Compositions comprising (i) lactate oxidase (LOX) and Catalase (CAT), preferably in a 1:1 molar ratio; or (ii) a fusion polypeptide comprising both LOX and CAT, e.g., LOXCAT, and methods of use thereof for reducing blood lactate levels, increasing blood pyruvate levels, and/or decreasing blood lactate/pyruvate ratio in a subject.

A diagnostic device 10 for screening for a target analyte in a sample is provided. The diagnostic device 10 comprises a substrate 12 and a hydrophobic material 20 disposed on the substrate. The hydrophobic material 20 is selected to be converted from the hydrophobic material 20 to a hydrophilic material 22 upon contact with a conversion component within or derived from a sample introduced to the device 10.

Active biofluid management may be advantageous to the realization of wearable bioanalytical platforms that can autonomously provide frequent, real-time, and accurate measures of biomarkers in epidermally-retrievable biofluids (e.g., sweat). Accordingly, exemplary implementations include a programmable epidermal microfluidic valving system capable of biofluid sampling, routing, and compartmentalization for biomarker analysis. An exemplary system includes a network of individually-addressable microheater-controlled thermo-responsive hydrogel valves, augmented with a pressure regulation mechanism to accommodate pressure built-up, when interfacing sweat glands. The active biofluid control achieved by this system may be harnessed to create unprecedented wearable bioanalytical capabilities at both the sensor level (decoupling the confounding influence of flow rate variability on sensor response) and the system level (facilitating context-based sensor selection/protection). Through integration with a wireless flexible printed circuit board and seamless bilateral communication with consumer electronics (e.g., smartwatch), contextually-relevant (scheduled/on-demand) on-body biomarker data acquisition/display may be achieved.

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 disclosure relates to textile biosensors and related systems that can be used for in situ health monitoring and disease detection. The biosensors include a flexible or textile substrate, a working electrode embroidered thereon, a reference electrode embroidered thereon, optionally a counter electrode embroidered thereon, and an enzyme probe bound to the working electrode. The biosensors can be integrated directly onto fabrics and garments to provide lightweight, unobtrusive wearable sensing systems that do not compromise wearer mobility, comfort or attention.

Disclosed is a biochemical-immunological hybrid biosensor. The biochemical-immunological hybrid biosensor includes a reaction strip in the form of a porous membrane through which a sample moves by capillary action. The reaction strip can simultaneously measure heterogeneous multiple biomarkers through both a biochemical analysis and an immunoassay in an independent manner based on membrane chromatography to diagnose a particular disease.

Compositions comprising (i) lactate oxidase (LOX) and Catalase (CAT), preferably in a 1:1 molar ratio; or (ii) a fusion polypeptide comprising both LOX and CAT, e.g., LOXCAT, and methods of use thereof for reducing blood lactate levels, increasing blood pyruvate levels, and/or decreasing blood lactate/pyruvate ratio in a subject.

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.

The present invention relates to compositions comprising a polymeric matrix or a gel containing functional enzymes capable of re-creating under culture conditions the cell microenvironment existing in vivo. The present invention also relates to devices for cell cultures comprising such compositions, in particular hydrogel and the use thereof to control the chemical microenvironment of a cell culture or mimic physiological or pathological conditions of the in vivo cells. The compositions and the devices described herein could be also used in vitro for evaluating the therapeutic effect of a compound on a determined cell line or on primary cells.