A woman paralyzed from the waist down has regained the ability to walk, thanks to a robotic exoskeleton. Amanda Boxtel was told she would never walk again after suffering a serious ski accident, but a 3D-printed robotic exoskeleton has helped her walk again.
Robotic exoskeletons were once the stuff of movies, giving fictional superheroes superhuman powers. But fiction has now seemingly become reality. Amanda’s implant was made by scanning her body and inputting her attributes into a 3D-printer to create a personalized robotic exoskeleton.
This is an example of how technology can make the seemingly impossible possible. On the basis of medical science alone, doctors were right in telling Amanda Boxtel that she’d never walk again. Cutting-edge robotics have made possible what no existing medicines or surgeries can, and that’s encouraging.
3D-Printed Exoskeletons
This Robotic Exoskeleton is Changing Lives
Trend Themes
1. Medical Robotics - The use of robotic exoskeletons in medicine has the potential to revolutionize the way we treat patients with mobility impairments.
2. Personalized Healthcare - The ability to create customized 3D-printed exoskeletons opens up new possibilities for personalized healthcare solutions.
3. Advancements in 3D Printing - The development of 3D-printed exoskeletons showcases the continuous advancements being made in the field of 3D printing technology.
Industry Implications
1. Healthcare - The healthcare industry can integrate robotic exoskeletons to improve rehabilitation outcomes for patients with mobility challenges.
2. Orthopedics - The orthopedic industry can leverage 3D printing technology to create innovative and customized solutions for patients requiring assistive devices.
3. Manufacturing - The manufacturing industry can explore the potential of 3D printing in producing advanced exoskeletons for various applications, including healthcare and industrial sectors.