A lattice and distribution network for a stackable chromatography cassette comprising: a peripheral seal; at least one screen forming the lattice surrounded by the peripheral seal, each at least one screen comprising a plurality of struts in a latticed arrangement; a first internal distribution network fluidly coupled to the lattice and surrounded by the peripheral seal; a second internal distribution network disposed opposite the first internal distribution network, fluidly coupled to the lattice and surrounded by the peripheral seal; wherein a direction of fluid flow is established from the first internal distribution network through the lattice to the second internal distribution network; and wherein preferential streamlines are minimized.

Adsorptive bed devices include a scaffold in housing having a stress absorbing rigid structure and open cells filled with adsorptive beads. The scaffold restricts movement of the plurality of adsorptive beads, absorbs stress induced by a hydraulic pressure gradient along a direction of liquid flow and transfers a portion of the induced compressive stress to the housing. In one embodiment the adsorptive bed is packed into a chromatography column, and in another embodiment the adsorptive bed is sealed in a monolithic block. In another embodiment, the adsorptive bed device includes an adsorptive block, first and second planar distributors and peripheral seal. The adsorptive media includes multiple layers of planarly cohesive media and when operated in a shallow bed configuration possesses significant tensile strength along its planar dimensions enabling it to support the hydraulic pressures that will be generated by the fluids being processed through the adsorptive devices.

A temperature responsive monolithic porous material is obtained that comprises a polymer having a hydration ability that changes in a temperature range of 0 to 80 C. and being immobilized to a surface of the porous material at a high density by binding an atom transfer radical polymerization initiator to a surface of the porous material, and inducing a growth reaction of a polymer, having a hydration ability that changes in a temperature range of 0 to 80 C., from the initiator using an atom transfer radical process under a presence of a catalyst.

An insert mounted in a mixing cup and used by an automated chemical analyzer for removing a targeted component of a liquid sample includes a porous matrix formed of or carrying in an immobilized state functionalized particles having properties such that the targeted component of the liquid sample adheres to the functionalized particles. When the liquid sample is expelled from a disposable tip fitted on the end of a pipette forming part of the automated chemical analyzer into the mixing cup, the liquid sample is drawn into the matrix of the insert by capillary action, whereupon the targeted component of the liquid sample adheres to the immobilized functionalized particles of the matrix.

Methods and devices are disclosed for a separation device. A separation device includes a plurality stacked modules and a distribution network including an inter-module LEVEL-1 distributor an intermediate LEVEL-2 distributor and a planar LEVEL-3 distributor. The distribution network enables streamline lengths which are approximately equal and induces uniform velocity fluid flow. These features provide a narrow residence time distribution providing improved chromatographic performance.

An insert mounted in a mixing cup and used by an automated chemical analyzer for removing a targeted component of a liquid sample includes a porous matrix formed of or carrying in an immobilized state functionalized particles having properties such that the targeted component of the liquid sample adheres to the functionalized particles. When the liquid sample is expelled from a disposable tip fitted on the end of a pipette forming part of the automated chemical analyzer into the mixing cup, the liquid sample is drawn into the matrix of the insert by capillary action, whereupon the targeted component of the liquid sample adheres to the immobilized functionalized particles of the matrix.