Biomechanics

Anatomy and Physiology: Understanding the structure and functions of the human body is crucial to understanding biomechanics.

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

Kinetics: The study of the forces that cause motion.

Force: A push or pull acting on an object.

Torque: The turning force produced by a force acting on a lever.

Power: The rate at which work is done.

Work: Work is done when a force acts on an object to cause a displacement.

Muscle Mechanics: The study of the properties of skeletal muscles in order to understand how they produce force and movement.

Joint Mechanics: How bones move in response to the forces applied to them.

Biomechanical Analysis: Measuring and analyzing the motion and forces of the human body.

Functional Anatomy: How the structure and function of the body combine to produce movement.

Analysis of Human Movement: An interdisciplinary field that involves the study of the mechanics of human movement.

Sports Biomechanics: The application of biomechanics to sports performance, used to understand how athletes move and perform.

Exercise Physiology: The study of the physiological and metabolic changes that occur in the body during exercise.

Biomechanical Assessment: An evaluation of the movement patterns, strength, and flexibility of an individual.

Ergonomics: The study of the interaction between humans and their environment.

Biomechanics of Injury: The study of the mechanisms of injury in the human body.

Rehabilitation Biomechanics: The application of biomechanics to rehabilitation, used to understand the injury and recovery process.

Biomechanics of Aging: The study of how the human body changes with age and how it affects movement.

Biomechanics in Medicine: The application of biomechanics to medical conditions and diseases, used to understand the biomechanical aspects of medical care.

Sport Biomechanics: This type of biomechanics deals with the analysis of movement in sports. It aims to identify the most effective techniques that can improve an athlete's performance in a particular sport.

Clinical Biomechanics: Clinical biomechanics is the field of study that focuses on the relationship between mechanical elements and biological systems. It is used in the diagnosis and treatment of musculoskeletal disorders.

Occupational Biomechanics: This type of biomechanics analyses the work environment, including the task, equipment and movement of workers, to evaluate the risk of injury or stress.

Rehabilitation Biomechanics: This field is concerned with the restoration of normal physiological function after an injury, such as through the use of physical therapy and rehabilitation exercises.

Ergonomics: This type of biomechanics studies the interaction between humans and their work environment, equipment, and tools, aiming to maximize work productivity, safety, and comfort.

Biomechanics of Aging: This field of biomechanics mainly focuses on the changes that occur in the musculoskeletal system with age, and how these changes affect physical performance and activities of daily living.

Biomechanics of Running: This area of biomechanics analyses the various aspects of running movement and its effect on performance, injury risk, and prevention.

Biomechanics of Resistance Training: This type of biomechanics deals with the analysis of resistance training, aiming to develop optimal training programs by understanding the forces involved during exercise.

Biomechanics of the Spine: This field of biomechanics analyses the structure, function, and movement of the spine, with the goal of improving spinal health and preventing injuries.

Biomechanics of the Foot and Ankle: This area of biomechanics mainly focuses on the structure and function of the foot and ankle, and how these affect movement, balance, and gait.