Abstract: Improved composite microarray slides for use in micro-analytical diagnostic applications are disclosed. Specifically, composite microarray slides useful for carrying a microarray of biological polymers on the surface thereof including composite microarray slides having a porous membrane formed by a phase inversion process effectively attached by covalent bonding through chemical agents that comprise anchor/linker moieties to a substrate that prepares the substrate to sufficiently bond to the porous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the composite microarray slides are covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating the composite microarray slides are also disclosed.

Abstract: Improved composite microarray slides for use in micro-analytical diagnostic applications are disclosed. Specifically, composite microarray slides useful for carrying a microarray of biological polymers on the surface thereof including composite microarray slides having a porous membrane formed by a phase inversion process effectively attached by covalent bonding through chemical agents that comprise anchor/linker moieties to a substrate that prepares the substrate to sufficiently bond to the porous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the composite microarray slides are covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating the composite microarray slides are also disclosed.

Abstract: The present disclosure relates to processes and methods for producing a hydrophobic zone boundary that surrounds a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores such that the fluid contained within one hydrophilic layer region does not cross the hydrophobic zone boundary and the articles formed thereby and, more particularly, to processes and methods for producing a hydrophobic zone boundary that separates adjacent regions of a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores mounted on a substrate such that a uniform hydrophobic zone boundary layer in the z-direction is formed in the hydrophilic porous material or the removal of the hydrophilic porous material layer from the substrate to form a hydrophilic porous material zone on the substrate, the so formed hydrophilic porous material zone having a predetermined geometric shape such th

Abstract: The present disclosure relates to processes and methods for producing a hydrophobic zone boundary that surrounds a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores such that the fluid contained within one hydrophilic layer region does not cross the hydrophobic zone boundary and the articles formed thereby and, more particularly, to processes and methods for producing a hydrophobic zone boundary that separates adjacent regions of a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores mounted on a substrate such that a uniform hydrophobic zone boundary layer in the z-direction is formed in the hydrophilic porous material or the removal of the hydrophilic porous material layer from the substrate to form a hydrophilic porous material zone on the substrate, the so formed hydrophilic porous material zone having a predetermined geometric shape such th

Abstract: The present disclosure relates to processes and methods for producing a hydrophobic zone boundary that surrounds a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores such that the fluid contained within one hydrophilic layer region does not cross the hydrophobic zone boundary and the articles formed thereby and, more particularly, to processes and methods for producing a hydrophobic zone boundary that separates adjacent regions of a hydrophilic porous material layer mounted on a substrate, the hydrophilic porous material layer containing tortuous channels and pores mounted on a substrate such that a uniform hydrophobic zone boundary layer in the z-direction is formed in the hydrophilic porous material or the removal of the hydrophilic porous material layer from the substrate to form a hydrophilic porous material zone on the substrate, the so formed hydrophilic porous material zone having a predetermined geometric shape such th

Abstract: An improved combination non-luminescent microporous membrane and solid support for use in micro-analytical diagnostic applications is disclosed. Specifically, composite microarray non-luminescent slides having a microporous membrane effectively attached by covalent bonding through a surface treatment to a substrate that prepares the substrate to sufficiently, covalently bond to the non-luminescent microporous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the porous non-luminescent nylon composite microarray slides are covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating the non-luminescent composite microarray slides are also disclosed.

Abstract: An improved combination non-luminescent microporous membrane and solid support for use in micro-analytical diagnostic applications is disclosed. Specifically, composite microarray non-luminescent slides having a microporous membrane effectively attached by covalent bonding through a surface treatment to a substrate that prepares the substrate to sufficiently, covalently bond to the non-luminescent microporous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the porous non-luminescent nylon composite microarray slides are covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating lithe non-luminescent composite microarray slides are also disclosed.

Abstract: Improved composite microarray slides for use in micro-analytical diagnostic applications are disclosed. Specifically, composite microarray slides useful for carrying a microarray of biological polymers on the surface thereof including composite microarray slides having a porous membrane formed by a phase inversion process effectively attached by covalent bonding through chemical agents that comprise anchor/linker moieties to a substrate that prepares the substrate to sufficiently bond to the porous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the composite microarray slides are covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating the composite microarray slides are also disclosed.

Abstract: An improved combination non-luminescent microporous membrane and solid support for use in micro-analytical diagnostic applications is disclosed. Specifically, a multi-cell non-luminescent substrate having a porous membrane formed by a phase inversion process effectively attached by covalent bonding through a surface treatment to a substrate that prepares the substrate to sufficiently, covalently bond to the non-luminescent microporous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the porous non-luminescent nylon multi-cell substrate is covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus and methods for fabricating the non-luminescent multi-cell substrate are also disclosed.

Abstract: An improved combination microporous membrane and solid support for use in micro-analytical diagnostic applications is disclosed. Specifically, a multi-cell substrate useful for carrying a microarray of biological polymers on the surface thereof including a multi-cell substrate having a porous membrane formed by a phase inversion process effectively attached by covalent bonding through a surface treatment to a substrate that prepares the substrate to sufficiently, covalently bond to the microporous membrane formed by a phase inversion process such that the combination produced thereby is useful in microarray applications and wherein the porous nylon multi-cell substrate is covalently bonded to a solid base member, such as, for example, a glass or Mylar microscope slide, such that the combination produced thereby is useful in microarray applications. Apparatus for fabricating a multi-cell substrate is also disclosed.