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. Described herein is an artificial mammalian skin substitute product, comprising: (a) optionally, but in some embodiments preferably, a first (“hypodermis-like”) layer comprising live mammalian adipocytes (e.g., induced pre-adipocytes) in a first hydrogel carrier; (b) a second (“dermis-like”) layer contacting or directly contacting the first layer and comprising live mammalian fibroblast cells and' live mammalian follicle dermal papilla cells in combination in a second hydrogel carrier; (c) a third (“epidermis-like”) layer contacting or directly contacting the second layer (i.e., on the opposite side thereof as the first layer, so that the second layer is sandwiched between the first and third layers when the first layer is present), the third layer comprising live mammalian keratinocytes and live mammalian melanocytes in combination in a third hydrogel carrier.

Disclosed herein are synthetic leathers, artificial epidermal layers, artificial dermal layers, layered structures, products produced therefrom and methods of producing the same.

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 invention relates to a method for producing hair microfollicles comprising the steps of: a) providing de novo papillae, b) providing other cell populations selected from the group of fibroblasts, keratinocytes and melanocytes, and co-culturing the de novo papillae with at least one other cell population in non-adherent culture vessels. The present invention relates also to methods of producing de novo papillae usable in said method for producing hair microfollicles.

A method for manufacturing a skin chip according to an exemplary embodiment of the present disclosure may include: a step of forming first and second PDMS layers disposed on both surfaces of a porous membrane and each having a microfluidic channel through which a culture medium is transferred to both surfaces of the porous membrane; a step of forming first and second MEA substrate layers disposed on the outer surfaces of the first and second PDMS layers, respectively, and having metal electrodes for measurement of TEER arranged at positions corresponding to the channels; and a step of forming first and second PMMA layers disposed on the outer surfaces of the first and second MEA substrate layers, respectively. In the method for manufacturing a skin chip according to in an exemplary embodiment of the present disclosure, the porous membrane may be made of a polycarbonate having pores of a predetermined size.

Disclosed herein are improved methods for fabricating bioprinted, three-dimensional, biological tissues. The methods relate to exposures to low temperatures, incubations at low temperatures of various durations, and fabrication in environments without structural cross-linking treatments.

Provided herein are methods and systems for bio-printing of three-dimensional organs and organoids. Also provided herein are bio-printed three-dimensional organs and organoids for use in the generation and/or the assessment of immunological products and/or immune responses. Also provided herein are methods and system for bio-printing three-dimensional matrices.

The present invention relates to the treatment of sensory neuropathy induced by a marine neurotoxic poisoning. The invention further encompasses an in vitro method for producing a neuro-cutaneous model allowing to study the cellular and/or molecular mechanisms involved in said neuropathy, a neuro-cutaneous model obtainable according to said method, and applications thereof.

Methods of screening rinse-off personal care compositions can include the use of explant skin in combination with measurements for moisture and/or cell proliferation.

The present disclosure provides, in various aspects, a method of forming a prefabricated innervated pre-vascularized pre-laminated (PIPP) flap having a stoma or lumen. The method includes providing a cell construct including skin cells and/or mucosa cells. The method further includes forming an integrated in vivo composite at a donor site by grafting the cell construct onto a muscle. The method further includes stabilizing the composite on an obturator component. The method further includes developing a microvascular system in the composite by retaining it in vivo at the donor site for a predetermined period of time. The method further includes removing the obturator component from the stoma or lumen. In certain aspects, the present disclosure also provides a method of restoring a defect including damaged or surgically removed soft tissue using a PIPP flap. In certain aspect, the present disclosure also provides an obturator component for maintaining the stoma or lumen.