Your search keyword '"Sanket Goel"' showing total 36 results

1. IoT integrated and deep learning assisted electrochemical sensor for multiplexed heavy metal sensing in water samples

Author

Sreerama Amrutha Lahari, Nikhil Kumawat, Khairunnisa Amreen, R. N. Ponnalagu, and Sanket Goel

Subjects

Water supply for domestic and industrial purposes, TD201-500

Abstract

Abstract Heavy metal measurement is vital for ecological risk assessment and regulatory compliance. This study reports a sensor using gold nanoparticle-modified carbon thread electrodes for the simultaneous detection of Cd²⁺, Pb²⁺, Cu²⁺, and Hg²⁺ in water samples. Differential pulse voltammetry (DPV) was employed, achieving detection limits of 0.99 µM, 0.62 µM, 1.38 µM, and 0.72 µM, respectively, with a linear span of 1–100 µM. The sensor operated effectively in acidic conditions, with excellent selectivity, repeatability, and reproducibility. Real water samples from various lakes in Hyderabad, India, were analyzed to validate their practical application. To extract the sensing features a convolutional neural network (CNN) model was used to process DPV signals, enhancing heavy metal ion classification with high accuracy. Performance metrics such as precision, recall, and F1 score were evaluated. Integration with IoT technology has improved the user experience, advanced heavy metal quantification capabilities, and further enabled remote monitoring.

Published

2025

2. An implantable glucose enzymatic biofuel cell integrated with flexible gold-coated carbon foam and carbon thread bioelectrodes grafted inside a living rat

Author

S. Vanmathi, U. S. Jayapiriya, Pravesh Sharma, Onkar Prakash Kulkarni, and Sanket Goel

Subjects

Carbon thread, Carbon foam, Gold nanostructures, Ferritin, Implants, Self-powered, Energy conservation, TJ163.26-163.5, Renewable energy sources, TJ807-830

Abstract

Abstract The advent of long-term implants has increased the urgent need for self-powered biomedical devices. Utilize enzymes to expedite the process of biofuel oxidation. These systems frequently make use of glucose oxidase. A possible solution involves glucose biofuel cells powered by the glucose found in physiological fluids. Biocompatible substances like carbon electrode designs help to transport electrons from the biological reactions to the external circuit as efficiently as possible while maximizing surface area. Despite advances in implantable electrodes, developing miniaturized and flexible electrodes remains challenging. In this work, a metal-coated flexible carbon thread and foam bioelectrode are fabricated and successfully implanted inside a living and freely moving rat. These electrodes are prepared using gold nanostructures as electron enhancers, a negatively charged conducting polymer, a biocompatible redox mediator, and enzymes as biocatalysts. The carbon foam-based enzymatic biofuel cell produces in vitro and in vivo settings, generates a power density of 165 µW/cm2 and 285 µW/cm2, and the carbon thread-based fuel cell produces a power density of 98 µW/cm2 and 180 µW/cm2 in vitro and in vivo environments, respectively. This work paves the way for the possible use of inexpensive electrodes for subdermal implantable microsystems.

Published

2025

3. Miniaturized Devices for Isothermal Amplification and Photometric Quantification of Pseudomonas Aeruginosa

Author

P Ramya Priya, Satish Kumar Dubey, and Sanket Goel

Subjects

Internet-of-things (IoT), isothermal nucleic acid amplification, led-photodiode, microcontroller, pseudomonas aeruginosa, recombinase polymerase amplification, Computer applications to medicine. Medical informatics, R858-859.7, Medical technology, R855-855.5

