A microorganism collection device comprises: (a) a base, the base comprising (i) a reservoir comprising a bottom and a side wall extending up from the bottom, (ii) a culture medium within the reservoir, the culture medium disposed upon the bottom of the reservoir and comprising a top surface that is elevated from the bottom higher than the side wall of the reservoir, (iii) a first tab extending laterally outward relative to the reservoir; and (b) a lid comprising (i) an associated state where the lid is covering the culture medium and (ii) a dissociated state where the lid is separated from the base and not covering the culture medium.

A microorganism collection device comprises: (a) a base, the base comprising (i) a reservoir comprising a bottom and a side wall extending up from the bottom, (ii) a culture medium within the reservoir, the culture medium disposed upon the bottom of the reservoir and comprising a top surface that is elevated from the bottom higher than the side wall of the reservoir, (iii) a first tab extending laterally outward relative to the reservoir; and (b) a lid comprising (i) an associated state where the lid is covering the culture medium and (ii) a dissociated state where the lid is separated from the base and not covering the culture medium.

A lab-on-chip type system, capable of identifying antibiotic sensitivity at the point of care of patients, especially in rural areas, clinics, hospitals that do not have care 24/7, hospitals with low level of equipment, among others, from the extraction of a sample, comprising a micro device or medical base device and a dispenser, wherein said micro device comprises a plurality of microwells, arranged in a circular fashion on one of the faces of the micro device, and wherein the micro-dispenser comprises a central plunger for taking and supplying the sample, a chamber for storage and distribution of the sample and a plurality of microdispensers arranged in a circular manner through which the sample is introduced into the microwells of the micro device.

A device for sampling microorganisms comprising a hollow probe that can be inserted into a growth substrate or water system, the probe containing a growth medium for microorganisms wherein the growth medium contains a chemoattractant particularly a plant pathogen chemoattractant wherein the growth medium is specific for the microorganism/microorganisms which a grower wishes to know if they are present in the growth substrate or water system.

The invention relates to a device for obtaining biological material and/or biological information from a sample with a heterogeneous matrix, to the uses of said device, to methods implementing said device, and to kits for obtaining biological material and/or biological information from a sample with a heterogeneous matrix, comprising the different constituents of said device.

Devices and methods for isolating and characterizing microbial cells from an environment are provided. The devices integrate sub-micron constrictions in a nanofluidic device with a standard microtiter plate format to facilitate the high throughput isolation, culturing, analysis, and screening of bacteria and other microbial cells in natural and man-made environments, particularly environments containing microbes adhered on particulate matter.

A container system includes a flexible bag bounding a chamber. A probe port includes an elongated tubular member having an interior surface bounding a first passageway and extending between a first end and an opposing second end, the first passageway being closed at the first end and open at the second end; and a flange encircling and radially outwardly projecting from the tubular member at or toward the second end thereof, the flange being secured to the flexible bag so that the first end of the elongated tubular member projects into the chamber of the flexible bag while the open second end of the elongated tubular member is accessible from outside of the flexible bag. A probe is received within the first passageway of the probe port.

A container system includes a flexible bag bounding a chamber. A probe port includes an elongated tubular member having an interior surface bounding a first passageway and extending between a first end and an opposing second end, the first passageway being closed at the first end and open at the second end; and a flange encircling and radially outwardly projecting from the tubular member at or toward the second end thereof, the flange being secured to the flexible bag so that the first end of the elongated tubular member projects into the chamber of the flexible bag while the open second end of the elongated tubular member is accessible from outside of the flexible bag. A probe is received within the first passageway of the probe port.

A cell isolation method includes: a cell trapping step of allowing a test liquid to pass through a cell trapping filter which has a plurality of through-holes in the thickness direction, thereby trapping isolation target cells contained in the test liquid on one surface of the cell trapping filter; a gel embedding step of introducing a stimulus-responsive hydrogel onto the one surface of the cell trapping filter on which the cells have been trapped in the cell trapping step, thereby embedding the cells in the stimulus-responsive hydrogel; a gel hardening step of applying a stimulus to the stimulus-responsive hydrogel in which the cells are embedded, thereby hardening the stimulus-responsive hydrogel; and a detachment step of detaching the stimulus-responsive hydrogel that was hardened in the gel hardening step from the cell trapping filter.

A cell isolation method includes: a cell trapping step of allowing a test liquid to pass through a cell trapping filter which has a plurality of through-holes in the thickness direction, thereby trapping isolation target cells contained in the test liquid on one surface of the cell trapping filter; a gel embedding step of introducing a stimulus-responsive hydrogel onto the one surface of the cell trapping filter on which the cells have been trapped in the cell trapping step, thereby embedding the cells in the stimulus-responsive hydrogel; a gel hardening step of applying a stimulus to the stimulus-responsive hydrogel in which the cells are embedded, thereby hardening the stimulus-responsive hydrogel; and a detachment step of detaching the stimulus-responsive hydrogel that was hardened in the gel hardening step from the cell trapping filter.