A plastic body including a generally cylindrical upper portion having an open end configured for engagement with an automated pipettor. The plastic body further includes a plurality of longitudinally oriented ribs disposed on an inner surface of the open end of the upper portion and a plurality of concave recesses disposed on an outer surface of the upper portion. Each of the recesses is disposed directly opposite an associated one of the ribs, and each of the recesses extends along at least part of the length of the associated rib.

The invention discloses a chromatography column module stackable with like chromatography modules, comprising a column chamber (2) fluidically connected to a column inlet 3) and a column outlet (4), wherein the column inlet and outlet each comprise a valve (5), arranged to move from a closed position to an open position upon connection of the column inlet or outlet with a) a column outlet or inlet of a like chromatography module or b) with an outlet or inlet of a fluidics plate. The invention further discloses a stack of chromatography column modules and the use of the stack for separation of biomolecules.

The invention features methods of making devices, or platens, having a high-density array of through-holes, as well as methods of cleaning and refurbishing the surfaces of the platens. The invention further features methods of making high-density arrays of chemical, biochemical, and biological compounds, having many advantages over conventional, lower-density arrays. The invention includes methods by which many physical, chemical or biological transformations can be implemented in serial or in parallel within each addressable through-hole of the devices. Additionally, the invention includes methods of analyzing the contents of the array, including assaying of physical properties of the samples.

A reagent well having a capillary insert that contains a lyophilized reagent therein.

Disclosed is a chromatographic separation column assembly (100) comprising a column cylinder (120) having a cylinder wall (126) including an inner wall surface (124) partially defining a column volume (50), and a column component (110/130) insertable into to the cylinder (120), wherein at least an edge region (113/133) of the column component is intended to be in contact or adjacent a part of the inner wall surface (124) in use, the edge region and the contacting or adjacent part of inner wall surface each being formed from a compatible heat fusible material or materials, and wherein at least the cylinder wall in the area of the contacting or adjacent part of the inner wall is formed from a material which allows transmission of the light energy needed to cause said fusing of the adapter plate edge region to the inner wall surface.

A sample cartridge for a liquid chromatography device includes a microfluidic chip. A collector in the microfluidic chip includes a collector flow channel and a first window for acquisition of spectral data from a sample in the collector flow channel.

Systems, apparatus, methods, and kits are provided for automated mass spectrometric analysis of small volumes of liquid samples, such as biological samples. The systems, apparatus, and kits may be used in facilities where high throughput of samples, as well as reliable and repeatable assay results with little training of staff, are needed. Such facilities include hospital emergency wards.

A parallel assembly (2; 11; 51) of chromatography column modules (3a,b,c; 13a,b,c; 53a,b,c, 90a, b), the assembly having one common assembly inlet (15; 55) and one common assembly outlet (17; 57), each column module comprising a bed space (29) filled with chromatography medium and each column module comprises integrated fluid conduits which when the column module is connected with other column modules are adapted to connect the bed space (29) of the column module with the assembly inlet (15; 55) and the assembly outlet (17; 57), wherein the total length and/or volume of the fluid conduit from the assembly inlet to one bed space together with the length and/or volume of the fluid conduit from the same bed space to the assembly outlet is substantially the same for all bed spaces and modules installed in the parallel assembly.

A reagent cartridge including (a) a support having reservoirs; (b) a main channel within the support, the channel having first and second ends exiting the support; (c) a pump channel that connects to the main channel between the first and second ends; (d) a valve manifold in the support, including (i) a first passage at the first end of the main channel, (ii) a second passage at the second end of the main channel, (iii) a first master valve between the pump channel and the first end of the main channel, (iv) a second master valve between the pump channel and the second end of the main channel, and (v) reservoir valves for regulating flow from individual reservoirs to the main channel. The valves can be normally closed diaphragm valves formed by magnetic pistons attached to an elastomeric sheet that is sandwiched in the support.

A reactor for a liquid chromatography system comprises a first capillary cartridge, a second capillary cartridge, a first housing for accommodating the first capillary cartridge, and a second housing for accommodating the second capillary cartridge. The first housing comprises a heating element for heating the first capillary cartridge. The second housing can comprise a cooling element for cooling the second capillary cartridge.