Abstract

Goal: This study introduced a proof-of-concept prototype for isothermal recombinase polymerase amplification (RPA) with miniaturized photometric detection, enabling rapid P. aeruginosa detection. Methods: The researchers conducted the amplification process within a microchamber with a diameter of 10 mm, utilizing a standalone Thermostat driven thermal management setup. RPA, an amplification technique was employed, which required a lower operating temperature of 37 °C–40 °C to complete the reaction. The amplified amplicon was labeled with a fluorophore reporter, stimulated by an LED light source, and detected in real-time using a photodiode. Results: The developed prototype successfully demonstrated the rapid detection of P. aeruginosa using the RPA assay. The process only required the utilization of 0.04 ng of working concentration of DNA. The entire process, from amplification to detection, could be completed in over 15 minutes. The platform showed enhanced sensitivity and specificity, providing a cost-effective and accurate solution for on-site detection/quantification of pathogens. Conclusions: The integration of isothermal RPA with the miniaturized photometric detection platform proved successful in achieving the goal of rapid and specific pathogen detection. This study proved the benefits of Isothermal Nucleic Acid Amplification Technology (INAAT), emphasizing its potential as an accessible, user-friendly point-of-care technology for resource-constrained institutions. The RPA-based prototype demonstrated capability without requiring costly laboratory equipment or expertise. The developed platform, when combined with Internet of Things (IoT) enabled cloud platform, also allowed remote monitoring of data. Overall, the methodology presented in this study offered a cost-effective, accurate, and convenient solution for on-site testing in resource-limited settings.

Published

2025

4. Modification of glass screen printed electrodes with graphene quantum dots for enhanced power output in miniaturized microbial fuel cells

Author

Yuvraj Maphrio Mao, Khairunnisa Amreen, Rajnish Kaur Calay, Aritro Banerjee, and Sanket Goel

Subjects

Graphene Quantum Dots, Glass Screen Printed, Miniaturized Microbial Fuel Cell, And Power Generation, Medicine, Science

Abstract

Abstract This paper demonstrates screen-printing technique, Glass Screen printed (GSP) on glass layer with Graphene Quantum Dots (GQDs) via drop casting approach to manufacture electrodes for Miniaturized Microbial Fuel Cells (MMFCs). MMFCs are viable options to sustainably operate low-power devices such as sensors, implantable medical devices, etc. However, the technology is still not fully mature for practical applications due to limitations of output power. Materials and design improvements are required for decreasing internal resistance for better electron transfer and improving overall performance. In this work the electrodes manufactured by GSP technique, and anode modified by GQD was tested in MMFC using RO wastewater. It was found that the GQDs increased the surface area to improve electron transfer kinetics at the anode. As a result, GQDs-based GSPEs showed 7.4 times higher power output 332 nW/cm2 compared to its unaltered electrode which displayed a power output of 44.8 nW/cm2. Electrodes made by GSP technique are more durable and less susceptible to biofouling and corrosion compared to conventional methods. The modified anodes further showed sustained output for long term operation.

Published

2024

5. Flexible Supercapacitor Device Based on Laser‐Synthesized Nanographene for Low‐Power Applications

Author

Himanshi Awasthi, Pavar Sai Kumar, Thomas Thundat, and Sanket Goel

Subjects

direct‐laser writing, flexible supercapacitors, laser‐induced graphene, reduced graphene oxide, Environmental technology. Sanitary engineering, TD1-1066, Renewable energy sources, TJ807-830

Abstract

Laser‐induced graphene (LIG) and laser‐induced reduced graphene oxide (LIrGO) are two relatively recent graphene‐based nanoscale materials suitable for miniaturized flexible supercapacitors. This study employs direct laser engraving techniques to generate patterns on flexible substrates, such as paper and polyamide (PI). This methodology allows fine control over the formed nanographene structures to fabricated LIG and LIrGO supercapacitors. The LIG on PI exhibits a distinctive porous structure and high surface area, adsorption, and transportation of ions. Furthermore, paper‐based LIrGO electrodes are recyclable and are formed in a single step. The morphological study is done using scanning electron microscopy, Raman spectroscopy, X‐ray photoelectron spectroscopy, and X‐ray diffraction. Galvanostatic charge–discharge studies at 0.05 mA cm−2 current density show an areal capacitance of 3.69 mF cm−2 for LIG and 1.61 mF cm−2 for LIrGO. The comparable energy densities for LIG and LIrGO are 0.32 and 0.16 μWh cm−2, respectively. From the calculative analysis of both types, the variation in specific areal capacitance enabling effective is 56.3% from GCD, indicating that the LIG device performs better. Finally, a portable potentiostat is employed to investigate the viability of utilizing supercapacitors to operate self‐powered sensors in a portable and integrable fashion.

