Abstract: A purified water manufacturing device monitoring system includes: a detecting device that illuminates, with an inspection beam, water either that is in a process of being manufactured or that has been manufactured by a purified water manufacturing device, detects light in a region illuminated by the inspection beam, and detects a microorganism or a non-microorganism particle included in the water; a measured value specifying portion that specifies a measured value for a number of microorganisms detected and specifies a measured value for a number of non-microorganism particles detected; and a state evaluating portion that evaluates that a problem has occurred in the purified water manufacturing device when either or both the measured value for the number of microorganisms and the measured value for the number of non-microorganism particles are greater than a prescribed value.

Abstract: A purified water manufacturing device monitoring system includes: a detecting device that illuminates, with an inspection beam, water either that is in a process of being manufactured or that has been manufactured by a purified water manufacturing device, detects light in a region illuminated by the inspection beam, and detects a microorganism or a non-microorganism particle included in the water; a measured value specifying portion that specifies a measured value for a number of microorganisms detected and specifies a measured value for a number of non-microorganism particles detected; and a state evaluating portion that evaluates that a problem has occurred in the purified water manufacturing device when either or both the measured value for the number of microorganisms and the measured value for the number of non-microorganism particles are greater than a prescribed value.

Abstract: A particle detecting system includes an airborne particle detecting device that detects scattered light and/or fluorescent light produced through illuminating with light a particle included in a gas, a gas inspection flow path that introduces, into the airborne particle detecting device, a particle included in a gas that is subject to inspection, an aerosol generating portion that generates an aerosol from a liquid that is subject to inspection, and a liquids inspection flow path that introduces a particle included in the aerosol into the airborne particle detecting device.

Abstract: A virtual impactor includes a jet nozzle that jets, from a jet outlet, a gas that contains particles, an opposing nozzle that is disposed with a specific separation distance from the jet nozzle and draws in, as a secondary flow, from a vacuum inlet at one end portion, a portion of the gas that is jetted from the jet nozzle, and a variable mechanism that varies at least one of a width of the jet outlet, the specific distance, and a width of the vacuum inlet.

Abstract: A microorganism detecting system includes: a microorganism detecting device that detects microorganisms included in the air through drawing in air and directing light into the air; at least one chamber that stores a culture medium for trapping microorganisms illuminated with light by the microorganism detecting device; and an opening/closing device that connects, when a microorganism is detected, or blocks, when no microorganism is detected, a path connecting the microorganism detecting device and the at least one chamber.

Abstract: The present invention relates to a process for the manufacturing of solid supports functionalized by saccharide type molecules (glycochips or carbohydrate arrays or alternatively oligosaccharide arrays). The present invention also relates to the glycochips directly obtained by such a manufacturing process and to their use, in particular for biological analysis and especially for the screening of saccharides or proteins such as Hepatocyte Growth Factors (HGFs) or for the study of saccharides/proteins interactions.

Abstract: An environment providing device having a test chamber; a spraying device for receiving the supply of a gas flow to spray, into the test chamber, a fluid that contains particles; a flow meter for measuring a measured value for the flow rate of the gas flow that is supplied to the spraying device; a flow rate controlling device for controlling to a prescribed value, based on the measured value, the flow rate of the gas flow that is supplied to the spraying device; a timer for measuring a time interval over which the fluid that includes the particles has been sprayed into the test chamber; and a spraying-device-controlling device for stopping the spraying of the fluid that contains the particles after spraying a prescribed quantity of particles into the test chamber.

Abstract: A particle detecting device evaluating system having a test chamber provided, in one face thereof, with a plurality of gas intake vents, where respective particle detecting devices are provided; an injecting device for injecting particles into the test chamber; a light sheet forming device for forming a light sheet within the test chamber; and an imaging device for imaging particles made visible by the light sheet.

Abstract: A particle detecting system includes an airborne particle detecting device that detects scattered light and/or fluorescent light produced through illuminating with light a particle included in a gas, a gas inspection flow path that introduces, into the airborne particle detecting device, a particle included in a gas that is subject to inspection, an aerosol generating portion that generates an aerosol from a liquid that is subject to inspection, and a liquids inspection flow path that introduces a particle included in the aerosol into the airborne particle detecting device.

