Swiss researchers have invented tiny vascular turbines that, when placed inside a human artery, can produce energy to power pacemakers and other critical medical devices. The vascular turbine could be a solution to the problem of having to surgically replace i batteries that run implanted medical devices. Pacemakers require about 10 microwatts of power to function, and the in-line artery turbine can produce about 80,000 times that amount. So long as your blood flows, the artery-implanted turbines will keep your pacemaker, bood-pressure sensor, drug-delivery pump or neurostimulator powered.
Mechanical engineer Alois Pfenniger and his colleagues at the University of Bern and the Bern University of Applied Sciences in Switzerland, Pfenniger have tested the vascular turbines and are pleased with the initial results. Though the vascular turbine can generate enough power to recharge pacemakers, it works like an implantable hydroelectric generator and cause turbulence that increases the potential for blood clots. Blood clots could cause unwanted medical complications and remain an important problem that is yet to be overcome.
Artery-Implanted Generators
Tiny Vascular Turbine Uses Blood Flow to Produce Power for Pacemakers
Trend Themes
1. Artery-implanted Generators - Tiny vascular turbines implanted in arteries as a renewable power source for critical medical devices like pacemakers.
2. Implantable Hydroelectric Generators - Development of turbines that generate power from blood flow as an alternative to surgically replacing batteries in medical devices.
3. Blood Clot Prevention Technology - Innovations needed to address the potential for blood clots caused by implantable vascular turbines and ensure safe usage in medical devices.
Industry Implications
1. Medical Devices - Integration of artery-implanted turbines as a sustainable power source for pacemakers, drug-delivery pumps, neurostimulators, and other crucial medical devices.
2. Renewable Energy - Exploration of new applications for implantable hydroelectric generators to harness power from blood flow for various industries, including healthcare.
3. Biotechnology - Development of blood clot prevention technologies to enhance the safety and effectiveness of implantable vascular turbines in medical settings.