A method for performing microscopy-based imaging of samples comprises: loading a sample holder (100) onto a support (50) configured to receive the sample holder (100); moving the sample holder (100) in a first direction, from a starting position on a first strip of the sample holder (100), to move the sample holder (100) relative to an imaging line of a line camera (10), to capture an image of the first strip of the sample holder (100); monitoring a focal plane using an autofocus system (15) as the sample holder (100) is moved in the first direction; in response to a signal from the autofocus system (15), moving an objective lens (25) along the optical axis to adjust the focal plane; and moving the sample holder (100) in a second direction, to align the imaging line of the line camera (10) with a position on a second strip of the sample holder (100).

Provided is a synthetic quartz glass substrate for use in a microfluidic device to which bonding by optical contact can be applied in manufacturing a microfluidic device, and which has high adhesion in a bonded interface and does not cause defects such as non-bonding and breakage of the substrate and a defect in which air bubbles are sandwiched at the bonded interface.

A synthetic quartz glass substrate for use in a microfluidic device, wherein a maximum value of a cyclic average power spectral density at a spatial frequency of 0.4 mm.sup.−1 or more and 100 mm.sup.−1 or less is 5.0×10.sup.15 nm.sup.4 or less, the maximum value being obtained by measuring any given region of 6.0 mm×6.0 mm on a surface of the synthetic quartz glass substrate with a white interferometer.

Magnetic beads having cell components of interest are translated between a sequence of processing wells in a tray without need for pipetting. The circular tray contains one or more sequences of wells each interconnected by a respective channel. The tray is rotated about a central axis and a magnet, an agitator, and a heater provided external to the tray enable magnetic bead translation, mixing, and incubation, respectively. The magnet proximate a well forms a cluster of beads. Manipulation of the tray in rotation and elevation results in translation of the cluster from one well, through a channel, and into an adjacent well. The well containing a cluster may be rotationally positioned in front of the agitator, the agitator extended into contact with the well, followed by mechanical agitation. The heater, disposed beneath the tray, may accept a well lowered thereto for selective heating.

A liquid handling device having an axis of rotation about which the device can be rotated to drive liquid flow. The device includes a vented upstream chamber having an outlet port and an unvented chamber including an inlet port to receive liquid from the outlet port of the upstream chamber and an outlet port radially outward the inlet port. The device further includes a vented downstream chamber having an inlet port to receive liquid from the outlet port of the unvented chamber. A downstream conduit connects the outlet port of the unvented chamber to the inlet port of the downstream chamber and includes a bend radially inward of the outlet port of the unvented chamber. An upstream conduit connects the outlet port of the upstream chamber to the inlet port of the unvented chamber.

The invention relates to a discoid sample holder (1), on which a device (2) for carrying out at least one processing step is formed. According to the invention, a slot (3), into which a sampling instrument (4) can be introduced, and means (5) for releasing a sample from the sampling instrument (4) arranged in the receptacle (3), are formed in the sample holder.

The present invention relates to methods of conducting cholinesterase inhibition assays. In one instance, the assays can be configured to determine the presence of inactivated and activated cholinesterases. Also described herein are microfluidic devices and systems for conducting such assays.

A rotor assembly includes a rotor plate to rotate around a first axis, a bucket attached to the rotor plate and to rotate around a second axis, and a stop plate to rotate around the first axis between an open position and a closed position. When in the closed position, the stop plate engages the bucket to fix an angular position of the bucket relative to a plane of rotation of the rotor assembly. The rotor assembly further includes a housing for a sensor array component, the housing disposed in the bucket and including a solution inlet, a solution outlet, a transfer basin, a solution retainer disposed between the solution outlet and the transfer basin, and a collection reservoir in fluid communication with the transfer basin. The solution inlet and the solution outlet to engage ports of a flow cell of a sensor array.

The present invention discloses a kind of centrifugal detection channel, including: a first chamber, at least one inlet channel, at least one buffer valve, at least one outlet channel, and a second chamber. Specifically, at least one inlet channel is connected to the first chamber. At least one buffer valve is connected to the inlet channel, including: a valve body and a transient chamber. At least one outlet channel is connected to the buffer valve. At least one second chamber is connected to the outlet channel. In addition, the detection devices and the detection methods comprising the centrifugal detection channel have also been proposed.

The present invention discloses a nucleic acid extraction apparatus and a method using the apparatus for extracting nucleic acids and amplifying target nucleic acids. The nucleic acid extraction apparatus comprising: a nucleic acid extraction element, a waste storage chamber, and a reaction chamber, wherein the reaction chamber is selectively in communication with the nucleic acid extraction element and the waste storage chamber, and the apparatus realizes fluid exchange through the pressure between the waste storage chamber and the reaction chamber. In the present invention, by using an integrated control system, the conventional manual process of nucleic acid extraction and purification is integrated into a fully automatic closed process, making the operation more conveniently and quickly and improving the efficiency of experimental work.

A method of performing an optical measurement of an analyte in a processed biological sample using a cartridge is provided. The cartridge is operable for being spun around a rotational axis. The method comprises: placing the biological sample into a sample inlet; controlling the rotational rate of the cartridge to process a biological sample into the processed biological sample using a fluidic structure; controlling the rotational rate of the cartridge to allow the processed biological sample to flow from the measurement structure inlet to an absorbent structure via a chromatographic membrane, and performing an optical measurement of a detection zone on the chromatographic membrane with an optical instrument. An inlet air baffle reduces evaporation of the processed biological sample from the chromatographic membrane during rotation of the cartridge.