Khairunnisa Amreen scite author profile

Recently, the usage of automated microfluidic integrated platforms in chemical synthesis has emerged as an extremely useful tool for nano/micro structures fabrication. Owing to their cost-effectiveness, portability and low sample consumption, these devices has gained substantial attention especially towards industrial outlook. The physical, chemical, mechanical and magnetic properties of the nanomaterials are greatly influenced by their morphological aspects. The broad spectrum applications of nanostructures in versatile fields like biomedical, energy storage/harvest, biosensing, catalysis, imaging, electronics and engineering, hugely depend on their morphology. Therefore, an automated, robust but customizable synthesis is the key to attain uniformity and reproducibility of morphology. Therefore, microfluidic devices offer features like control fluid flow, faster mixing of reagents, precise heat transfer mechanism and well-regulated pressure, giving a homogenous quality of nanocrytalline material for multiplexed applications. The studies have reported that the micro-devices assisted synthesized nanoparticles have less particle size distribution curve than those prepared traditionally. During the last decade, nano-and-micro sized crystals, colloids, particles, clusters have been synthesized so far using micro-controlled devices. This review summarizes the recent advances and the future scope of various miniaturized and microfluidic automated devices to realize nano crystalline materials.

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Emerging trends in miniaturized and microfluidic electrochemical sensing platforms

Mohan

Amreen

Javed

et al. 2022

Current Opinion in Electrochemistry

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Highly Redox-Active Hematin-Functionalized Carbon Mesoporous Nanomaterial for Electrocatalytic Reduction Applications in Neutral Media

Amreen

Kumar

2018

ACS Appl. Nano Mater.

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Hematin is a hydroxyl group linked heme site (hydroxyl heme) of the natural enzymes/proteins like hemoglobin, cytochrome c, catalase, and horseradish peroxidase, and it has an important role in the physiological function. Because of problems like poor electron-transfer functionality (on solid electrodes), poor solubility, and molecular aggregation in aqueous solution, limited electrochemical studies have been reported in the literature. A new electrode modification method for hematin using graphitized mesoporous carbon nanomaterial and chitosan for enhanced redox-active and efficient electrocatalytic reductions of hydrogen peroxide and dissolved oxygen in neutral pH was demonstrated in this work. The hematin-modified electrode showed a highly stable redox peak at E°′ = −0.390 V versus Ag/AgCl with a heterogeneous rate constant value of 1.34 s–1. Calculated hematin-active loading concentration (Γhemat = 126 × 10–10 mol cm–2) is ∼20 times higher than the reported values. Physicochemical and electrochemical characterizations revealed trapping of the hematin via axial bond coordination and intermolecular hydrogen bonding with amino functional groups of chitosan and π–π interactions with the graphitic site of mesoporous carbon within the matrix. The new hematin electrode showed ∼400 mV reduction in the overpotential with current sensitivity/detection range of 570 nA μM–1/100–900 μM and 6.7 μA ppm–1/1–10 ppm, respectively, for H2O2 and dissolved oxygen reduction reactions in pH 7 phosphate buffer solution. Michaelis–Menten kinetics were applied for the H2O2 reduction reaction and estimated the rate constant values as K M = 0.78 mM and k s = 1.15 s–1. No marked interference was noticed with common biochemicals such as nitrite, nitrate, glucose, uric acid, ascorbic acid, xanthine, hypoxanthine, cysteine, and dopamine on amperometric i–t detection of H2O2 indicating the activity similar to the heme-based proteins/enzymes.

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A human whole blood chemically modified electrode for the hydrogen peroxide reduction and sensing: Real-time interaction studies of hemoglobin in the red blood cell with hydrogen peroxide

Amreen

Kumar

2018

Journal of Electroanalytical Chemistry

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Laser-Induced Flexible Electronics (LIFE) for Resistive, Capacitive and Electrochemical Sensing Applications

et al. 2020

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