Introduction

Biomechanics is described as the use of mechanical principles in the study of movement for all living beings. It is a rapidly expanding sub-discipline of the kinesiology area with a lot to offer society. To put it another way, biomechanics is the branch of science that studies how and why bodies move the way they do. Biomechanics is a basic and applied science that combines the principles of physics with engineering ideas to describe the internal and external forces acting on the body, as well as the consequences these forces produce. Although biomechanics is primarily concerned with the mechanical principles governing bodily systems, physiological processes and biological tissues are frequently included when addressing motion. The mechanical function of muscles, connective tissues, cartilage, skin, nerves, joints, bones and even internal organs are all common subjects of biomechanics research.

The researcher studies kinesiology, which is the science of how nerves, muscles, and joints work together to perform physical tasks. He is also knowledgeable with the body’s response to varying degrees of exercise and stress, particularly the cardiovascular and respiratory systems, as well as associated medical and physiologic topics. A biomechanist is a specialist in human motion who utilises his knowledge to help individuals with injuries address medical and mobility problems and enhance their quality of life. Biomechanics is a rapidly expanding subject of research, despite its youth. To become a biomechanist, you must have the necessary training, education, and skill set.

Nature of work

• Working in team along with life science specialists, medical scientists, and biomechanical engineers
• using the principles of bio-behavioral sciences and engineering, considering its usefulness for the people with disabilities
• Evaluating the safety and efficiency of biomechanical product, conducting research on its effectiveness before carrying out the clinical trials, conducting precautionary maintenance of the equipment, etc.
• Maintaining technical specifications of the equipment
• writing technical documents describing research protocols, standard of use, maintenance procedures, and user policies for assisted research program
• Researching on new methodologies of biomechanical equipment development, developing new products and mechanisms, and executing experimental and non-experimental evaluations on the same
• Conducting training programs for educating clinical practitioners and other associated personnel
• Developing computerized programs for biomechanical modeling, running systems and processes for studying bio-behavioral processes
• Analyzing latest medical procedures and applying specific biomechanic research techniques for developing the products beneficial in the current age

Scope of Biomechanics

Biomechanics is becoming a more significant field of research for solving issues relating to human health and performance. Physical education instructors, physical therapists, doctors, personal trainers, and coaches frequently use biomechanics research. Biomechanists are highly trained scientists that may work in a variety of disciplines, including biology, exercise science, sports science, health sciences, ergonomics, human factors psychology, and biomedical engineering. The majority of biomechanical specialists are involved in conducting vital kinesiology research in laboratories. As a result, biomechanists can be found working in gait analysis research laboratories, inventing sports products, doing flexibility testing, building man-machine interfaces, or assessing athletes.

How to become a biochemist

A bachelor’s degree from a recognised institution or university is the minimal educational qualification to enter the sector. A master’s degree in kinesiology, medical engineering, or biomedical engineering is required for the perfect biomechanist. A doctoral degree generally qualifies a biomechanist for research and high level employment. Coursework focuses on subject matter such as anatomy, physiology, biomechanics, fluid and solid mechanics, computer programming, circuit design and biomaterials.

Job opportunities

• Research facilities run by universities or private companies
• Companies that manufacture athletic products
• Consultants for competitive athletes
• Medical facilities or in orthopedics
• Private businesses, such as car manufacturers, analyzing injury prevention.

Qualities needed

• Keen interest in learning new technologies 
• Ability to work autonomously is important.
• Effective communication, often of complex ideas, to clients, peers and management is essential.
• Critical thinking ability
• Judgment and decision making skills
• Computing and statistical skills
• Organizational skills.