A centrifuge rotor includes a rotor body having a base, a sidewall, and a top. The top defines an opening that provides access to an annulus cavity inside the rotor body. A cover is removably attachable to the rotor body to seal the annulus cavity. A drive hub extends from a portion of the base of the rotor body and couples to a drive shaft of a centrifuge motor. The rotor body is sized to receive one or more sample containers in the annulus cavity, and to constrain the one or more sample containers inside the annulus cavity between the base, the sidewall, and the top when the one or more containers are advanced radially against the sidewall.

Miniaturized DNA microarrays are described to be used in conjunction with microfluidic channels or microcentrifuge tubes and microcentrifuge filters to reduce sample size, incubation time and to increase overall binding efficiency.

A separation container for extracting a portion of a sample for use or testing and method for preparing samples for downstream use or testing are provided. The separation container may include a body defining an internal chamber. The body may define an opening, and the body may be configured to receive the sample within the internal chamber. The separation container may further include a seal disposed across the opening, such that the seal may be configured to seal the opening of the body, and a plunger movably disposed at least partially inside the internal chamber. The plunger may be configured to be actuated to open the seal and express the portion of the sample.

The disclosure provides a microcentrifuge powered by pressurized gas. The microcentrifuge can be used to separate chemical and biological samples, including blood. The microcentrifuge can be made of plastic using 3D printing techniques.

A centrifuge rotor for sample vessels includes a seal between a lower part and a cover. The seal comprises a gasket, which is arranged in a first groove. The first groove is arranged on one of the elements constituted by the cover and the lower part. The first groove, in relation to the axis of rotation of the centrifuge rotor, is open axially toward the other of the elements constituted by the cover and the lower part.

A sample processing unit (SPU)-equipped drone for transporting and processing biological materials and method of using same is disclosed. In some embodiments, the presently disclosed SPU-equipped drone and method provide a drone equipped to carry an SPU and wherein the SPU may include a centrifuge arranged inside a temperature-controlled chamber and wherein the centrifuge may be used to process biological materials at the same time that the SPU-equipped drone is in flight. Further, a method of using the presently disclosed SPU-equipped drone for transporting and processing biological materials is provided.

Provided is a centrifuge. In a centrifuge having a rotor with a rotor body that holds a sample and that is rapidly rotated, an inclined surface that extends upward as it extends radially outward is formed on an upper-side outer peripheral portion of the rotor, in a region that is at a radially outward side and at an upper side of the outer edge of an opening. The inclined surface is a continuous ring-like inclined surface that has the same cross-sectional shape in the circumferential direction and is formed into a straight-line shape or a curved-line shape in cross-section along a rotation central axis. Although winds occur during high-speed rotation of the rotor, the winds are rectified by the inclined surface, and a component force for pressing the rotor body in a downward direction acts thereon.

An hourglass shaped blood fractionation tube is sized and shaped such that whole blood that has been centrifuged with a density gradient medium yields a PBNC layer within the narrowed neck of the tube. This orientation results in an elongated or widened PBMC layer, versus what would result in a conventional fractionation tube. Elongating or widening the PBMC layer allows technicians to harvest higher purity and higher volume PBMC samples versus samples harvested with a standard cylindrical blood fractionation tube. The hourglass shaped blood fractionation tube according to the present invention preferably includes a cap and can be used in conventional centrifuges and robotic pipetting stations.

Described herein are methods, systems, and apparatus for separating components of a sample; as well as methods of using compositions prepared by same. In one aspect, the apparatus can comprise a tubular body for receiving sample, a thixotropic material, and a float. The system comprising the apparatus can be configured to separate the component of the sample using centrifugation. The float can have a specific gravity less than or equal to the specific gravity of the thixotropic material. The thixotropic material can be positioned along a bottom inner surface of the tubular body, and a portion of the float can be embedded in the thixotropic material. The float can be made of a single, integral piece or a plurality of pieces that are configured to be fixed and immobile relative to each other during centrifugation. The float can be solid, nonporous and without any aperture.

A centrifuge for washing magnetic beads in a reaction vessel unit that includes at least one opening, having a housing including an inner surface and a drain, a rotor disposed within the housing, the rotor being configured to hold a reaction vessel unit with its opening(s) directed outwardly toward the inner surface of the housing, a motor coupled with the rotor to rotate around a horizontal rotation axis, and a magnetic element arranged in the rotor to apply a magnetic field to one or more reaction vessels of a reaction vessel unit held by the rotor.