Apparatus for extracting organic analytes from a sample comprising a first compressed gas source connected to valving and a sample extraction cell connected to the valving. A pressure regulator is connected to the extraction cell outlet to the pressure regulator. The pressure regulator blocks fluid flow when the pressure at the pressure regulator inlet is below a predetermined pressure and permits fluid flow when above said predetermined pressure. The apparatus is free of operative association with a mechanical pump or with a compressed gas source other than the compressed gas source. An extraction method for using the above apparatus is described.

A biological substance extraction device includes an adsorption container that includes a first flow channel, and seal-tightly holds an adsorbent and a fluid within the first flow channel, and a washing container that includes a second flow channel, and seal-tightly holds a washing liquid and a fluid within the second flow channel, the adsorption container and the washing container being joined to form a flow channel through which a biological substance is moved. The first flow channel and the second flow channel communicate with each other in a state in which an insertion section is inserted into a reception section. The insertion section includes a guide member that extends from the first flow channel to the second flow channel. The guide member forms part of the flow channel between a first inner wall of the first flow channel and a second inner wall of the second flow channel.

Assay cartridges are described that have purification, reaction, and detection zones and other fluidic components which can include sample chambers, waste chambers, conduits, vents, reagent chambers, reconstitution chambers and the like. The assay cartridges are used to conduct multiplexed nucleic acid measurements. Also described are kits including such cartridges, methods of using the same, and a reader configured to analyze an assay conducted using an assay cartridge.

A pipette tip device for use in dispersive SPE. The device includes a pipette tip having a lower barrier, loose sorbent that is freely moveable during the extraction process, and a baffle system that is shaped to disrupt the flow of liquid sample that is aspirated into the pipette tip. The baffle system includes an insert that may be separate from or monolithic with the interior of the pipette tip.

A multi-channel bio-separation system configured to utilize a cartridge that has a individual, separate integrated reagent (i.e., a separation buffer) reservoir dedicated for each separation channel. The multiple channels may have different characteristics, such as different separation medium of different chemistries, different separation length, different channel sizes and internal coatings. In one embodiment, the cartridge does not include integrated detection optics. Not all channels need to be operative. One or more of the channels in the cartridge may be “dummy channels” that are not operative (e.g., not provided with a capillary tube). A capillary tube may be routed between the reservoir/electrode (anode) of one channel to an electrode (cathode) in another channel, thus allowing a longer length of capillary tube to be used to define a longer separation channel to improve resolution.

A method for preparing a sample by utilizing a shearing force in the presence of a size stabilizer to break apart the sample to obtain nucleic acid molecules in a usable size range. Once nucleic acid molecules are obtained, magnetic nanoparticles are used to concentrate and clean the nucleic acid molecules for further testing.

Described is a modular microfluidic device (MMD) for producing an analyte composition from a biological fluid sample, said device comprising: (a) a reagent module (RM) comprising a reagent reservoir containing a reagent and an eluent reservoir containing an eluent, said reagent and eluent reservoirs being coupled to one or more RM microchannels; and (b) a sample preparation module (SPM) comprising a SPM microchannel adapted to couple with the RM microchannel whereby fluid continuity between SPM and RM microchannels is produced on coupling, and: (i) a sample inlet for receiving said biological fluid sample; (ii) an outlet for delivering said analyte composition; (iii) a mixing chamber; (v) a metering chamber; (vi) an eluent chamber; (vii) a valve; (viii) a solid phase extraction element (SPE); and (ix) an aspirator in fluid communication with the sample inlet of the SPM for withdrawing an aliquot of said biological fluid when contained in a sample vessel, said aspirator being operably coupled to a pneumatic fluid level sensor.

The present invention relates to an apparatus (1) and method (2) for automatically preparing liquid-based cytology (LBC) slides (107) by means of filtration comprising of at least one substrate (101) for holding a vial (103) containing specimen, a filter (105) and a slide (107) wherein said substrate (101) is located at a first station (FS); at least one working station (WS) comprises of a working platform (109) connected to said first station (FS) wherein said first station (FS) includes a vertical rotary conveyor system (121) which is flexible, user friendly and capable of providing uniformity of the cell distribution in the homogenous thin-layer LBC slides (107) as well as increase system throughput.

A laser microdissectate specimen collector for a laser microdissection device includes a collecting chamber configured to receive a dissectate. The collecting chamber has, on a specimen side, an opening open to the environment for receiving the dissectate. The collecting chamber also has a first valve. The first valve, in a closed state thereof, forms a closure of the collecting chamber opposite to the opening for retaining the dissectate. A capillary line is connected downstream of the first valve to the collecting chamber such that the capillary line is configured to transport the dissectate out of the collecting chamber.

Methods and devices are provided for sample collection and sample separation. In one embodiment, a device is provided for use with a formed component liquid sample, the device comprising at least one sample inlet for receiving said sample; at least a first outlet for outputting only a liquid portion of the formed component liquid sample; at least a second outlet for outputting the formed component liquid sample at least a first material mixed therein.