Provided herein are compositions and methods to make and use engineered cells, for the purpose of increasing the cell density of a culture comprising metazoan cells and for the production of a cultured edible product.

Provided herein are compositions and methods to make and use engineered cells, for the purpose of increasing the cell density of a culture comprising metazoan cells and for the production of a cultured edible product.

An intracellular delivery system and method are provided. The intracellular delivery system comprises a laser-activated surface and cells positioned at a distance from the laser-activated surface. A laser provided a laser pulse that is used to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells. The method of intracellular delivery comprises positioning a laser-activated surface at a distance from cells and applying a laser pulse from the laser to the surface to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells.

An intracellular delivery system and method are provided. The intracellular delivery system comprises a laser-activated surface and cells positioned at a distance from the laser-activated surface. A laser provided a laser pulse that is used to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells. The method of intracellular delivery comprises positioning a laser-activated surface at a distance from cells and applying a laser pulse from the laser to the surface to porate membranes of the cells to deliver or extract cargo from the cells into a liquid surrounding the cells.

Provided herein are compositions and methods to make and use engineered cells, for the purpose of increasing the cell density of a culture comprising metazoan cells and for the production of a cultured edible product.

Provided herein are compositions and methods to make and use engineered cells, for the purpose of increasing the cell density of a culture comprising metazoan cells and for the production of a cultured edible product.

The present invention relates to the field of non-viral vectors and pharmaceutical compositions comprising polypropyleneimine and a nucleic acid, and their use in human or veterinary medicine. More precisely, the present invention relates to pharmaceutical compositions comprising a polymer or co-polymer of polypropyleneimine for delivery or transfection of a nucleic acid, e.g. RNA. The pharmaceutical compositions described herein are particularly useful for (nucleic acid) vaccination, nucleic acid-based protein therapy, nucleic-acid based protein replacement therapy, gene editing, base editing, cell therapy, immunotherapy, stem cell therapy, regenerative medicine, gene silencing, nucleic acid inhibition or protein inhibition.

The present invention relates to the field of non-viral vectors and pharmaceutical compositions comprising polypropyleneimine and a nucleic acid, and their use in human or veterinary medicine. More precisely, the present invention relates to pharmaceutical compositions comprising a polymer or co-polymer of polypropyleneimine for delivery or transfection of a nucleic acid, e.g. RNA. The pharmaceutical compositions described herein are particularly useful for (nucleic acid) vaccination, nucleic acid-based protein therapy, nucleic-acid based protein replacement therapy, gene editing, base editing, cell therapy, immunotherapy, stem cell therapy, regenerative medicine, gene silencing, nucleic acid inhibition or protein inhibition.

The present disclosure pertains to methods of modifying an immune cell by delivering a modified messenger RNA (mRNA) encoding a chimeric antigen receptor (CAR) and modified immune cells comprising CARs.

The present disclosure pertains to methods of modifying an immune cell by delivering a modified messenger RNA (mRNA) encoding a chimeric antigen receptor (CAR) and modified immune cells comprising CARs.