Biomechanics

Anatomy and physiology: Basic knowledge of the structure and function of the human body, including muscles, bones, joints, and tissues, is essential in biomechanics.

Biomechanical principles: Understanding the principles of movement, such as force, torque, velocity, acceleration, and momentum, is crucial in biomechanics.

Kinematics: Study of motion of the body without considering the forces causing the motion.

Kinetics: Study of motion with respect to the forces that cause it.

Muscle mechanics: Understanding how muscles work and how their movements and interactions affect the body’s movement as a whole.

Joint mechanics: Understanding how joints work, the range of motion they allow, and how they are affected by external forces.

Gait analysis: Analysis of human motion during walking, running, and other activities of daily living.

Biomechanics of sports and exercise: The study of how the body functions during different physical activities.

Ergonomics: The science of designing and arranging the workplace to fit the worker, ensuring optimal comfort, safety, and productivity.

Biomechanics of rehabilitation: Understanding how biomechanics principles can be used to develop rehabilitation programs for patients with musculoskeletal injuries.

Injury prevention: Strategies to reduce the risk of musculoskeletal injuries.

Rehabilitation techniques: Different techniques used to restore function and mobility after an injury.

Biomechanical assessment: Evaluating the mechanics of the body to determine the cause of injury or dysfunction.

Biomechanical modeling and simulation: Using computer modeling and simulation to study the biomechanics of the human body.

Biomechanics of prosthetics and orthotics: The design and fitting of prosthetics and orthotics to improve mobility and function of the body.

Sports Biomechanics: This field of biomechanics focuses on analyzing the movement patterns of athletes during various sporting activities to identify ways to optimize performance and reduce the risk of injury.

Occupational Biomechanics: This branch of biomechanics looks at how the human body adapts to different work environments to reduce the risk of developing injuries or disorders.

Clinical Biomechanics: This is used in rehabilitation of patients with injuries or disorders, where biomechanical analysis techniques are used to assess the patient's functional impairments and potential areas of improvement.

Pediatric Biomechanics: The study of biomechanics in children and adolescents, looking at how the musculoskeletal development changes over time and how injuries may affect growth and development.

Medical Biomechanics: This branch of biomechanics involves the analysis of medical devices and surgical techniques to improve their safety and effectiveness.

Ergonomics Biomechanics: This branch deals with designing equipment and workspaces with the goal of improving efficiency while also reducing the risk of musculoskeletal disorders.

Biomechanics Rehabilitation: It involves developing treatment plans and exercise protocols to improve the musculoskeletal and neuromuscular functions of patients who have suffered an injury or disability.

Sports Rehabilitation Biomechanics: This area of biomechanics focuses on developing rehabilitation programs for athletes who have suffered injuries to help them return to their former physical abilities.

Prosthetic Biomechanics: This involves the design and optimization of prosthetic devices to enhance their functionality and the patients' quality of life by alleviating musculoskeletal disorders.