Published

2024

6. IoT enabled carbon cloth-based 3D printed hydrogen fuel cell integrated with supercapacitor for low-power microelectronic devices

Author

S. Vanmathi, Himanshi Awasthi, Abhishesh Pal, and Sanket Goel

Subjects

Medicine, Science

Abstract

Abstract A Hydrogen fuel cell (HFC) broad range associated with Internet of Things (IoT) technologies that require slightly less and constant electricity made possible by remote climate monitoring connections. Novelty demonstrates a miniature HFC based on carbon cloth electrodes and sealing elements manufactured via 3D printing. Cobalt (II) Oxide (Co3O4)—reduced Graphene Oxide (rGO) and Platinum (Pt) based nanoparticles are coated over carbon cloth to increase the catalytic activity at the anode and cathode. Hydrogen is produced by using an aluminium foil (Al) that is stored in between the filter paper and through capillary action the sodium hydroxide pellets (NaOH) are applied and reacted with Al foil to produce hydrogen. The single HFC device working surface area of 1 × 1 cm2 effectively generates an open circuit voltage (OCV) of 1.3 V, a current density of 1.602 mA/cm2, and a peak power density of 761 mW/cm2. The fuel cell stability performance is monitored for up to 10 h. The power obtained from the HFC is stored in a supercapacitor and used to supply energy to the IoT component. The module includes a built-in sensor that monitors the temperature, pressure, and humidity. The measured data is then transmitted to a smartphone via Bluetooth.

Published

2024

7. Graphitization on Natural Biopolymer Shellac: Toward Substrate Independent Coatings and a Recyclable Flexible Heater

Author

Sai Kumar Pavar, Srinivasan Madapusi, Sushanta K. Mitra, and Sanket Goel

Subjects

graphene – graphene derivatives, laser induced process, natural biopolymer, reduced graphene oxide (rGO), shellac, Physics, QC1-999, Technology

Abstract

Abstract Extraction of graphene and graphene derivatives from non‐toxic, biocompatible, eco‐friendly, and biodegradable resources with a one‐step production process is a challenge. This work is the first attempt at the one‐step graphenization of Shellac, a biopolymer derived from natural resources, achieved using direct laser patterning. Interestingly, the process highlights substrate independence by producing reduced graphene oxide (rGO) from multiple substrates, such as glass slides, Copper (Cu) adhesive tape, and overhead projector (OHP) plastic films. The produced rGO is fully characterized, and it is found that the sheet resistance is as low as 5.4., 24.65, and 8.4 Ω Sq−1. on the glass slide, OHP plastic sheet, and Cu adhesive, respectively. Moreover, developing various logos on resin‐coated ceramic tiles demonstrated the possibility of patterning desired conductive rGO patterns. Furthermore, a recyclable flexible rGO/Shellac heater is fabricated to validate its electrothermal performance (117.3 °C at 9.5 V) with foldable stability. The proposed one‐step substrate independent two‐material fabrication will revolutionize the process, potentially replacing conventional toxic routes of graphene production.

Published

2024

8. Microfluidic Microreactor Device With Integrated Heaters for Temperature Assisted Synthesis of Gold Nanoparticles and Alkene

Author

Tinku Naik Banavathi, Mukesh Kumar Sivakumar, Aniket Balapure, Sohan Dudala, Satish Kumar Dubey, and Sanket Goel

Subjects

Laser-induced graphene heaters, microfluidics, polydimethylsiloxane, microreactors, Chemical technology, TP1-1185, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Thermal synthesis is an essential process in most chemical formulations. While several well-established methods exist for synthesizing materials in large quantities, synthesizing materials on a small scale is challenging and costly. This work delves into the design and functionality of microfluidic-based thermal synthesis microreactors, which are highly customizable and cost-effective. Instead of conventional electrothermal heaters, Laser-Induced Graphene (LIG) heaters are leveraged over traditional electrothermal heaters due to their cost-effectiveness, simplified fabrication process, and high level of customization. The parameters for developing these LIG heaters were optimized by tuning the speed and power of the CO2 laser to obtain both the desired electrical conductivity and mechanical strength. The developed heaters were integrated with microfluidic devices fabricated using the soft-lithography technique. The functionality of these devices was demonstrated by performing gold nanoparticles (inorganic) and alkene (organic) synthesis. The synthesized gold nanoparticles (AuNPs) and alkene solution were analyzed using UV-visible spectroscopy, Fourier Transform Infrared (FTIR) spectroscopy, and Nuclear Magnetic Resonance (NMR) techniques to evaluate the quality of the end products. The functionality of synthesized solutions can be utilized as catalyst in electrochemical applications and as precursors in downstream chemical syntheses.

