A bioelectronic device for regulating stem cell differentiation, a method for differentiating stem cells using the same, and a method for manufacturing the bioelectronic device. According to the present invention, it is possible to effectively control the differentiation of stem cells at a single-cell level, and to simultaneously perform a free radical inhibition function.

Compositions disclosed herein, and methods of use thereof included those for inhibiting or reducing the incidence of cytokine release syndrome or cytokine storm in a subject undergoing CAR T-cell therapy, methods of treating a cancer or tumor, methods of reducing tumor load, methods of reducing the size or growth rate of a cancer or a tumor, and methods of extending of the survival of a subject suffering from a cancer or tumor, wherein the subjects are administered compositions comprising apoptotic cells or apoptotic cell supernatants. Compositions and methods of use thereof may increase the efficacy of a CAR T-cell cancer therapy. Disclosed herein are also compositions and methods of use thereof for decreasing or inhibiting cytokine production in a subject experiencing cytokine release syndrome or cytokine storm. In certain instances compositions may include additional chemotherapeutic or immunomodulatory agents.

The present disclosure is directed to kits and methods for performing optical dynamic clamping on an excitable cell. In some embodiments, the excitable cell is selected from the group consisting of a neuron, a muscle cell and an excitable cell derived from an induced Pluripotent Stem Cell (IPSC). In a specific embodiment, the muscle cell is a cardiomyocyte.

Disclosed are methods and compositions for preventing or disrupting mitosis of pluripotent stem cells, killing pluripotent stem cells, preventing or disrupting division of pluripotent stem cells, reducing the viability of pluripotent stem cells, slowing the progression or differentiation of pluripotent stem cells, and treating an ectopic pregnancy.

A method of stimulating and controlling stem cell activity and differentiation on a modified material substrate and a device including the modified material substrate are provided. The method includes providing a material substrate configured for medical use. The material substrate includes at least one surface or interior area available for modification, and the at least one surface or interior area is treated with a plurality of pulsed light beams to obtain a modified material substrate with at least one modified surface or interior area. The at least one modified surface or interior area has a biomimetic architecture with surface and bulk (interior) features, properties, and textures configured to accelerate and control stem cell differentiation when the modified material substrate is contacted with stem cells.

A sterilised platelet lysate obtained with a method for sterilising a platelet lysate in the liquid state comprising at least the endogenous growth factors TGF-beta 1, EGF, PDGF-AB, IGF-1, VEGF and bFGF. The method comprising freezing the liquid platelet lysate in order to obtain a frozen platelet lysate, and irradiating the frozen platelet lysate with ionising radiation in order to obtain a sterilised platelet lysate, the irradiation being adapted so as to preserve at least 80% of the concentration of at least one of the endogenous growth factors chosen from the group consisting of TGF-beta 1, EGF, PDGF-AB, IGF-1 and VEGF.

The present invention relates to a nano-ligand for promoting cell adhesion and differentiation of stem cells and a method of promoting cell adhesion and differentiation of stem cells by using the nano-ligand, and the method of promoting cell adhesion and differentiation of stem cells according to the present invention may temporally and spatially, and reversibly control nano-ligand sliding by applying a magnetic field to a substrate including the nano-ligands, and efficiently control stem cell adhesion and differentiation ex vivo or in vivo through the magnetic-field based on spatiotemporal control.

The present disclosure relates to methods of stimulating cell proliferation, promoting differentiation of cells, regenerating cells, promoting nodule formation, and promoting myotube formation. The methods include applying one or more pulses of electricity to cells, each pulse of electricity having a duration of between about 10 nanoseconds and about 1,000 nanoseconds, wherein said pulses of electricity are applied under conditions effective to stimulate cell proliferation, promote differentiation of cells, regenerate cells, promote nodule formation, and promote myotube formation.

The present invention relates to a method for preparing a growth-factors containing platelet releasate from a fluid mammalian platelet concentrate, comprising the consecutive steps of subjecting the platelet concentrate to a pathogen reduction step to disrupt non-enveloped viruses; subjecting the platelet concentrate to an activation step to cause the platelets to release growth factors; recovering a fibrinogen depleted fluid platelet releasate; subjecting the fibrinogen depleted fluid platelet releasate to a second pathogen concentration reduction step to disrupt enveloped viruses; subjecting the platelet releasate to sterile filtering and recovering a filtrate liquid containing the growth factors. The platelet releasate obtained with the method of the present invention may be used as a therapeutic agent to enhance the proliferation of multi lineage cells in regenerative medicine and in the management of non healing wounds and resistant ulcers. The second indication is as a substitute to fetal bovine serum in in cell culture media.

A cell culture system includes: a cell culture container disposed in an anaerobic chamber; and an external apparatus. The external apparatus has a main body unit disposed in the anaerobic chamber and an operation unit disposed outside the anaerobic chamber. The main body unit is configured to perform a predetermined process onto the cell culture container. The operation unit is configured to transmit or receive a signal associated with the predetermined process to or from the main body unit by wireless communication.