Methods and apparatus for rapid, culture free pathogen detection. The methods utilize optical spectroscopy techniques to identify and/or characterize pathogens in a sample via the detection of unique properties and/or analytes that are specific to particular pathogens.

Described herein are engineered microbe-targeting or microbe-binding molecules, kits comprising the same and uses thereof. The microbe-targeting or microbe-binding molecules can comprise a microbe surface-binding domain linked to a portion of an Fc region. Further, the microbe-targeting molecules can be conjugated to substrate (e.g., a magnetic particle) to form a microbe-targeting substrate. Such microbe-targeting molecules and/or substrates and the kits comprising the same can be used in various applications, such as diagnosis and/or treatment of an infection caused by microbes. Moreover, the microbe-targeting molecules and/or substrates can be easily regenerated after use.

The present disclosure relates generally to detection of contamination of a sample or diagnosis of subject based upon detection or quantification of amino acid sequences in a sample, specifically to the identification and use of molecular biomarkers for Candida albicans biofilm infections.

Anti-CaENO1 antibodies and humanized antibodies are provided as an effective diagnostic agent or a therapeutic treatment against infections caused by Candida spp., preferably Candida albicans, Candida tropicalis, fluconazole resistance Candida spp., Strepcococcus, Staphylococcus.

The present disclosure provides methods for determining whether a subject has a fungal infection such as candidemia, or is at risk of developing the same, and methods of treating the subject based on the determination. This determining may include rapid detection of one or multiple pathogen classes at once, such as fungal, viral and bacterial. Systems useful for the same are also provided.

A method for characterizing at least one microorganism from a sample includes identifying the at least one microorganism and determining the properties of typing, potential resistance to at least one antimicrobial, and virulence factor. The properties of typing, resistance to at least one antimicrobial, and virulence factor for the at least one microorganism are determined by implementing mass spectrometry using proteins, peptides and/or metabolites as markers of the properties of typing, resistance to at least one antimicrobial, and virulence factor.

A method for rapid differential diagnosis of infection using supercritical fluid chromatographic separation of quorum sensing molecules as biomarkers for infection agents.

The invention is directed to methods for identifying targets for antimicrobial and antiproliferative compounds as well as methods for identifying novel compounds for treating cancer and microbial infections.

The present invention provides novel compounds (e.g., compounds of Formula (I)), and pharmaceutically acceptable salts, solvates, hydrate, polymorphs, co-crystals, tautomers, stereoisomers, isotopically labeled derivatives, prodrugs, and compositions thereof. Also provided are methods and kits comprising the inventive Compounds, or compositions thereof, for treating and/or preventing a fungal or protozoan infection, inhibiting the activity of a fungal or protozoan enzyme, killing a fungus or protozoan, or inhibiting the growth of a fungus or protozoan. The fungus may be a Candida species, Sacchawmyces species, or other pathogenic fungal species. The compounds of the invention may inhibit the activity of fungal or protozoan mitochondrial phosphate carrier protein.

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.