A method and system for processing particles contained in a liquid biological sample is presented. The method uses a rotatable vessel for processing particles contained in a liquid biological sample. The rotatable vessel has a longitudinal axis about which the vessel is rotatable, an upper portion having a top opening for receiving the liquid containing the particles, a lower portion for holding the liquid while the rotatable vessel is resting, the lower portion having a bottom, and an intermediate portion located between the upper portion and the lower portion, the intermediate portion having a lateral collection chamber for holding the liquid while the rotatable vessel is rotating. The method employs dedicated acceleration and deceleration profiles for sedimentation and re-suspension of the particles of interest.

Coordinated conveyors in an automated system. A system comprises a plurality of conveyors, which each comprise a plurality of segments, and one or more stations. An instruction is received to perform an operation that requires at least one station to process at least a first item held by a first segment of a first conveyor and a second item held by a second segment of a second conveyor. In response to the instruction, one or both of the first and second conveyors are moved, such that the first segment and the second segment are aligned at the station. After alignment, one or more instruments of the station process the first item and the second item.

This invention relates to a continuous flow centrifugation device and method of using the device for separation of solids, particles, liquids, or gases from a mixture containing them. The device contains rotating separation chamber in which incoming material in continuously enters the chamber via an inlet and the separated materials continuously flow out via two outlets. Solids or heavier materials exit from an outlet tubing, whose opening is placed in a space that is farthest from the center of rotation and has the highest centrifugal force. The liquid/supernatant outlet is placed in the space that is closer to the center of rotation with the lowest centrifugal force. The reference of placement of inlet to solids outlet is in the same direction as the direction of rotation so that the flow of incoming material, directed from inlet to solids outlet, is in the same direction as the direction of rotation. All product contact surfaces can be disposable and diverse separation methods for different applications can be executed in a fully automated or manual manner by a controller that manages different inputs and outputs of system components.

The present invention relates to a centrifuge rotor with a rotor body and a receptacle arranged centrally therein for receiving a drive head of a drive shaft of a centrifuge which can be rotated about an axis of rotation (R), and sample receptacles for accommodating a plurality of sample containers. A holding crown is arranged on a top side (O) of the rotor body facing away from an insertion side (E) of the drive head, said holding crown having an annular base body, which encloses a central opening, and prongs extending upward away from the top side (O), wherein the holding crown is arranged in such a way that the axis of rotation (R) runs through the central opening. The present invention further relates to a holding crown for use with a centrifuge rotor and having an annular base body enclosing a central opening and prongs emanating from the base body and extending upward, wherein the prongs are offset at least in the region of their free ends by a spacing (A) from an inner edge of the base body. The present invention further relates to a holding crown arrangement comprising the holding crown, and a centrifuge comprising the centrifuge rotor, the holding crown or the holding crown arrangement.

An umbilicus-driven centrifuge includes a yoke configured to orbit a midsection of the umbilicus around a rotational axis at a first speed so as to cause a separation chamber associated with the umbilicus to rotate about the rotational axis at a second speed that is approximately double the first speed. An optical monitoring system directly monitors the separation chamber, with a light source oriented to emit light toward the separation chamber and a light detector oriented to receive at least a portion of the light after the light has passed through the separation chamber. A controller receives a plurality of signals from the light detector, then compares the period or frequency of the signals to an expected period or frequency. The controller determines that the umbilicus is experiencing an irregularity when the period or frequency is different from the expected period or frequency.

Provided herein are devices and methods of processing a sample that include, in several embodiments, rotating one or more microfluidic chips that are mounted on a support plate using a motor driven rotational chuck. By spinning one or more of the microfluidic chips about a common center of rotation in a controlled manner, high flow rates (and high shear forces) are imparted to the sample in a controlled manner. Each microfluidic chip can be rotated 180° on the support plate so that the sample can be run back-and-forth through the microfluidic devices. Because the support plate can be driven at relatively high RPMs, high flow rates are generated within the microfluidic chips. This increases the shear forces on the sample and also decreases the processing time involved as the sample can quickly pass through the shear-inducing features of the microfluidic chip(s).

A chamber for centrifugal separation includes a main body including a first opening and a second opening opposite to the first opening, a first cover coupled to the main body to close the first opening and including a first injection port to inject a material, a second cover coupled to the main body to close the second opening and including a second injection port to inject a material, and a filter device provided inside the main body and interposed between the first injection port and the second injection port, to prevent the material injected into the first injection port from being mixed with the material injected into the second injection port.

A centrifuge for cleaning a reaction vessel unit, having a rotor for holding at least one reaction vessel unit with its opening(s) directed outwardly, a motor for rotating the rotor around a rotation axis, a housing having a substantially cylindrical inner surface, wherein a drain is provided for discharging fluid expelled from the reaction vessel unit, wherein a gap is provided between the inner surface and the rotor so that by rotating the rotor a wind is generated which drives the expelled fluid on the inner surface to the drain wherein an aspiration pump is connected to the drain for discharging fluid.

A centrifuge for cleaning a reaction vessel unit, having a rotor for holding at least one reaction vessel unit with its opening(s) directed outwardly, a motor for rotating the rotor around a rotation axis, a housing having a substantially cylindrical inner surface, wherein a drain is provided for discharging fluid expelled from the reaction vessel unit, wherein a gap is provided between the inner surface and the rotor so that by rotating the rotor a wind is generated which drives the expelled fluid on the inner surface to the drain wherein an aspiration pump is connected to the drain for discharging fluid.

Systems, methods and devices are provided for the automated centrifugal processing of samples. In some embodiments, an integrated fluidic processing cartridge is provided, in which a centrifugation chamber is fluidically interfaced, through a lateral surface thereof, with a microfluidic device, and wherein the integrated fluidic processing cartridge is configured to be inserted into a centrifuge for centrifugation. A cartridge interfacing assembly may be employed to interface with the integrated fluidic processing cartridge for performing various fluidic processing steps, such as controlling the flow of fluids into and out of the centrifugation chamber, and controlling the flow of fluids into the microfluidic device, and optionally for the further fluidic processing of fluids extracted to the micro-fluidic device. The integrated fluidic processing cartridge may include a supernatant chamber the extraction of a supernatant thereto, and a diluent chamber for diluting a suspension collected in the centrifugation chamber.