Abstract: There is disclosed a PCR-based test kit and PCR process for identification of multiple clonal sub-species lineages of infectious bacteria, such as uropathogenic E. coli causing cystitis, pyelonephritis and urosepsis, for the purposes of predicting antibiotic resistance of the bacteria. More specifically, there is further disclosed a SNP (single nucleotide polymorphism) identification process that simultaneously detect compilations of the presence of absence of predictive SNPs within mutated loci of infectious bacterial clonal subspecies variants, such as the fumC/fimH loci of the E. coli bacterium. This disclosure provides a PCR detection kit incorporating a SNP compilation that forms a BFC (Binary Footprint Code) that allows for rapid identification of multiple infectious bacterial clonotypes based on their SNP footprint. More specifically there is disclosed a clonotyping method for clonal typing E.

Abstract: Methods, compositions and devices are provided based on changing the binding strength of an adhesion molecule to a ligand by changing the force exerted on the bound complex between adhesion molecule and ligand, for example by changing the shear stress acting on the complex. The adhesion molecules and their ligands of this invention bind more tightly when a force-activated bond stress, such as shear force, applied to the adhesion molecules is increased, and bond less tightly when the stress is decreased. The adhesion molecules can be isolated from their sources in nature or can remain attached to their natural sources. They can be engineered, e.g., by altering their amino acid sequences or by binding to antibodies or other particles, to alter their binding properties.

Abstract: Methods, compositions and devices are provided based on changing the binding strength of an adhesion molecule to a ligand by changing the force exerted on the bound complex between adhesion molecule and ligand, for example by changing the shear stress acting on the complex. The adhesion molecules and their ligands of this invention bind more tightly when a force-activated bond stress, such as shear force, applied to the adhesion molecules is increased, and bond less tightly when the stress is decreased. The adhesion molecules can be isolated from their sources in nature or can remain attached to their natural sources. They can be engineered, e.g., by altering their amino acid sequences or by binding to antibodies or other particles, to alter their binding properties.