Biomechanics

The study of the mechanical properties of living organisms and how forces affect movement.

Anatomy and Physiology: Understanding the structure and function of human body parts, their movements and how they interact with each other is crucial for biomechanics.

Kinematics: Kinematics deals with the study of motion and its characteristics, such as displacement, velocity, acceleration and angular motion.

Dynamics: Dynamics is the study of forces and their effects on motion, including Newton's laws of motion, friction and collisions.

Biomechanics of Muscles: Understanding the basics of muscle mechanics and how they create movement in the body is essential for biomechanics.

Biomechanics of Joints: Understanding the different types of joints in the body, their biomechanics and ranges of motion is important for analyzing human movement.

Biomechanics of the Spine: The spine is a complex biomechanical structure that controls postural balance and movement. Understanding its structure and function is important for understanding overall body mechanics.

Biomechanics of the Upper and Lower Extremities: Understanding the mechanics of the arms and legs, including movement patterns, range of motion and joint mechanics, is essential for analyzing human movement.

Gait Analysis: Gait analysis involves the measurement and analysis of human walking, running, and other forms of locomotion. It is an important tool in both sports and clinical settings.

Sports Biomechanics: Biomechanics plays a critical role in optimizing athletic performance, preventing injuries and improving technique in sports.

Injury Mechanics: Understanding injury mechanics, including the mechanisms of injury and factors that contribute to injury risk, is important for prevention and rehabilitation.

Ergonomics: Ergonomics focuses on the design of equipment and workspaces to optimize human performance and reduce injury risk.

Biomechanical Modeling and Simulation: Biomechanical modeling and simulation is the use of computer models to assess and predict human movement and function.

Biomechanical Testing and Instrumentation: Biomechanical testing and instrumentation involves the use of specialized equipment to measure and analyze human movement and function.

Biomechanics of Aging and Disease: Understanding the biomechanics of aging and disease is important for developing effective rehabilitation and treatment strategies.

Biomechanics in Rehabilitation: Biomechanics plays an important role in optimizing rehabilitation outcomes, including the prevention of re-injury and the restoration of function.

Clinical Biomechanics: Clinical Biomechanics deals with the assessment, diagnosis, and treatment of biomechanical problems that cause disorders or injuries in individuals. It incorporates biomechanics into clinical practice for the prevention and rehabilitation of musculoskeletal problems.

Rehabilitation biomechanics: Almost similar to clinical biomechanics, it mainly focuses on the application of biomechanical principles to the rehabilitation of people recovering from injuries, surgeries or those suffering from chronic pain or disabilities.

Neuromechanics: Neuromechanics involves the integration of neuromuscular and biomechanical processes. It studies the control of movement and the relationship between the nervous and musculoskeletal systems.

Sports Biomechanics: Sports biomechanics is a subfield of biomechanics that studies the movement patterns of athletes during sporting events. It examines how the human body functions during sporting activities, and how that knowledge can be used to improve athletic performance.

Ergonomics: Ergonomics analyzes how people interact with their work environments, including equipment, tools, and technology. It involves ensuring people can perform their jobs safely and effectively.

Computational biomechanics: Computational biomechanics involves using computer models to simulate the behavior of biological systems. It is an analytical technique used to understand the biomechanics of human or animal movement at the molecular, cellular, and system levels.

Occupational Biomechanics: Occupational biomechanics focuses on the study of physiological and biomechanical stresses imposed by work environments. It examines the effects of work on the human body, particularly on the musculoskeletal system.

Forensic Biomechanics: Forensic biomechanics is the use of biomechanics principles and techniques to investigate accidents and crimes, particularly in cases involving blunt force trauma or injury.

Biomechanics of Aging: Biomechanics of aging studies the changes in the musculoskeletal and neuromuscular systems as people age. It examines how aging affects movement, strength, coordination, and balance.

Biomechanics of Disease: Biomechanics of disease studies the mechanical changes that occur in the musculoskeletal system as a result of disease or injury. It includes studies of osteoarthritis, osteoporosis, and other chronic conditions that alter biomechanical function.

What is biomechanics?

"Biomechanics is the study of the structure, function and motion of the mechanical aspects of biological systems."

What does biomechanics study at different levels?

"...at any level from whole organisms to organs, cells and cell organelles."

What methods are used in biomechanics?

"...using the methods of mechanics."

What is biomechanics considered a branch of?

"Biomechanics is a branch of biophysics."

What aspects does computational mechanics go beyond?

"Computational mechanics goes far beyond pure mechanics..."

What other physical actions does computational mechanics involve?

"...and involves other physical actions: chemistry, heat and mass transfer, electric and magnetic stimuli..."

What is the focus of biomechanics?

"The study of the structure, function and motion of the mechanical aspects of biological systems."

What are the various levels at which biomechanics can be applied?

"...from whole organisms to organs, cells and cell organelles."

What is the purpose of using the methods of mechanics in biomechanics?

"...to study the structure, function and motion of biological systems."

How is biochemistry related to biomechanics?

"Biomechanics is a branch of biophysics."

What actions does computational mechanics involve beyond pure mechanics?

"...chemistry, heat and mass transfer, electric and magnetic stimuli and many others."

What does biomechanics encompass in terms of biological systems?

"Biomechanics encompasses the mechanical aspects of biological systems."

What disciplines does computational mechanics extend its scope to?

"Computational mechanics extends its scope to include other physical actions such as chemistry, heat and mass transfer."

What are the different levels at which biomechanics can analyze biological systems?

"Biomechanics can analyze biological systems at any level, from whole organisms to organs, cells, and cell organelles."

How can biomechanics be defined in relation to mechanical aspects of living organisms?

"Biomechanics is the study of the structure, function and motion of the mechanical aspects of biological systems."

What is the fundamental focus of computational mechanics?

"Computational mechanics goes far beyond pure mechanics..."

How does computational mechanics differ from traditional mechanics?

"Computational mechanics involves other physical actions such as chemistry, heat and mass transfer, electric and magnetic stimuli."

What is the primary area of study in biophysics?

"Biomechanics is a branch of biophysics."

What additional physical phenomena can be incorporated into computational mechanics?

"...electric and magnetic stimuli and many others."

What methods are employed to study the mechanical aspects of biological systems?

"...using the methods of mechanics."