Published

2024

9. Multiple 3D-Printed Miniaturized Microbial Fuel Cells With Embedded Electrodes Optimized by Sustainable and Synergistic Perovskites Materials

Author

Yuvraj Maphrio Mao, Khairunnisa Amreen, and Sanket Goel

Subjects

3D printing, miniaturized microbial fuel cell, perovskites materials, and power generations, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Miniaturized Microbial Fuel Cells (MMFCs) are the focus of this research, aimed at enhancing microscale power generation in Single Chambered Microbial Fuel Cells (SMFCs). The study involves the development of two 3D-printed conductive devices using a Fused Deposition Modeling approach with polylactic acid (PLA). These devices feature inbuilt electrodes coated with piezoelectric materials. The research addresses key challenges, including low power output and voltage reversal, achieving power outputs of $8.72~\mu $ W/cm2 for Conductive Device I and $1.05~\mu $ W/cm2 for Conductive Device II. The incorporation of assistance electrodes demonstrates potential in mitigating voltage reversal and improving SMFC efficiency.

Published

2024

10. Fully 3D Printed Miniaturized Electrochemical Platform With Plug-and-Play Graphitized Electrodes: Exhaustively Validated for Dopamine Sensing

Author

K S Jaya Lakshmi, Ramya K, Khairunnisa Amreen, and Sanket Goel

Subjects

Stereolithography, 3D printing, plug-and-play microelectrodes, electrochemical sensing, microfluidics, point of need (pon), Chemical technology, TP1-1185, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Globally, a contemporary trend is towards the realization of sustainable, eco-friendly, miniaturized, and cost-effective sensors. This work focuses on developing a plug-and-play device using inexpensive and biodegradable UV resin fed 3D printing stereolithography (SLA) to produce miniaturized microfluidic platforms for electrochemical sensing. The device consists of three compartments designed to accommodate the 3-electrodes according to the need. SLA 3D printing technique solves these restrictions, making sensors reliable, repeatable, and durable. For electrochemical detection at the point of need or as a lab-on-chip (LoC) platform with minimal sample volume, this work attempts to construct a flexible as well as non-flexible microelectrode setup. The analytical capability of the platform is examined by quantifying nanomolar levels of dopamine in human body fluids. Chronoamperometry and cyclic voltammetry on surface-treated graphene-poly lactic acid (g-PLA) microelectrodes modified with gold nanoparticles are carried out utilizing a handheld potentiostat. The designed device has a linear range of 0.1 to 120 nM with limit of detection and limit of quantification of 0.083 and 0.27 nM, respectively. Various electrode characterizations, including scanning electron microscopy, energy-dispersive X-ray spectroscopy, and electrochemical impedance spectroscopy are carried out. The developed device is finally tested for real-time analysis on human blood and serum samples.

Published

2024

11. IoT-Enabled Triglyceride Microstrip Electrochemical Sensor Using Enzymes Anchored to Gold by Polydopamine

Author

Mrunali D. Wagh, Akhilesh Gowrishetty, K. Ramya, Subhendu Kumar Sahoo, and Sanket Goel

