A particle capturing device including a substrate, a particle capturing film configured to capture particles, and a support configured to support the particle capturing film when tension is applied to the particle capturing film such that the particle capturing film is in parallel with the substrate and a space is formed between the particle capturing film and the substrate.

The present invention relates to a filter device for capturing a target cell and a target cell collecting method using the same. A filter substrate by which a target cell is captured is formed of an elastic material. When blood passes, the size of a lattice hole of the filter substrate by which the target cell is captured is reduced. When the blood completely passes, the size of the lattice hole of the filter substrate by which the target cell is captured is restored, so that a destruction rate of the target cell may be reduced and a collect rate of the target cell may be increased.

A purpose is to provide a monitoring system to monitor whether there is a substance to be monitored in the air, and a detecting device used in the monitoring system. The monitoring system includes a detecting device, an analyzing device, and an abnormality notification system. The detecting device determines whether the air is in an abnormal state on the basis of an output signal from an abnormality detection sensor, pours liquid to be inspected, into which the air is sucked and liquefied, into a previously-installed reagent container when determining the abnormal state, generates mixed liquid in which a reactant in the reagent container and the poured liquid to be inspected are mixed, and drops the generated mixed liquid to an electrode of the analyzing device. The analyzing device determines existence/non-existence of a substance to be monitored on the basis of the mixed liquid dropped to the electrode, and gives a predetermined notification to the abnormality notification system when determining that there is the substance to be monitored. The abnormality notification system gives a predetermined notification when receiving the notification from the analyzing device.

The present disclosure relates to a culturing patch, culturing method, culture test method, culture test device, drug test method, and drug test device, and the culturing patch according to an aspect of the present disclosure includes component required for growth of an object to be cultured, and a mesh structural body provided in a mesh structure forming micro-cavities in which the component required for growth are contained that is configured to come into contact with a reaction region in which the object to be cultured is placed and provide some of the contained component required for growth to the reaction region.

A testing method that includes the steps of evacuating air from a container to a negative atmospheric pressure, the container being a collapsible, flexible container, and comprising at least two opposing flexible walls, wherein a surface of at least one of the walls internal to the container comprises a plurality of channels or recessed features on said at least one wall and monitoring a mass flow or a state of vacuum so as to determine the integrity of the container. The container can be of any size or conformation, with or without attached fittings.

A collection device is disclosed having a tubular housing detachably receiving a valved bulb reservoir at a first end thereof, the housing having a second end for dispensing fluids. The valved bulb reservoir has a sample capillary tube attached at one end thereof. The bore of the capillary is fluidically coupled to the valved bulb reservoir. The capillary is removed from the tubular housing to collect a sample in its bore, and is then replaced into the tubular housing. The contents of the valved tubular reservoir, which can be a buffer solution, a reagent, or other analytic fluid, or a gas, are then passed through the capillary bore to expel the sample and mix therewith in the housing. The sample product can then be dispensed from the tubular housing.

A sample heating/cooling device (2) comprises a plurality of members (6) operable in use to heat and/or cool one or more samples (22). Each member (6) has a sample contact surface and is biased towards a resting position under the operation of a biasing means. The members (6) are movable independently of one another against said bias under the application of a force on the sample contact surface and so are able to conform to the shape of a sample placed on the members to provide a uniform heating/cooling profile. The members (6) may be mounted in a heating/cooling element (4) and adapted to conduct thermal energy between the sample (22) and the element (4). The device (2) is particularly suitable for thawing frozen sample bags having an irregular shape. A corresponding method is also described.

Specially designed collection strips and their processing. By using specially designed collection strips, having a backer and one or more absorbent pads, in conjunction with a unique processing method, the processes of analyzing biological samples such as blood, or the like, may be done efficiency with the elimination of cross contamination risk. Identification of the sample stays with the sample throughout the process as it resides on the collection strip. The strip absorbs a known volume. The sample with identification is placed directly in an elution solution, without mechanically separating the sample from its identification information. Elimination of the need for mechanical separation tends to reduce cross contamination, as well as reducing sample processing time.

An extraction container includes a molded tubular body having openings at opposing first and second end thereof. A base cap is configured to obstruct a base opening disposed at the base of the tubular body. The base cap is integrally molded with the tubular body and connected thereto by a frangible connection. The base cap can be removed by breaking the frangible connection to de-obstruct the second opening. The first base cap and tubular body include integrally molded engagement features to permit the base cap to be reattached to the tubular body to re-obstruct the base opening. A removable foil or polymer seal obstructs a top opening disposed at the top end of the tubular body. A top cap and hinge are integrally molded with the tubular body and configured to re-obstruct the top opening following removal of the seal.

A high-reliability analyte detection device, includes: a bottom shell ; a sensor, with the sensor being assembled on the bottom shell, the sensor including a signal output end and a detection end, wherein the signal output end is provided with at least two mutually insulated first electrical connection areas, and the signal output end is curved or bent toward the bottom surface of the bottom shell; a transmitter, with the transmitter and the bottom shell being engaged with each other, and the transmitter being provided with at least two mutually insulated second electrical connection areas which correspond to the first electrical connection areas, wherein the first electrical connection areas are electrically connected to the corresponding second electrical connection areas; and an elastic member, with the signal output end being in contact with the elastic member.