A fluid handling device, comprising: a substrate including a first channel, a second channel and a partition wall formed between the first channel and the second channel; a film including a diaphragm, the film being disposed on the substrate so that the diaphragm faces the partition wall; and a sliding member slidable on the film while contacting with the film, the sliding member including a protrusion formed on an underside thereof, and the sliding member being disposed on the film with the underside facing the film, wherein: the sliding member is capable of switching between a first state and a second state by sliding on the film, wherein the protrusion is positioned so as not to face the partition wall with the diaphragm therebetween in the first state, and the protrusion is positioned so as to face the partition wall with the diaphragm therebetween in the second state.

Provided is microparticle extraction technology capable of stably extracting only a target microparticle at high speed from a sheath flow flowing through a flow path.

A particle extraction apparatus includes: a first extraction unit for extracting, from a whole sample containing a target particle, an extraction sample containing the target particle without performing abort processing; and a second extraction unit for subjecting the extraction sample to abort processing and extracting only the target particle.

Provided is microparticle extraction technology capable of stably extracting only a target microparticle at high speed from a sheath flow flowing through a flow path.

A particle extraction apparatus includes: a first extraction unit for extracting, from a whole sample containing a target particle, an extraction sample containing the target particle without performing abort processing; and a second extraction unit for subjecting the extraction sample to abort processing and extracting only the target particle.

An analysis device includes a turntable holding a substrate, an optical pickup driven in a direction perpendicular to a rotation axis of the turntable and configured to emit laser light to reaction regions and to receive reflected light from the respective reaction regions, an optical pickup drive circuit, and a controller. The reaction regions are formed at positions different from the center of the substrate. The center of the substrate is located on the rotation axis of the turntable. The optical pickup detects a reception level of the reflected light to generate a light reception level signal. The controller controls a turntable drive circuit to rotate the substrate, controls the optical pickup drive circuit to drive the optical pickup, and specifies the respective reaction regions in accordance with a positional information signal and the light reception level signal.

An analysis device includes a turntable holding a substrate, an optical pickup driven in a direction perpendicular to a rotation axis of the turntable and configured to emit laser light to reaction regions and to receive reflected light from the respective reaction regions, an optical pickup drive circuit, and a controller. The reaction regions are formed at positions different from the center of the substrate. The center of the substrate is located on the rotation axis of the turntable. The optical pickup detects a reception level of the reflected light to generate a light reception level signal. The controller controls a turntable drive circuit to rotate the substrate, controls the optical pickup drive circuit to drive the optical pickup, and specifies the respective reaction regions in accordance with a positional information signal and the light reception level signal.

An automatic analysis device includes a reagent container, a reagent disk for holding the reagent container, a dispensing mechanism for dispensing a solution into the reagent container, an inversion mixing mechanism for subjecting the reagent container to inversion mixing, and a control unit for controlling the dispensing mechanism and the inversion mixing mechanism. The inversion mixing mechanism has a rotating mechanism for rotating the reagent container and a tilting mechanism for tilting a rotating shaft of the reagent container. The reagent container has a lid which can be pierced. The lid has a tubular mechanism having an opening part formed at the tip end and extending inside the reagent container. The control unit controls the dispensing conditions of the dispensing mechanism.

A fluid-handling system has: a reservoir; a channel chip; and a cap in which a first end is fitted into an opening of the reservoir and a second end is connected to an introduction port of the channel chip, the cap having a through hole connecting the first end and the second end. The reservoir has a first engaging part, and the channel chip has a second engaging part. The first engaging part of the reservoir and the second engaging part of the channel chip are in a first engaging state when the cap is closed. The first engaging part of the reservoir and the second engaging part of the channel chip are in a second engaging state when the cap is open.

To reduce optical noise in fluorescence measurement. A biochip 110 for fluorescence measurement includes a transparent substrate 111, multiple microlenses 112 dispersively formed on a first surface 111a of the transparent substrate 111, multiple protruding portions 113 formed corresponding one-to-one with the microlenses 112 on a second surface 111b of the transparent substrate 111, and a fluorescence measurement site 114 formed at a top portion of each protruding portion 113.

To provide a single particle capture technique that can shorten cell capture time without damaging a cell.

The present technology provides a particle capture device including: a particle capture unit having a particle capture region including a plurality of wells that captures particles, and dividing a space into a first space and a second space; a particle supply channel which is connected to the first space and through which a fluid containing the particles is supplied; a first discharge channel which is connected to the first space and through which a fluid is discharged from the first space; and a second discharge channel which is connected to the second space and through which a fluid is discharged from the second space, in which the particles are captured in the wells by simultaneous discharge of fluids from the first discharge channel and the second discharge channel.

A technology for efficiently discharging a bubble present in a fluid in a chamber is provided.

There is provided a bubble discharging method carried out in a chamber including a microchip that includes at least one well or through hole to divide a space into a first space and a second space, the bubble discharging method including: a pressurizing step of applying a positive pressure to a fluid in the chamber; and a valve opening/closing step of operating a valve for opening/closing a first flow path connected to the first space and/or a second flow path connected to the second space.