Basics of Biomedical Engineering
Basics of Biomedical Engineering
Published 6/2024
Duration: 1h9m | .MP4 1280x720, 30 fps(r) | AAC, 44100 Hz, 2ch | 403 MB
Genre: eLearning | Language: English
Exploring the Interface of Biology and Engineering through Biomedical Innovations.
What you'll learn
Understand the fundamental principles and scope of biomedical engineering, including its key disciplines and historical development.
Gain knowledge of human anatomy and physiology, focusing on the structure and function of major body systems and organs.
Learn about various biomaterials, their properties, and their applications in medical devices and prosthetics.
Acquire skills in biomedical imaging techniques, including the principles, applications, and emerging technologies in this field.
Requirements
This course is designed as an introductory exploration, perfect for beginners eager to delve into the exciting world of biomedical engineering. No prior knowledge of biomedical engineering is required, making it accessible to all curious minds. A foundational understanding of high school-level biology, chemistry, and physics can enhance your learning experience. What we value most is your enthusiasm and passion for discovering how healthcare and technology intersect to revolutionize medical science. Whether you're a budding engineer, a future medical professional, or simply fascinated by innovative healthcare solutions, this course will provide you with the essential knowledge and inspiration to embark on this transformative journey.
Description
In the course "Basics of Biomedical Engineering," you will embark on a journey at the intersection of biology and engineering. This introductory course is designed to familiarize you with the fundamental principles and applications shaping modern healthcare technology.
You will start by exploring the diverse disciplines within biomedical engineering, from biomaterials and imaging technologies to biomechanics and bioinstrumentation. Discover how these fields contribute to developing medical devices, prosthetics, and innovative treatment solutions.
Gain a deeper understanding of human anatomy and physiology, focusing on how engineering principles are applied to study and enhance bodily functions and health outcomes. Dive into the world of biomaterials, learning about metals, polymers, ceramics, and composites used in implants and medical devices, and explore their properties and biocompatibility.
Delve into biomedical imaging techniques such as X-ray, MRI, CT scans, and ultrasound, understanding their principles, diagnostic applications, and emerging technologies. Learn how signal processing techniques analyze biological data from devices like electrocardiograms (ECGs) and electromyograms (EMGs), aiding in clinical diagnostics and research.
Throughout the course, you will discover the ethical considerations, regulatory standards, and intellectual property issues essential to biomedical engineering practice. By the end, you will have a foundational knowledge base, empowering you to appreciate the impact of biomedical engineering on healthcare advancements and inspiring further exploration in this dynamic field.
Who this course is for:
This course is ideal for: Aspiring Biomedical Engineers: Individuals considering a career in biomedical engineering who want to gain a foundational understanding of the field. Medical and Healthcare Professionals: Doctors, nurses, and healthcare workers interested in the technological advancements driving modern medical practices. Engineering Students: Students from various engineering disciplines who wish to explore the applications of their skills in the biomedical domain. STEM Enthusiasts: High school and college students with a passion for science, technology, engineering, and mathematics, eager to learn about innovative healthcare solutions. Curious Learners: Anyone with an interest in how technology and engineering are used to solve medical challenges and improve patient care. Whether you are aiming for a professional career, seeking interdisciplinary knowledge, or simply driven by curiosity, this course will provide valuable insights and a solid introduction to the fascinating world of biomedical engineering.
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What you'll learn
Understand the fundamental principles and scope of biomedical engineering, including its key disciplines and historical development.
Gain knowledge of human anatomy and physiology, focusing on the structure and function of major body systems and organs.
Learn about various biomaterials, their properties, and their applications in medical devices and prosthetics.
Acquire skills in biomedical imaging techniques, including the principles, applications, and emerging technologies in this field.
Requirements
This course is designed as an introductory exploration, perfect for beginners eager to delve into the exciting world of biomedical engineering. No prior knowledge of biomedical engineering is required, making it accessible to all curious minds. A foundational understanding of high school-level biology, chemistry, and physics can enhance your learning experience. What we value most is your enthusiasm and passion for discovering how healthcare and technology intersect to revolutionize medical science. Whether you're a budding engineer, a future medical professional, or simply fascinated by innovative healthcare solutions, this course will provide you with the essential knowledge and inspiration to embark on this transformative journey.
Description
In the course "Basics of Biomedical Engineering," you will embark on a journey at the intersection of biology and engineering. This introductory course is designed to familiarize you with the fundamental principles and applications shaping modern healthcare technology.
You will start by exploring the diverse disciplines within biomedical engineering, from biomaterials and imaging technologies to biomechanics and bioinstrumentation. Discover how these fields contribute to developing medical devices, prosthetics, and innovative treatment solutions.
Gain a deeper understanding of human anatomy and physiology, focusing on how engineering principles are applied to study and enhance bodily functions and health outcomes. Dive into the world of biomaterials, learning about metals, polymers, ceramics, and composites used in implants and medical devices, and explore their properties and biocompatibility.
Delve into biomedical imaging techniques such as X-ray, MRI, CT scans, and ultrasound, understanding their principles, diagnostic applications, and emerging technologies. Learn how signal processing techniques analyze biological data from devices like electrocardiograms (ECGs) and electromyograms (EMGs), aiding in clinical diagnostics and research.
Throughout the course, you will discover the ethical considerations, regulatory standards, and intellectual property issues essential to biomedical engineering practice. By the end, you will have a foundational knowledge base, empowering you to appreciate the impact of biomedical engineering on healthcare advancements and inspiring further exploration in this dynamic field.
Who this course is for:
This course is ideal for: Aspiring Biomedical Engineers: Individuals considering a career in biomedical engineering who want to gain a foundational understanding of the field. Medical and Healthcare Professionals: Doctors, nurses, and healthcare workers interested in the technological advancements driving modern medical practices. Engineering Students: Students from various engineering disciplines who wish to explore the applications of their skills in the biomedical domain. STEM Enthusiasts: High school and college students with a passion for science, technology, engineering, and mathematics, eager to learn about innovative healthcare solutions. Curious Learners: Anyone with an interest in how technology and engineering are used to solve medical challenges and improve patient care. Whether you are aiming for a professional career, seeking interdisciplinary knowledge, or simply driven by curiosity, this course will provide valuable insights and a solid introduction to the fascinating world of biomedical engineering.
More Info