In relation to an automated nucleic acid processor and an automated nucleic acid processing method using a multi function dispensing unit, processing involving extraction and amplification of the nucleic acid, can be consistently, quickly and efficiently conducted at a low cost with the use of a multi function dispensing unit, while saving user's trouble without expanding the scale of the device. The multi function dispensing unit includes: a nozzle head provided with a suction-discharge mechanism and nozzles detachably provided with dispensing tips; a container group having, at the very least housing parts for liquids and reaction containers for housing an amplification solution; a transfer mechanism that makes an interval between the nozzles and the container group relatively movable; a temperature controller whereby temperature control of the interior of the reaction vessels is possible; sealing liquids and/or sealing lids that are transportable to the reaction vessels using the nozzles, and which make the amplification solutions housed in the reaction vessels sealable within the reaction vessels; and a sealing control part that controls the suction-discharge mechanism or the transfer mechanism, such that the sealing liquid and/or the sealing lids seal the amplification solution within the reaction vessels when the housing of the amplification solution in the reaction vessels is completed.

An assembly for storing sample processing consumables can include a cover and a tray. The cover defines a cover cavity. The tray defines a first plurality of wells. The tray includes a first portion received within the cover cavity such that a press fit is formed between a first tray surface of the first portion of the tray and a first cover surface of the cover defining the cover cavity, thereby releasably coupling the cover to the tray. Each of the first plurality of wells contains a sample processing consumable. The assembly can be used to load sample processing consumables into a sample processing instrument.

A device for container storing is presented. The device comprises storage with at least one storing level including a pipetting storing level for fluid pipetting. Each storing level has storing positions having a container holder to detachably hold at least one container. A handler is movable with respect to the storage for transferring containers with respect to the storing positions. A storing position of the pipetting storing level includes a flat spring to bias a container against the container holder. The flat spring has a through hole to provide a pipette access to a lid of the container. A system for pipetting is also presented, comprising the device and a pipettor movable with respect to the pipetting storing level with at least one pipette for pipetting contained in a container stored in the pipetting storing level. The pipette has a pipette tip to penetrate a lid of the container.

The present invention relates to the automation of incubation, processing, harvesting and analysis of samples in a multi-cell plate. In particular, a multi-cell plate including a body with a plurality of cells is presented. Furthermore, an automated crystal harvesting and processing system with a cutting unit, a fluid unit and a removing device is presented. The multi-cell plate further includes a sealing film for sealing the cells on a first side of the body and a sample film for sealing the cells on a second side of the body. The sample film is adapted for accommodating a biological material for crystallization. Furthermore, the sample film is of a thickness and composition that makes it compatible with x-rays and also with laser ablation. The design of the multi-cell plate and the automated crystal harvesting and processing system allows for several steps of incubation, processing, harvesting and analysis of the samples to be automated.

A method and a device for handling a closing element in a laboratory automation system are presented. The closing element is a sealing foil having at least two layers forming a first surface and an opposing second surface, respectively. The layers differ in at least one material property. The material property on at least one of the first surface and the second surface for identifying the orientation of the sealing foil is determined. A laboratory automation system for carrying out the method and/or with the device is also presented.

An analytical toilet is disclosed. The toilet includes a bowl for receiving excreta, a mechanism that uses a consumable for analyzing a sample of excreta, a storage structure for storing the consumable, a sensor that detects at least one property of the consumable, and a processor that generates an alert when the property is outside a predetermined parameter. The property the sensor detects can be used to determine at least one of the identity of the consumable, the quantity or supply of the consumable, or a property related to the suitability of the consumable.

A thermal analysis of samples and proposes a device for a thermal analysis of a sample, having: a sample chamber for receiving a sample crucible including a crucible cover attached thereto, in the interior of which a sample to be analyzed is located, wherein the sample chamber has a chamber opening for introducing the sample crucible into the sample chamber; a temperature control mechanism for controlling the temperature of the sample chamber; a measuring mechanism for measuring a temperature of the sample and one or several further measured variables; a gas conveying mechanism for creating a gas atmosphere in the sample chamber; a chamber cover, which can be attached to the chamber opening of the sample chamber; and a piercing mechanism equipped with a needle, which is suitable to pierce a hole into the crucible cover of the sample crucible by means of the needle when the sample crucible is received in the sample chamber and when the chamber cover is attached to the chamber opening. A corresponding method for a thermal analysis of a sample, a sample crucible including a crucible cover, as well as a covering/piercing unit are further proposed as part of the invention.

A rack for a diagnostic robot with at least one support for at least one container; at least one gas-outlet to supply the at least one container with a gas at a predefined but individually adjustable pressure level; a first gas pump to generate a gas at a predefined super-atmospheric pressure level; a second gas pump to generate a gas at a pre-defined sub-atmospheric pressure level; a first tubing system attached to the first gas pump and holding the gas generated by the first gas pump; a second tubing system attached to the second gas pump and holding the gas generated by the second gas pump; and at least one tube bridge, wherein one end of the bridge connects via a first valve into the first tubing system and the other end of the bridge connects via a second valve into the second tubing system, and wherein the at least one gas-outlet is connected to the center of the bridge.

An assembly for storing sample processing consumables can include a cover and a tray. The cover defines a cover cavity. The tray defines a first plurality of wells. The tray includes a first portion received within the cover cavity such that a press fit is formed between a first tray surface of the first portion of the tray and a first cover surface of the cover defining the cover cavity, thereby releasably coupling the cover to the tray. Each of the first plurality of wells contains a sample processing consumable. The assembly can be used to load sample processing consumables into a sample processing instrument.