In India, 10-30% of hospital admissions are due to road traffic injuries and a majority of these people tend to develop varying levels of disabilities.
An accident victim may just have a fracture, but not handling the person properly while transferring them to a hospital can worsen the condition. A simple splint could prevent matters from getting worse.
BETiC innovator develops FractoAid to prevent disability after a severe accident. Mayur Sanas, an award winning innovator explains, “The tendency of a fracture to cause swelling during the first few days, prevents a full plaster cast from being applied to immobilise the limb. Hence, doctors use a splint which is essentially a half-cast to accommodate tissue volume changes due to swelling and subsiding, after which a full plaster cast is applied.”
Sanas goes on to explain that splints available in the market were either ineffective or expensive. “I developed an alternative design using paper as the base material, stacking it with plaster rolls, enclosing both in a fabric envelope, and attaching Velcro straps.” Adds Sanas.
The split is dipped in water, placed at the fractured area, gently pressed to give it the desired shape, and tied up with the straps. It dries within a few minutes, giving ample support to the fracture site. The material allows the skin to breathe. Initially called ‘hybrid plaster splint’, the product is now called as FractoAid after a few technical upgradations with respect to its fabric and packaging.
A native of a small village located in Satara district of Maharashtra, Sanas joined an engineering college in Kolhapur. After his master’s in mechanical engineering from IIITDM, Kanchipuram, he planned to pursue a PhD in Taiwan, but after seeing an advertisement stating a position vacant at BETiC, he was intrigued and joined BETiC.
In early 2018, Mayur won the Biotechnology Ignition Grant. He also won the award for social innovation at national conference of social innovations in November 2019
How Important Is This Innovation?
This innovation is important because majority victims of road traffic injuries are men in the peak working age group of 15-44 years and belong to the poorer sections of society.
Prof B Ravi, founder of BETiC- Biomedical Engineering and Technology Incubation Center, IIT-B, who has mentored Mayur explains, “The challenge was to select the right type and thickness of paper and other required materials, so that the desired strength could be achieved with the least possible weight. The product has developed 6 variants up to date, suitable for different age groups, that is, a small size splint for individuals between 6-10 years of age, a medium size splint for individuals between 11-21 years of age and a large size splint for individuals above 21 years of age.”
Other BETiC Innovators
“Low cost accessible medical devices are a priority for BETiC,” affirms Prof B Ravi.
BETiC innovators have also developed
1.Club foot Brace Monitor
One in five hundred children in India are affected by clubfoot deformities. These are birth deformities where the feet get rotated at the ankle. It can be corrected using leg braces, where the feet of the child are placed in a series of plaster casts and changed every week for 6 weeks. However, the results are varied as parents do not always follow the instructions properly.
BETiC developed a clubfoot brace monitor with touch sensors- that capture and help to monitor the time span for which the child wears the braces. For the first three months the child wears the braces round the clock, the duration is then reduced to 8 hours by the age 4. This data is tracked every 15 mins and is recorded in the device software. Doctors can then access the actual usage of the brace and suggest accurate treatment. In some cases, the child’s feet get completely cured.
2. Ratna Nidhi prosthetic leg
The Ratna Nidhi Leg, derived from the Jaipur Foot, has been created using a new process that enables rehabilitation engineers to deliver prosthetic legs to amputees and landmine victims mostly in rural and vulnerable populations within a shorter span of time.
The new process uses mobile 3D parametric modelling to accurately capture and transmit 3D models of the residual limb, to design comfortable and yet affordable trans-femoral sockets. The pilot phase is on right now.