Researchers at Stanford have combined 3D printing and pyrolysis to produce a robust and biocompatible high resolution micro-array patch (MAP) for transdermal drug delivery.
This invention describes reinforced grafts made from biocompatible materials that are designed for use in surgical procedures such as coronary bypass graft surgery, vascular surgery, and arteriovenous fistula.
The DeSimone Research Group at Stanford University developed a method for fabricating 3D pyrolytic carbon structures from polyacrylonitrile (PAN) generated by a scalable Vat Polymerization 3D-printing continuous liquid interface production (CLIP) process.
Researchers in the DeSimone Research Group have developed a high-resolution injection Continuous Liquid Interface Production (iCLIP) 3D printing process.
Background: Researchers at Stanford have discovered a method to create lattice microneedle structures using high resolution continuous liquid interface printing (CLIP) technology.
Researchers at Stanford have developed an additive manufacturing approach, called VIA, that enables rapid printing of solid 3D geometries with high viscosity composite resins and multimaterials.