The schematic representation of the various stages involved in the user-centered, iterative process of prosthesis design. (Image: SUTD)

Upper-limb forequarter amputations that involve the removal of the entire arm and scapula require highly customized prosthetic devices that are expensive but yet usually underutilized due to their high maintenance and low comfort levels. At the same time, while cosmetic prostheses — artificial limbs that provide patients the appearance of a pre-amputated body part — have a higher rate of continuous use, they have limitations in functional use.

Combining both technical and clinical expertise, the Singapore University of Technology and Design’s (SUTD) Medical Engineering and Design Laboratory collaborated with Tan Tock Seng Hospital’s (TTSH) Foot Care and Limb Design Centre, the largest provider of prosthetic services in Singapore, on a patient-specific upper limb prosthesis. This cosmetic prosthesis with a self-locking function was found to be more comfortable and around 20 percent cheaper compared to similar prostheses available.

To reduce the underutilization and delivery time while taking improved fit, function, and comfort into consideration, the research team turned to 3D printing due to its versatility and ability to cater to the device’s geometrical and functional complexity.

The team also adopted a user-centered design approach, involving the patient throughout the customized design and development process. They then meticulously captured and documented the design process so that it can serve as a blueprint for other device applications or be replicated for other patients with limb amputations, thus reducing the over reliance on a prosthetist’s judgment, skills, and experience for an optimal fit.

Based on regular consultations with the patient and prosthetist at TTSH, including the shadowing of the patient to better understand his daily activities and functional needs, it was concluded that the new prosthesis needed to be lightweight, capable of dissipating heat, locking at 90° of flexion, comfortable to wear, and void of metal components that would be detectable by airport scanners.

The research team used a digital scanner to capture residuum and contralateral arm geometries to replicate the patient’s arm with high precision. They then designed different parts of the prosthesis from the captured geometries, 3D printed and verified these for fit, comfort, and function. Their research paper was published in the Prosthetics and Orthotics International Journal.

The patient’s satisfaction for the 3D-printed prosthesis over his conventionally made prosthesis rated higher for its overall effectiveness, accurate size, symmetrical appearance and ease of use. Even though the new prosthesis weighed 100 g more than the current prosthesis, the patient preferred it due to its improved suspension contributing to the feel of a lighter arm during use. However, the prosthesis was perceived to be less durable due to the patient’s unfamiliarity with the quality of 3D printing, his concerns of the elbow locking mechanism breaking, and the appearance of the mesh structure compared to his current prosthesis.

“Digitalization and 3D printing have been transforming the design and manufacture of complex medical devices, surgery planning, medical education, and care delivery. Even though 3D printing technology has been around for more than three decades since the early 90s, it wasn’t until recently that people really began to appreciate and trust it for end-use fabrication. In this work, 3D printing freed us from the manufacturing constraints and enabled us to optimize the design to suit the patient’s needs. More importantly, this work sets the groundwork for future patient-specific end-use 3D printed parts for prosthetic needs,” said Principal Investigator, Subburaj Karupppasamy, an Assistant Professor in SUTD’s Engineering Product Development pillar.

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