The present disclosure provides a complex comprising a nanoparticle; a Type II or a Type V CRISPR system comprising a site-directed DNA-modifying polypeptide and a guide RNA; and a polycation-based endosomal escape polymer. The present disclosure provides methods of making and using a complex of the present disclosure.

The present invention provides compositions and methods for the regeneration of tissue. In particular, the present invention provides mesenchymal stem cells (MSCs) and endothelial progenitor cells (EPCs) for bladder regeneration.

It is an object of the present invention to provide a sensor, which is capable of measuring, quickly and in high accuracy, concentration of neutral fat from a sample such as a biological sample or the like, without executing pretreatment of the sample. This object is attained by a biosensor for measuring concentration of neutral fat, based on value of current flowing in the electrode system, having: an insulating substrate; an electrode system having a working electrode and a counter electrode, formed onto the insulating substrate: and a reaction layer having a lipoprotein lipase, a glycerol dehydrogenase and an electron mediator, formed at the upper part or the vicinity of the electrode system.

The invention provides a non-particulate cross-linked poly--lysine polymer. The poly--lysine and cross linker are linked by amide bonds and may the cross linker has at least two functional groups capable of reacting with an alpha carbon amine of poly--lysine. The polymer is suitably insoluble in water and other solvents and is provided in macro form for example a sheet, article or fiber. The macro form polymer is useful in a wide range of applications including wound treatment, as a medical diagnostic comprising a particulate support and a functional material bound or retained by the support and solid phase synthesis of peptides, oligonucleotides, oligosaccharides, immobilization of species, cell culturing and in chromatographic separation.

Overlay processes are disclosed for making ethanol that not only increase ethanol conversion but do so in a cost effective manner with a reduction in energy requirements per unit of ethanol production. The processes can provide, if desired, higher organic compound as a co-product with ethanol.

The invention uses a highly porous MTAM to immobilize yeast cells for bioethanol fermentation, a first in bioethanol production. The invention also optimizes the conditions to prepare MTAM-immobilized cells and evaluates their potential for batch bioethanol fermentation.

Overlay processes are disclosed for making ethanol that not only increase ethanol conversion but do so in a cost effective manner with a reduction in energy requirements per unit of ethanol production. The processes can provide, if desired, higher organic compound as a co-product with ethanol.

According to one embodiment, a microcapsule for selective catalysis of gases, the microcapsule comprising: a polymeric shell permeable to one or more target gases; and at least one biocatalyst disposed in an interior of the polymeric shell. In more embodiments, methods of forming such microcapsules include: emulsifying at least one biocatalyst in a polymer precursor mixture; emulsifying the polymer precursor mixture in an aqueous carrier solution; crosslinking one or more polymer precursors of the polymer precursor mixture to form a plurality of microcapsules each independently comprising: a polymeric shell permeable to one or more target gases; and at least one biocatalyst disposed in an interior of the polymeric shell. In further embodiments, corresponding methods of using the inventive microcapsules for catalyzing one or more target gases using include: exposing a plurality of the biocatalytic microcapsules to the one or more target gases.

The invention uses a highly porous MTAM to immobilize yeast cells for bioethanol fermentation, a first in bioethanol production. The invention also optimizes the conditions to prepare MTAM-immobilized cells and evaluates their potential for batch bioethanol fermentation.

The present invention includes an anisotropic scaffold, which is prepared by electrospinning a solution of matrix material upon a textile template. The present invention further includes a method of preparing such scaffold. The anisotropic scaffold of the invention finds use in tissue engineering and regenerative medicine.