The present invention relates to an implantable cell chamber device capable of retaining cells but permitting diffusion of biomolecules. Also disclosed are methods for delivering a therapeutic biomolecule to a subject in need thereof on a continuous or semi-continuous basis, by administering to the subject a cell chamber device comprising cells that secrete the therapeutic biomolecule.

The present invention relates to a method of preparing a three-dimensional (3D) cell composition comprising the steps of a) forming a support matrix containing oral fibroblasts suspended within the support matrix by mixing fibrinogen, a modifier and oral fibroblasts with thrombin, b) incubating the support matrix in a cell culture media for a sufficient time to allow development of a first layer of the three-dimensional cell composition, and c) seeding oral keratinocytes on a surface of the first layer and culturing the oral keratinocytes to form a second layer of the three-dimensional cell composition. In specific embodiments of the invention, the method is exemplified for the production of an artificial gingival tissue, wherein polyethylene oxide), 4-arm, succinimidyl glutarate terminated is used as the modifier. Also disclosed are uses of the 3D cell composition which include treatment of a gum disease or condition, regenerative therapy and for in vitro testing.

This document provides methods and materials for performing retinal pigment epithelium transplantation. For example, methods and materials for using fibrin supports for retinal pigment epithelium transplantation are provided.

The present invention relates to artificial skin having structure and properties by age, and more specifically to artificial skin having structure and properties, for which effective analysis and application are possible on the basis of age of the skin, as the human skin can be replicated according to age by simple control in the internal structure of properties such as height and width, and a method for manufacturing the same.

Methods are disclosed for fabricating a three-dimensional engineered blood retinal barrier (BRB) comprising a choroid and retinal pigment epithelial cells. The methods include the use of bioprinting. Also disclosed is a three-dimensional engineered BRB, and its use. Methods are also disclosed for using the three-dimensional engineered BRB, such as for the treatment of retinal degeneration in a subject or screening. A three-dimensional printing insert that is adapted for bioprinting on a culture substrate sheet that is securely retained within and exposed through a printing frame is also disclosed.

Provided are live, artificial, skin substitute products and methods of making and using the same, such as for wound treatment and compound testing, including compound testing for efficacy, toxicity, penetration, irritation and/or metabolism testing of drug candidates or compositions such as cosmetics.

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.

Systems and methods for identifying a cell suspension with therapeutic potential for skin regeneration and related compositions are disclosed herein. In some variations, a method may include receiving a cell suspension that comprises a population of viable cells and non-viable cells, then measuring a value indicative of at least one characteristic of the cell suspension, such as but not limited to one or more of total cell count, total cell viability, cell viability percentage, and median live cell diameter. A cell suspension composition having therapeutic potential may comprise a cell suspension met certain thresholds relating to total cell count, total viable cell count, cell viability percentage, and median live cell diameter.

A bioactive suspension derived from freshly disaggregated tissue is provided, as well as related methods of formulation and use. The bioactive suspension may comprise a cell-free supernate derived from epidermal and dermal tissue that has been enzymatically and mechanically disaggregated, then separated, and which may contain tissue regeneration factors known to speed healing. The bioactive suspension may further comprise genetically-modified treatment cells, wild type cells, or both, and may be combined with one or more scaffolding elements to form a bioactive suspension combination product suitable for treatment of a cutaneous defect. Synthetic bioactive suspensions and bioactive suspension combination products are also provided.

A bioactive suspension derived from freshly disaggregated tissue is provided, as well as related methods of formulation and use. The bioactive suspension may comprise a cell-free supernate derived from epidermal and dermal tissue that has been enzymatically and mechanically disaggregated, then separated, and which may contain tissue regeneration factors known to speed healing. The bioactive suspension may further comprise genetically-modified treatment cells, wild type cells, or both, and may be combined with one or more scaffolding elements to form a bioactive suspension combination product suitable for treatment of a cutaneous defect. Synthetic bioactive suspensions and bioactive suspension combination products are also provided.