Various embodiments comprise systems, methods, architectures, mechanisms or apparatus configured to separate particles of varying size within a fluid flow, or filter particles from a fluid flow, via an array of anchored-liquid drops or anchored-gas drops.

Provided is an automated analysis device with which sufficient reaction process data can be acquired irrespective of the scale of the device, and with which it is possible to ensure freedom of the device configuration. An automated analysis device 100 is provided with: a reaction disk 1 which circumferentially accommodates a plurality of reaction vessels 2; a specimen dispensing mechanism 11 which dispenses a specimen into the reaction vessels 2; a reagent dispensing mechanism 7 which dispenses a reagent into the reaction vessels 2; a measuring unit 4 which measures a reaction process of a mixture of the specimen and the reagent in the reaction vessels 2; and a cleaning mechanism 3 which cleans the reaction vessels 2 after measurement. Further, the automated analysis device 100 includes a controller 21 which controls the drive of the reaction disk 1 such that in one cycle the reaction vessels 2 move by an amount A in the circumferential direction in such a way that N and A are mutually prime, B and C are mutually prime, and the relationship A×B=N×C±1 holds, where N is the total number of reaction vessels 2 accommodated in the reaction disk 1, the reaction disk 1 moves through C (where C>1) rotations+an amount equivalent to one reaction vessel after B (where B>2) cycles, and the number of reaction vessels 2 moved in one cycle is A (where N>A>N/B+1).

A clinical diagnostic sample analyzer for analyzing a sample of a patient is disclosed. The analyzer includes a telescoping closed-tube sampling assembly with a sample probe concentrically housed within a piercing probe and a venting mechanism. The closed-tube sampling assembly is used for aspirating a sample from a sample tube for analysis by a clinical diagnostic sample analyzer.

Disclosed herein are high-throughput sample processing systems and waste management systems, and methods of using the same.

A manipulation apparatus and a manipulation method for performing culturing, manipulation, and analysis of minute samples such as cells and microbes on a large scale, the manipulation apparatus including a stage unit on which a predetermined cell incubator is mounted and a probe array unit having a plurality of probes. The probe array unit includes a first probe array and a second probe array. The first probe array includes a plurality of probes arranged side by side at a predetermined pitch along the X-axis direction. The second probe array includes a plurality of probes arranged side by side at a predetermined pitch along the Y-axis direction.

The invention relates to a method for cleaning dissolution vessels and for the subsequent dosing of a dissolution media, and to mobile modular cleaning and dosing equipment for the implementation of said method. According to said method, injected water steam is used for the cleaning and is subsequently aspirated, together with the residues of the dissolution, and the vessel is then refilled with the desired quantity of a new dissolution media. The mobile modular cleaning and dosing equipment allows the cleaning and dosing to be carried out in situ without having to remove the dissolution vessels from the equipment or site where the dissolution tests are carried out, using self-sufficient modular equipment, and a novel steam supply line is used for the cleaning, which sprays the steam against the bottom of the vessel and the inner side walls.

A microfluidic system includes a chip holder that holds a microchip including a plurality of reservoirs, a chip cover, a sealing member; a dispensing probe, a suction mechanism, a first storage where a first cleaning solution is stored, a second storage where a second cleaning solution is stored, a pump, a channel switch, and a controller. The channel switch is configured to switch between a channel through which the first cleaning solution is suctioned from the first storage and a channel through which the second cleaning solution is suctioned from the second storage. The controller controls operations of the channel switch and the pump.

A spray assembly for a dishwasher of the kind wherein utensils are disposed inside a dishwashing chamber and a generally L-shaped spray assembly is rotated to and fro so that a horizontal leg thereof sweeps across a lower surface of the dishwashing chamber and a vertical leg of the spray assembly sweeps across a side wall of the dishwashing chamber. The spray assembly has channels for conveying detergent and hot water and further has multiple nozzles disposed along the horizontal and vertical legs for directing detergent and hot water on to the utensils inside the dishwashing chamber from multiple different directions as the spray assembly rotates. A fluid inlet coupler at an end of the spray assembly is adapted for coupling to a rotatable hub having duct connectors projecting downwardly substantially parallel to an axis of rotation of the hub and fluidly coupled to respective channels of the spray assembly.

A washing apparatus includes a stage, a suction nozzle, and a control unit. On the stage, an analytical unit is mounted. In the analytical unit, a well having a hole shape including a bottom surface and an inner peripheral surface is formed. The suction nozzle sucks a solution in the well. The control unit, after controlling the suction nozzle to sucks the solution in the well, controls the stage to rotate the stage on which the analytical unit is mounted at a predetermined speed of rotation, and controls the suction nozzle to suck a residue of the solution existing in the well.

A washing device comprises a manifold dispenser comprising at least one liquid input and a plurality of liquid outputs that operably direct fluid to contact a plurality of laboratory consumables held by a rack in the washing device, an ultra-violet (UV) light source, and a plurality of fiber optic channels coupled to the UV light source, each of the fiber optic channels extending into a corresponding one of the liquid outputs. The plurality of liquid outputs may each comprise a nozzle having an opening into which a respective one of the plurality of fiber optic channels extends.