Abstract: A device to aid in the production and regeneration of tissues and organs, standing alone, or on or inside of the human body, with a method of fabrication of tissues and organs and use of the device.

Abstract: A device to aid in the production and regeneration of tissues and organs, standing alone, or on or inside of the human body, with a method of fabrication of tissues and organs and use of the device.

Abstract: A device to aid in the production and regeneration of tissues and organs, standing alone, or on or inside of the human body, with a method of fabrication of tissues and organs and use of the device.

Abstract: A device to aid in the production and regeneration of tissues and organs, standing alone, or on or inside of the human body, with a method of fabrication of tissues and organs and use of the device.

Abstract: Success of in vitro vasculogenesis has been limited to structuring relatively small leaky capillary networks and short scaffold-supported vascular-like, tubes that have in some cases, stimulated limited vasculogenesis in vivo. These attempts lacked the structural design millions of years of evolution has established in creating vascular structures. Many mathematical models have taken an approach at computing the anastomosis and patterning found in the vascular branching systems present tissue structures. These attempts at modeling a vascular tree system fall far short in being able to reproduce the structural specificity need for specialized tissue structure such as lung and kidney tissues. I define this vascular tree network as a blood vascular system that includes the capillary bed system, which supplies blood to and from a tissue structure. By using what I term as reverse bioengineering, vascular trees can be created on scaffolds designed using image data obtained from select in vivo vascular networks.