Cells Reagents

Bifurcating channel for monoculture work. With various options of symmetric and asymmetric bifurcating angles and parent/daughter channel widths, you can likely find a set of designs to provide you the best models for your research. Use symmetric and asymmetric bifurcations to study cell/particle adhesion and cell-cell or cell-particle interactions at bifurcations and to study the effect of the bifurcation angle and asymmetry on adhesion. Compare adhesion in linear sections and bifurcations simultaneously. 45° Sym (22.5° + 22.5°) 100um parent, 50um daughter widths, 100um depth.

Bifurcating channel for monoculture work. With various options of symmetric and asymmetric bifurcating angles and parent/daughter channel widths, you can likely find a set of designs to provide you the best models for your research. Use symmetric and asymmetric bifurcations to study cell/particle adhesion and cell-cell or cell-particle interactions at bifurcations and to study the effect of the bifurcation angle and asymmetry on adhesion. Compare adhesion in linear sections and bifurcations simultaneously. 30° Sym (15° + 15°) 100μm parent, 50μm daughter widths, 50μm depth.

Bifurcating channel for monoculture work. With various options of symmetric and asymmetric bifurcating angles and parent/daughter channel widths, you can likely find a set of designs to provide you the best models for your research. Use symmetric and asymmetric bifurcations to study cell/particle adhesion and cell-cell or cell-particle interactions at bifurcations and to study the effect of the bifurcation angle and asymmetry on adhesion. Compare adhesion in linear sections and bifurcations simultaneously. 60° Sym (30° + 30°) 100μm parent, 50μm daughter widths, 50μm depth.

Bifurcating channel for monoculture work. With various options of symmetric and asymmetric bifurcating angles and parent/daughter channel widths, you can likely find a set of designs to provide you the best models for your research. Use symmetric and asymmetric bifurcations to study cell/particle adhesion and cell-cell or cell-particle interactions at bifurcations and to study the effect of the bifurcation angle and asymmetry on adhesion. Compare adhesion in linear sections and bifurcations simultaneously. 90° Sym (45° + 45°) 100μm parent, 50μm daughter widths, 50μm depth.

Bifurcating channel for monoculture work. With various options of symmetric and asymmetric bifurcating angles and parent/daughter channel widths, you can likely find a set of designs to provide you the best models for your research. Use symmetric and asymmetric bifurcations to study cell/particle adhesion and cell-cell or cell-particle interactions at bifurcations and to study the effect of the bifurcation angle and asymmetry on adhesion. Compare adhesion in linear sections and bifurcations simultaneously. 120° Sym (60° + 60°) 100μm parent, 50μm daughter widths, 50μm depth.

Idealized microvascular network for co-culture work (w/2D tissue compartment). Use idealized co-culture assays to mimic the cellular make up in vivo. Investigate cell-cell interactions and perfusion vs. diffusion-based effects. Analyze the experiments in real-time for all the cell populations. Intended to mimic the formation of and transport across tight and gap junctions such as the blood-brain barrier and other endothelial/tissue interfaces, the idealized co-culture constructs are available with several options for channel size, tissue chamber size and scaffolding, and barrier design. 100μm OC, 100μm slit spacing, 2 µm wide slit, 50μm travel, 100μm depth.

Idealized microvascular network for co-culture work (w/2D tissue compartment). Use idealized co-culture assays to mimic the cellular make up in vivo. Investigate cell-cell interactions and perfusion vs. diffusion-based effects. Analyze the experiments in real-time for all the cell populations. Intended to mimic the formation of and transport across tight and gap junctions such as the blood-brain barrier and other endothelial/tissue interfaces, the idealized co-culture constructs are available with several options for channel size, tissue chamber size and scaffolding, and barrier design. 200μm OC, 50μm slit spacing, 3µm wide slit, 50μm travel, 100μm depth.

Idealized microvascular network for co-culture work (w/2D tissue compartment). Use idealized co-culture assays to mimic the cellular make up in vivo. Investigate cell-cell interactions and perfusion vs. diffusion-based effects. Analyze the experiments in real-time for all the cell populations. Intended to mimic the formation of and transport across tight and gap junctions such as the blood-brain barrier and other endothelial/tissue interfaces, the idealized co-culture constructs are available with several options for channel size, tissue chamber size and scaffolding, and barrier design. 200μm OC, 50μm slit spacing, 3µm wide slit, 100μm travel, 100μm depth.

Idealized microvascular network for co-culture work (w/2D tissue compartment). Use idealized co-culture assays to mimic the cellular make up in vivo. Investigate cell-cell interactions and perfusion vs. diffusion-based effects. Analyze the experiments in real-time for all the cell populations. Intended to mimic the formation of and transport across tight and gap junctions such as the blood-brain barrier and other endothelial/tissue interfaces, the idealized co-culture constructs are available with several options for channel size, tissue chamber size and scaffolding, and barrier design. 200µm OC, Pillars, 3µm Gap, 100µm Travel-----3/100 µm.