The present invention is, in combination, a bone marrow isolation tube and a centrifuge tube. The combination includes a centrifuge tube which defines a tube cavity and includes an upper cylindrical section connected to a lower tapered section which terminates at a bottom reservoir. The isolation tube is adapted to be received within the centrifuge tube cavity. The isolation tube includes a body with a tubular shaped outer surface wherein the interior of the isolation tube defines a lumen which includes an upper cylindrical lumen section and a lower conical lumen section terminating at an orifice. The isolation tube includes at least one wing extending radially outward from the outer surface of the isolation tube. The wing is configured to make contact with the interior surface of the centrifuge tube and wedge the isolation tube into the tapered section of the centrifuge tube during centrifuging. The present invention is also, in combination, a bone marrow isolation tube and a centrifuge tube. The centrifuge tube defines a tube cavity and includes at least two support members defining an insertion space and attached to the interior surface in an upper cylindrical section, the upper cylindrical section connected to a lower tapered section which terminates at a bottom reservoir. The isolation tube is adapted to be received within the insertion space with a flange that is configured to make contact with the support members of the centrifuge tube thereby wedging the isolation tube into the insertion space of the centrifuge tube during centrifuging.

A microfluidic system can include a substrate comprising an elastic material and defining a microfluidic channel. The substrate can have a first set of dimensions defining a thickness of a wall of the microfluidic channel and a second set of dimensions defining a width of the microfluidic channel. A transducer can be mechanically coupled with the substrate. The transducer can be operated at a predetermined frequency different from a primary thickness resonant frequency of the transducer. A thickness and a width of the transducer can be selected based on the first set of dimensions defining the thickness of the wall of the microfluidic channel and the second set of dimensions defining the width of the microfluidic channel.

Microscale and/or mesoscale condenser arrays that can facilitate microfluidic separation and/or purification of mesoscale and/or nanoscale particles and methods of operation are described herein. An apparatus comprises a condenser array comprising pillars arranged in a plurality of columns, wherein a pillar gap greater than or equal to about 0.5 micrometers is located between a first pillar of the pillars in a first column of the columns and a second pillar of the plurality of pillars in the first column, and wherein the first pillar is adjacent to the second pillar. The first ratio can be characterized by D.sub.x/D.sub.y is less than or equal to a first defined value, wherein D.sub.x represents a first distance across the lattice in a first direction, wherein D.sub.y represents a second distance across the lattice in a second direction, and wherein the first direction is orthogonal to the second direction.

A microfluidic device comprising a channel within a substrate and a condenser or a hydrodynamic focusing chamber along the channel, configured to focus a fluid containing particles of a plurality of sizes. A negative angle deterministic lateral displacement (DLD) array is configured to receive the focused fluid and separate the particles in the focused fluid into three sizes ranges. The negative angle DLD array comprises a plurality of rows of pillars, wherein the rows of pillars are positioned to repeat a pattern every N rows with a shift of M columns, N and M are relatively coprime, and N is greater than 1.

A detection chip is disclosed. The detection chip includes a sample injection structure, a filter structure, and a reaction structure which are sequentially connected. The filter structure includes a first main body, and a first inlet portion and a first outlet portion respectively on two sides of the first main body. A width of the first inlet portion gradually decreases in a direction away from the first main body, and a width of the first outlet portion gradually decreases in a direction away from the first main body.

A biopsy container assembly having a container with a lower chamber suitable for containing a buffer liquid, and a cap coupled with the container. The cap being provided with a chamber that contains a biopsy liquid sealed by a membrane, and a crown with a toothing-suitable for tearing off the membrane of the cap. The crown is also suitable for being disposed in the container in an initial position, wherein the toothing is directed downwards in order not to interfere with the membrane of the cap when the cap is closed on the container, and in an operating position, wherein the toothing is directed upwards in order to tear off the membrane of the cap when the cap is closed on the container.

A system for loading pipette tips. A system for accommodating pipette tips is provided, comprising a tray having openings for accommodating pipette tips in a plate, wherein the openings have at their upper end a surrounding contour which has curved surface area corresponding to a section of a spherical washer, and pipette tips having at their upper end an offset forming a contact surface for the surrounding contour of the tray's opening, wherein the shape of the contact surface corresponds to the section of a spherical washer so that the centers of both spheres of surrounding contour and contact surface are congruent

A microfluidic device includes a lower casing and an upper casing covering the lower casing. The lower casing includes a lower base wall having a top surface and a plurality of spaced-apart columns that protrude upwards from the top surface. The upper casing includes an upper base wall. A first gap between the upper base wall and a column top surface of each of the columns is large enough to permit passage of large biological particles of a liquid sample, and a second gap between any two adjacent ones of the columns is not large enough to permit passage of the large biological particles and is large enough to permit passage of small biological particles of the liquid sample.

A reaction vessel comprises a lower chamber with a first volume, and an upper chamber with a second volume greater than the first volume. A thermocycling system for heating the reaction vessel includes a lower heating zone to heat the lower chamber, an upper heating zone to heat the upper chamber, and a lid heater to heat an opening of the upper chamber. A method comprises loading a sample into a lower chamber of a reaction vessel, thermocycling the lower chamber using a lower heating zone of the thermo cycler, combining an additive into the sample to produce a combination filling the lower chamber and at least partially filling an upper chamber of the reaction vessel, and incubating the upper and lower chambers using the lower heating zone and an upper heating zone. The lower and upper chambers can have different wall thicknesses to facilitate heat transfer.

A microfluidic device includes a microfluidic substrate having a porous media channel, an oil inlet port in fluid communication with the porous media channel, a fluid inlet port in fluid communication with the porous media channel, and an outlet port in fluid communication with the porous media channel. The porous media channel has a plurality of dividers that provide the porous media channel with a network of fluid pathways. A method for assessing miscibility of an oil composition and a fluid includes flowing an aliquot of a fluid through a porous media channel to displace at least an oil composition from the porous media channel, and conducting an optical investigation of the porous media channel to assess the miscibility of the oil composition and the fluid at the test pressure and test temperature.