In vitro and in vivo biocompatibility assessment of free radical scavenging nanocomposite scaffolds for bone tissue regeneration.

Bone is the second most transplanted tissue in the world, resulting in increased demand for bone grafts leading to the fabrication of synthetic scaffold grafting alternatives. Fracture sites are under increased oxidative stress after injuries, affecting osteoblast function and hindering fracture healing and remodeling. To counter oxidative stress, free radical scavenging agents, such as cerium oxide nanoparticles, have gained traction in tissue engineering.

Multi-layer approaches to scaffold-based small diameter vessel engineering: A review.

Cardiovascular disease is one of the leading causes of death in the world. A characteristic symptom of cardiovascular disease is occlusion of vessels. Once vascular occlusion occurs there is a critical need to re-establish flow to prevent ischemia in the downstream tissues.

Fabrication of a bilayer scaffold for small diameter vascular applications.

One of the greatest challenges plaguing cardiovascular tissue engineering has been the development of a compliant vascular graft. In this work, we report the development of a synthetic vascular graft with compliance similar to native arteries at physiological pressures. A bilayer scaffold was fabricated from a solid polymeric lumen made from poly(1,8 octanediol-co-citrate) (POC) and a microfibrous medial layer composed of type I collagen, elastin, and POC.

Development of poly (1,8 octanediol-co-citrate) and poly (acrylic acid) nanofibrous scaffolds for wound healing applications.

Wound care is one of the leading health care problems in the United States costing billions of dollars yearly. Annually, millions of acute wounds occur due to surgical procedures or traumas such as burns and abrasions, and these wounds can become non-healing due to bacterial infection or underlying pathologies. Current wound care treatments include the use of bioinert constructs combined with topical administration of anti-bacterial agents and growth factors.

Biocompatible shaped particles from dried multilayer polymer capsules.

We demonstrated a simple and facile approach to fabricate biocompatible monodisperse hollow microparticles of controlled geometry. The hemispherical, spherical, and cubical microparticles are obtained by drying multilayer capsules of hydrogen-bonded poly(N-vinylpyrrolidone)/tannic acid (PVPON/TA)n. Drying spherical capsules results in hemispherical particles if 15 < n < 20.