Provided herein are non-naturally occurring microbial organisms having biosynthetic pathways for production of target products and one or more genetic modifications that reduce a byproduct of the biosynthetic pathway. Compositions of target products from such cells and methods of using such cells are provided.

Provided herein are non-naturally occurring microbial organisms having biosynthetic pathways for production of target products and one or more genetic modifications that reduce a byproduct of the biosynthetic pathway. Compositions of target products from such cells and methods of using such cells are provided.

The present disclosure provides analyte sensors including one or more NAD(P)-dependent enzymes and an internal supply of NAD(P) for the detection of an analyte. The present disclosure further provides methods of using such analyte sensors for detecting one or more analytes present in a biological sample of a subject, and methods of manufacturing said analyte sensors.

The present invention relates to a mutant 3-hydroxybutyrate dehydrogenase (3-HBDH) with improved performance relative to the wild-type 3-HBDH, a nucleic acid encoding the mutant 3-HBDH, a cell comprising the mutant 3-HBDH or the nucleic acid, a method of determining the amount or concentration of 3-hydroxybutyrate in a sample, and a device for determining the amount or concentration of 3-hydroxybutyrate in a sample.

The present disclosure relates to a mutant 3-hydroxybutyrate dehydrogenase (3-HBDH) with improved performance relative to the wild-type 3-HBDH, a nucleic acid encoding the mutant 3-HBDH, a cell having the mutant 3-HBDH or the nucleic acid, and/or a method of determining the amount or concentration of 3-hydroxybutyrate in a sample. Also disclosed is the use of the mutant 3-HBDH for determining the amount or concentration of 3-hydroxybutyrate in a sample, and a device for determining the amount or concentration of 3-hydroxybutyrate in a sample.

A conductive substrate for a working electrode for a biological sensor includes a plastic substrate comprising an organic polymer or a thermoplastic. A carbon compound is on the plastic substrate. The carbon compound includes an elastomeric material and a carbon material from an aqueous solution. The carbon compound includes at least two materials from a group of carbon black, graphene, pyrolytic carbon, pyrolytic graphite, and diamagnetic graphite. The conductive substrate receives and transfers free electrons generated by an enzyme in the working electrode.

A butanol expression cassette includes a butanol production related genes and a fermentation regulatory element. The fermentation regulatory element controls the expression of the butanol production related gene and locates upstream of the butanol production related gene. The fermentation regulatory element includes a promoter, a ribosome binding site and a transcription factor binding site of a fermentation gene. A fermentation in which the fermentation regulatory element involves includes an acetic acid fermentation, an alcohol fermentation, a succinic acid fermentation or a lactic acid fermentation, the butanol production related gene is not the fermentation gene or a gene of an upstream product of the fermentation in which the fermentation gene involves. The present invention provides a recombinant plasmid formed by cloning the butanol expression cassettes in the expression vector. The present invention also provides a butanol production related gene expression method to express butanol production related gene by using recombinant plasmid.

A method of processing data from a test device is provided. The method comprises determining a concentration of a first analyte in a fluid sample using first sensing chemistry, wherein the first analyte is an acidosis-related analyte; determining a concentration of a second analyte in the fluid sample using second sensing chemistry, wherein the second analyte is glucose; displaying a first indication related to the determined concentration of the second analyte; if the determined concentration of the first analyte is equal to or greater than a first threshold, providing a user-selectable option to display a second indication related to the determined concentration of the first analyte.

A working electrode for a subcutaneous sensor for use with a continuous biological monitor for a patient is disclosed. The working electrode includes a conductive substrate and a carbon-enzyme layer on the conductive substrate. The carbon-enzyme layer includes a polyurethane or silicone crosslinked with an acrylic polyol, and an enzyme fully entrapped by the polyurethane or silicone crosslinked with the acrylic polyol. The enzyme is selected according to a biological function to be monitored. The carbon-enzyme layer also includes a carbon material. The carbon-enzyme layer is electrically conductive and facilitates a generation of either peroxide or electrons within the carbon-enzyme layer responsive to reacting the enzyme with a target biologic from blood of the patient.

The present invention provides for a method to increase production of isoprenol by a genetically modified Pseudomonas cell, the method comprising: (a) providing a genetically modified Pseudomonas cell comprising one or more of heterologous genes encoding: MvaE, AtoB, MvaS, MK, PMD.sub.HKQ, AphA, and PhoA; and (b) culturing or growing the genetically modified Pseudomonas cell in a medium to produce isoprenol; wherein (i) the genetically modified Pseudomonas cell is deleted, knocked out, or reduced in expression of one or more of the following endogenous genes: a gene at PP_2675 locus (or a deletion of the PP_2675 locus), phaABC, mvaB, hbdH, ldhA, gntZ, ppsA, pycAB, gltA, and aceA, and/or (ii) the medium comprises one or more amino acids that reduce the catabolism of isoprenol.