Abstract: A particle counter testing method includes the steps for storing particles in a container, blowing a compressed gas through an inlet flow path, through a wall of the container, into the particles that are stored within the container, spraying the particles that are blown by the compressed gas to outside of the container through a nozzle that is provided on the container, and measuring the number of particles by a particle counter. In the method, an outer shape of the nozzle is a conical shape. The compressed gas is blown into the container through an inlet flow path so that a pressure of a sprayed aerosol gas flow that includes particles is lower than a pressure of a surrounding gas.

Abstract: A microorganism detecting device is provided for illuminating a solution with light, for detecting fluorescent light that is produced by a microorganism included in the solution, and for detecting the number of microorganisms included in the solution. The microorganism detecting device includes a relationship storing device that stores a correlation relationship between a number of microorganisms in a solution and a number of colonies formed by the microorganisms on a culture medium, and a converting portion that uses the correlation relationship to convert, into a number of colonies that may be formed, the number of microorganisms detected by the microorganism detecting device.

Abstract: A virtual impactor includes a jet nozzle that jets, from a jet outlet, a gas that contains particles, an opposing nozzle that is disposed with a specific separation distance from the jet nozzle and draws in, as a secondary flow, from a vacuum inlet at one end portion, a portion of the gas that is jetted from the jet nozzle, and a variable mechanism that varies at least one of a width of the jet outlet, the specific distance, and a width of the vacuum inlet.

Abstract: A particle condensing apparatus includes a gas-borne particle condensing device that condenses a gas that includes gas-borne particles. The gas-borne particle condensing device includes a cyclone portion that causes a supplied first gas to swirl along an inner wall face to cause centrifugal force to act on particles in the first gas to produce a second gas with a relatively high particle concentration and a third gas with a low particle concentration. A fluorocarbon polymer film is formed on an inner wall face of the cyclone portion.

Abstract: A substrate for biochips is manufactured so that the substrate has a substrate surface having a reaction region capable of reacting with biological substances and a non-reaction region not reacting with the biological substances, sunken bottomed wells formed in the substrate surface, and a layer of a material capable of reacting with the biological substances having a surface exposed only at the bottoms of the bottomed wells, the exposed surface forming the reaction region.

Abstract: A base plate having a surface on which a plurality of hydroxyl groups can be introduced, a metallic membrane disposed on the base plate and having a plurality of wells reaching the base plate, and a crosslinkable polymer membrane disposed on the metallic membrane are included.

Abstract: A base plate having a surface on which a plurality of hydroxyl groups can be introduced, a metallic membrane disposed on the base plate and having a plurality of wells reaching the base plate, and a crosslinkable polymer membrane disposed on the metallic membrane are included.

Abstract: A substrate for biochips is manufactured so that the substrate has a substrate surface having a reaction region capable of reacting with biological substances and a non-reaction region not reacting with the biological substances, sunken bottomed wells formed in the substrate surface, and a layer of a material capable of reacting with the biological substances having a surface exposed only at the bottoms of the bottomed wells, the exposed surface forming the reaction region.

Abstract: A substrate for biochips has a substrate surface having a reaction region capable of reacting with biological substances and a non-reaction region not reacting with the biological substances, sunken bottomed wells formed in the substrate surface, and a layer of a material capable of reacting with the biological substances having a surface exposed only at the bottoms of the bottomed wells, the exposed surface forming the reaction region.

Abstract: A base plate having a surface on which a plurality of hydroxyl groups can be introduced, a metallic membrane disposed on the base plate and having a plurality of wells reaching the base plate, and a crosslinkable polymer membrane disposed on the metallic membrane are included.

Abstract: The present invention relates to a process for the manufacturing of solid supports functionalized by saccharide type molecules (glycochips or carbohydrate arrays or alternatively oligosaccharide arrays). The present invention also relates to the glycochips directly obtained by such a manufacturing process and to their use, in particular for biological analysis and especially for the screening of saccharides or proteins such as Hepatocyte Growth Factors (HGFs) or for the study of saccharides/proteins interactions.