Abstract: In one embodiment, a method is provided for the manufacture of a nano-sensor array. A base having a sensing region is provided along with a plurality of nano-sensors. Each of the plurality of nano-sensors is formed by: forming a first nanoneedle along a surface of the base, forming a dielectric on the first nanoneedle, and forming a second nanoneedle on the dielectric layer. The first nanoneedle of each sensor has a first end adjacent to the sensing region of the base. The second nanoneedle is separated from the first nanoneedle by the dielectric and has a first end adjacent the first end of the first nanoneedle. The base is provided with a fluidic channel. The plurality of nano-sensors and the fluidic channel are configured and arranged with the first ends proximate the fluidic channel to facilitate sensing of targeted matter in the fluidic channel.

Abstract: A sensing apparatus for sensing target materials including biological or chemical molecules in a fluid. One such apparatus includes a semiconductor-on-insulator (SOI) structure having an electrically-insulating layer, a fluidic channel supported by the SOI structure and configured and arranged to receive and pass a fluid including the target materials, and a semiconductor device including at least three electrically-contiguous semiconductor regions doped to exhibit a common polarity. The semiconductor regions include a sandwiched region sandwiched between two of the other semiconductor regions, and configured and arranged adjacent to the fluidic channel with a surface directed toward the fluidic channel for coupling to the target materials in the fluidic channel, and further arranged for responding to a bias voltage. The sensing apparatus also includes an amplification circuit in or on the SOI and that is arranged to facilitate sensing of the target material near the fluidic channel.

Abstract: 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.

Abstract: 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.

Abstract: 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.