GGrantIndex
← Search

I-Corps: Minimally-invasive Patient-specific Intracardiac Implants

$50,000FY2024TIPNSF

Massachusetts Institute Of Technology, Cambridge MA

Investigators

Abstract

The broader impact/commercial potential of this I-Corps project is the development of a transcatheter manufacturing platform. Mass-produced, off-the-shelf medical implants often fail to match the geometric, mechanical, and biological characteristics of human anatomy. Traditional manufacturing techniques typically involve hard materials and are restricted to producing pre-defined devices in a limited range of sizes and shapes. However, human anatomy is composed of soft and delicate tissues displaying a virtually-limitless range of sizes and shapes with complex convexities, concavities, lobes, and trabeculations. This profound patient-device mismatch leads to poorly-fitting implants, sub-optimal treatment outcomes, local tissue damage, impaired healing responses, lengthy pre-procedural workflows, and elevated risk for peri- and post-procedural complications. Successful realization of this vision would represent a paradigm shift in medical manufacturing technology and open the door for better outcomes for patients, providers, and the overall healthcare system. This I-Corps project is based on the development of a manufacturing technology for point-of-care, minimally-invasive, patient-specific implant generation directly inside the human body. The envisioned toolkit leverages technical and conceptual advancements in materials science, additive manufacturing, catheter-based technologies, and implantable devices. The proposed solution will allow clinicians to deliver, assemble, and stabilize soft biomaterials at the target tissue site. Densely-compacted biopolymeric building blocks are fluidized and delivered via catheter into a distensible biopolymeric encapsulation layer. At the target tissue, the soft building blocks are additively-layered into user-defined 3D shapes that self-heal to match the size and shape of the host anatomy. Finally, the outer encapsulation mesh provides additional stability to support long-term structural integrity and rapid tissue healing and bio-integration. Together, this system could enable bottom-up fabrication of atraumatic, personalized 3D medical implants in deep anatomic locations without any need for invasive surgery or pre-procedural planning and device selection. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

View original record on NSF Award Search →