Flower-like ZnO decorated polyaniline/reduced graphene oxide nanocomposites for simultaneous determination of dopamine and uric acid

Ghanbari, Kh.; Moloudi, Maryam

doi:10.1016/j.ab.2016.08.014

Cited by 116 publications

(52 citation statements)

References 69 publications

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“…Ghanbari et al . demonstrated the rGO‐ZnO‐PANI composite for UA sensing wherein three‐step synthesis approach such as electrochemical reduction of GO, eletro‐polymerization of PANI followed by electro‐deposition of ZnO was used . Dai et al .…”

Section: Resultsmentioning

confidence: 99%

FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

2019

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While most electrochemical uric acid (UA) sensors are developed on the conventional electrodes and involve either multiple steps based synthesis routes and/or complicated fabrication processes, this paper is the first demonstration of direct growth of pyrite FeS2 on pencil‐graphite electrode (PGE) for non‐enzymatic UA sensing. FESEM images of the pyrite FeS2‐PGE reveal mesoporous microspherical structure of pyrite FeS2 along with graphite flakes of PGE and EDX, Raman spectroscopic data validate growing of pyrite FeS2 on PGE. The pyrite FeS2‐PGE sensor exhibited detection limit of 6.7 μM, excellent linearity, reproducibility, selectivity over glucose, urea, ascorbic acid with the sensitivity of 370 μA mM−1 cm−2 in the range of 10–725 μM of UA. These improved analytical performances can be attributed to high conductivity of the pyrite FeS2, larger electro‐active surface area of the mesoporous microspherical pyrite FeS2 grown on PGE (than only PGE) and abundance in defect sites originating from both the pyrite FeS2 as well as functional groups of pencil graphite. Furthermore, the sensor was validated against UA in urine sample and the result supports well with the UA concentration achieved from colorimetric technique. Development of this low cost, non‐enzymatic, sensitive and highly selective pyrite FeS2‐PGE bases UA sensor is a significant step in the development of practically viable sensors for point‐of‐care applications in clinical and pharmaceutical analyses.

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Section: Resultsmentioning

confidence: 99%

FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

2019

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“…The result shows with linear range of 3-300 μM and good selectivity because of its high electrical conductivity. Ghanbari and Moloudi (2016) introduced a biosensor with nano-composites of novel materials. ZnO (flower like)/polyaniline nano-fibre/reduced graphene oxide nano-composite was coated over the GCE to detect the UA content.…”

Section: Hybrid and Carbon-based Materials Modified Electrodementioning

confidence: 99%

A comprehensive review on thin film-based nano-biosensor for uric acid determination: arthritis diagnosis

Parthasarathy

Vivekanandan

2018

WRSTSD

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This article aims to provide a survey on the development of thin film-based nano-biosensor over the decade, which includes sensing principles, electrode types and various thin film matrices. The theoretical and experimental results suggest that the thin film-based sensor are suitable for highly sensitive detection of low concentration bio molecules and can be used for early diagnosis and screening of arthritis, kidney diseases and other cardiovascular diseases. This review concludes that enzyme immobilisation and surface functionalisation methods were used to increase sensitivity of the biosensor and new combination of polymer nano-composites with metal oxide thin films results in increased efficiency due to its high biocompatibility.

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“…5 In comparison to other metal oxides, nanocrystalline zinc oxide (ZnO) has been widely used in biosensing applications due to its biocompatibility, reasonable cost, low toxicity, high electron mobility, easy synthesis, large exciton binding energy (60 meV) at room temperature, higher chemical stability, etc. [6][7][8] To overcome these constraints, as well as to tune the properties of bare ZnO, investigators are continuously searching for different approaches such as, using binary NCs with other metal oxides 9 and with carbon nanostructures, [10][11][12] doping with metals 13,14 or non metals, 15,16 multicomponent hybrid systems [17][18][19] and supporting with metals. 20 Among these strategies, the focus on the doped as well as their binary/ternary ZnO-based NCs is gaining the importance due to their extraordinary properties compared to bare materials.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Ni²⁺ ion doped ZnO–MWCNTs nanocomposites using an in situ sol–gel method: an ultra sensitive non-enzymatic uric acid sensing electrode material

et al. 2020

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Flower-like ZnO decorated polyaniline/reduced graphene oxide nanocomposites for simultaneous determination of dopamine and uric acid

Cited by 116 publications

References 69 publications

FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

A comprehensive review on thin film-based nano-biosensor for uric acid determination: arthritis diagnosis

Synthesis of Ni²⁺ ion doped ZnO–MWCNTs nanocomposites using an in situ sol–gel method: an ultra sensitive non-enzymatic uric acid sensing electrode material

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Flower-like ZnO decorated polyaniline/reduced graphene oxide nanocomposites for simultaneous determination of dopamine and uric acid

Cited by 116 publications

References 69 publications

FeS2 Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

FeS2 Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

A comprehensive review on thin film-based nano-biosensor for uric acid determination: arthritis diagnosis

Synthesis of Ni2+ ion doped ZnO–MWCNTs nanocomposites using an in situ sol–gel method: an ultra sensitive non-enzymatic uric acid sensing electrode material

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Product

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FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

FeS₂ Grown Pencil Graphite as an In‐expensive and Non‐enzymatic Sensor for Sensitive Detection of Uric Acid in Non‐invasive Samples

Synthesis of Ni²⁺ ion doped ZnO–MWCNTs nanocomposites using an in situ sol–gel method: an ultra sensitive non-enzymatic uric acid sensing electrode material