A sample processing system that may be automated and methods are disclosed where samples are arranged on a carrier element and a process operation control system automatically processes the samples perhaps robotically with an operationally-influential exteriorly-consequential information monitor or a data capture element. Significant process details as well as operationally-influential exteriorly-consequential information may be monitored and an automatic notice element may cause notification of a person at some display that may be remote. Various people may be notified, such as an administrator, a supplier, or a manufacturer of an opportunity for some action such as reagent reordering or the like. A simulated motion display may be included to watch simulated operation in real time or long after completion of the actual processing.

A device and method for delivering a laboratory sample carrier from a stack of sample carriers includes providing a retaining mechanism that retains the stack of laboratory sample carriers, and an ejector mechanism including a displaceable mechanism comprising a carrier support portion and a carrier transporting portion which are hingeably interconnected. The stack is supported by the carrier transporting portion and the carrier transporting portion is supported by a carrier transporting portion support of the ejector mechanism when the displaceable mechanism is in a first carrier receiving position and configuration. The displaceable mechanism is displaced from the first carrier receiving position and configuration to a second carrier release position and configuration by a further displacement mechanism of the ejector mechanism. This involves moving a lowermost carrier from the bottom of the stack in a carrier accommodating region of the carrier transporting portion as the displaceable mechanism is displaced from the first carrier receiving position and configuration. The displaceable mechanism is displaced such that the carrier transporting portion moves past the carrier transporting portion support and drops so that the displaceable mechanism adopts the second carrier release position and configuration and the carrier in the carrier accommodating region is released. The stack is supported with the carrier support portion when the displaceable mechanism is in the second carrier release position and configuration.

The present invention relates to a horizontal-flow-type apparatus for automatically transporting reagent cartridges. The apparatus includes: a magazine (110) in which a plurality of reagent cartridges (1) is stacked; a conveyer belt (120) having a plurality of separating projections (121) arranged in a conveying direction to horizontally separately convey the reagent cartridges (1); a driving motor (130) for driving the conveyer belt (120); a feeding unit (140) for feeding the reagent cartridges (1) stacked in the magazine (110) onto the conveyer belt (120); an examining unit (150) disposed over the front end of the conveyer belt (120) to examine the reagent cartridges (1); and reagent cartridge aligning members (161, 162) disposed in the conveying line of the conveyer belt (120), opposite to the examining unit (150), to align the reagent cartridges (1) in position.

Disclosed is a method for washing a smearing member, the method including: dropping a washing agent on a glass slide; and causing the smearing member to be in contact with the washing agent on the glass slide, to wash the smearing member.

The present invention relates to an apparatus for the automated processing of a body fluid sample, preferably for analysis of liquid biopsy, configured to obtain one or more informative components of the fluid sample separate and distinct from each other, wherein a first component includes cellular elements which result to be immobilized on planar supports, a second component includes suspension sample cells, and a third component includes the sample liquid fraction, preferably contained in a test tube. The invention further relates to a method for preparation of the components implemented by the apparatus.

The present invention discloses an automatic fecal occult blood detector for detecting a sample kit, comprising: a feed passage and a discharging passage which are provided in parallel and convey a sample kit separately; a transfer platform configured between the feed passage and the discharging passage; a push rod configured to push the sample kit on the feed passage onto the discharging passage through the transfer platform; and an image capturing device provided on one side of the discharging passage to acquire the color band information presented on a test strip. In the present invention, the parallel arrangement of the feed passage and the discharging passage shortens the whole length of the automatic detector, meeting the requirement that the color band information of the test strip is automatically acquired after the sample kit is left in the device a certain time.

Disclosed is a liquid sealed cartridge in which a liquid injected through an inlet is previously sealed, and the liquid is transferred by a centrifugal force being applied by rotation, and the liquid sealed cartridge includes: a liquid storage portion configured to store the liquid; a bypass flow path having one end and the other end connected to the liquid storage portion, the bypass flow path having the inlet; and a transfer flow path into which the liquid is transferred from the liquid storage portion when the centrifugal force is applied.

A microscope system may comprise a plurality of microscope modules, a cassette for holding a plurality of slides, a slide loader configured to move the plurality of slides between the cassette and the plurality of microscope modules, and a processor coupled to the slide loader. The processor may be configured with instructions which, when executed, cause the slide loader to move a slide into or from a selected microscope module among the plurality of microscope modules. Various other methods, systems, and computer-readable media are also disclosed.

A slide storage, retrieval, transfer and scanning system for a slide scanner presents multiple components which work together in an automated fashion to streamline slide scanning in digital pathology. A slide storage assembly stores several slide baskets and can deliver a particular basket through a rotation mechanism. A slide basket transfer assembly retrieves the basket from the slide storage assembly and transfers the basket to a secondary location, where a slide transfer assembly retrieves a single slide from the basket and delivers the slide to a slide scanning stage for scanning.

A magazine device (14) and method are provided for a measuring device (12) for measuring a concentration of gaseous and/or aerosol components of a gas mixture. The magazine device (14) includes a holding device (16) for a plurality of reaction carriers (18), which have each at least one reaction chamber with a reactant. The reactant is designed to react with a particular component to be measured in the gas mixture or with a reaction product of the component to be measured in an optically detectable manner. A feed device (20) removes a reaction carrier (18) of the plurality of reaction carriers (18) from the holding device (16) and feed the reaction carrier to the measuring device (12) for carrying out a measurement of the particular component to be measured in the gas mixture. A control unit (22) controls the holding device (16) and/or the feed device (20).