Abstract:
Disclosed herein is an optical detector at least including: a first substrate in which a plurality of wells are formed; a second substrate in which a heating section is provided to heat the wells; a third substrate in which a plurality of photoirradiation sections are provided in alignment with the wells; and a fourth substrate in which a plurality of photodetection sections are provided in alignment with the wells.
Abstract:
There is provided a sample liquid injection tool including a reservoir section configured to store a sample liquid, a channel having one end protruding from an outer surface and configured to discharge the sample liquid therein from a protrusion end to an outside, and a heating unit and a filter installed between the reservoir section and the channel to enable passage of the liquid.
Abstract:
Disclosed herein is an optical detector at least including: a first substrate in which a plurality of wells are formed; a second substrate in which a heating section is provided to heat the wells; a third substrate in which a plurality of photoirradiation sections are provided in alignment with the wells; and a fourth substrate in which a plurality of photodetection sections are provided in alignment with the wells.
Abstract:
There is provided a microchip including a plurality of substrate layers, and bonding layers provided at boundary surfaces between the substrate layers and configured to include a silicon compound. At least one of the bonding layers is configured to include an organic silicon compound.
Abstract:
Disclosed herein is an optical detector at least including: a first substrate in which a plurality of wells are formed; a second substrate in which a heating section is provided to heat the wells; a third substrate in which a plurality of photoirradiation sections are provided in alignment with the wells; and a fourth substrate in which a plurality of photodetection sections are provided in alignment with the wells.
Abstract:
A microchip is provided. The microchip includes a substrate structure including a fluid channel configured to contain a sample solution, wherein the fluid channel is maintained at a pressure lower than atmospheric pressure prior to injection of the sample solution into the fluid channel.
Abstract:
Provided is a microchip which enables to easily confirm, from the outside of the microchip, filling of a solution into an analysis region.The microchip includes: an introduction part for introducing a liquid; an analysis region in which a substance contained in the liquid or a reaction product of the substance is analyzed; an indication region to indicate that the analysis region has completely been filled with the liquid; and a flow channel to connect the introduction part, the analysis region, and the indication region. In the microchip, the flow channel is configured in such a manner that an amount of time it takes for the liquid introduced from the introduction part to reach the indication region is longer than an amount of time it takes for the liquid introduced from the introduction part to fill up the analysis region.
Abstract:
Disclosed herein is an optical detector at least including: a first substrate in which a plurality of wells are formed; a second substrate in which a heating section is provided to heat the wells; a third substrate in which a plurality of photoirradiation sections are provided in alignment with the wells; and a fourth substrate in which a plurality of photodetection sections are provided in alignment with the wells.
Abstract:
A liquid injecting jig is provided. The liquid injecting jig includes a jig configuration including a plurality of parts adapted to be in cooperative engagement so as to position a channel within the jig configuration, wherein the jig configuration is adapted to fit an opening through which the channel is adapted to be received so as to expose the channel from the jig configuration. A jig set, a microchip case, and a microchip set are also provided.