Development of Biosensors for the Detection of Hydrogen Peroxide

“…Another μPAD was designed for simultaneous detection of uric acid and glucose based on peroxidase mimicking platinum nanoparticles (Pt NPs) [ 443 ]. Hydrogen peroxide is an important analyte itself and a prominent product or substrate of catalyzed oxidation reactions [ 444 ]. Hence, various microfluidic biosensors utilizing nanozymes including Au@PtNP/GO [ 445 ], graphene oxide-gold [ 446 ], and cerium oxide nanosheets (NSs) [ 444 , 447 ] were developed for H202 measurement.…”

“…Hydrogen peroxide is an important analyte itself and a prominent product or substrate of catalyzed oxidation reactions [ 444 ]. Hence, various microfluidic biosensors utilizing nanozymes including Au@PtNP/GO [ 445 ], graphene oxide-gold [ 446 ], and cerium oxide nanosheets (NSs) [ 444 , 447 ] were developed for H202 measurement. Nanozymes are exploited for point-of-care (POC) cancer diagnosis as well [ 442 , 448 , 449 ].…”

Biomedical Applications of Microfluidic Devices: A Review

“…Another μPAD was designed for simultaneous detection of uric acid and glucose based on peroxidase mimicking platinum nanoparticles (Pt NPs) [ 443 ]. Hydrogen peroxide is an important analyte itself and a prominent product or substrate of catalyzed oxidation reactions [ 444 ]. Hence, various microfluidic biosensors utilizing nanozymes including Au@PtNP/GO [ 445 ], graphene oxide-gold [ 446 ], and cerium oxide nanosheets (NSs) [ 444 , 447 ] were developed for H202 measurement.…”

“…Hydrogen peroxide is an important analyte itself and a prominent product or substrate of catalyzed oxidation reactions [ 444 ]. Hence, various microfluidic biosensors utilizing nanozymes including Au@PtNP/GO [ 445 ], graphene oxide-gold [ 446 ], and cerium oxide nanosheets (NSs) [ 444 , 447 ] were developed for H202 measurement. Nanozymes are exploited for point-of-care (POC) cancer diagnosis as well [ 442 , 448 , 449 ].…”

Biomedical Applications of Microfluidic Devices: A Review

“…A number of electroactive chemical species can interfere since they are oxidised within the same potential range. Several electrochemical sensors and biosensors have been described to minimize the interferences (Giannoudi et al, 2006) by modifying the transducers particularly by Prussian blue and its analogous (Karyakin, 2001;Ricci & Palleschi, 2005), carbon nanotubes (Wang, 2005;Zagal et al, 2009) and peroxidase enzymes. The latter are based on electron transfer reactions between the enzyme and the working electrode either directly (Ferapontova, 2004) or through redox mediators (Ruzgas et al, 1996).…”

“No calibration” type sensor in routine amperometric bio-sensing: An example of a disposable hydrogen peroxide biosensor

“…It is generally detected by classical approaches as titration analysis, batch injection analysis (BIA) coupled to amperometric detectors (Silva et al 2012), or by colorimetric assays (Costa et al 2020). To reduce the time and costs of the analysis, enzymatic biosensors and non-enzymatic sensors were J o u r n a l P r e -p r o o f optimised (Giannoudi et al 2006;Shamkhalichenar et al 2020, Hou et al, 2019. Particularly, the nonenzymatic sensors were developed mainly to overcome the thermal and chemical instability suffered by enzymes.…”

NiO-nanoflowers decorating a plastic electrode for the non-enzymatic amperometric detection of H2O2 in milk: Old issue, new challenge