The present disclosure provides tissue products produced from adipose tissues, as well as methods for producing such tissue products. The tissue products can include acellular tissue matrices for treatment of a breast.

A tissue construct is provided that comprises a pancreas derived microvessel fragment and a pancreatic islet cell. The pancreas derived microvessel fragment and the pancreatic islet cell can be incorporated into a biocompatible medium. Tissue constructs can be comprised of other cells, such as stem cells, combined with the pancreas derived microvascular fragment. Methods for isolating microvessel fragments from a pancreas are also provided and include enzymatic digestion of pancreatic tissue and separation of microvessel fragments from endocrine and exocrine tissue. Methods for treating diabetes are further provided and include administration of the tissue constructs.

The present invention concerns a tissue-engineered medical device, as well as a method for the production said medical device, comprising the following steps: providing a polymer scaffold comprising a mesh comprising polyglycolic acid, and a coating comprising poly-4-hydroxybutyrate; application of a cell suspension containing preferably human cells to the polymer scaffold; placement of the seeded polymer scaffold in a bioreactor and mechanical stimulation by exposure to a pulsatile flux of incremental intensity, thereby forming an extracellular matrix; mounting of the graft on a conduit stabilizer and incubation in cell culture medium; decellularisation of the graft in a washing solution; nuclease treatment of the graft; and rinsing of graft. The invention further comprises and various steps of quality control of the tissue-engineered medical device.

Compositions and methods of transplanting cells by grafting strategies into solid organs (especially internal organs) are provided. These methods and compositions can be used to repair diseased organs or to establish models of disease states in experimental hosts. The method involves attachment onto the surface of a tissue or organ, a patch graft, a “bandaid-like” covering, containing epithelial cells with supporting early lineage stage mesenchymal cells. The cells are incorporated into soft gel-forming biomaterials prepared under serum-free, defined conditions comprised of nutrients, lipids, vitamins, and regulatory signals that collectively support stemness of the donor cells. The graft is covered with a biodegradable, biocompatible, bioresorbable backing used to affix the graft to the target site. The cells in the graft migrate into and throughout the tissue such that within a couple of weeks they are uniformly dispersed within the recipient (host) tissue. The mechanisms by which engraftment and integration of donor cells into the organ or tissue involve multiple membrane-associated and secreted forms of MMPs.

The invention is directed to methods for preparing artificial heart valves by preconditioning a matrix seeded with endothelial cells and smooth muscle cells differentiated from isolated progenitor cells. These cell seeded matrices are exposed to fluid conditions that mimic blood flow through the heart to produce tissue engineered heart valves that are analogous to native heart valves.

A method for treating an oral condition of a subject by grafting cultured tissue constructs to the oral tissue. The cultured tissue constructs comprise cultured cells and endogenously produced extracellular matrix components without the requirement of exogenous matrix components or network support or scaffold members. Some tissue constructs of the invention are comprised of multiple cell layers or more than one cell type. The tissue constructs of the invention have morphological features and functions similar to tissues their cells are derived and their strength makes them easily handleable. Preferred cultured tissue constructs of the invention comprise cells derived from human tissue.

The present disclosure provides devices and methods for treating a tissue site. The device and methods can be used to treat tissue that has been irradiated and can include a tissue matrix having the ability to support tissue regeneration and vascularization with cells from the tissue site.

In alternative embodiments, provided are compositions, e.g., pharmaceutical compositions, formulations, kits and other products of manufacture, comprising a hydrogel and active ingredients, including mixed thickness skin micrografts, or full or split-thickness skin grafts, contained or mixed in or within the hydrogel; and methods for making and using them. In alternative embodiments, compositions and methods as provided herein are used for the treatment or amelioration of wounds and surgical sites, and include compositions and methods for micrografting, or for micrografting a wound, or for micrografting a wound for rapid re-epithelialization, or for micrografting a wound for rapid re-epithelialization of large non-healing wounds.

Disclosed are methods, devices, and techniques useful for enhancing function of an organ or cellular graft through photoceutical manipulation. In one embodiment a hematopoietic graft is treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance homing and engraftment. In another embodiment the recipient long bones are treated with one or more wavelengths of low level laser irradiation at a sufficient energy to enhance chemoattraction and growth factor secretion on recipient stromal cells. Application of the invention includes areas of cellular transplants such as islet and hepatic cell grafts.

The invention provides a method of producing a synthetic retina, comprising: i) providing a three dimensional stem cell culture throughout the differentiation time course, ii) differentiating the three dimensional stem cell culture for a first time period in a first neural cell culture medium comprising: a) L-glutamine; b) B27 supplement; and c) an IGF-1 receptor agonist, iii) subsequently differentiating the three dimensional stem cell culture for a second time period in a second neural cell culture medium comprising: a) L-glutamine; b) B27 supplement; c) N2 supplement; and d) an IGF-1 receptor agonist, wherein said synthetic retina contains laminated retinal tissue comprising.