Coffee Time Challenge
The Challenge:
Cutting the cord
Can medical implants be powered from an external source?
While implantable electronic devices such as pacemakers and drug delivery systems have come on in leaps and bounds in the past 50 years, there is still considerable room for improvement.
Implanted into the chest area, the pacemaker is a small metal box weighing between 20 and 50g which sends electrical pulses to the heart to keep it beating regularly. The device usually lasts about eight years depending on how advanced it is and has been deployed in millions of patients worldwide.
While effective, the technology is reliant on battery power alone, which means invasive surgery is required when the battery runs out. Other potential sources of power including inductive systems, but even these have their downsides. As well as exhibiting differences in efficiency based on location, position and movement, they are often limited in how long each charge lasts.
In the future, it is envisaged that miniaturised, intelligent systems will take over therapeutic and diagnostic functions, while future implantable sensors are expected to be able to measure things like glucose levels, blood pressure and even the oxygen saturation of tumour tissue.
Devices that can effectively administer drugs and even counteract side effects in the process could also be on the cards, but only if a long term, reliable power source can be found.
The Challenge
The challenge this month, then, is to come up with an improved power transfer system for medical devices inside the human body that is small, cost effective and has no harmful side effects.
The technology should be able to remotely supply power to implants, medication dosing systems and other medical applications without touching them. Ideally the device should have a large range and be traceable at any time with respect to its position and location.
The system should also be unobtrusive, able to transmit power through an array of different materials and not require any special gels or adhesives.
The patented solution takes advantage of recent breakthroughs in wireless technology and even has applications outside of the medical field. It is currently being used to stimulate the growth of cartilage and bone cells in a hip implant.
We will publish the solution in the next issue of Eureka. In the mean time, see if you can come up with something better.
Author
Laura Hopperton
This material is protected by Findlay Media copyright
See Terms and Conditions.
One-off usage is permitted but bulk copying is not.
For multiple copies contact the sales team.