Provided is a sensing apparatus comprising a chip for integrated amplification and sequencing of a template polynucleotide in a sample. The apparatus comprises a chip with at least one ISFET in a well or chamber, amplification means for amplifying the template polynucleotide on a surface of said chip and comprising at least one heating means suitable for conducting amplification of the template polynucleotide at temperatures elevated with respect to room temperature, and sequencing means for sequencing the amplified template polynucleotide in said well or chamber. Methods of use are also provided.

Provided is a sensing apparatus comprising a chip for integrated amplification and sequencing of a template polynucleotide in a sample. The apparatus comprises a chip with at least one ISFET in a well or chamber, amplification means for amplifying the template polynucleotide on a surface of said chip and comprising at least one heating means suitable for conducting amplification of the template polynucleotide at temperatures elevated with respect to room temperature, and sequencing means for sequencing the amplified template polynucleotide in said well or chamber. Methods of use are also provided.

The disclosure herein relates to engineered biosensor-containing bacteria, which is bacteria that contain at least one biosensor circuit, and uses thereof. A biosensor circuit can comprise an essential gene of the bacteria operably linked to an inducible promoter. Additionally, the bacteria can be engineered to be deficient in the endogenous copy of the at least one essential gene.

The disclosure herein relates to engineered biosensor-containing bacteria, which is bacteria that contain at least one biosensor circuit, and uses thereof. A biosensor circuit can comprise an essential gene of the bacteria operably linked to an inducible promoter. Additionally, the bacteria can be engineered to be deficient in the endogenous copy of the at least one essential gene.

Provided is a method for monitoring a change of ion strength in a sample solution by a closed-loop device that provides continuous cycling of electrochemical pH modulation between pre-defined pH values. In particular, the change of ion strength may be induced by a chemical reaction and may ultimately alter the electrical control parameters of the closed-loop device. By measuring such electrical control parameters, the degree and progress of the underlying chemical reaction may be monitored.

Provided is a method for monitoring a change of ion strength in a sample solution by a closed-loop device that provides continuous cycling of electrochemical pH modulation between pre-defined pH values. In particular, the change of ion strength may be induced by a chemical reaction and may ultimately alter the electrical control parameters of the closed-loop device. By measuring such electrical control parameters, the degree and progress of the underlying chemical reaction may be monitored.

Disclosed are nucleic acid-based molecular switches that respond to changes in pH. The switches may be used in DNA nanodevices. The switches may also act as sensors for measuring the pH of a sample, including cells, regions thereof, and whole organisms. The switch includes an A-motif that forms at acidic pH. Also disclosed are compositions and methods for measuring the pH of cells or regions thereof, such as vesicles, the nucleus, mitochondrial matrix, or the Golgi lumen.

Disclosed are nucleic acid-based molecular switches that respond to changes in pH. The switches may be used in DNA nanodevices. The switches may also act as sensors for measuring the pH of a sample, including cells, regions thereof, and whole organisms. The switch includes an A-motif that forms at acidic pH. Also disclosed are compositions and methods for measuring the pH of cells or regions thereof, such as vesicles, the nucleus, mitochondrial matrix, or the Golgi lumen.

The present method involves sequencing by synthesis in which a template strand having an attached primer is immobilized in a small volume reaction mixture. In one embodiment, the reaction mixture is in contact with a sensitive heat sensor, which detects the heat of reaction from incorporation of a complementary base (dNTP) in the presence of appropriate reagents (DNA polymerase, and polymerase reaction buffer). Alternatively, or in addition, a change in pH resulting from the incorporation of nucleotides in the DNA polymerase reaction is measured. A device is provided having delivery channels for appropriate reagents, including dNTPs, which may be delivered sequentially or in a mixture. Preferably, the dNTPs are added in a predetermined sequence, and the dNTP is incorporated or not depending on the template sequence.

The present method involves sequencing by synthesis in which a template strand having an attached primer is immobilized in a small volume reaction mixture. In one embodiment, the reaction mixture is in contact with a sensitive heat sensor, which detects the heat of reaction from incorporation of a complementary base (dNTP) in the presence of appropriate reagents (DNA polymerase, and polymerase reaction buffer). Alternatively, or in addition, a change in pH resulting from the incorporation of nucleotides in the DNA polymerase reaction is measured. A device is provided having delivery channels for appropriate reagents, including dNTPs, which may be delivered sequentially or in a mixture. Preferably, the dNTPs are added in a predetermined sequence, and the dNTP is incorporated or not depending on the template sequence.