Kalyan Kumar Mistry scite author profile

In this brief review, we summarize the recent research activities involved in the development of amperometric-type immunosensors based on screen-printed electrodes (SPEs). We focus on the underlying principle involved in these types of sensors, their fabrication and electrode surface modification. We also discuss the various factors involved in the designing of such immunosensors and how they affect their performances. Finally we provide an insight into the drawbacks associated with these SPEs.

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Study of electrical characteristics of porous alumina sensors for detection of low moisture in gases

Basu

Chatterjee

Saha

et al. 2001

Sensors and Actuators B: Chemical

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Development of screen-printed electrode based immunosensor for the detection of HER2 antigen in human serum samples

Tallapragada

Layek

Mukherjee

et al. 2017

Bioelectrochemistry

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Magnesium chromate–TiO2 spinel tape cast thick film as humidity sensor

Saha

Giri

Mistry

et al. 2005

Sensors and Actuators B: Chemical

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Electrochemical Characterization of some Commercial Screen-Printed Electrodes in Different Redox Substrates

Mistry¹,

Deepthy²,

Chau³

et al. 2015

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A Comparative Study in Electrochemical Response of Some Commercial Screen–Printed Electrodes (SPEs)

Mistry¹,

Kashyup²,

RoyChaudhuri³

et al. 2014

Sen Lett

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Dependence of moisture absorption property on sol–gel process of transparent nano-structured γ-Al2O3 ceramics

Saha

Mistry

Giri

et al. 2005

Sensors and Actuators B: Chemical

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Design and simulation of a thermo transfer type MEMS based micro flow sensor for arterial blood flow measurement

Mistry

Mahapatra

2012

Microsyst Technol

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Thermo transfer type MEMS (Micro Electro Mechanical System) based micro flow sensing device have promising potential to solve the limitation of implantable arterial blood flow rate monitoring. The present paper emphasizes on modeling and simulation of MEMS based micro flow sensing device, which will be capable of implantable arterial blood flow rate measurement. It describes the basic design and model architecture of thermal type micro flow sensor. A pair of thin film micro heaters is designed through MEMS micro machining process and simulated using CoventorWare; a finite element based numerical code. A rectangular cross section micro channel has been modeled where in micro heater and thermal sensors are embedded using the same CoventorWare tools. Some promising and interesting results of thermal dissipation depending upon very small amount of flow rate through the micro channel are investigated. It is observed that measuring the variation of temperature difference between downstream and upstream, the variation of fluid flow rate in the micro channel can be measured. The numerical simulation results also shows that the temperature distribution profile of the heated surface depends upon microfluidic flow rate i.e. convective heat transfer is directly proportional to the microfluidic flow rate on the surface of the insulating membrane. The simplified analytical model of the thermo transfer type flow sensor is presented and verified by simulation results, which are very promising for application in arterial blood flow rate measuring in implantable micro devices for continuous monitoring of cardiac output.

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