The invention relates to a system is provided that comprises a first container, a second container and a fluorescence detection device. The first container comprises a first set of chemicals and/or agents and is closed prior to use. The second container comprises a second set of chemicals and/or agents that are at least in part distinct from the chemicals and/or agents of the first set. The first container comprises a lid, that can be opened when the first container and the second container are combined to form a single, fluid tight assembly, in order to allow the contents of the first container to enter the second container.

The invention concerns a filtration assembly (1) for microbiological testing and a method of using the filtration assembly for that purpose. The filtration assembly (1) comprises a ring-like membrane support (10) holding a filtration membrane (11), a cylindrical reservoir (20) of which opposite axial ends have openings and one axial opening is removably and fluid-tightly attachable to the membrane support (10) to define a sample volume adjacent to the filtration membrane (11) on one axial side of the membrane support (10); and a drain member (30) removably and fluid tightly attachable to the membrane support (10) to define a drain channel space adjacent to the filtration membrane (11) on an opposite axial side of the membrane support (10).

An extraction device includes an extraction container including a discharge port and capable of storing a biological sample and an extractant, a discharge accelerator configured to discharge the biological sample extracted into the extractant in the extraction container from the discharge port, and a controller configured to instruct the discharge accelerator to discharge the biological sample from the discharge port.

A transfer container for a fluid includes a tube, the tube including a conical portion at one end, the tube defining an interior space and one or more fluid passages configured to allow flow of fluid into or out of the interior space of the tube. The transfer container also includes a connector configured to seal the end of the conical portion when the connector is joined only to the conical portion and a pressure control mechanism configured to increase or decrease a pressure in the interior space of the tube. The transfer container can be used in a method including connecting fluid lines to the fluid passages, adding a fluid including cryoprotectant and cells, centrifuging the transfer container, and then connecting the transfer container to a second fluid transfer container containing another fluid. This allows the sterile transfer of fluids and separation of cells from cryoprotectant.

Embodiments of the present disclosure provide a target capturing apparatus and a manufacturing method thereof, and a target detecting method. The target capturing apparatus includes a cavity structure, the cavity structure includes: an inlet portion, an outlet portion and a capture region positioned between the inlet portion and the outlet portion, and the capture region includes a capture component, and a combination specifically combined with a to-be-captured target is included in the capture component so as to capture the target in a sample entering the cavity structure.

Provided is a magnetic signal detection chip. Each flow sensing component thereof includes lead portions and notch portion(s) located between the adjacent lead portions, wherein the notch portion(s) is(are) located in the flow path and at least a part of each lead portion adjacent to the notch portion is exposed to the chemical fluid, so that the flow sensing component(s) is(are) conducted when the chemical fluid completely covers the notch portion(s). Thus one could regulate the processing steps according to the sensing results of the flow sensing component, which can avoid inaccurate detection results. Further provided is a detection card including the magnetic signal detection chip and further provided is a nucleic acid detection device including the detection card. Further provided is a method of detecting composition containing target DNA fragment in chemical fluid.

A sample pretreatment tube includes a first tube receiving a primary reagent and a second tube receiving a secondary reagent, wherein the sample pretreatment tube can easily perform sequential reactions by allowing a primary reaction solution to be immediately discharged from the first tube to the second tube by breaking a separation membrane formed at a lower end of the first tube using a pipette, and can limit an insertion depth of the pipette using a stopper formed inside the first tube, thereby preventing damage to the second tube due to the pipette while allowing a space to be formed inside the first tube to facilitate discharge of a primary reaction solution, thus making it possible to immediately perform secondary reaction.

The present disclosure provides methods of preparing a biological specimen for imaging analysis, comprising fixing and clearing the biological specimen and subsequently analyzing the cleared biological specimen using microscopy. Also included are methods of quantifying cells, for example, active populations of cells in response to a stimulant. The present disclosure also provides devices for practicing the described methods. A flow-assisted clearing device provides rapid clearing of hydrogel-embedded biological specimens without the need of specialized equipment such as electrophoresis or perfusion devices.

A method of analyzing and/or sorting selected cells or other biological components, for example for cell-based therapy, includes sampling a sample with an open end of a probe to obtain a fluid stream with the sample in it. The probe with the open end also has a fluid supply to convey fluid to the open end, and a fluid exhaust to convey the fluid stream away from the open end. The method then includes conveying the fluid stream to a flow cytometer and analyzing the fluid stream by flow cytometry; and/or separating it into at least two components. An apparatus with the probe connected to the flow cytometer may support this method. The method can provide for sampling of multiple samples efficiently, in particular to select cells for cell-based therapies.

The transfer systems, devices, kits, and methods described here may be used to facilitate the transfer of a material (e.g., a fluid) to or from a donor container, e.g., to or from wells of a donor plate while leaving target agents attached to the wells. The systems may comprise a donor plate, a transfer adapter, and a receiver plate that may be coupled to form a transfer assembly. The transfer adapter may comprise a planar sheet and a plurality of openings, and it may be configured to regulate the flow of fluid out of the wells. The transfer assembly may be placed into a centrifuge, and the fluid transfer force produced by the centrifuge may cause fluid to flow out of the wells of the donor plate, through the openings in the transfer adapter, and into the receiver plate.