A method for vascular regeneration comprises delivering endothelial cells to a lung scaffold, delivering perivascular cells to the lung scaffold, and providing a multiphase culture program to the scaffold. The multiphase culture program comprises a first phase including delivering an angiogenic medium, e.g., having 40-100 ng/ml of pro-angiogenic factors, and a second phase including delivering a stabilization medium, e.g., having 0.5-2% of serum and 1-20 ng/ml of angiogenic factors.

Provided are a method of preparing a stem cell-derived epidermal progenitor cell conditioned medium, the method including: differentiating stem cells to stem cell-derived epidermal progenitor cells by culturing the stem cells in a differentiation medium containing ascorbic acid and hydrocortisone; producing a culture of stem cell-derived epidermal progenitor cells by culturing the differentiated stem cell-derived epidermal progenitor cells in a medium; and recovering the stem cell-derived epidermal progenitor cell conditioned medium from the culture of the stem cell-derived epidermal progenitor cells, a stem cell-derived epidermal progenitor cell conditioned medium prepared by the method, and a method of producing a protein from stem cell-derived epidermal progenitor cells, the method including the method of preparing the stem cell-derived epidermal progenitor cell conditioned medium.

The present invention relates to a method for the preparation of autologous human primary hair follicles in 3D cultures, comprising the isolation of primary fetal follicles; isolation of the patient's hair follicle cells; isolation of skin cells of the patient's scalp; extraction of growth factors from fetal follicle cells; the fibrin gel creation that contains growth factors of fetal follicles; sandwich cultivation of patient's hair follicle cells and skin of the patients scalp on or into fibrin gel that contains growth factors of fetal follicles; separation from fibrin gel the patients primary hair follicles, which can be used to treat baldness as an autologous graft.

Embodiments disclosed here provide engineered modified hematopoietic stem cells (HSCs), artificially prostaglandin E2 (PGE.sub.2)-stimulated HSCs, compositions comprising these HSCs, methods of using these modified HSCs for treating autoimmune diseases and disorders and for suppressing the immune system. In particular, the engineered modified HSCs or PGE.sub.2-stimulated HSCs express the surface marker, programmed cell death-1 ligand 1 (PD-L1).

Embodiments disclosed here provide engineered modified hematopoietic stem cells (HSCs), artificially prostaglandin E2 (PGE.sub.2)-stimulated HSCs, compositions comprising these HSCs, methods of using these modified HSCs for treating autoimmune diseases and disorders and for suppressing the immune system. In particular, the engineered modified HSCs or PGE.sub.2-stimulated HSCs express the surface marker, programmed cell death-1 ligand 1 (PD-L1).

The present invention provides new protease resistant polypeptides, as well as compositions and methods for treating, ameliorating or preventing conditions related to joint damage, including acute joint injury and arthritis.

The present invention provides new protease resistant polypeptides, as well as compositions and methods for treating, ameliorating or preventing conditions related to joint damage, including acute joint injury and arthritis.

Embodiments disclosed here provide engineered modified hematopoietic stem cells (HSCs), artificially prostaglandin E2 (PGE.sub.2)-stimulated HSCs, compositions comprising these HSCs, methods of using these modified HSCs for treating autoimmune diseases and disorders and for suppressing the immune system. In particular, the engineered modified HSCs or PGE.sub.2-stimulated HSCs express the surface marker, programmed cell death-1 ligand 1 (PD-L1).

The current disclosure describes methods of expanding precursor cells for hematopoietic transplantation in subjects. The methods culture precursor cells in media containing an immobilized high molecular weight LILRB2 agonist or an LILRB2 agonist in combination with a Notch agonist. The expanded cells can be used to treat a variety of hematopoietic disorders.

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.