Subjects

Enzyme immobilization, gold nanoparticle, IoT, point-of-care device, polydopamine, smartphone-based sensor, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The accurate detection of triglycerides (fats) in the blood is useful for diagnosing cardiovascular health. This study reports a point-of-care (PoC) electrochemical assay to detect triglycerides using a IoT based smartphone-assisted platform. The assay consists of a flexible polyimide-based microstrip with electrodes composed of polydopamine (PDA)-coated gold nanoparticles (AuNPs) deposited on laser-induced graphene A coating of PDA on the AuNPs helps to anchor lipase enzymes to the electrode, resulting in an enzymatic sensor that is sensitive and specific toward triglycerides. The sensor is connected to a smartphone for data acquisition and monitoring, making it IoT-enabled for PoC applications. Because smartphones are ubiquitous, the approach presented in this paper is more compatible with PoC use than the conventional bulky sensors. The sensor had a linear response to triglyceride concentration, with a limit of detection of 17.89 mg/dL. The apparent Michaelis-Menten constant (K $_{\mathrm {appm}}$ ) of 21.6 mg/dL indicates that lipase conjugates strongly with triglyceride, resulting in a limit of quantification of 59.63 mg/dL of triglycerides in a low $2~\mu $ L of reference triglyceride solution. The validation of the test using human serum spiked with triglycerides demonstrated a recovery rate of 93.87 % of triglycerides, showing its efficacy when compared to alternative triglyceride sensors, such as metal oxides, conducting polymers, and flow injection that typically have recover rates from 90 % to 110 %. Other common analytes in the serum did not interfere with the sensing. The ability to detect triglycerides using smartphones can lead to improved personalized health monitoring.

Published

2024

12. Efficient Standalone Flexible Small Molecule Organic Solar Cell Devices: Structure-Performance Relation Among Tetracyanoquinodimethane Derivatives

Author

Anuradha Mohitkar, Renuka H, Sanket Goel, and Subbalakshmi Jayanty

Subjects

Chemistry, QD1-999

Published

2023

13. Mini-thermal platform integrated with microfluidic device with on-site detection for real-time DNA amplification

Author

Madhusudan B Kulkarni and Sanket Goel

Subjects

DNA, Internet of Things (IoT), LED photodiode, microcontroller, microfluidics, PCR, Biology (General), QH301-705.5

Abstract

The recent cases of COVID-19 have brought the prospect of and requirement for point-of-care diagnostic devices into the limelight. Despite all the advances in point-of-care devices, there is still a huge requirement for a rapid, accurate, easy-to-use, low-cost, field-deployable and miniaturized PCR assay device to amplify and detect genetic material. This work aims to develop an Internet-of-Things automated, integrated, miniaturized and cost-effective microfluidic continuous flow-based PCR device capable of on-site detection. As a proof of application, the 594-bp GAPDH gene was successfully amplified and detected on a single system. The presented mini thermal platform with an integrated microfluidic device has the potential to be used for the detection of several infectious diseases.

Published

2023

14. A protocol to execute a lab-on-chip platform for simultaneous culture and electrochemical detection of bacteria

Author

Sonal Fande, Sangam Srikanth, Jayapiriya U S, Khairunnisa Amreen, Satish Kumar Dubey, Arshad Javed, and Sanket Goel

Subjects

Biotechnology and bioengineering, Material sciences, Science (General), Q1-390

Abstract

Summary: Here, we present a protocol for a miniaturized microfluidic device that enables quantitative tracking of bacterial growth. We describe steps for fabricating a screen-printed electrode, a laser-induced graphene heater, and a microfluidic device with its integrations. We then detail the electrochemical detection of bacteria using a microfluidic fuel cell. The laser-induced graphene heater provides the temperature for the bacterial culture, and metabolic activity is recognized using a bacterial fuel cell.Please see Srikanth et al.1 for comprehensive information on the application and execution of this protocol. : Publisher’s note: Undertaking any experimental protocol requires adherence to local institutional guidelines for laboratory safety and ethics.

Published

2023

15. Electromicrofluidic Device for Interference-Free Rapid Antibiotic Susceptibility Testing of Escherichia coli from Real Samples

Author

Sonal Fande, Khairunnisa Amreen, D. Sriram, Valentin Mateev, and Sanket Goel

Subjects

antibiotic susceptibility testing, microfluidic, antimicrobial resistance, E. coli, multidrug resistance, minimum inhibitory concentration, Chemical technology, TP1-1185

