Biomechanics is deeply rooted in scientific history and has been influenced by the work and research of early networks engineers, mathematicians, physical scientists, biologists, and physicians. Neither of these disciplines can claim any rights on the maturation of the current state of biomechanics alone. In short, mechanics is a branch of physical science that studies the behavior of objects under force, while biomechanics uses the basic methods of mechanics, it studies the mechanical aspects, functions and movements of biological systems at any level, from whole organisms to organs, cells and cell organelles.

What is Biomechanics?

When we look at what biomechanics is, it is the science of movement of a living body, including how muscles, bones, tendons and ligaments work together to produce their movements. It is part of the larger field of kinesiology that focuses specifically on movement mechanics. It is also a fundamental and applied science that encompasses research and practical use of findings.
The field of biomechanics studies not only the movements by which they can produce muscle and bone structure, but also kidney function, blood circulation, and other body function. In fact, it covers not only the human body, but also the mechanical work inside animals, plants and cells. Biomechanics applications are very important applications today and provide a better life for people with mobility restrictions.

Biomechanics Application Areas

Biomechanics application areas are very diverse. Application areas include comparative biomechanics, allometry, animal locomotor and gait analysis, forensic biomechanics, musculoskeletal system, rehabilitation, soft tissue dynamics, sports biomechanics, orthotic prosthesis and implants, ergonomics and occupational biomechanics. application areas are available. A few words about the application areas; For example, the use of biomechanical analysis in the design of implanted artificial prostheses such as artificial hearts and small blood vessels can be exemplified in fields such as the engineering of living tissues such as heart valves and intervertebral discs. > For example, sports biomechanics deals with performance improvement and injury prevention for athletes. In occupational biomechanics, biomechanical analyzes are used to understand and optimize the mechanical effects of employees with the environment. Moreover, it improves the mobility of individuals with disabilities by optimizing the biomechanical-based design of assistive devices such as wheelchairs or environmental elements such as stairs.
 

What is Biomechanics?

When we look at what biomechanics is, it is the science of movement of a living body, including how muscles, bones, tendons and ligaments work together to produce their movements. It is part of the larger field of kinesiology that focuses specifically on movement mechanics. It is also a fundamental and applied science that encompasses research and practical use of findings.
The field of biomechanics studies not only the movements by which they can produce muscle and bone structure, but also kidney function, blood circulation, and other body function. In fact, it covers not only the human body, but also the mechanical work inside animals, plants and cells. Biomechanics applications are very important applications today and provide a better life for people with mobility restrictions.

Biomechanics Application Areas

Biomechanics application areas are very diverse. Application areas include comparative biomechanics, allometry, animal locomotor and gait analysis, forensic biomechanics, musculoskeletal system, rehabilitation, soft tissue dynamics, sports biomechanics, orthotic prosthesis and implants, ergonomics and occupational biomechanics. application areas are available. A few words about the application areas; For example, the use of biomechanical analysis in the design of implanted artificial prostheses such as artificial hearts and small blood vessels can be exemplified in fields such as the engineering of living tissues such as heart valves and intervertebral discs. > For example, sports biomechanics deals with performance improvement and injury prevention for athletes. In occupational biomechanics, biomechanical analyzes are used to understand and optimize the mechanical effects of employees with the environment. Moreover, the biomechanical-based design of assistive devices such as wheelchairs or optimization of environmental elements such as stairs improves the mobility of individuals with disabilities.