The present disclosure relates to a method and a solid phase microextraction sampling instrument for inserting into or through a solid or semisolid material to extract a component of interest from a sample, comprising a support structure at least partially coated with an extraction phase for extracting the component of interest, a protrusion that shields the coating during insertion, where the distances within a cross-sectional plane of the sampling instrument are greater than or equal to the corresponding distances in all of the cross-sectional planes located between the cross-sectional plane of interest and the insertion end of the sampling instrument. The present disclosure also discusses methods of making the instrument, desorption chambers, and methods for desorbing a component of interest from the instrument.

A pipette tip includes a main body section; and a straight pipe section disposed at the leading end of the main body section, in which the inner diameter of the straight pipe section is 0.8 mm to 1.5 mm inclusive, and the length of the straight pipe section is 5 mm to 15 mm inclusive.

The invention relates to a device for the automatic determination of an analyte in the liquid phase by conducting a specific chemical reaction and subsequent optical measurement of the concentration of its products, using spectroscopic techniques, operating in stationary or flow mode. This device is equipped with a reaction-detection system with a replaceable cartridge. The device enables conducting chemical reactions in the liquid phase with the mixing of many streams of reagents, and also ensures the quantitative nature of the determination.

The invention also relates to a method for the automatic determination of an analyte in the liquid phase using the device according to the invention, in particular for monitoring the progress of the dialysis process.

An object moving device includes: a first drive mechanism configured to move a head unit in a first direction and in a second direction; a second drive mechanism configured to move an illumination unit in the first direction; and a third drive mechanism configured to move a camera unit in the first direction. A control unit controls the first drive mechanism to move the head unit on a first path. The control unit controls the second and third drive mechanisms to move the illumination unit and the camera unit on the first path between the first container and the second container. When the head unit and the illumination unit interfere with each other on the first path, the control unit implements control such that the head unit moves in the second direction and the head units moves in the first direction on a second path parallel to the first path.

After disposable pipette tips are used by an automated pipettor, they are released by the pipettor and fall into a waste container. When the waste container is removed to be emptied, the pipette tips are temporarily sequestered in a pipette tip holding station so that the automated pipettor may operate uninterrupted. After the waste container is replaced, the sequestered pipette tips are released by the holding station into the waste container.

After disposable pipette tips are used by an automated pipettor, they are released by the pipettor and fall into a waste container. When the waste container is removed to be emptied, the pipette tips are temporarily sequestered in a pipette tip holding station so that the automated pipettor may operate uninterrupted. After the waste container is replaced, the sequestered pipette tips are released by the holding station into the waste container.

After disposable pipette tips are used by an automated pipettor, they are released by the pipettor and fall into a waste container. When the waste container is removed to be emptied, the pipette tips are temporarily sequestered in a pipette tip holding station so that the automated pipettor may operate uninterrupted. After the waste container is replaced, the sequestered pipette tips are released by the holding station into the waste container.

After disposable pipette tips are used by an automated pipettor, they are released by the pipettor and fall into a waste container. When the waste container is removed to be emptied, the pipette tips are temporarily sequestered in a pipette tip holding station so that the automated pipettor may operate uninterrupted. After the waste container is replaced, the sequestered pipette tips are released by the holding station into the waste container.

The present invention relates to a method for qualitative analysis of a sample protein, which method comprises the steps of providing a water swollen gel column bed comprising bound protease and a sample protein in liquid buffer, digesting the sample protein into polypeptides by contact with the gel bed and subjecting the polypeptides to mass spectrometry (MS). The method is advantageously performed using back and forth flow of the sample protein including two or more repeats, and may be performed at a temperature of less than about 37 C., such as a temperature of less than about 30 C. The invention also includes an automated method as well as a device and a kit for performing mass-based analysis of proteins with higher speed than the prior art while maintaining conditions that are tolerable to the protease.

A micro-syringe for inserting into a sample matrix. The micro-syringe includes a micro-syringe body having an orifice at an insertion end; and a plunger at least partially coated with a solid-phase micro-extraction (SPME) coating. The plunger is longitudinally movable between an internal position and an extended position. When the syringe is inserted into the sample matrix, the extraction phase is shielded from the sample matrix by the micro-syringe body when the plunger is in the internal position, and at least a portion of the extraction phase extends past the orifice and is exposed to the sample matrix when the plunger is in the extended position. The plunger is sized to fit the internal diameter of the micro-syringe body to draw a liquid into the micro-syringe body when the plunger is moved from the extended position to the internal position.