Abstract
This work reports on the advantages of using carbon nanodots (CNDs) in the development of reagent-less oxidoreductase-based biosensors. Biosensor responses are based on the detection of H2O2, generated in the enzymatic reaction, at 0.4 V. A simple and fast method, consisting of direct adsorption of the bioconjugate, formed by mixing lactate oxidase, glucose oxidase, or uricase with CNDs, is employed to develop the nanostructured biosensors. Peripherical amide groups enriched CNDs are prepared from ethyleneglycol bis-(2-aminoethyl ether)-N,N,N′,N′-tetraacetic acid and tris(hydroxymethyl)aminomethane, and used as precursors. The bioconjugate formed between lactate oxidase and CNDs was chosen as a case study to determine the analytical parameters of the resulting L-lactate biosensor. A linear concentration range of 3.0 to 500 µM, a sensitivity of 4.98 × 10−3 µA·µM−1, and a detection limit of 0.9 µM were obtained for the L-lactate biosensing platform. The reproducibility of the biosensor was found to be 8.6%. The biosensor was applied to the L-lactate quantification in a commercial human serum sample. The standard addition method was employed. L-lactate concentration in the serum extract of 0.9 ± 0.3 mM (n = 3) was calculated. The result agrees well with the one obtained in 0.9 ± 0.2 mM, using a commercial spectrophotometric enzymatic kit.
Highlights
The inclusion of nanomaterials has marked a turning point in biosensor development
Among carbon-based nanomaterials, carbon nanodots (CNDs) have attracted great interest, because they can be produced from a wide range of raw materials, and excel with their robust chemical inertness, high solubility in aqueous media, and biocompatibility
The CNDs employed in this work were prepared using a previously described method, by carbonization of EGTA and TRIS, and characterized using different techniques [26]
Summary
With remarkable achievements in nanotechnology and nanoscience, nanomaterials-based electrochemical signal amplifications have great potential in improving both the sensitivity and selectivity of electrochemical biosensors [1,2]. The high sensitivity and selectivity of nanomaterials-based biosensors have led to great advances in the development of new methodologies for the early detection and diagnosis of disease associated biomarkers. Carbon nanotubes and graphene are the most employed ones, due to their unique mechanical, electrical, thermal, and optical properties. These carbon nanomaterials have significant drawbacks, derived from the difficulty of fabrication and high cost for commercial production [6]
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