Abstract

Antimicrobial resistance (AMR) is a global health threat, progressively emerging as a significant public health issue. Therefore, an antibiotic susceptibility study is a powerful method for combating antimicrobial resistance. Antibiotic susceptibility study collectively helps in evaluating both genotypic and phenotypic resistance. However, current traditional antibiotic susceptibility study methods are time-consuming, laborious, and expensive. Hence, there is a pressing need to develop simple, rapid, miniature, and affordable devices to prevent antimicrobial resistance. Herein, a miniaturized, user-friendly device for the electrochemical antibiotic susceptibility study of Escherichia coli (E. coli) has been developed. In contrast to the traditional methods, the designed device has the rapid sensing ability to screen different antibiotics simultaneously, reducing the overall time of diagnosis. Screen-printed electrodes with integrated miniaturized reservoirs with a thermostat were developed. The designed device proffers simultaneous incubator-free culturing and detects antibiotic susceptibility within 6 h, seven times faster than the conventional method. Four antibiotics, namely amoxicillin–clavulanic acid, ciprofloxacin, ofloxacin, and cefpodoxime, were tested against E. coli. Tap water and synthetic urine samples were also tested for antibiotic susceptibility. The results show that the device could be used for antibiotic resistance susceptibility testing against E. coli with four antibiotics within six hours. The developed rapid, low-cost, user-friendly device will aid in antibiotic screening applications, enable the patient to receive the appropriate treatment, and help to lower the risk of anti-microbial resistance.

Published

2023

16. A lab-on-chip platform for simultaneous culture and electrochemical detection of bacteria

Author

Sangam Srikanth, U.S. Jayapiriya, Satish Kumar Dubey, Arshad Javed, and Sanket Goel

Subjects

Bio-electrochemistry, Applied sciences, Sensor system, Science

Abstract

Summary: A simple, cost-effective and miniaturized lab-on-a-chip platform has been developed amenable to perform simultaneous cultivation and detection of bacteria. A microfluidic chamber was integrated to screen-printed electrodes for electrochemical detection of bacteria. The temperature required for the bacterial culture was provided through the optimized laser-induced graphene heaters. The concentration of bacteria was quantified accurately with the three-electrode system in the range of 2 × 104 to 1.1 × 109 CFU/mL without any need of biological modifications to the electrodes. The viability of cultured bacteria in the microfluidic device was also confirmed through fluorescent imaging. Furthermore, the metabolic activity of the cultured bacteria was validated through a miniaturized microbial fuel cell. Furthermore, the specificity of electrodes was also performed through electrochemical technique. Finally, a handheld and portable lab-on-a-chip platform was realized by 3D packaging, integrated with a portable potentiostat for real-time and on-field applications.

Published

2022

17. Droplet-based lab-on-chip platform integrated with laser ablated graphene heaters to synthesize gold nanoparticles for electrochemical sensing and fuel cell applications

Author

Sangam Srikanth, Sohan Dudala, U. S. Jayapiriya, J. Murali Mohan, Sushil Raut, Satish Kumar Dubey, Idaku Ishii, Arshad Javed, and Sanket Goel

Subjects

Medicine, Science

Abstract

Abstract Controlled, stable and uniform temperature environment with quick response are crucial needs for many lab-on-chip (LOC) applications requiring thermal management. Laser Induced Graphene (LIG) heater is one such mechanism capable of maintaining a wide range of steady state temperature. LIG heaters are thin, flexible, and inexpensive and can be fabricated easily in different geometric configurations. In this perspective, herein, the electro-thermal performance of the LIG heater has been examined for different laser power values and scanning speeds. The experimented laser ablated patterns exhibited varying electrical conductivity corresponding to different combinations of power and speed of the laser. The conductivity of the pattern can be tailored by tuning the parameters which exhibit, a wide range of temperatures making them suitable for diverse lab-on-chip applications. A maximum temperature of 589 °C was observed for a combination of 15% laser power and 5.5% scanning speed. A LOC platform was realized by integrating the developed LIG heaters with a droplet-based microfluidic device. The performance of this LOC platform was analyzed for effective use of LIG heaters to synthesize Gold nanoparticles (GNP). Finally, the functionality of the synthesized GNPs was validated by utilizing them as catalyst in enzymatic glucose biofuel cell and in electrochemical applications.

