Provided herein are a device and a method for preparation of immobilized proteins, enzymes or cells on a carrier to achieve the industrial batch production of the immobilized proteins, enzymes or cells.

The present invention provides a unit and a method useful for more precise phenylalanine measurement. More specifically, the present invention provides a modified phenylalanine dehydrogenase that includes a mutation of at least one amino acid residue so as to improve the characteristics (for example, substrate specificity, solubility, and phenylalanine dehydrogenase activity) of a phenylalanine dehydrogenase related to measurement of phenylalanine, a method for analyzing phenylalanine by measuring phenylalanine contained in a test sample using the modified phenylalanine dehydrogenase, and others.

The present disclosure relates to a kit for sample preparation, the kit including a solid support surface with a polymer coating covering the solid support surface, wherein the polymer coating reduces undesired interactions between the sample and the solid support surface, a buffer comprising arginine and methionine, and a vessel for containing the solid support surface and the buffer.

A hydrogen peroxide and gluconic acid production method and system is disclosed that can include receiving an aqueous solution having glucose, water, and glucose oxidase at a reaction chamber. Here, the reaction chamber facilitates an enzymatic reaction between a gas phase and a liquid phase of the aqueous solution, thereby yielding a first solution comprising hydrogen peroxide, gluconic acid, and the glucose oxidase. The method can further include receiving the first solution at a separation chamber, wherein the separation chamber is comprised of a semi-permeable membrane having a pre-defined molecular weight barrier for separating the glucose oxidase, thereby resulting in a combined hydrogen peroxide and gluconic acid solution. The method can further include at least partially converting the gluconic acid into a gluconate salt, and separating and concentrating the hydrogen peroxide from the gluconic acid or gluconate salt via vacuum flash evaporation and vacuum distillation.

In a method and an apparatus for an enzymatic hydrolysis in which plant based raw material is hydrolysed by means of enzymes in at least one enzymatic hydrolysis stage. A plant based feed (1) is fed to the enzymatic hydrolysis stage (2) in which the plant based feed is hydrolysed. A liquid fraction (3) comprising carbohydrates is separated from a solid fraction (4) in a solid-liquid separation stage (11). At least a part (5) of the solid fraction (4) comprising enzymes is recirculated to the plant based feed (1) of the enzymatic hydrolysis stage (2) or to the enzymatic hydrolysis stage (2), and a rest part (6) of the solid fraction (4) is recovered. Further, the invention relates to the liquid fraction and the solid fraction and their use.

The present invention provides a method of recovering viable microbial cells from a complex sample, said method comprising: a) providing a sample having a volume of at least 1 ml; b) contacting said sample with a buffer solution and one or more proteases, wherein said buffer solution has a pH of at least pH 6 and less than pH 11, wherein said buffer solution and said one more proteases do not comprise a detergent or a chaotrope, and wherein the buffer solution/protease/sample mixture is non-hypotonic; c) filtering the mixture obtained in step (b) through a filter suitable for retaining microbial cells; and d) recovering the microbial cells retained by the filter in step (c), wherein the recovered microbial cells are viable, and a microbial recovery device for the same.

An exemplary embodiment of the present disclosure provides A method and system for forming a microscale cell-laden matrix using an aqueous two-phase system (“ATPS”) comprising a mixture of a first material and a second material having a phase boundary between the first and second materials. The method can comprise mixing an enzyme with the first material, mixing a protein with the second material, and mixing a suspension comprising cells with one of the first material or the second material, wherein the enzyme, protein, and suspension comprising cells generate the cell-laden matrix and wherein the first material comprises a first polymer comprising polyethylene glycol and the second material can be a second polymer selected from the group consisting of dextran, polyvinyl pyrrolidone, polyvinyl alcohol, or ficoll.

A new quantification method for measuring citrulline, which has an association with various diseases and is a biomarker particularly useful for early diagnosis of rheumatoid arthritis, an enzyme for quantification, a composition for quantification, and a kit for quantification are provided. A quantification method of citrulline is provided by adding a citrulline oxidoreductase to a sample. The oxidoreductase is an oxidase, and a concentration of the citrulline may be determined by quantifying hydrogen peroxide produced by addition of the oxidase. A concentration of the citrulline may be determined by reacting a reagent with hydrogen peroxide produced by addition of the oxidase.

A method for selecting cells highly responsive to a target substance according to the present invention comprises step of: (1a) bringing a sample containing a target substance into contact with a plurality of cells, wherein the cells are cells having a receptor for the target substance and a fluorescent indicator, and the fluorescent indicator emits fluorescence as a result of binding between the target substance and the receptor; (1b) calculating a fluorescence intensity increase rate for each of the cells; and (1c) selecting arbitrary cells exhibiting a fluorescence intensity increase rate within the top 50% among the plurality of cells. According to the present invention, it is possible to detect the target substance in the sample with high sensitivity.

A method for selecting cells highly responsive to a target substance according to the present invention comprises step of: (1a) bringing a sample containing a target substance into contact with a plurality of cells, wherein the cells are cells having a receptor for the target substance and a fluorescent indicator, and the fluorescent indicator emits fluorescence as a result of binding between the target substance and the receptor; (1b) calculating a fluorescence intensity increase rate for each of the cells; and (1c) selecting arbitrary cells exhibiting a fluorescence intensity increase rate within the top 50% among the plurality of cells. According to the present invention, it is possible to detect the target substance in the sample with high sensitivity.