Assay for filtration of suspended particles in microporous membranes

What is claimed is: 1 . A method of assessing a membrane, the method comprising: calculating fluid dynamic characteristics of at least one of a membrane and a material to be passed through the membrane from an inlet end of the membrane to an outlet end of the membrane, the membrane comprises a plurality of rows and a plurality of teardrop structures arranged in the plurality of rows, the material comprises particles; obtaining characteristics of at least one force acting on the particles of the material to be passed through the membrane due to the interaction between the particles and the membrane, the at least one force being an intermolecular force; and combining the calculated fluid dynamic characteristics and the obtained characteristics to assess the flow of the material through the membrane. 2 . The method of claim 1 , further comprising improving at least one characteristic of the membrane in relation to the material. 3 . The method of claim 2 , wherein improving at least one characteristic comprises improving the capture or release of particles by the membrane. 4 . The method of claim 1 , wherein calculating fluid dynamic characteristics comprises computation of the fluid and particle drag mechanics associated with the material in at least two spatial dimensions. 5 . The method of claim 1 , wherein obtaining characteristics of at least one force comprises measuring the intermolecular forces between the membrane and the particles. 6 . The method of claim 1 , wherein the teardrop structures in each row are arranged such that a bulbous end of each teardrop structure is oriented toward the outlet end of the membrane. 7 . The method of claim 1 , wherein the teardrop structures in each row are arranged at the same angle with respect to an anticipated direction of flow through the membrane. 8 . The method of claim 7 , further comprising that rows of the teardrop structures in which the structures are at an angle of 10° alternate with rows of the teardrop structure in which the structures are at an angle of −10° relative to the anticipated direction of flow through the membrane. 9 . The method of claim 7 , further comprising that rows of the teardrop structures in which the structures are at an angle of 45° alternate with rows of the teardrop structure in which the structures are at an angle of −45° relative to the anticipated direction of flow through the membrane. 10 . The method of claim 7 , further comprising that rows of the teardrop structures in which the structures are at an angle of 70° alternate with rows of the teardrop structure in which the structures are at an angle of −70° relative to the anticipated direction of flow through the membrane. 11 . The method of claim 7 , further comprising that rows of the teardrop structures in which the structures are at an angle of 170° alternate with rows of the teardrop structure in which the structures are at an angle of −170° relative to the anticipated direction of flow through the membrane. 12 . The method of claim 1 , wherein the membrane is formed of a microporous hydrophilic polymer material. 13 . A microporous membrane, comprising a plurality of rows and a plurality of structures having a uniform shape arranged in the plurality of rows, the microporous membrane having an anticipated direction of flow through the membrane from an inlet end of the membrane toward an outlet end of the membrane, wherein the structures in each row are arranged at the same angle with respect to the anticipated direction of flow through the membrane, the structures in each row being arranged to have the same orientation toward the outlet end of the membrane. 14 . The microporous membrane of claim 13 , wherein the plurality of structures are teardrop structures. 15 . The microporous membrane of claim 14 , wherein the anticipated direction of flow through the membrane is from an inlet end of the membrane to an outlet end of the membrane, and wherein the teardrop structures in each row are arranged such that a bulbous end of each teardrop structure is oriented toward the outlet end of the membrane. 16 . The microporous membrane of claim 13 , further comprising that rows of the structures in which the structures are at an angle of 10° alternate with rows of the structure in which the structures are at an angle of −10° relative to the anticipated direction of flow through the membrane. 17 . The microporous membrane of claim 13 , further comprising that rows of the structures in which the structures are at an angle of 45° alternate with rows of the structure in which the structures are at an angle of −45° relative to the anticipated direction of flow through the membrane. 18 . The microporous membrane of claim 13 , further comprising that rows of the structures in which the structures are at an angle of 70° alternate with rows of the structure in which the structures are at an angle of −70° relative to the anticipated direction of flow through the membrane. 19 . The microporous membrane of claim 13 , further comprising that rows of the structures in which the structures are at an angle of 170° alternate with rows of the structure in which the structures are at an angle of −170° relative to the anticipated direction of flow through the membrane. 20 . The microporous membrane of claim 13 , wherein the membrane is formed of a hydrophilic polymer material.