Graphical abstract.
Graphical abstract.

Source: University of Glasgow

News • Additive manufacturing

'Smart' 3D-printed braces for scoliosis treatment

Researchers have developed a new type of lightweight 3D-printed back brace capable of sensing how effectively it fits patients. Its developers say it could lead to improved treatment for scoliosis.

Scoliosis, a common form of spine deformity, affects around three percent of the population, most often between the ages of 10 and 15. It can be corrected in younger people by a back brace, which is worn until the child stops growing. While back brace treatment is effective, it can be uncomfortable and can require a time-consuming trial-and-error process to find the best fit for each patient.

A team of engineers and medics from the UK and the United States have combined polypropylene, a lightweight recyclable plastic, with carbon nanotubes to create a cellular material capable of sensing the amount of strain (and stress) it experiences while in use.

The researchers say this material could be used to create a ‘smart’ brace capable of detecting the pressures it applies on the human body, allowing better fine-tuning of the brace and making the process of treatment more comfortable.

In a new paper published in the journal ACS Applied Materials and Interfaces, the University of Glasgow-led team describe how the carbon nanotubes, placed throughout a material known as polypropylene random copolymer, gave it the ability to form an electrically-conductive network across its structure.

They used 3D printing to create lattice-like structures made from the material and subjected them to static and cyclic loadings, while measuring how the change in electrical resistance of the smart composite under load. This measure of the material’s changing piezoresistance is what could help to create a smart brace in the future by allowing medics to see which areas of the body are exerting the maximum pressure on the brace.

Their tests showed that, even after 100 cycles of loading and unloading, the material retained its ability to sense the strain experienced by the material, suggesting it could be sufficiently smart to make it suitable for use in a brace.

Dr Shanmugam Kumar, of the University of Glasgow’s James Watt School of Engineering, is the corresponding author of the paper. “Scoliosis is a painful and debilitating disorder, and while the current generation of braces are better than they have ever been, there is still a lot of room for improvement. The self-sensing material that we’ve developed has a great deal of potential to deliver that next generation of improvement. What we hope to see is a future where scoliosis patients can be individually assessed by a doctor and have a 3D-printed brace produced for them which is unique to their condition," Dr Kumar said.

Then, after a few weeks of wearing it, they can return to their doctor and use the readout from the piezoresistive strain sensing brace to have it adjusted to make it even more effective, without the trial-and-error process that clinicians have to rely on at the moment. 

“That could help patients benefit from more accurate adjustments to the stiffness of the bracing in different directions, better data to inform the optimal timing and manner of brace adjustments. That would make them a potentially significant improvement over conventional rigid bracing made from passive materials via conventional manufacturing approaches. Cellular designs of smart composites make the braces lightweight besides offering tuneable mechanical and functional attributes,” Dr Kumar added.

Scientists from Texas A&M University, Massachusetts General Hospital and Massachusetts Institute of Technology in the United States of America also contributed to the research.

Source: University of Glasgow

08.02.2022

More on the subject:
Read all latest stories

Related articles

Photo

News • Opening the blood-brain barrier

3D-printed acoustic holograms against Alzheimer's or Parkinson's

A research team in Spain and the US has created 3D-printed acoustic holograms to improve the treatment of diseases like Alzheimer's and Parkinson's, among others.

Photo

News • Tumor organoid platform

Personalized 3D bioprinting to advance gastric cancer treatment

Using 3D bioprinting to accurately replicate the biological environment surrounding gastric cancer cells, researchers predicted a patient’s response to anticancer drugs during the preclinical stage.

Photo

News • Cardiovascular disease research

"Heart on a chip": 3D printing cardiac biorings

Researchers have developed a 3D-bioprinted, miniaturized chip to advance the understanding of cardiovascular disease and aid in the development of new precision treatments.

Related products

Subscribe to Newsletter