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The wireless pacemaker as small as a grain of rice
A tiny, no-fuss device promises to keep faulty hearts beating on schedule. How does it work?
This pacemaker, which is currently being tested in Europe, uses ultrasound instead of electricity-carrying wires to keep your heart ticking on schedule.
This pacemaker, which is currently being tested in Europe, uses ultrasound instead of electricity-carrying wires to keep your heart ticking on schedule.
Cambridge Consultants
A

new wireless, ultrasound-powered pacemaker promises to make implantation easier for doctors, and life more comfortable for patients. The device, which was unveiled Monday, is currently undergoing a rigorous trial in Europe. If those tests are successful, this new pacemaker could hit the commercial market soon. Here's how it would work:

Remind me: What does a pacemaker do?
An artificial pacemaker is implanted in the chest of a cardiology patient "to help restore a normal heartbeat," says The Economist. Traditionally, the device consists of a battery and control system implanted "just under the wearer's skin," and electrodes attached directly to the heart. If a person's heartbeat becomes irregular, the system "deliver[s] an electrical charge from the artificial pacemaker's batteries that causes the cardiac muscle to contract, pacing the pumping." 

What's so special about this new version?
Usually a pacemaker's battery is connected to the electrodes through a complex system of leads fed through a person's veins. This new device, called a wireless cardiac simulation (WiCS) system, has no wires at all. Instead, it uses ultrasound to transmit signals and energy between the battery and electrodes, says Duncan Graham-Rowe at Technology Review. The implantable receiver is about the size of a "grain of rice," and converts ultrasound signals into heart-regulating electricity. 

And this is better?
Potentially. By eliminating wires, the device "simplifies the delivery and implantation of the system and means you can put the electrode in a place where it can better mimic the body’s natural electrical-to-muscle movement," says Andrew Diston, head of global medical technology practice at Cambridge Consultants, which developed WiCS along with EBR Systems. Plus, "all leads are prone to failure, especially when they are exposed to continual movement inside the body." This new device means less invasive surgeries and less chance of patient infection.

Sources: The Economist, The Engineer, Technology Review

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