Botulinum Neurotoxin C Dual Detection through Immunological Recognition and Endopeptidase Activity Using Porous Silicon Interferometers.

Botulinum neurotoxins (BoNTs) are the most potent toxins known in nature produced by Clostridium botulinum strains, which can cause life-threatening diseases in both humans and animals. The latter is of serious environmental and economic concern, resulting in high mortality, production losses, and rejection of contaminated animal feed. The available in vivo mouse assay is inadequate for real-time and on-site assessment of outbreaks. Herein, we present a reflective-based approach for the detection of BoNT/C while estimating its activity. Two adjacent porous Si Fabry-Pérot interferometers are simultaneously utilized to quantify minute BoNT/C concentrations by a competitive immunoassay and to assess their endopeptidase activity. The reflectivity signals of each interferometer are amplified by biochemical reaction products infiltration into the scaffold or by peptide fragments detachment from the nanostructure. The optical assay is highly sensitive in compliance with the in vivo approach by presenting a detection limit of 4.24 pg mL-1. The specificity and selectivity of the designed platform are cross-validated against BoNT/B and BoNT/D, also relevant to animal health. Finally, the analytical performances of both interferometers for real-life scenarios are confirmed using actual toxins while depicting excellent compliance to complex media analysis. Overall, the presented sensing scheme offers an efficient, rapid, and label-free approach for potential biodiagnostic elucidation of botulism outbreaks.

Inflammatory biomarker detection in milk using label-free porous SiO2 interferometer.

N-acetyl-ß-d-glucosaminidase (NAGase) is an established indicative biomarker released upon damage or necrosis of tubular epithelial cells in both humans and animals, indicating severe nephrological disorders and bovine mastitis (BM), respectively. The latter is the most common and costly disease in dairy cattle associated with production losses, elevated somatic cell counts and deteriorated health status. Herein, we report on a reflective based assay for early diagnosis of BM through the analysis of NAGase inherent content found in whole milk samples using a miniaturized optical transducer. Gelatin functionalized porous Si Fabry-Pérot interferometers are employed for monitoring the lysosomal activity in various stages of the inflammation (healthy, subclinical and clinical). The enzymatic reaction products precipitate and accumulate within the porous nanostructure, thus alter the average refractive index monitored using reflectometric interference spectroscopy. The optical assay is calibrated within the clinically relevant concentrations of BM while presenting a dynamic range of 1.04-16.7 µM min-1 and the detection limit of 0.49 µM min-1. The specific optical performance of the biosensor correlates with a gold standard laboratory-based approach, in which escalated somatic cell counts reveal augmented NAGase levels and thus severe pathogenesis. Overall, our study provides new opportunities to develop a convenient bio-diagnostic sensing system for BM detection and classification by addressing the limitations of conventional practices.

Deceiving SARS-CoV-2 molecular-tropism clues - A combinational contemporary strategy.

Several attempts to control the dreadfulness of SARS-CoV-2 are still underway. Based on the literature evidences we have speculated a prospective contemporary remedy, which was categorized into Specificity, Remedy, and a Conveyor. In which, pros and cons were discussed and inferred the possible alternatives. (a) Specificity: Implicit to express the ACE2 receptors in conveyor cells to deceive SARS-CoV-2 frompreponetargets. (b) Remedy: As depletion of pulmonary surfactants causes strong acute respiratory distress syndrome, we propose an entity of a cost-effective artificialsurfactantsystem as a remedy to pulmonary complications. (c) Conveyor: We propose red blood cells (RBCs) as a conveyor with embedded artificial surfactant and protruding ACE2 receptors for the target-specific delivery. Overall we postulate focused insights by employing a combinational contemporary strategy to steer towards a prospective direction on combating SARS-CoV-2.

Porous Silicon Fabry-Pérot Interferometer for N-Acetyl-ß-d-Glucosaminidase Biomarker Monitoring.

Bovine mastitis (BM) is a prominent inflammatory disease affecting the dairy industry worldwide, originated by pathogenic agent invasion onto the mammary gland. Early detection of new BM cases is of high importance for infection control within the herd. Conventional analytical techniques lack the ability to detect BM-predicting biomarkers, used as analytical indicators for health status evaluation, in real time or outside the laboratory boundaries. Herein, we describe a biosensing platform for label-free detection and identification of BM onset through targeting N-acetyl-ß-d-glucosaminidase (NAGase) for potential evidence-based therapy. The lysosomal activity in dissimilar milk qualities was monitored by a gelatin-functionalized porous Si Fabry-Pérot interferometer, while estimating the biochemical reaction precipitating products within the nanostructure. The optical response was proportional to the inherent NAGase concentration found in real milk samples, influenced by two dominant BM causative pathogens (i.e., Escherichia coli and Streptococcus dysgalactiae) at various somatic cell counts. Quantitative analysis of NAGase levels within the entire inflammatory spectrum (healthy, subclinical, and clinical BM) was obtained within the range of 1.0-4.2 µM/min (enzymatic activity per volume unit), while presenting a detection limit of 0.51 µM/min. The optical performances correspond with standardized biochemical activity assay in dissimilar milk qualities. Overall, the presented sensing concept exhibits the potential of BM-predicting biomarker detection using a simple and portable experimental setup for convenient early biodiagnostics and health status evaluation.