This disclosure relates to synthetic oligosaccharide subunits of the Pseudomonas exosaccharide Psi and uses thereof, e.g., for epitope mapping of anti-Psl antibodies, for identification of anti-Psl antibodies, and for use as vaccines. In one aspect a synthetic oligosaccharide subunit of a Pseudomonas aeruginosa Psl oligosaccharide is provided, comprising the trisaccharide of formula I.

Provided are methods for detecting a target molecule or particle suspected to be present in a sample, comprising (a) contacting the sample with (i) a fusion molecule comprising a ligand capable of binding to the target molecule or particle and a binding domain, and (ii) a polymer scaffold comprising at least one binding motif to which the binding domain is capable of binding, under conditions that allow the target molecule or particle to bind to the ligand and the binding domain to bind to the binding motif; (b) loading the polymer into a device comprising a pore that separates an interior space of the device into two volumes, and configuring the device to pass the polymer through the pore from one volume to the other volume, wherein the device further comprises a sensor adjacent to the pore configured to identify objects passing through the pore; and (c) determining, with the sensor, whether the fusion molecule or particle bound to the binding motif is bound to the target molecule or particle, thereby detecting the presence of the target molecule or particle in the sample.

The present invention provides compositions and methods that can be used to determine a peptide signature for an antibody repertoire in a sample comprising multiple antibodies. The method can be used to characterize a phenotype in a sample, such as providing a diagnosis, prognosis or theranosis of a medical condition.

A method of determining an infection type in a subject is disclosed. The method comprises measuring the concentration of a first determinant selected from the group consisting of the determinants which are set forth in Table 1 and a second determinant selected from the group of the determinants which are set forth in Table 2 in a subject derived sample, wherein the concentration is indicative of the infection type.

The present specification discloses SNAP-25 compositions, methods of making -SNAP-25 antibodies that bind an epitope comprising a carboxyl-terminus at the P.sub.1 residue from the BoNT/A cleavage site scissile bond from a SNAP-25 cleavage product, -SNAP-25 antibodies that bind an epitope comprising a carboxyl-terminus at the P.sub.1 residue from the BoNT/A cleavage site scissile bond from a SNAP-25 cleavage product, methods of detecting BoNT/A activity, and methods of detecting neutralizing -BoNT/A antibodies.

Described herein are engineered microbe-targeting or microbe-binding molecules, kits comprising the same and uses thereof. Some particular embodiments of the microbe-targeting or microbe-binding molecules comprise a carbohydrate recognition domain of mannose-binding lectin, or a fragment thereof, linked to a portion of a Fc region. In some embodiments, the microbe-targeting molecules or microbe-binding molecules can be conjugated to a substrate, e.g., a magnetic microbead, forming a microbe-targeting substrate (e.g., a microbe-targeting magnetic microbead). Such microbe-targeting molecules and/or substrates and the kits comprising the same can bind and/or capture of a microbe and/or microbial matter thereof, and can thus be used in various applications, e.g., diagnosis and/or treatment of an infection caused by microbes such as sepsis in a subject or any environmental surface. Microbe-targeting molecules and/or substrates can be regenerated after use by washing with a low pH buffer or buffer in which calcium is insoluble.

A method of analyzing biological data containing expression values of a plurality of polypeptides in the blood of a subject. The method comprises: calculating a distance between a segment of a curved line and an axis defined by a direction, the distance being calculated at a point over the curved line defined by a coordinate along the direction. The method further comprises correlating the distance to the presence of, absence of, or likelihood that the subject has, a bacterial infection. The coordinate is defined by a combination of the expression values, wherein at least 90% of the segment is between a lower bound line and an upper bound line.

A barrel defines a channel, and has an opening into the channel, and an outlet from the channel. A porous carrier disposed within the channel carries an albumin. A cellulosic stationary phase is disposed within the channel between the carrier and the distal region of the barrel. A lateral flow platform is coupled to the barrel such that a sample pad of the lateral flow platform is in fluid communication with the outlet. A sponge, coupled to a plunger, is configured to hold saliva. The plunger is dimensioned to compress the sponge within the channel such that the saliva is driven (i) out of the sponge and through the carrier, dissolving at least some of the albumin, (ii) with the dissolved albumin, into the stationary phase, and (iii) as an eluate, out of the stationary phase, through the outlet, and onto the sample pad. Other embodiments are also described.

The inventions described herein relate generally to the methods for monitoring the health of the mammalian gut by checking for whether dysbiotic parameters exceed a threshold level or not. In particular, this invention is directed to the use of parameters which correlate with the level of bifidobacteria, especially Bifidobacterium longum subsp. infantis in the mammalian colon.

A device for the capture and adsorption of blood-borne materials of interest comprising a fluidic cartridge with at least one inlet and at least one outlet; a multidirectional fluidic channel between the at least one inlet and the at least one outlet; said multidirectional fluidic channel comprising at least one inner wall; and a substance coating at least a portion of the at least one inner wall of the multidirectional fluidic channel.