The present disclosure relates generally to therapeutic agents that may be useful as inhibitors of Integrated Stress Response (ISR) pathway.

The present invention relates to a method of transporting a stem cell population, the method comprising transporting the stem cell population contacted with a liquid carrier. In addition, the present invention concerns a method of treating a subject having a disease, the method comprising topically administering a defined mesenchymal stem cell population to the subject, wherein the mesenchymal stem cell population is administered within about 96 hours from the time point the mesenchymal stem cell population has been harvested. Also concerned is a unit dosage comprising about 20 million cells, of about 15 million cells, of about 10 million cells, of about 5 million cells, of about 4 million cells, of about 3 million cells, of about 2 million cells, of about 1 million cells, of about 0.5 million cells, of about 0.25 million cells or of less than 0.25 million cells of a defined mesenchymal stem cell population.

The present invention relates to a method for in-vitro production of mammalian neurons expressing the 6 isoforms of the Tau protein (2N4R, 1N4R, 0N4R, 2N3R, 1N3R, 0N3R), comprising a step of neuronal differentiation, in which cellular microcompartments are cultivated for a period of 5 weeks to 100 weeks, each one comprising a hollow hydro gel capsule surrounding post-mitotic neuronal cells and an extracellular matrix, the neuronal differentiation step being carried out in a bioreactor, the cellular microcompartments being kept in suspension in an enclosure of the bioreactor containing a neuronal differentiation medium.

Described herein are methods of generating induced muscle progenitor cells (iMPCs) and uses thereof. Embodiments further provide for methods of promoting muscle regeneration and/or repair and methods of treating a muscle disease or disorder.

The present invention provides a new method for producing Engineered Heart Muscle (EHM) under chemically fully defined conditions all compatible with GMP regulations. The resulting human myocardium generates force and shows typical heart muscle properties.

Methods are disclosed for treating a subject with a tumor. These methods include administering to the subject a therapeutically effective amount of CD8.sup.+CD39.sup.+CD103.sup.+ T cells. Methods also are disclosed for isolating a nucleic acid encoding a T cell receptor (TCR) that specifically binds a tumor cell antigen. These methods include isolating CD8.sup.+CD39.sup.+CD103.sup.+ T cells from a sample from a subject with a tumor expressing the tumor cell antigen, and cloning a nucleic acid molecule encoding a TCR from the CD8.sup.+CD39.sup.+CD103.sup.+ T cells. In addition, methods are disclosed for expanding CD8.sup.+CD39.sup.+CD103.sup.+ T cells. In additional embodiments, methods are disclosed for determining if a subject with a tumor will respond to a checkpoint inhibitor. The methods include detecting the presence of CD8.sup.+CD39.sup.+CD103.sup.+ T cells in a biological sample from a subject.

The present invention provides a tissue-engineering vascular graft (TEVG) comprising a biodegradable scaffold, and a plurality of stem cell-derived vascular smooth muscle cells (VSMCs), wherein the plurality of stem cell-derived VSMCs are seeded on the biodegradable synthetic polymer scaffold and are cultured under mechanical and biochemical stimulation.

A cell preservation medium, a cell recovery medium and a cell culture medium, and methods which employ the media, are provided.

A corneal storage composition is disclosed. The composition comprises a buffered, balanced, nutrient and electrolyte aqueous solution; γ-PGA; and ferulic acid, in amounts effective to maintain cell integrity and viability of the corneal tissue for a period of greater than 14 days.

The present invention discloses formulation of a serum-free medium used for human pluripotent stem cells, which comprises the following raw materials: inorganic salt components, organic components, amino acids and amino acid salts, energy substances and metabolic intermediates, vitamins and antioxidants, proteins and polypeptides, trace elements and chromogenic substances; while the culture process comprises the following steps: selecting a basic formulation, performing combination screening, identifying and evaluating results, and testing a new formulation of culture; and proportioning according to the following methods: adding aforesaid raw materials into 950 ml of water for injection, stirring gently until dissolved, and finally adding 2.438 g of sodium bicarbonate, and stirring gently until dissolved, and then adding 1 liter of water for injection, adjusting the pH to the desired value with 1 mol/L sodium hydroxide solution or 1 mol/L hydrochloric acid solution, finally filtering sterilized with 0.1 μm diameter filter under positive pressure, and storing the medium solution in dark place at 2° C.-8° C., the invention solves the problem of high cost of domestic import of serum-free formulation.