Indirect detection of Porphyromonas gingivalis in saliva, based on proteolytic cleavage by an Arg-specific gingipain (Arg-gingipain), has traditionally been used for simple, initial diagnosis of periodontitis. To accurately detect P. gingivalis using a point-of-care format, development of a simple biosensor that can measure the exact concentration of P. gingivalis is required. However, electrochemical detection in saliva is challenging due to the presence of various interfering electroactive species in different concentrations. Here, we report a washing-and separation-free electrochemical biosensor for sensitive detection of P. gingivalis in saliva. Glycine−proline−arginine conjugated with 4-aminophenol (AP) was used as an electrochemical substrate for a trypsin-like Arg-gingipain, and glycylglycine was used to increase the Arg-gingipain activity. The electrochemical signal of AP was increased using electrochemical−chemical (EC) redox cycling involving an electrode, AP, and tris(2-carboxyethyl)phosphine, and the electrochemical charge signal was corrected using the initial charge obtained before a 15 min incubation period. The EC redox cycling combined with the matrix-corrected signal facilitated a high and reproducible signal without requiring washing and separation steps. The proteolytic cleavage of the electrochemical substrate was specific to P. gingivalis. The calculated detection limit for P. gingivalis in artificial saliva was 5 × 10 5 colony-forming units/mL, and the concentration of P. gingivalis in human saliva could be measured. The developed biosensor can be used as an initial diagnosis method to distinguish between healthy people and patients with periodontal diseases.
It is more difficult to obtain high signal‐to‐background ratios in biosensors using electrochemical reduction than using electrochemical oxidation. Here, we present a method for trypsin detection using electrochemical reduction‐based redox cycling. Electrochemical‐enzymatic (EN) redox cycling and electrochemical‐chemical (EC) redox cycling for trypsin detection were tested and compared. Trypsin cleaves a peptide bond in an electrochemically inactive p‐aminophenol (AP)‐conjugated oligopeptide, and this cleavage results in the release of electrochemically active AP, which is involved in EN and EC redox‐cycling reactions. Horseradish peroxidase and cytochrome c (Cyt c) were tested as redox enzymes for EN redox cycling involving a redox enzyme and H2O2. Cyt c was better than horseradish peroxidase, as its use resulted in lower background levels. The trypsin detection based on the EN redox cycling involving Cyt c and H2O2 (~50 ng/mL) exhibited lower detection limits than the detection based on EC redox cycling involving IO3− (~100 ng/mL), because of higher signal levels.
Various methods have been developed for the detection of Escherichia coli (E. coli); however, they are complex and time-consuming. OmpTa cell membrane endopeptidase of E. colistrongly embedded in the outer membrane of only E. coli, exposed to external solutions, with high proteolytic activity, could be a suitable target molecule for the rapid and straightforward detection of E. coli. Herein, a wash-free, sensitive, and selective amperometric method for E. coli detection, based on rapid and specific proteolytic cleavage by OmpT, has been reported. The method involved (i) rapid proteolytic cleavage of consecutive amino acids, after cleavage by OmpT, linked to an electrochemical species (4-aminophenol, AP), by leucine aminopeptidase (LAP, an exopeptidase), (ii) affinity binding of E. coli on an electrode, and (iii) electrochemical-enzymatic (EN) redox cycling. OmpT cleaved the intermediate peptide bond of a peptide substrate containing alaninearginine-arginine-leucine-AP (−A-R-R-L-AP), forming R-L-AP, followed by the cleavage of two peptide bonds of R-L-AP sequentially by LAP, to liberate an electroactive AP. Affinity binding and EN redox cycling, in addition to rapid proteolytic cleavage by OmpT and LAP, enabled high electrochemical signal amplification. Two-sequential-cleavage was employed for the first time in protease-based detection. The calculated detection limit for E. coli cells in tap water (approximately 10 3 CFU/mL after 1 h incubation) was lower than those obtained without affinity binding and EN redox cycling. The detection method was highly selective to E. coli as OmpT is present in only E. coli. High sensitivity, selectivity, and the absence of wash steps make the developed detection method practically promising.
Propagating cascade reactions based on two enzymes have been used to achieve high signal amplification in biosensors wherein one enzyme continually triggers the activation of the other enzyme that produces signaling species. However, in many cases, biosensors that use cascade reactions are not sensitive enough to allow low detection limits because of the inherent slowness of proteolytic reactions. This paper reports a sensitive electrochemical immunosensor using a high-signal-amplification method that combines a propagating cascade reaction and a redox cycling reaction. The cascade reaction uses ecarin and prothrombin: the ecarin label proteolytically converts inactive prothrombin into active thrombin, which then proteolytically liberates electroactive p-aminophenol (AP) from an AP-conjugated peptide. The liberated AP is electrochemically oxidized to p-benzoquinone imine (QI), regenerated by the reduction of QI by NADH, and then electrochemically reoxidized. This electrochemical−chemical (EC) redox cycling reaction significantly increases the electrochemical signal. The developed immunosensor is also compared with an immunosensor that uses only a propagating cascade reaction and an immunosensor that uses a single proteolytic reaction and an EC redox cycling reaction. The detection limits for thyroid-stimulating hormone (TSH) obtained using the three immunosensors are 3 pg/mL, 2 ng/mL, and 4 ng/mL, respectively, indicating that the newly developed immunosensor is more sensitive than the others. The measured concentrations of TSH in clinical serum were found to agree well with those determined using a commercial instrument, indicating that the immunosensor is highly promising for sensitive detection of biomolecules. Keyword: Electrochemical biosensor, Cascade reaction, Redox cycling, Proteolytic reaction
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