We report the fabrication of an amperometric NADH biosensor system that employs an allosterically modulated bacterial reductase in an adapted osmium(III)-complex-modified redox polymer film for analyte quantification. Chains of complexed Os(III) centers along matrix polymer strings make electrical connection between the immobilized redox protein and a graphite electrode disc, transducing enzymatic oxidation of NADH into a biosensor current. Sustainable anodic signaling required (1) a redox polymer with a formal potential that matched the redox switch of the embedded reductase and avoided interfering redox interactions and (2) formation of a cross-linked enzyme/polymer film for stable biocatalyst entrapment. The activity of the chosen reductase is enhanced upon binding of an effector, i.e. p-hydroxy-phenylacetic acid ( p-HPA), allowing the acceleration of the substrate conversion rate on the sensor surface by in situ addition or preincubation with p-HPA. Acceleration of NADH oxidation amplified the response of the biosensor, with a 1.5-fold increase in the sensitivity of analyte detection, compared to operation without the allosteric modulator. Repetitive quantitative testing of solutions of known NADH concentration verified the performance in terms of reliability and analyte recovery. We herewith established the use of allosteric enzyme modulation and redox polymer-based enzyme electrode wiring for substrate biosensing, a concept that may be applicable to other allosteric enzymes.
We report a novel system for glucose estimation in model and real samples, utilizing enzyme-modified pencil leads (PL) as effective electrochemical biosensors for robotic substrate quantification in 24-well microplates. Electrochemically formed carboxyl groups on the surface of the graphite were cross-linked to amino groups in the enzyme so as to attach glucose oxidase to the PL surface. Automated amperometric sensing of glucose solutions in microtiter-plate wells used computer-controlled stepper motors to move the biosensor/counter/reference electrode assemblies sequentially between the samples. This setup achieved stable analyte response and, in calibration trials, a linear response range and detection limit of 0.1-8 mM and 0.05 ± 0.01 mM, respectively. The biosensor microplate assay offered accurate "hands-off" evaluation of 4 or 20 samples per plate run, in the standard addition or calibration curve mode, respectively. Mode-independent glucose assays in standard solutions and human serum samples worked reproducibly with close to 100% recovery. The choice of cheap and practical PL enzyme biosensors and simple nonmicrofluidic measurement automation offers a convenient, labor- and cost-efficient form of quantitative biosensing, with a reduced risk of operator errors. The robotic approach is best suited to repetitive measurements of sample series, with academic research and clinical, environmental, pharmaceutical, or biotechnological analysis being potential areas for future exploitations of the methodology.
For sustainable high‐quality biosensor preparation, the biopolymers zein and gelatin are placed on Pt electrodes as base‐ and top‐coats, respectively, through simple drop‐and‐dry addition. The gelatin top‐coat of the biocompatible sandwich supports covalent external attachment of glucose oxidase (GOx), ensuring easy access of substrate to enzyme, while the lower, selectively permeable zein base‐coat protects electro‐oxidative detection of enzymically‐produced hydrogen peroxide from interferents. The functional cooperativity between gelatin‐GOx immobilization and molecular filtering by zein produced signal linearity up to 1 mm glucose, a sub‐µm practical detection limit, a rapid response time, a long shelf‐life, and excellent glucose analytical quality testing even with serum samples with intentionally elevated levels of interferents. This demonstrates for the first time the exceptional power of the cooperative action of two natural polymers in the ecofriendly improvement of a biosensor. The excellent performance of the novel biosensor design is confirmed here using GOx as a model, however, its application to other enzymes, antibodies, and DNA is feasible, offering economical biosensing while utilizing green functional materials. Moreover, the successful establishment of the cooperative dual biopolymer functionality on mass‐fabricated commercial screen‐printed electrode platforms verify the essential suitability of this methodology for portable clinical and personal health care monitoring.
We report an amperometric biosensor for the urinary disease biomarker para-hydroxyphenylacetate (p-HPA) in which the allosteric reductase component of a bacterial hydroxylase, C1-hpah, is electrically wired to glassy carbon electrodes through incorporation into a low-potential Os-complex modified redox polymer. The proposed biosensing strategy depends on allosteric modulation of C1-hpah by the binding of the enzyme activator and analyte p-HPA, stimulating oxidation of the cofactor NADH. The pronounced concentration-dependence of allosteric C1-hpah modulation in the presence of a constant concentration of NADH allowed sensitive quantification of the target, p-HPA. The specific design of the immobilizing redox polymer with suitably low working potential allowed biosensor operation without the risk of co-oxidation of potentially interfering substances, such as uric acid or ascorbic acid. Optimized sensors were successfully applied for p-HPA determination in artificial urine, with good recovery rates and reproducibility and sub-micromolar detection limits. The proposed application of the allosteric enzyme C1-hpah for p-HPA trace electroanalysis is the first successful example of simple amperometric redox enzyme/redox polymer biosensing in which the analyte acts as an effector, modulating the activity of an immobilized biocatalyst. A general advantage of the concept of allosterically modulated biosensing is its ability to broaden the range of approachable analytes, through the move from substrate to effector detection.
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