A filter includes an inlet side, an outlet side, and a body. The body includes a first substrate that includes an array of inlet holes passing through the first substrate, and a second substrate that includes an array of outlet holes passing through the second substrate. The body further includes an intermediate region that includes a plurality of channels extending along a plane that is transverse or at an angle to a main axis of the filter. Each channel communicates directly or indirectly with at least one of the inlet holes and at least one of the outlet holes. The filter provides a plurality of fluid flow paths through the body from the inlet side to the outlet side.

The invention relates to a method for providing an aseptic chromatography column, said method comprising the steps of: pre-sterilize an empty chromatography column; pre-sterilize a chromatography medium; introducing the pre-sterilized chromatography medium into the pre-sterilized chromatography column using aseptic equipment, thereby providing an aseptic chromatography column comprising chromatography medium.

A chromatography column has a column assembly that further includes a column jacket tube and a column liner tube. The column assembly is configured with end fittings that have compression limiting features and are able to withstand very high pressure, such as used in UHPLC, in conjunction with flange portions of the column liner tube that seal the column assembly. The column liner tube may be biocompatible and may have a smooth consistent inner diameter of less than 2 mm, and an inner diameter of 1 mm in particular embodiments. The end fittings for the microtube assembly may ensure durability and reliability by preventing over- or under-tightening.

A chromatographic device including a coated metallic frit is disclosed. The coating is provided over the fluid exposed surfaces of the frit, thereby covering metallic surfaces to prevent interaction with an analyte in the flowstream. This technology relates to the use of a vapor deposition coated frit together with an uncoated frit in a liquid flow path for improved chromatography. More specifically, this technology relates to liquid chromatographic devices for separating analytes in a sample having a single coated frit within an uncoated metallic fluidic flow path (i.e., the column tube or channel is formed of stainless steel, titanium (pure or alloyed), or some mixture of stainless steel and titanium) and does not include the coating applied to the frit.

A chromatographic device including a coated metallic frit is disclosed. The coating is provided over the fluid exposed surfaces of the frit, thereby covering metallic surfaces to prevent interaction with an analyte in the flowstream. This technology relates to the use of a vapor deposition coated frit together with an uncoated frit in a liquid flow path for improved chromatography. More specifically, this technology relates to liquid chromatographic devices for separating analytes in a sample having a single coated frit within an uncoated metallic fluidic flow path (i.e., the column tube or channel is formed of stainless steel, titanium (pure or alloyed), or some mixture of stainless steel and titanium) and does not include the coating applied to the frit.

Microstructure separation filters are provided herein, as well as chromatography and other separation devices. An exemplary filter device includes a microstructure filter has a plurality of layers of alternating sacrificial and/or structural material which have been etched to create inlet channels and outlet channels. Adjacent ones of the inlet channels and the outlet channels are spaced apart from one another by cross channels that filter a fluid from the inlet channels to the outlet channels. The cross channels include filter features formed by etching away of a portion of the layers. The device also includes a housing configured to receive the microstructure filter.

A filter device includes a first filter, a first retaining member that has a hollow shape, the first filter being fitted inside the first retaining member, a second filter that has a smaller pore size than the first filter, a second retaining member that is disposed downstream of the first filter and that has a hollow shape, the second filter being fitted inside the second retaining member, and a spacer that has a hollow shape, that is disposed between the first retaining member and the second retaining member, that maintains a non-contact state between the first filter and the second filter, and that includes a first contact portion contacting the first filter.

A chromatographic device including a coated metallic frit is disclosed. The coating is provided over the fluid exposed surfaces of the frit, thereby covering metallic surfaces to prevent interaction with an analyte in the flowstream. This technology relates to the use of vapor deposition coated frit(s) in a liquid flow path for improved chromatography. More specifically, this technology relates to liquid chromatographic devices for separating analytes in a sample having coated frit(s) within an uncoated metallic fluidic flow path (i.e., the column tube or channel is formed of stainless steel, titanium (pure or alloyed), or some mixture of stainless steel and titanium) and does not include the coating applied to the frit.

The present invention relates to the readily automated methods for the separation of biomolecules, such as proteins or nucleic acids. More specifically, the invention relates to a separation device, which includes at least one column provided with a bottom liquid inlet/outlet and adapted to receive a separation media. At least part of an elongated frit has been arranged substantially parallel to the column side walls, segregating the separation media from the bottom liquid inlet/outlet. The elongated frit may be shaped as a tube and should have a porosity that serves to retain separation media within the column during sample processing.

Further, the invention relates to a method of separating at least one target molecule from a liquid, which method comprises providing at least one column provided with a bottom liquid inlet/outlet and optionally with a top liquid inlet. The column retains a separation media; and at least part of an elongated frit has been arranged substantially parallel to the column side walls to segregate the separation media from the bottom liquid inlet/outlet. A liquid sample is processed in said column in a method including aspiration and dispensing of fluid to and from the bottom liquid inlet/outlet; adding a liquid at the top liquid inlet; or any combination thereof.

Disclosed is a continuous process in which a subset of a number of mutually identical columns, are connected in series. The process liquid, e.g. crude cell culture harvest, is supplied to the most upstream column of the subset. It flows successively through the in series connected columns and leaves the subset through the most downstream and flows into the downstream collection vessel. As soon as the packed bed of the most upstream column is become saturated with product, this column is disconnected from the subset. It is removed from the series connection. A replacement, identical, column is added such that it is connected in series downstream from the most downstream column of the subset. This process is repeated.