3-D Generated Anatomic Custom Talar Cement Spacers: A Technical Tip and Literature Review

Abstract

Category:Basic Sciences/Biologics; Hindfoot; TraumaIntroduction/Purpose:Three dimensional printing is an actively emerging field within the realm of medical devices. This technology expands therapeutic options and customization of implants to individual patients. The ability to create products that replicate normal bony anatomy has been a significant advancement in the setting of difficult clinical scenarios. 3-D generated, custom implants increase the potential for joint and limb salvage with the goal of improving functional outcomes. We present a technical tip for utilizing 3-D printing technology to create custom, anatomically-matched antibiotic cement spacers for limb- salvage applications. We present two illustrative cases and share our experiences, lessons learned, and a succinct review of the pertinent literature merging 3-D printing and the use of antibiotic cement as temporary and permanent reconstructive solutions.Methods:While the majority of 3-D printing is done for the purpose of generating devices for implantation, we present a technical tip for designing a 3-D printed mold from which to create an antibiotic cement spacer for implantation. Two case illustrations demonstrate comorbid patients presenting with infected implants, osteomyelitis, bone loss, deformity and wound dehiscense. We describe the process of patient selection, implant design, fabrication, and implantation of a custom molded antibiotic cement talus for the purpose of limb salvage.Results:Case illustrations present two successful limb salvage patients while giving a thorough explanation of our technique, learned tips and tricks. This applied technology builds on prior use of antibiotic cement in limb salvage of the lower extremity, most of which is joint sacrificing. 3-D printing the mold for an anatomic talus cement spacer results in a joint sparing limb salvage solution.Conclusion:Utilization of currently available 3-D printing technology as applied to production of anatomic cement spacers should be considered to enhance limb salvage. This innovative application of printing technology is merged with current, pertinent literature regarding antibiotic cement to offer surgeons expanded options for temporary or definitive reconstructive techniques in some of the most challenging patients.