Biomechanics and Rehabilitation Engineering

Restoring Movement, Enhancing Life

Are you fascinated by the mechanics of the human body and passionate about helping people regain lost function? This comprehensive online course, “Biomechanics and Rehabilitation Engineering,” provides a deep dive into the principles of biomechanics and their practical application in the field of rehabilitation. Across 15 engaging modules, you’ll explore the intricate workings of human movement, learn how to analyze musculoskeletal systems, and discover the cutting-edge technologies used to restore and enhance mobility.

What you’ll learn

  • human movement analysis, musculoskeletal mechanics,.
  • biomaterials, assistive devices, prosthetics, orthotics.
  • rehabilitation strategies.
  • practical applications and hands-on learning.

Course Content

  • Foundations of Biomechanics –> 3 lectures • 46min.
  • Musculoskeletal Biomechanics –> 4 lectures • 40min.
  • Biomaterials and Tissue Mechanics –> 2 lectures • 20min.
  • Rehabilitation Engineering Applications –> 5 lectures • 52min.
  • Advanced Topics and Projects –> 1 lecture • 11min.

Biomechanics and Rehabilitation Engineering

Requirements

Are you fascinated by the mechanics of the human body and passionate about helping people regain lost function? This comprehensive online course, “Biomechanics and Rehabilitation Engineering,” provides a deep dive into the principles of biomechanics and their practical application in the field of rehabilitation. Across 15 engaging modules, you’ll explore the intricate workings of human movement, learn how to analyze musculoskeletal systems, and discover the cutting-edge technologies used to restore and enhance mobility.

This course is designed for students and professionals in engineering, biomedical engineering, kinesiology, physical therapy, and related disciplines, as well as anyone with a keen interest in the science of movement and rehabilitation. No prior advanced knowledge is strictly required; we’ll build a solid foundation from the ground up.

What you will learn:

  • Foundational Biomechanics: Grasp the core concepts of statics, dynamics, kinematics, and kinetics as they apply to human movement.
  • Musculoskeletal Mechanics: Analyze forces and moments acting on joints and bones, understand muscle mechanics and modeling, and delve into the biomechanics of major joints like the knee, hip, and spine.
  • Biomaterials and Tissue Mechanics: Explore the properties of biomaterials used in rehabilitation and gain insight into the mechanical behavior of biological tissues like bone, cartilage, and muscle.
  • Rehabilitation Engineering Applications: Discover the design and principles behind a wide range of assistive devices, including walkers, crutches, wheelchairs, prosthetics, and orthotics.
  • Advanced Rehabilitation Technologies: Explore the exciting world of rehabilitation robotics and learn about the biomechanics of neurological rehabilitation for conditions like stroke and spinal cord injury.
  • Practical Skills: Develop your abilities through hands-on exercises, case studies, simulations, and a final project where you can apply your knowledge to real-world rehabilitation challenges.

Course Highlights:

  • Comprehensive Curriculum: 15 modules covering all essential aspects of biomechanics and rehabilitation engineering.
  • Engaging Learning Experience: Clear explanations, illustrative diagrams, real-world examples, and interactive exercises.
  • Practical Focus: Emphasis on applying biomechanical principles to the design and analysis of rehabilitation solutions.
  • Expert Instruction: Learn from experienced professionals in the field.
  • Flexible Online Learning: Study at your own pace and on your schedule.

Who should take this course?

  • Undergraduate and graduate students in engineering, biomedical engineering, kinesiology, physical therapy, and related fields.
  • Professionals working in rehabilitation, healthcare, or related industries.
  • Anyone with an interest in biomechanics, human movement, and assistive technologies.

By the end of this course, you will be able to:

  • Analyze human movement using biomechanical principles.
  • Understand the mechanics of musculoskeletal systems.
  • Design and evaluate assistive devices, prosthetics, and orthotics.
  • Apply biomechanical principles to rehabilitation strategies.
  • Contribute to the development of innovative solutions for restoring movement and enhancing quality of life.
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