Paper-based electrochemical peptide sensor for label-free and rapid detection of airborne Bacillus anthracis simulant spores.

Bacillus anthracis is a fatal biological warfare agent, with a mortality rate of almost 100% when the bacteria are inhaled. Therefore, developing a biosensor for rapidly detecting B. anthracis spores in the ambient air is critical. Conventional techniques tend to be time-consuming, labor-intensive, and require highly trained personnel, thereby preventing rapid onsite detection. Moreover, low-cost, stable probes are required for continuous monitoring of multiple airborne targets. This study presents a paper-based electrochemical peptide sensor for rapid, label-free, sensitive, and economical quantification of liquid-borne and airborne Bacillus subtilis spores, widely used nonpathogenic B. anthracis simulant spores. These sensors were fabricated using wax printing on Whatman filter paper along with stencil-printed carbon paste electrodes and Ag/AgCl ink, as well as subsequent peptide (NHFLPKV) immobilization. These low-cost quickly fabricated sensors were characterized by differential pulse voltammetry and could detect spore concentrations as low as 6.9 × 102 colony-forming units (CFU) mL-1 in 30 min with high specificity towards the spores and stability. Furthermore, spore concentrations were determined from air samples obtained using the BioSampler, which demonstrated that these measurements agreed with those using the plate-counting assay; therefore, the surface proteins of the spores were intact through sampling with the BioSampler. These paper-based peptide sensors can be used for onsite rapid and continuous airborne spore-monitoring systems. • The first study to use a peptide-immobilized electrochemical paper-based sensor for detection of whole bacteria. • Rapid, label-free, sensitive, and economical quantification of airborne B. subtilis spores is presented. • The sensors detected spore concentrations as low as 6.9 × 102 CFU/mL in 30 min with low-cost and fast fabrication. • Measurements of air-sampled spores agreed with those using the plate-counting assay. • The surface proteins of the spores were intact through sampling with the BioSampler. [ABSTRACT FROM AUTHOR]