LEXINGTON, Va. June 26, 2026 — Imagine living in an impoverished country and being a parent of a child in need of a prosthetic bone. The cost of one prosthesis would be prohibitive, but over the lifetime of a developing child, it would have to be replaced multiple times to keep up with the child’s growth. Xavier Zarza ’28, a biology major at Virginia Military Institute, envisions a substantially less expensive alternative in his Summer Undergraduate Research Program (SURP) project, “Electroplating 3D Prints for Antiseptic and Inert Properties in Prosthetics.”

3D printing is the process of creating three-dimensional objects from a digital file by building them layer by layer. Farming equipment, virtual reality simulators, non-essential car parts, and hobbyist models are all examples of ordinary items made from 3D printers. Zarza purchased a printer for his own daily use in high school. He has designed his own prints using computer-aided design (CAD) software, and has created many items including fitted containers, fishing gear, a remote control airplane, luggage ID tags, and planters.

The goal of Zarza’s SURP project is to provide low-cost prosthetics for use in developing countries that do not have access to high-tech facilities. His ideal production method should be simple enough to complete with readily available equipment, and capable to assist a growing child needing replacements. He explained his process for designing and printing external and internal prosthetics. “I spent a lot of time with CAD software grafting the shapes and getting the right measurements. I printed the prosthetics using two different substances: polylactic acid (PLA), a non-conductive plastic filament; and ABS–like photopolymer resin, which is a light-sensitive material that mimics the durability and flexibility of ABS plastic. Resin printing requires three separate machines, while filament printing only requires one machine. The primary difference between the two materials is their strength. Resin is much stronger and smoother than filament, although prolonged exposure to resin is toxic to the human body.”

In addition to the toxicity of resin, Zarza observed metal plating would provide increased strength, sterility, and flexibility, as well as preventing cracking or deformation under a heavy load. Additionally, copper and gold contain antiseptic qualities. He was unsure though how to apply the metal. He came up with the idea of electroplating while conducting an experiment in his general chemistry lab course taught by Maj. Christopher Shingledecker, assistant professor in the chemistry department. “The experiment was on redox chemistry, where we were consuming part of a metal by dissolving it into solution. That’s essentially electroplating in reverse. Zarza very perceptively asked me if it could be run the other way—building the metal up instead of stripping it off—and I told him absolutely, that’s electroplating,” explained Shingledecker.

In order for the electroplating to be successful, Zarza first coated his prosthetic with low electrical resistance graphene. This enabled the electroplated metal to better adhere.

For his capstone project during the next academic year, Zarza will attempt to simulate gold plated bones in the human body to ensure of their safe use. If successful, he has no aspirations of selling his findings for personal gain. “The goal is to lower the cost and make it much more applicable for anyone else,” he said.

Zarza is from Lewisberry, Pennsylvania, where he attended Red Land High School. He is the son of Noel and Cecilia Zarza. He plans to commission into the Army medical corps.

Marianne Hause
Communications & Marketing
VIRGINIA MILITARY INSTITUTE