摘要:
A chilled reagent container comprises a reagent vessel containing part for containing therein a plurality of reagent vessels, a container lid including a container lid hole through which the reagent vessels contained by the reagent vessel containing part are accessible, and a cooling block for cooling the reagent vessels contained by the reagent vessel containing part, wherein the container lid slides to be changeable between an opened situation wherein the reagent is accessible from an outside and a closed situation wherein the reagent is prevented from being accessed from the outside, wherein the chilled reagent container further comprises a reagent container packing including another hole through which the reagent vessels are accessible and arranged between the container lid and the reagent vessel containing part to be pressed against the container lid.
摘要:
The present invention has an object to provide a method for efficiently detecting an image with a smaller number of pixels.The invention relates to fluorescence analysis which uses a substrate having a plurality of regions for being capable of immobilizing biologically-related molecules in positions of lattice points of a lattice structure, and which causes the fluorescence from a certain lattice point to be wavelength-dispersed in a direction other than the direction toward the adjacent closest lattice point. According to an embodiment, for example, the number of pixels of a two-dimensional sensor required for fluorescence analysis of the regions with the biologically-related molecules immobilized can be set to several hundred times to fifty times smaller than that in the conventional case without degrading the measurement accuracy. This can achieve the improvement of throughput, reduction in price, and/or improvement of the operability of an analyzing device.
摘要:
A chilled reagent container comprises a reagent vessel containing part for containing therein a plurality of reagent vessels, a container lid including a container lid hole through which the reagent vessels contained by the reagent vessel containing part are accessible, anda cooling block for cooling the reagent vessels contained by the reagent vessel containing part, wherein the container lid slides to be changeable between an opened situation wherein the reagent is accessible from an outside and a closed situation wherein the reagent is prevented from being accessed from the outside, wherein the chilled reagent container further comprises a reagent container packing including another hole through which the reagent vessels are accessible and arranged between the container lid and the reagent vessel containing part to be pressed against the container lid.
摘要:
Compounds, pharmaceutical compositions and methods that are useful in the treatment or prevention of metabolic and cell proliferative diseases or conditions are provided herein. In particular, the invention provides compounds which modulate the activity of proteins involved in lipid metabolism and cell proliferation.
摘要:
An object of the present invention is to provide an analytical method and an analytical instrument with high capability of quantitative determination and reproducibility which can be used for detecting the minor difference between expression levels and measuring the protein concentration, for example. An analytical method for a biological sample is disclosed, wherein two or more labels are present in the same area, and the signal intensity of one specific label is used to normalize the signal intensity of other labels. An analytical instrument, a microarray, and an immunoassay are also disclosed.
摘要:
The interior of a vacuum chamber is maintained at a specified pressure by introducing a specified gas into the vacuum chamber having a plasma trap provided therein. Simultaneously, therewith, evacuation of the chamber is performed by a pump as an evacuating device, and a high-frequency power of 100 MHz is supplied to a counter electrode by counter-electrode use high-frequency power supply. Thus, uniform plasma is generated within the vacuum chamber, where plasma processing such as etching, deposition, and surface reforming can be carried out uniformly with a substrate placed on a substrate electrode.
摘要:
The interior of a vacuum chamber is maintained at a specified pressure by introducing a specified gas into the vacuum chamber having a plasma trap provided therein. Simultaneously, therewith, evacuation of the chamber is performed by a pump as an evacuating device, and a high-frequency power of 100 MHz is supplied to a counter electrode by counter electrode use high-frequency power supply. Thus, uniform plasma is generated within the vacuum chamber, where plasma processing such as etching, deposition, and surface reforming can be carried out uniformly with a substrate placed on a substrate electrode.
摘要:
Provided is an analyzer capable of reducing the amount of wasted reagents and shortening time required for solution sending, thus increasing throughput for analysis. A microsyringe sucks a minimum required amount of reagent that is substantially the same amount of capacity of a flow cell to a sampling nozzle. Then, the sampling nozzle is inserted into an injection port of the flow cell, and the reagent is injected into the flow cell by driving the microsyringe. The inside of the sampling nozzle is cleaned by moving the sampling nozzle to the cleaning tank and ejecting cleaning water from the sampling nozzle, and the outside of the sampling nozzle is cleaned by spraying cleaning water from an inner wall of the cleaning tank.
摘要:
A process for producing a photovoltaic device that can improve the power generation characteristics of a solar cell having a heterojunction composed of a p-type crystalline Ge (substrate), an i-type amorphous silicon semiconductor layer, and an n-type amorphous silicon semiconductor layer. A process for producing a photovoltaic device (100) comprising a heterojunction cell (1) prepared by sequentially stacking an i-type amorphous silicon semiconductor layer (12) and an n-type amorphous silicon semiconductor layer (13) on top of a substrate (p-type crystalline Ge (11)), the process comprising a PH3 exposure treatment stage of adjusting the temperature of the substrate (11), from which a surface oxide film has been removed, to a prescribed temperature, and subsequently placing the substrate in a vacuum chamber and exposing the substrate to PH3, an i-layer deposition stage of depositing the i-type amorphous silicon semiconductor layer (12) on the PH3-exposed substrate, an n-layer deposition stage of depositing the n-type amorphous silicon semiconductor layer (13) on the i-type amorphous silicon semiconductor layer (12), and an electrode formation stage of forming electrodes (2, 3, 4) on the surface of the n-type amorphous silicon semiconductor layer, and on the back surface of the substrate (11).
摘要:
A process for producing a photovoltaic device that can improve the power generation characteristics of a solar cell having a heterojunction composed of a p-type crystalline Ge (substrate), an i-type amorphous silicon semiconductor layer, and an n-type amorphous silicon semiconductor layer. A process for producing a photovoltaic device (100) comprising a heterojunction cell (1) prepared by sequentially stacking an i-type amorphous silicon semiconductor layer (12) and an n-type amorphous silicon semiconductor layer (13) on top of a substrate (p-type crystalline Ge (11)), the process comprising a PH3 exposure treatment stage of adjusting the temperature of the substrate (11), from which a surface oxide film has been removed, to a prescribed temperature, and subsequently placing the substrate in a vacuum chamber and exposing the substrate to PH3, an i-layer deposition stage of depositing the i-type amorphous silicon semiconductor layer (12) on the PH3-exposed substrate, an n-layer deposition stage of depositing the n-type amorphous silicon semiconductor layer (13) on the i-type amorphous silicon semiconductor layer (12), and an electrode formation stage of forming electrodes (2, 3, 4) on the surface of the n-type amorphous silicon semiconductor layer, and on the back surface of the substrate (11).