The sKan was created by a team of four electrical and biomedical engineering students from McMasters University and can detect a melanoma by sensing minute changes in temperature on the skin.
Michael Takla, Rotimi Fadiya, Shivad Bhavsar and Prateek Mathur were inspired to create the device after they saw the statistics around skin cancer.
"Melanoma has one of the highest survivability's of all cancers, 94%," explains Fadiya. "So it's absolutely crazy that so many people still die even though we know how to cure it."
While equipment exists that can test for skin cancer, the team found there were prohibitive costs involved that were preventing quick and early diagnoses from taking place.
"With these advanced technologies, the cost just keeps creeping up and up and up," explains Mathur. "We found one competitor that had a device that was over $250,000 which is just not obtainable for what we're trying to do."
Mathur and the rest of the team were able to bring the cost of their device down to just $1000, while still maintaining the same levels of accuracy and reliability that doctors would expect.
How does sKan work?
An easy way to detect if there is a melanoma is to cool the skin and then measure the rate at which it returns to room temperature.
If a melanoma is present, the skin will heat up much quicker. An easy way to record this is to create a thermal map of the surrounding skin that a doctor can easily see on a display.
Now there are devices out there that can already do this. However the vast majority of them suffer from one major problem. "The issue was that they all use high-end ultra-expensive cameras." explains Shivat.
That's where the sKan comes in.
Rather than using expensive thermal imaging, sKan uses a grid of small thermistors which turn electrical signals into thermal readings.
The thermistors themselves are a cheap off-the-shelf component, yet can still detect the minuscule temperature changes needed to make an accurate diagnosis.
The readings are then translated into a heat map which can be read by any GP using a piece of software that the students designed and wrote themselves.
Why is sKan such a breakthrough?
Availability. It's as simple as that.
Most of today's devices that can detect skin cancer cost anywhere from $10,000-$250,000, putting them completely out of reach for most GPs.
At $1,000, sKan can provide the same second-source diagnosis for GPs but at a fraction of the cost.
The team envisage their prototype being used by GPs as a quick, and reliable tool that can allow someone to walk in, voice their concerns and then be diagnosed quickly and efficiently.
"The doctors office for the most part looks the same as it did 10 years ago," explains Rotima. "It's a fine balance to find tools that physicians could use while still remaining affordable."
What's next for the sKan?
The team have won the 2017 International Dyson Award which means that not only do they get a cash prize of £30,000 (plus £5,000 for their university), but they also get the kudos and recognition that comes with it.
Using the publicity and reputation boost of the Dyson Award, the team are hoping to take sKan to pre-clinical trials.
To do that they'll need to create a slicker, more professional-looking prototype. The team are already hard at work miniaturising the device by using smaller, yet more accurate thermistors. They hope to have the next version ready within 6-8 months.
For the moment though, the team of students are just soaking it all in.
Previous Winners Of The James Dyson Award:
- 2016 - EcoHelmet
- 2015 - VolteraJames Dyson Awards
- 2014 - MOMJames Dyson Awards
- 2013 - Titan ArmJames Dyson Awards
- 2012 - SafetyNetJames Dyson Awards
- 2011 - AirdropJames Dyson Awards
- 2010 - Longreach Buoyancy Deployment SystemJames Dyson Awards
- 2009 - AutomotistJames Dyson Awards
- 2008 - ReactivJames Dyson Awards
- 2007 - SenjoSenjo