A device for determining presence or absence of infection due to an infectious agent is described. The device comprises a sample receiving zone configured to receive a liquid sample from a subject suspected of having an infection due to an infectious agent, the sample receiving zone positioned to distribute the sample along a first fluid flow path to a first label zone and along a second fluid flow path to a second label zone. Test lines in each fluid flow path capture a mobile detectable species as an indicator of presence or absence of the infectious agent. The device also comprises a reference line positioned in the one of the fluid flow paths. The bidirectional fluid flow paths emanate from a common sample zone and provide an efficient approach to detection and differentiate two species as indicators of the same infectious agent or as indicators of two different infectious agents.

The present invention provides for engineered molecular opsonins that may be used to bind biological pathogens or identify subclasses or specific pathogen species for use in devices and systems for treatment and diagnosis of patients with infectious diseases, blood-borne infections or sepsis. An aspect of the invention provides for mannose-binding lectin (MBL), which is an abundant natural serum protein that is part of the innate immune system. The ability of this protein lectin to bind to surface molecules on virtually all classes of biopathogens (viruses, bacteria, fungi, protozoans) make engineered forms of MBL extremely useful in diagnosing and treating infectious diseases and sepsis.

The invention provides methods, kits, compositions, and devices useful for detection of antibodies that bind to Ehrlichia antigens and/or for differentiation of certain Ehrlichia species from others. In particular, the invention provides methods and kits useful for identifying species of Ehrlichia using populations of isolated peptides.

Methods and compositions for the treatment of Brucella induced diseases and disorders are disclosed herein. In preferred embodiments, the invention relates to vaccines. In additional embodiments, the invention relates to formulations capable of releasing said vaccines at a controlled rate of release in vivo. In further embodiments, the invention relates to modified strains of the bacteria Brucella melitensis and Brucella abortus. In still further embodiments, the invention relates to compositions that do not induce clinical symptoms or splenomegaly in a subject receiving said compositions.

Disclosed herein are methods and systems for rapid diagnosis and treatment of biofilm-related infections in a subject having a medical implant. A reporter cocktail composition is disclosed herein and may be used to detect a microorganism of interest and determine the presence of an infection. A therapeutic cocktail composition is also disclosed herein and may be used to treat a subject diagnosed with a biofilm-related infection.

The present invention refers to a method for the production of live attenuated bacterial strains, suitable as vaccine candidates, comprising the steps of: A. providing a bacterial strain capable of expressing glutamate racemase and possibly D-amino acid transaminase and comprising a peptidoglycan cell wall, and B. inactivating the gene or genes encoding for the glutamate racemase enzyme and, if needed, the gene or genes encoding for the enzyme D-amino acid transaminase in such way that the bacterial strain is no longer capable of expressing a functional glutamate racemase and/or a functional D-amino acid transaminase;
wherein the inactivation of said genes causes said bacterial strain to be auxotrophic for D-glutamate.

The invention relates to a method for labeling specifically living bacteria, comprising the steps of: a) incubating said bacteria of said sample with at least one modified monosaccharide compound comprising a first reactive chemical group capable to chemically react with a second reactive group, so that a residue bearing said first reactive group is incorporated into the envelope of such bacteria, and b) contacting said modified monosaccharide residue incorporated within the envelope of the bacteria with a labeling molecule comprising a said second reactive group, for generating the chemical reaction of said first reactive group with said second reactive group, characterized in that said modified monosaccharide compound has the following formula (I), or a salt thereof: Wherein —A, B and C can be independently H, OH, NH.sub.2, OH and NH.sub.2 being substituted or not by protecting groups thereof and —D is an alkyl chain in C.sub.2 to C.sub.4, each carbon being substituted or not by OH or NH.sub.2, OH and NH.sub.2 being substituted or not by protecting groups thereof and —at least one of A, B, C or D groups is substituted by a said first reactive group. ##STR00001##

This application relates to assays, devices, and methods for conducting highly sensitive assays that employ two binding agents and are useful in detecting specific targets such as antigens. These devices and methods provide the ability to detect minute amounts of the specific target with reduced risk of false positive results.

A method for rapid antibiotic susceptibility testing by tracking sub-micron scale motion of single bacterial cells including obtaining a biological sample from a subject including live bacteria. Different doses of antibiotic are added to a multi-well glass slide and adding portions of the biological sample to the wells. Bacterial cells are tethered onto the surface. The tethered bacterial cells are imaged and tracked. Bacterial sub-micron motion of tethered cells is measured at the different doses. A processor performs statistical analysis on a population of cells for each antibiotic dose to generate an antibiotic dose curve proportional to the motion changes, where the antibiotic dose curve plots data including a decrease in movement over time indicating a proportional effectiveness of an antibiotic applied to a well.

A multiplexed vertical flow serodiagnostic testing device for diseases such as Lyme disease includes one or more multi-piece cassettes that include vertical stacks of functionalized porous layers therein. A bottom piece of the cassette includes a sensing membrane with a plurality of spatially multiplexed immunoreaction spots or locations. Top pieces are used to deliver sample and/or buffer solutions along with antibody-conjugated nanoparticles for binding with the immunoreaction spots or locations. A colorimetric signal is generated by the nanoparticles captured on the sensing membrane containing disease-specific antigens. The sensing membrane is imaged by a cost-effective portable reader device. The images captured by the reader device are subject to image processing and analysis to generate positive (+) or negative (−) indication for the sample. A concentration of one or more biomarkers may also be generated. The testing device is rapid, simple, inexpensive, and allows for simultaneous measurement of multiple antibodies and/or antigens making it an ideal point-of-care platform for disease diagnosis.