2018
DOI: 10.1016/j.bios.2018.06.061
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Solution growth of 3D MnO2 mesh comprising 1D nanofibres as a novel sensor for selective and sensitive detection of biomolecules

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Cited by 33 publications
(20 citation statements)
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“…The different shapes of MnO 2 including NRs, NTs, NWs, NSPs, NFLs, NSs, NFs, and various other shapes can be synthesized, and also their properties are changed with the variation in shape or morphology. , Figure represents various morphologies of MnO 2 with four dimensions including 0-D, 1-D, 2-D, and 3-D. Various methods have been reported for the preparation of different morphologies of MnO 2 which include lithography, the electron beam method, templates, the precipitation method, the sol–gel method, electrospinning, as well as the electrodeposition method. , All these methods were reported as most acceptable due to their simplicity, biocompatibility, economical, and versatility points of view. The variations in crystal parameter, phase structure, and surface morphology of MnO 2 showed high catalytic activity and oxidative reactivity .…”
Section: Structure and Synthesis Of Different Morphologies Of Mno2 Na...mentioning
confidence: 99%
See 2 more Smart Citations
“…The different shapes of MnO 2 including NRs, NTs, NWs, NSPs, NFLs, NSs, NFs, and various other shapes can be synthesized, and also their properties are changed with the variation in shape or morphology. , Figure represents various morphologies of MnO 2 with four dimensions including 0-D, 1-D, 2-D, and 3-D. Various methods have been reported for the preparation of different morphologies of MnO 2 which include lithography, the electron beam method, templates, the precipitation method, the sol–gel method, electrospinning, as well as the electrodeposition method. , All these methods were reported as most acceptable due to their simplicity, biocompatibility, economical, and versatility points of view. The variations in crystal parameter, phase structure, and surface morphology of MnO 2 showed high catalytic activity and oxidative reactivity .…”
Section: Structure and Synthesis Of Different Morphologies Of Mno2 Na...mentioning
confidence: 99%
“…MnO 2 NFs with open structure result in higher surface area for the loading of antibodies and oxidase mimicking activity . The mesh morphology enhances the electrochemical activity of the biosensor by providing a greater surface area and, also, increases the mass transport due to its macroporous network . The flower-like nanostructure of MnO 2 (Figure I) consists of interconnected NFLs which provide desirable kinetics along with a high surface area for electrochemical biosensing.…”
Section: Structure and Synthesis Of Different Morphologies Of Mno2 Na...mentioning
confidence: 99%
See 1 more Smart Citation
“…Previously studies have shown that when the bulk materials are converted to nanoplates, it significantly enhanced their physical properties due to quantum confinement (Liang et al 2016;Bekenstein et al 2018). Certainly, the remarkable sensor performance can be attributed to the 2D morphology of the nanoplatelets which bear higher surface and the quantum confinement of electrons associated with them, which may have facilitated faster electrochemical analysis of biomarkers like glutathione (Liang et al 2016;Bekenstein et al 2018;Tehseen et al 2018).…”
Section: Sensor Studiesmentioning
confidence: 99%
“…Manganese oxide (MnO 2 ) has become an active material in the field of biosensing among different transition-metal oxides due to its attractive physical and electrochemical properties . MnO 2 has exceptional light absorption capability, a high surface area, and a rapid rate of electron transfer due to which it can be used as a proficient fluorescence quencher in developing a “turn-off-on” sensing platform. , The properties of nanomaterials can be tuned by controlling their size, shape, crystallographic orientation, and morphology. , Shape control becomes the most important technique for improving the activity of nanomaterials .…”
Section: Introductionmentioning
confidence: 99%