Provided herein is a delivery system, including: (a) an optical sensor configured to detect data to create a map of a patient bodily surface; and (b) a dispenser operatively associated with the optical sensor and configured to deliver compositions (optionally including cells) to the patient bodily surface based upon the data or map. Methods of forming a tissue on a patient bodily surface of a patient in need thereof are also provided, as are methods, systems and computer program products useful for processing patient bodily surface data.

A method, material, and kit for promoting neutrophils and monocytes to localize at a chronic ulcer site, promoting formation of a multi-layered cell structure in the ulcer site, promoting conversion of monocytes to macrophages, promoting secretion of the patient's own growth factors, promoting tissue proliferation and cell migration, promoting production and cross-linking of collagen at the chronic ulcer site, promoting growth of endothelial cells, promoting angiogenesis that was stalled at the chronic ulcer site, promoting formation of a vascular network and granulation, promoting oxygenation of the chronic ulcer site, and reducing one or more of purulent drainage, erythema, pain, warming, tenderness, induration, and bleeding at the chronic ulcer site.

A cutting device is provided having multiple evenly-spaced cutting blades and which is useful for producing tissue forms comprising membranous tissue fragments which are relatively uniformly sized and shaped. The present invention also relates to methods for using the cutter device to quickly and efficiently produce such tissue forms which are useful as grafts and can be flowable and easily passable through a luer-slip tip syringe or needle.

Tissue replacement implants are disclosed that include polarized retinal pigment epithelial cells on a polylactic-co-glycolic acid) (PLGA) scaffold, wherein the PLGA scaffold is 20-30 microns in thickness, has a DL-lactide/glycotide ratio of about 1:1, an average pore size of less than about 1 micron, and a fiber diameter of about 150 to about 650 nm. Also disclosed are methods of treating a subject with a retinal degenerative disease, retinal or retinal pigment epithelium dysfunction, retinal degradation, retinal damage, or loss of retinal pigment epithelium. These methods include locally administering to the eye of the subject the tissue replacement implant. In further embodiments, methods are disclosed for producing the tissue replacement implant.

Disclosed herein are dermal substitutes comprising: fibroblasts positioned in a biologically compatible matrix, the biologically compatible matrix comprising a plurality of protrusions on at least one surface; wherein the plurality of protrusions comprise a length and width sufficient to improve a dermal graft outcome. Also disclosed are methods of treating a skin wound on a subject, the method comprising: contacting a skin wound with a herein disclosed dermal substitute. Also disclosed are methods of preparing a dermal graft for transplantation, the method comprising: culturing fibroblasts positioned in a biologically compatible matrix in a scaffold comprising a plurality of protrusions on at least one surface; wherein the scaffold comprises a plurality of protrusions comprising a length and width sufficient to improve a dermal graft outcome.

Disclosed is a three-dimensional tissue comprising cells and collagen including endogenous collagen, wherein at least a portion of the cells is adhered to the collagen, and the content of the collagen is from 10 wt % to 90 wt % based on the three-dimensional tissue.

Described herein are implantable devices comprising means for mitigating the foreign body response (FBR) and at least one cell-containing compartment which comprises a plurality of cells (e.g., live cells) encapsulated in a polymer composition comprising a cell-binding substance (CBS), as well as compositions and methods of making and using the same. The cells are capable of expressing a therapeutic agent useful for the treatment of a disease, disorder, or condition described herein.

Described herein are engineered multilayered vascular tubes comprising at least one layer of differentiated adult fibroblasts, at least one layer of differentiated adult smooth muscle cells, wherein any layer further comprises differentiated adult endothelial cells, wherein said tubes have the following features: (a) a ratio of endothelial cells to smooth muscle cells of about 1:99 to about 45:55; (b) the tube is compliant; (c) the internal diameter of the tube is about 6 mm or smaller; (d) the length of the tube is up to about 30 cm; and (e) the thickness of the tube is substantially uniform along a region of the tube; provided that the engineered multilayered vascular tube is free of any pre-formed scaffold. Also described herein are methods of forming said tubes and uses for said tubes including methods for treating patients, comprising providing such a tube into to a patient in need thereof.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

The present disclosure provides methods for treating wounds by applying a meshed autograft and skin substitute overlay wherein the skin substitute is an organotypic human skin equivalent comprising NIKS® cells.