Abstract: A device, method, and system for the detection of ribosome inactivating protein activity, including the ricin toxin, in a sample. According to one embodiment, the ribosome inactivating protein in the sample removes an adenine from a labeled DNA substrate to create an abasic site. An AP lyase can then cleave the DNA substrate at the abasic site, allowing the fluorophore located at or near one end of the DNA substrate and the quencher at or near the other end of the DNA substrate to spatially separate. Once the fluorophore and the quencher are sufficiently separated, the fluorophore will emit a fluorescence signal. Increasing fluorescence, indicating ribosome inactivating protein activity, will be monitored in real time using a detection system.

Abstract: A method for identifying a dairy animal, the method comprising the steps of: providing an identification system comprising an imaging device and a database of stored vein patterns; obtaining at least one image of at least a portion of an udder of the dairy animal; extracting a vein pattern from the at least one image; comparing the extracted vein pattern to the database of stored vein patterns; and identifying, based on said comparison, the dairy animal in the database of stored vein patterns.

Abstract: A method for identifying mastitis in a dairy animal, the method including the steps of: (i) identifying a dairy animal suspected of being affected by mastitis; (ii) collecting a sample of milk from the identified dairy animal; (iii) analyzing the sample for the presence of one or more mastitic bacteria; (iv) analyzing the sample for the presence of one or more mastitic pathogens; (v) identifying, if the presence of one or more mastitic bacteria is indicated, the mastitic bacteria in the sample; and (vi) determining, based on the identified mastitic bacteria in the sample, a management decision for the dairy animal.

Abstract: A method for identifying a dairy animal, the method comprising the steps of: providing an identification system comprising an imaging device and a database of stored vein patterns; obtaining at least one image of at least a portion of an udder of the dairy animal; extracting a vein pattern from the at least one image; comparing the extracted vein pattern to the database of stored vein patterns; and identifying, based on said comparison, the dairy animal in the database of stored vein patterns.

Abstract: A real-time portable and rapid detection assay to identify the presence of biologically active toxins such as botulinum toxins. The proteolytic activity of BoNT/A is measured using a peptide cleavage assay, where a fluorescent substrate is cleaved by BoNT/A, resulting in increased fluorescence. This fluorescence can be monitored in real-time using a fluorescence detection instrument, such as a real-time PCR system that has been modified to implement a detection algorithm specific to the identification of the target toxin.

Abstract: A real-time portable and rapid detection assay to identify the presence of biologically active toxins such as botulinum toxins. The proteolytic activity of BoNT/A is measured using a peptide cleavage assay, where a fluorescent substrate is cleaved by BoNT/A, resulting in increased fluorescence. This fluorescence can be monitored in real-time using a fluorescence detection instrument, such as a real-time PCR system that has been modified to implement a detection algorithm specific to the identification of the target toxin.

Abstract: A real-time portable and rapid detection assay to identify the presence of biologically active toxins such as botulinum toxins. The proteolytic activity of BoNT/A is measured using a peptide cleavage assay, where a fluorescent substrate is cleaved by BoNT/A, resulting in increased fluorescence. This fluorescence can be monitored in real-time using a fluorescence detection instrument, such as a real-time PCR system that has been modified to implement a detection algorithm specific to the identification of the target toxin.

Abstract: A real-time portable and rapid detection assay to identify the presence of biologically active toxins such as botulinum toxins. The proteolytic activity of BoNT/A is measured using a peptide cleavage assay, where a fluorescent substrate is cleaved by BoNT/A, resulting in increased fluorescence. This fluorescence can be monitored in real-time using a fluorescence detection instrument, such as a real-time PCR system that has been modified to implement a detection algorithm specific to the identification of the target toxin.

Abstract: A device, method, and system for the detection of ribosome inactivating protein activity, including the ricin toxin, in a sample. According to one embodiment, the ribosome inactivating protein in the sample removes an adenine from a labeled DNA substrate to create an abasic site. An AP lyase can then cleave the DNA substrate at the abasic site, allowing the fluorophore located at or near one end of the DNA substrate and the quencher at or near the other end of the DNA substrate to spatially separate. Once the fluorophore and the quencher are sufficiently separated, the fluorophore will emit a fluorescence signal. Increasing fluorescence, indicating ribosome inactivating protein activity, will be monitored in real time using a detection system.