Supercapacitors or ultracapacitors besides having high capacitance, also boast of extended cycle times and high power density. This cutting-edge energy storage device can be quickly recharged and proves dependable when short bursts of power supply are needed. 

Supercapacitor technology delivers excellent performance, handles wider temperature ranges, and extends significant battery support. For high-power, lightweight, and environment-friendly supercap solutions, visit sites like

Role of Supercapacitators in the Medical Field

The advent of these high-value double-layer electric capacitors ensures the uninterruptable operation of medical imaging devices. Their technology helps make cardiac pacemakers plus other implantable medical devices safer and highly durable. 

Using charged ions from bodily fluids, these supercapacitors operate pacemakers that help regulate heart rhythm abnormalities. Highlighted below are supercaps notable features which enable them to play a critical role in the medical domain:

Stores Energy

Traditional batteries installed in pacemakers need to be replaced once they run out of power. It involves a surgical procedure that puts the patient at risk of contracting an infection. 

The only alternative to battery power is to store energy in similar implants with the help of supercapacitors. Such technology effectively captures the energy and is also known to suit human bodies, resulting in no adverse reactions.

A supercapacitor can capture the electricity generated by an energy harvester. The latter generates electricity by converting bodily heat and motion. Combining energy harvesters with supercapacitors provides an endless power supply, thereby ensuring that such implantable devices never run out of stored energy.


Unlike batteries which contain toxic materials, supercapacitors are non-toxic to living cells. There is no scope of them endangering a patient’s life like batteries can do when they leak. 

Even when supercaps bend and twist inside a human body, they cause no mechanical or physical damage. While batteries depend on chemical reactions to store energy, supercapacitors utilize readily available charged molecules from human blood serum and urine.


Batteries occupy space when inserted into six to eight-millimetre thick modern pacemakers. High-powered supercapacitors are extremely thin, and their one-micrometre thickness is less than that of human hair. 

When inserted into an implantable medical device like a pacemaker, supercapacitors maintain the device’s performance for extended durations. 

Supercaps are proven to be highly energy-efficient. They capably store more charge than similar-sized energy lithium batteries commonly used in pacemakers.

In time to come, supercapacitors may prove viable for futuristic medical implantable devices designed to promote healing, speed up bone growth, or stimulate the brain.

Medical equipment like CT scans run on electricity; thus, making reliable back-up power critical for hospitals to function smoothly. A longer-lasting and maintenance-free technology like supercapacitors is designed to replace traditional lead batteries eventually.

The backbone of functional, practical, and manageable medical systems, as well as patient safety, is proving to be supercapacitor technology. In the medical line, preventive maintenance is essential as you cannot risk service interruptions nor hazardous exposures.

Rely on a world leader dedicated to powering next-generation products, even those with space constraints. Their supercaps guarantee back-up and peak power support for mission-critical applications.