Sep 29, 2016 | By Benedict

Image credit: Clemson University

With the help of orthotics experts, researchers at South Carolina’s Clemson University have developed a process for creating 3D printed orthotics for diabetes and arthritis patients. The orthotics will have customizable softness levels and use multiple materials.

With sportswear brands racing to create 3D printed footwear and revealing their methodologies along the way, many researchers and designers are now beginning to see the potential of 3D printing when it comes to improving comfort underfoot. But while Nike, New Balance, Under Armor etc. are creating their 3D printed midsoles to provide comfort and “bounce” for running and sports, some researchers are looking to develop similar technology for a rather different purpose: to ease the foot problems suffered by patients with diabetes, arthritis, and other conditions.

Many people who suffer from these conditions require specially made foot orthotics to enable them to walk without discomfort. Diabetics, for example, sometimes suffer from diabetic foot ulcers, which are prone to infection and can be difficult to walk on. The orthotics, however, can take weeks to make. Furthermore, it is often difficult to gauge what level of softness is required by the wearer. To counter these problems, researchers from Clemson university are developing a 3D printing solution which would enable the wearer to acquire a custom fit while also allowing them to select a custom level of softness.

Diabetic foot ulcers. Image: Diabetes Protocol Program

“We came up with the idea [that] we might be able to use 3D printing for biomedical devices and particularly for orthotics, where one problem was that the materials weren’t quite soft enough,” said John DesJardins, an associate professor in bioengineering at Clemson. “The materials they put in these shoes are more like foam, so we came up with a way to print these materials to make them softer.”

After conversing with diabetes clinicians, the Clemson researchers discovered that patients would certainly welcome a process which could provide a custom-fit, custom-softness orthotic. At present, orthotics for patients are made from six or seven materials, but their softness cannot be precisely adjusted. According to DesJardins, the new 3D printing method allows the researchers to vary the hardness of the material “in a thousand different blends.” The team can also alter the internal geometries of the 3D printed orthotics to make them harder or softer.

Brian Kaluf, clinical outcome and research director at Ability Prosthetics and Orthotics, has been working with the Clemson researchers on developing the 3D printed foot device. He believes that laser scanning could be used to measure the dimensions of a patient’s foot, allowing the researchers to make a perfectly sized orthotic for that patient. “The process could identify high-pressure areas with pressure-sensing technology and then inform the design of the 3D printed orthotic, so that specific area has changes in the way it’s printed to reduce pressure,” Kaluf explained. “The 3D printer allows a precise control over the design, where with foam we’re just kind of guessing.”

The Clemson researchers will own the intellectual property of the new technology, and have applied for a patent. In order to commercialize the technology, the researchers foresee a process in which doctors could order the custom orthotic electronically and have it shipped to them from a 3D printing bureau. “Our hope in the short term is to attract a major producer and have them license it,” DesJardins said. “We could have this on the market in three years.”

Goals of the Clemson research project:

Produce a 3D printed orthotic with varying hardness and geometry Test the orthotic to prove that it is comparable to orthotics created using the current standard industry methods Gauge the effectiveness of the orthotics pressure offloading

Posted in 3D Printing Application

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John DesJardins wrote at 11/2/2016 7:38:08 PM:Dear 3ders and article author "Benedict", I am the principle investigator for this work. Thank you so much for reposting the article that originally appeared in the Greenville Jouornal article at this link: http://greenvillejournal.com/2016/09/27/30584/ I was concerned that you have include photos in the article that are not associated with our work, and in fact refer to other investigators and products. We are working to differentiate ourselves from these products, so to have them embedded in our work is troubling. I would be happy to provide photos that we have from this work. Please contact me at: Jdesjar@clemson.edu Thank you! John DesJardins