Published

2021

18. Automated pencil electrode formation platform to realize uniform and reproducible graphite electrodes on paper for microfluidic fuel cells

Author

Lanka Tata Rao, Prakash Rewatkar, Satish Kumar Dubey, Arshad Javed, and Sanket Goel

Subjects

Medicine, Science

Abstract

Abstract Graphite pencil stroked electrodes for paper-based Microfluidic devices are gaining immense attention due to their electrochemical properties, cost efficiency, and ease-of-use. However, their widespread use has been hindered by the challenges associated with their manual fabrication such as non-uniformity in graphite deposition, applied pressure, etc. This work presents the design and development of an automated graphite pencil stroking device for graphite electrode fabrication with high efficiency through a compact, inexpensive and automatic process, with reduced fabrication time and human intervention leading to more uniformity. The motion platform of Graphtec plotter was used to create multiple strokes with the help of the proposed device. Such inexpensive graphite electrodes (less than the US $1) have been observed to be porous in nature, acting as diffusion agents. The automated graphite electrodes were used to study the performance of microfluidic paper fuel cells (MPFCs) with formic acid, oxygen, and sulphuric acid acting as fuel, oxidising agent and electrolyte respectively. From this configuration, the maximum current density and power density were measured to be 1,305.5 µA cm−2 and 135.5 µW cm−2, respectively at 0.3 V stable OCP at 100 strokes. Overall, the study enumerates the development of an automated pencil stroke device for fabricating graphite electrodes, which can potentially be harnessed in numerous miniaturized paper based applications.

Published

2020

19. Graphite electrodes as bioanodes for enzymatic glucose biofuel cell

Author

Madhavi Bandapati, Sanket Goel, and Balaj Krishnamurthy

Subjects

pencil graphite electrode, bioanode, glucose oxidase, multiwalled carbon nanotubes, enzymatic glucose biofuel cell, Chemistry, QD1-999

Abstract

This study investigates the performance of pencil graphite (PG) electrodes to identify the grade of pencil most suitable as bioanode for enzymatic glucose biofuel cell. Pencils of H, 3H, 5H and B grades are selected for this study. The surfaces of different grade PGs are modified with carboxylic acid functionalized multi walled carbon nanotubes (COOH-MW­CNT/PG), followed by immobilization with glucose oxidase (GOx) to fabricate the respect­tive bioanodes (GOx/COOH-MWCNT/PG). Morphological and electrochemical characteri­zations are carried out using scanning electron microscopy, electrochemical impedance spectroscopy, cyclic voltammetry and energy dispersive X-ray spectroscopy. All tested PG electrodes exhibited positive results with variable response characteristics towards glucose oxidation reaction. B-grade PG bioanode is found to have the highest coverage of the deposited nanobiocomposite with the fastest electron transfer rate. The half-cell electrode assembly with this grade of PG recorded the highest current density of 4.25 mA cm-2 at physiological glucose conditions (5 mM glucose, pH 7.0). Enzymatic glucose biofuel cell assembled with B-grade PG bioanode and platinum cathode generated an open circuit potential of 149 mV and maximum power density of 0.789 µW cm−2 from 5 mM glucose at ambient conditions (25 ± 3◦C). The results obtained for B-grade PG bioanode are comparable to those of conventional carbon and glassy carbon electrodes, thus demonstrating its applicability to enzymatic glucose biofuel cells.

Published

2020

20. Single microfluidic fuel cell with three fuels – formic acid, glucose and microbes: A comparative performance investigation

Author

Lanka Tata Rao, Prakash Rewatkar, Haroon Khan, Satish Kumar Dubey, Arshad Javed, Gyu Man Kim, and Sanket Goel

Subjects

electrocatalysis, biocatalysis, chemical fuel, biofuel, portable devices, Chemistry, QD1-999

Abstract

The development of microfluidic and nanofluidic devices is gaining remarkable attention due to the emphasis put on miniaturization of conventional energy conversion and storage processes. A microfluidic fuel cell can integrate flow of electrolytes, electrode-electrolyte interactions, and power generation in a microfluidic channel. Such microfluidic fuel cells can be categorized on the basis of electrolytes and catalysts used for power generation. In this work, for the first time, a single microfluidic fuel cell was harnessed by using different fuels like glucose, microbes and formic acid. Herein, multi-walled carbon nanotubes (MWCNT) acted as electrode material, and performance investigations were carried out separately on the same microfluidic device for three different types of fuel cells (formic acid, microbial and enzymatic). The fabricated miniaturized microfluidic device was successfully used to harvest energy in microwatts from formic acid, microbes and glucose, without any metallic catalyst. The developed microfluidic fuel cells can maintain stable open-circuit voltage, which can be used for energizing various low-power portable devices or applications.

