A magnetic bead separation method includes: storing, in a container, a mixed liquid containing a magnetic bead and a liquid containing target molecules, and adsorbing the target molecules on the magnetic bead, the magnetic bead containing a Fe-based metal soft magnetic particle and a coating film with which the Fe-based metal soft magnetic particle is coated, and having a saturation magnetization of 50 emu/g or more and 250 emu/g or less; applying an external magnetic field to the container and magnetically attracting at least a part of the magnetic bead by the external magnetic field; and applying an acceleration to the container while the magnetic bead is magnetically attracted by the external magnetic field and desorbing the liquid adhering to the magnetic bead.

A centrifugal separator for clarification of a liquid mixture into a heavy phase and a light phase, having a centrifugal separator bowl rotatable around an axis and encasing a separation space, and a sludge space radially outward of said separation space. The centrifugal separator bowl includes a hermetic inlet for feeding a liquid mixture to said separation space; a first hermetic outlet for a separated clarified light phase; and a second hermetic outlet for a separated heavy phase; a plurality of outlet conduits extending from an outer position in said sludge space to said second hermetic outlet. Each of the outlet conduits has a flow restriction in the form of a nozzle or vortex diode. A method to control such a centrifugal separator, in order to provide a stable flow through said outlet conduits, is also disclosed.

A pot for centrifugal separation of a biological fluid into multiple components. The pot comprises a wall (111) around a central axis (112), a top end (121) and a bottom end (113). The pot also comprises a plurality of baffles (114) protruding from the wall (111) into an inner volume of the pot, and/or a protrusion from the bottom end into the inner volume and around the central axis. Also, a consumable cartridge comprising the pot, a cartridge body adapted to receive the pot, and a first holding means. The first holding means is for holding the pot at least partly within the cartridge body, and is adapted to allow the pot to rotate.

A pot for centrifugal separation of a biological fluid into multiple components. The pot comprises a wall (111) around a central axis (112), a top end (121) and a bottom end (113). The pot also comprises a plurality of baffles (114) protruding from the wall (111) into an inner volume of the pot, and/or a protrusion from the bottom end into the inner volume and around the central axis. Also, a consumable cartridge comprising the pot, a cartridge body adapted to receive the pot, and a first holding means. The first holding means is for holding the pot at least partly within the cartridge body, and is adapted to allow the pot to rotate.

The disclosure describes methods and devices with which to process and analyze difficult chemical, biological, environmental samples including but not limited to those containing bulk solids or particulates. The disclosure includes a cartridge which contains a separation tube as well as one or more valves and cavities for receiving raw sample materials and for directing and containing various fluids or samples. The cartridge may contain a separation fluid or density medium of defined density, and structures which direct particulates toward defined regions of the cartridge. Embodiments can include a rotational device for rotating the cartridge at defined rotational rates for defined time intervals. Embodiments allowing multiple assays from a single sample are also disclosed. In some embodiments, this device is used for direct processing and chemical analysis of food, soil, blood, stool, motor oil, semen, and other samples of interest.

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 cell washer is disclosed. The cell washer includes a vessel configured to hold cells. The vessel includes an elongated body including an opening, an inner surface, and a pocket defined by a first inner surface portion of the inner surface disposed between and radially outward relative to a second inner surface portion and a third inner surface portion of the inner surface, and a cavity. The vessel also includes an actuating device capable of causing the vessel to spin about an axis.

Described herein are various embodiments directed to rotor devices, systems, and kits. Embodiments of rotors disclosed herein may be used to characterize one or more analytes of a fluid. An apparatus may include a first layer being substantially transparent. A second layer may be coupled to the first layer. The second layer may be substantially absorbent to infrared radiation. The second layer and the first layer may collectively define a set of wells. The first layer may define a base for each well of the set of wells. The second layer may define an opening for each well of the set of wells. At least one of the first layer and the second layer may define a sidewall for each well of the set of wells.

Embodiments of a portable and compact centrifugal system with methods of energy efficient centrifugation are described. The centrifugal system may be used to separate biological samples contained in conventional laboratory tubes and may be powered by a set of battery cells. The centrifugal system may comprise a vibration damping system which may comprise a tuned mass damper with a damper mass, a damper wall, and an elastic coupler. Many features such as the device's voltages, vibration damping methods, firmware, circuitry, component placement, and material required careful consideration, experimentation, and selection to converge into a functional product. Centrifugation of biological samples typically requires bulky instruments that cannot be readily moved, which can prove inconvenient for remote areas and third world countries. Biological sample quality also degrades outside the body over time, so immediate access to a centrifugal system can improve sample quality.

A continuous flow centrifuge bowl includes a rotatable outer body, and a top and bottom core that are rotatable with the outer body. The bottom core has a wall extending proximally from a bottom wall. The proximally extending wall is radially outward from at least a portion of the top core and, together with the top core, defines a primary separation region in which initial separation of the whole blood occurs. The bowl may also have a secondary separation region located between the top core and the outer body, and a rotary seal that couples an inlet port and two outlet ports to the outer body. The inlet port may be connected to an inlet tube that extends distally into a whole blood introduction region. Additionally, one of the outlet ports may be connected to an extraction tube that extends into a region below the bottom core.