The present invention provides an alternative L-glutamate oxidase that allows for measurement of L-glutamate. More specifically, the present invention provides the following L-glutamate oxidase mutant (a) or (b) and the like: (a) an L-glutamate oxidase mutant including an amino acid sequence that has 90% or more identity to an amino acid sequence of SEQ ID NO: 3 and exhibits an activity of oxidizing L-glutamate, except an L-glutamate oxidase including an amino acid sequence of SEQ ID NO: 1; or (b) an L-glutamate oxidase mutant comprising a peptide linker consisting of 1 to 20 amino acid residues which is inserted into one or more sites selected from the group consisting of (1) a site in a region proximity to a boundary between α1 and α2 regions, (2) a site in a region proximity to a boundary between α2 and γ regions and (3) a site in a region proximity to a boundary between γ and β regions in the L-glutamate oxidase mutant (a), and having the activity of oxidizing L-glutamate.

The present invention provides a method form making a composition of nanoparticles comprising a biological mimetic base component that forms the structure of the nanoparticle. By interacting with the functional groups of the base component, the half-life of a bioactive molecule is extended.

The present invention provides a composition of nanoparticles comprising a biological mimetic base component that forms the structure of the nanoparticle. By interacting with the functional groups of the base component, the half-life of a bioactive molecule is extended.

There is provided a dried L-glutamate oxidase composition containing an L-glutamate oxidase, which is stable even if it is stored for such a long term as one year or longer. The composition is a dried composition, preferably lyophilized product, containing an L-glutamate oxidase and a disaccharide. A preferred example of the disaccharide is lactose. Content of the disaccharide per 100 U of the L-glutamate oxidase is preferably 0.5 to 50 mg.

Embodiments of the present invention are directed to a semiconductor device. A non-limiting example of the semiconductor device includes a semiconductor substrate. The semiconductor device also includes a plurality of metal nanopillars formed on the substrate. The semiconductor device also includes an amperometric sensor associated with one of the plurality of nanopillars, wherein the amperometric sensor is selective to an enzyme-active neurotransmitter. The semiconductor device also includes a resistivity sensor associated with a pair of nanopillars, wherein the resistivity sensor is selective to an analyte.

Embodiments of the present invention are directed to a semiconductor device. A non-limiting example of the semiconductor device includes a semiconductor substrate. The semiconductor device also includes a plurality of metal nanopillars formed on the substrate. The semiconductor device also includes an amperometric sensor associated with one of the plurality of nanopillars, wherein the amperometric sensor is selective to an enzyme-active neurotransmitter. The semiconductor device also includes a resistivity sensor associated with a pair of nanopillars, wherein the resistivity sensor is selective to an analyte.

A biosensor includes an array of electrically conductive nanorods formed on a substrate. The nanorods each includes a nanoscale porous coating formed on a surface of the nanorods from silicon dioxide layers. An enzyme coating is bound to the porous coating.

A biosensor includes an array of electrically conductive nanorods formed on a substrate. The nanorods each includes a nanoscale porous coating formed on a surface of the nanorods from silicon dioxide layers. An enzyme coating is bound to the porous coating.

Embodiments of the present invention are directed to a semiconductor device. A non-limiting example of the semiconductor device includes a semiconductor substrate. The semiconductor device also includes a plurality of metal nanopillars formed on the substrate. The semiconductor device also includes an amperometric sensor associated with one of the plurality of nanopillars, wherein the amperometric sensor is selective to an enzyme-active neurotransmitter. The semiconductor device also includes a resistivity sensor associated with a pair of nanopillars, wherein the resistivity sensor is selective to an analyte.

The present invention provides a composition of nanoparticles comprising a biological mimetic base component that forms the structure of the nanoparticle. By interacting with the functional groups of the base component, the half-life of a bioactive molecule is extended.