of motion without considering the forces that cause the motion.

Kinetics: The study of the forces that produce motion and how these forces affect the human body.

Muscle Mechanics: The study of the properties of muscles that generate force and produce motion.

Joint Mechanics: The study of how the different parts of the joint interact to produce movement.

Biomechanics of the Spine: The study of the mechanics of the spine and how it functions in everyday movement.

Gait Analysis: The study of how people walk and run, including the forces and mechanics involved in those activities.

Sports Biomechanics: The application of biomechanics to athletic performance, including the mechanics of specific sports skills and techniques.

Ergonomics: The study of how people interact with their work environment, including the design of tools, equipment, and workstations to maximize safety and efficiency.

Rehabilitation Biomechanics: The application of biomechanics to the design of rehabilitation programs for people with injuries or disabilities.

Prosthetics and Orthotics Biomechanics: The application of biomechanics to the design and implementation of prosthetics and orthotics to improve mobility, reduce pain, and prevent further injury.

Human Factors Engineering: The application of biomechanics, psychology, and other disciplines to design products or systems that are easy and safe to use.

Biomechanical Modeling and Simulation: The use of computer models and simulations to predict the behavior of biological systems, including the human body and its interactions with the environment.

Kinematic analysis: Focuses on the movement patterns of the body without considering the forces involved.

Kinetics analysis: Analyzes the forces that affect the movement of the body, including gravity, ground reaction forces, and muscle forces.

Muscle modeling: Examines the role of individual muscles in generating movement and force in the body.

Joint biomechanics: Focuses on the movement and force transmission at the joints of the body, including joint kinematics, kinetics, and musculature.

Gait analysis: Studies the biomechanics of walking and running, including the kinematics and kinetics of the lower extremities.

Sports biomechanics: Analyzes the biomechanics of sports movements, such as throwing, jumping, and hitting.

Ergonomics: Studies the interaction of humans with their work environment, including the design of equipment and workstations to minimize physical stress and injury.

Injury biomechanics: Examines the causes and mechanisms of injury, including the forces involved and the resulting damage to tissues.

Biomechanical simulations: Uses computer models to simulate the biomechanics of the body or specific movements, allowing for prediction of performance and injury risk.

Rehabilitation biomechanics: Focuses on the biomechanical aspects of rehabilitation, including the development of exercises and interventions to improve movement and reduce pain.

Assistive device biomechanics: Studies the design and function of devices such as prosthetics and orthotics, which aid individuals with movement impairments.

Animal biomechanics: Studies the biomechanics of animal movement and behavior, including locomotion, feeding, and defense.

Plant biomechanics: Studies the biomechanics of plant growth and movement, including how plants respond to environmental stimuli such as wind and gravity.

Biomechanical engineering: Combines principles from biomechanics and engineering to design and develop new technologies and devices for use in healthcare, sports, and other fields.