Genetically modified compositions, such as non-viral vectors and T cells, for treating cancer are disclosed. Also disclosed are the methods of making and using the genetically modified compositions in treating cancer.

A device for treatment of cells with particles is disclosed. The device includes a semi-permeable membrane positioned between two plates, the first plate defining a first flow chamber and comprising a port, a flow channel, a transverse port, and a transverse flow channel, the first flow chamber constructed and arranged to deliver fluid in a transverse direction along the first side of the semi-permeable membrane, the second plate defining a second flow chamber and comprising a port. A method for transducing cells is disclosed. The method includes introducing a fluid with cells and viral particles into a flow chamber adjacent a semi-permeable membrane such that the cells and the viral particles are substantially evenly distributed on the semi-permeable membrane. The method also includes introducing a recovery fluid to suspend the cells and the viral particles, and separating the cells from the viral particles. A method of activating cells is disclosed.

A device for treatment of cells with particles is disclosed. The device includes a semi-permeable membrane positioned between two plates, the first plate defining a first flow chamber and comprising a port, a flow channel, a transverse port, and a transverse flow channel, the first flow chamber constructed and arranged to deliver fluid in a transverse direction along the first side of the semi-permeable membrane, the second plate defining a second flow chamber and comprising a port. A method for transducing cells is disclosed. The method includes introducing a fluid with cells and viral particles into a flow chamber adjacent a semi-permeable membrane such that the cells and the viral particles are substantially evenly distributed on the semi-permeable membrane. The method also includes introducing a recovery fluid to suspend the cells and the viral particles, and separating the cells from the viral particles. A method of activating cells is disclosed.

The present disclosure relates generally to methods and compositions for transferring a genetic circuit from one prokaryotic cell (“donor cell”) to another prokaryotic cell (“recipient cell” or “target cell” which are used interchangeably herein). More specifically, the present disclosure relates to prokaryotic donor cells comprising (i) a genetic circuit of interest and (ii) one or more expressed transcriptional repressor proteins and the use of said donor cells in the efficient transfer of the genetic circuit into a prokaryotic recipient cell. The genetic circuit includes nucleic acid sequences encoding a RNA molecule or protein of interest.

The present disclosure relates generally to methods and compositions for transferring a genetic circuit from one prokaryotic cell (“donor cell”) to another prokaryotic cell (“recipient cell” or “target cell” which are used interchangeably herein). More specifically, the present disclosure relates to prokaryotic donor cells comprising (i) a genetic circuit of interest and (ii) one or more expressed transcriptional repressor proteins and the use of said donor cells in the efficient transfer of the genetic circuit into a prokaryotic recipient cell. The genetic circuit includes nucleic acid sequences encoding a RNA molecule or protein of interest.

In an embodiment, the present disclosure pertains to a microfluidic platform composed of a droplet generator having an entry point for donor particles and target particles, a first droplet incubation chamber in fluid communication with the droplet generator, a droplet detection functionality to allow for analysis of the inner content of droplets, and a droplet sorting functionality to allow for the separation of droplets based on the analysis of the inner content of droplets. In another embodiment, the present disclosure pertains to a method for cell-to-cell DNA, RNA, or other genetic material transfer through use of a water-in-oil emulsion microdroplet-based microfluidic platform for automation and high throughput identification or screening of genetic transfer outcomes utilizing the microfluidic platforms as disclosed herein.

The present invention concerns platelets transfected with exogenous genetic material and microparticles deriving from said transfected platelets having a high percentage of transfection and able to transport and to transfect acceptor cells with genetic material and then used for example in gene and cell therapy. The invention further concerns a method for the preparation of mature platelets transfected with exogenous genetic material and microparticles deriving from said transfected platelets and microparticles deriving from said transfected mature platelets which permits to obtain high percentages of transfection.

The present invention concerns platelets transfected with exogenous genetic material and microparticles deriving from said transfected platelets having a high percentage of transfection and able to transport and to transfect acceptor cells with genetic material and then used for example in gene and cell therapy. The invention further concerns a method for the preparation of mature platelets transfected with exogenous genetic material and microparticles deriving from said transfected platelets and microparticles deriving from said transfected mature platelets which permits to obtain high percentages of transfection.

Nucleic acid delivery vehicles for delivering nucleic acid, e.g., for RNAi to cells that are typically refractory to RNAi by using extracellular vesicles (EVs) from cultured beetle cells as delivery vehicles. Instead of using high levels of long dsRNA and transfection reagents to accomplish suppression of an mRNA target in cells that don't respond to treatment with naked dsRNA, this approach applies the dsRNA to cultured beetle cells, collects nucleic-acid loaded EVs from the culture, then treats our target cells with the intracellularly loaded EVs, which results in significant enhancement of the RNAi response and greater suppression of transcript levels.

The present invention relates to an orally-administered gene carrier and a use thereof, and more specifically, to: an oral gene carrier comprising, at the C-terminus of an immunoglobulin Fc region, a linker formed from cationic arginine and enabling the condensation of an anionic gene; and an oral composition for preventing, ameliorating or treating metabolic diseases, the composition comprising the gene carrier and the GLP-1 gene as active ingredients. The gene carrier, according to the present invention, may be usefully employed as an orally-administered carrier for various genes, and especially, is expected to be usable for preventing, ameliorating or treating metabolic diseases, such as diabetes and obesity, by effectively transferring the GLP-1 gene.