Validation of Workflow Changes, Phage Concentration and Reformatted Detection Threshold for the Sample6 DETECT/L™ Test: Level 3 Modification.

The AOAC Research Institute Performance Tested MethodsSM Program certified Sample6 DETECT/L™ in April 2014 (Certification No. 041401) for the detection of Listeria species (L. monocytogenes, L. innocua, L. ivanovii, L. seeligeri, L. marthii, L. welshimeri) on stainless steel environmental surfaces. A modification was approved in January 2016, increasing the concentration of sanitizer-neutralizing reagents in detection reagents, increasing the number of phage in the detection solution, and increasing the sample test volume. Moreover, changes to reduce the number of negative controls and add compatibility with polyurethane sponges were also approved. In this modification, to ensure that DETECT/L continues to meet performance expectations, Sample6 evaluated workflow changes to enhance sensitivity and the ease-of-use of the assay. Changes to the phage concentration and detection threshold, plus the inclusion of a confirmation step (DETECT Check), were validated to obtain better accuracy and optimize assay performance. Inclusivity, exclusivity, and robustness testing were conducted by Sample6 to evaluate the changes. A third-party laboratory compared the DETECT/L assay and the U.S. Department of Agriculture reference method in a stainless steel environmental surface matrix study. The data presented in this report demonstrate that the changes proposed to the DETECT/L assay meet or exceed the performance in the current configuration.

The Validation of the Sample6 DETECTTM HT/L for AOAC Research Institute.

BACKGROUND: Listeria spp. are an important foodborne human pathogen because of their ability to cause disease and high mortality in individuals, particularly pregnant women, neonates, the elderly, immunocompromised individuals, and children. The Sample6 DETECTTM HT/L Kit is a semi-automated qualitative pathogen detection system designed to detect Listeria spp. (L. monocytogenes, L. innocua, L. ivanovii, L. seeligeri, L. welshimeri, and L. marthii) in environmental samples using the Sample6 BioIlluminationTM technology. OBJECTIVE: The study was done to evaluate the Sample6 DETECT HT/L Kit. The assay was evaluated for inclusivity, exclusivity, robustness, product consistency, and stability, and a matrix study of one environmental surface. METHODS: The performance of the Sample6 DETECT HT/L was compared with U.S. Food and Drug Administration reference culture method for Listeria using an unpaired study design. RESULTS: The Sample6 DETECT HT/L assay correctly identified all 50 inclusivity isolates and correctly excluded all 30 nontarget strains evaluated. The assay was not affected by minor variations in incubation temperature and time, or sample volume. Results across three production lots spanning the shelf life of the assay were consistent. In the matrix study, the Sample6 DETECT HT/L for Listeria correctly identified each test portion for the presence or absence of Listeria, and there were no statistically significant differences between candidate and reference method results. CONCLUSIONS: The data collected in this study demonstrate that the Sample6 DETECT HT/L assay is a reliable method for the detection of Listeria spp. on stainless-steel environmental surfaces after 22 h of enrichment.

Serotype-specific structural differences in the protease-cofactor complexes of the dengue virus family.

With an estimated 40% of the world population at risk, dengue poses a significant threat to human health, especially in tropical and subtropical regions. Preventative and curative efforts, such as vaccine development and drug discovery, face additional challenges due to the occurrence of four antigenically distinct serotypes of the causative dengue virus (DEN1 to -4). Complex immune responses resulting from repeat assaults by the different serotypes necessitate simultaneous targeting of all forms of the virus. One of the promising targets for drug development is the highly conserved two-component viral protease NS2B-NS3, which plays an essential role in viral replication by processing the viral precursor polyprotein into functional proteins. In this paper, we report the 2.1-A crystal structure of the DEN1 NS2B hydrophilic core (residues 49 to 95) in complex with the NS3 protease domain (residues 1 to 186) carrying an internal deletion in the N terminus (residues 11 to 20). While the overall folds within the protease core are similar to those of DEN2 and DEN4 proteases, the conformation of the cofactor NS2B is dramatically different from those of other flaviviral apoprotease structures. The differences are especially apparent within its C-terminal region, implicated in substrate binding. The structure reveals for the first time serotype-specific structural elements in the dengue virus family, with the reported alternate conformation resulting from a unique metal-binding site within the DEN1 sequence. We also report the identification of a 10-residue stretch within NS3pro that separates the substrate-binding function from the catalytic turnover rate of the enzyme. Implications for broad-spectrum drug discovery are discussed.