Published

2021

21. Microfluidic paper based membraneless biofuel cell to harvest energy from various beverages

Author

Prakash Rewatkar and Sanket Goel

Subjects

Paper based enzymatic biofuel cell (P-EBFC), beverages, Carbon nanotube (CNT), Buckypaper (BP), Cyclic Voltammetry (CV), Chemistry, QD1-999

Abstract

The present work establishes the cost-effective and miniature microfluidic self-pumping paper based enzymatic biofuel cell (P-EBFC). The developed Y-shaped P-EBFC consists of buckeye composite multiwall carbon nanotube (MWCNT) buckypaper (BP) based bio-anode and bio-cathode that were immobilized with electro-biocatalytic enzymes glucose oxidase (GOx) and laccase, respectively. The electrocatalytic activity of enzymes on electrode surface is confirmed using cyclic voltammetry (CV) technique. Such immobilized bio-anode and bio-cathode show exquisite electrocatalytic activity towards glucose and O2, respectively. Most appealingly, P-EBFC can directly harvest energy from widely available beverages containing glucose such as Mountain Dew, Pepsi, 7up and fresh watermelon juice. This could provide potential application of P-EBFC as a portable power device.

Published

2019

22. Enzymatic fuel cells in a microfluidic environment: Status and opportunities. A mini review

Author

Prakash Rewatkar, Vivek Pratap Hitaishi, Elisabeth Lojou, and Sanket Goel

Subjects

Industrial electrochemistry, TP250-261, Chemistry, QD1-999

Abstract

Miniaturized Enzymatic Fuel Cells (EFCs) have attracted great attention due to the possibility of integrating them with various low-powered microelectronic devices. In a flow-through system, harnessing the co-laminar property of microfluidics, membraneless microfluidic EFCs (M-MEFC) can be designed, enhancing the ease of use of bio-devices and offering opportunities for new concepts. This brief review encompasses the development, current challenges and future pathways in the field of M-MEFCs, focusing in particular on some fabrication aspects and related device performance. Keywords: Enzyme, Biofuel cell, Microfluidic, Membraneless, Microfabrication

Published

2019

23. Platinum utilization in proton exchange membrane fuel cell and direct methanol fuel cell - Review

Author

Madhavi Bandapati, Sanket Goel, and Balaji Krishnamurthy

Subjects

Electrochemical active surface area, hydrogen adsorption, CO stripping, catalyst particle size, catalyst loading, catalyst dispersion, Chemistry, QD1-999

Abstract

Proton exchange membrane fuel cell (PEMFC) and direct methanol fuel cell (DMFC) are increasingly used as substitutes to conventional energy systems. Their compact design, high energy density and efficient energy-conversion offer several advantages over existing energy systems with potential for use in a variety of applications. However, performance, robustness and cost are the key challenges to overcome before fuel cells can be commercialized. Even though the use of platinum (Pt) and platinum group metal (PGM) alloy catalysts provide higher performance and durability, they are at the same time the largest cost components which need to be addressed. This paper reviews different approaches adopted to enhance Pt utilization such as reducing Pt loading, decreasing Pt particle size, developing Pt free metallic alloy catalyst, improving Pt dispersion, developing membrane electrode assembly (MEA) fabrication methods, increasing mass-transport at the electrode surface and modifying the catalyst support materials. Finally, the performance optimization efforts for Pt utilization are summarized with insights into probable directions of future research in this area.

Published

2019

24. Rapid Inkjet-Printed Miniaturized Interdigitated Electrodes for Electrochemical Sensing of Nitrite and Taste Stimuli

Author

Sohan Dudala, Sangam Srikanth, Satish Kumar Dubey, Arshad Javed, and Sanket Goel

Subjects

inkjet printing, microfabrication, nitrite sensing, taste sensing, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper reports on single step and rapid fabrication of interdigitated electrodes (IDEs) using an inkjet printing-based approach. A commercial inkjet-printed circuit board (PCB) printer was used to fabricate the IDEs on a glass substrate. The inkjet printer was optimized for printing IDEs on a glass substrate using a carbon ink with a specified viscosity. Electrochemical impedance spectroscopy in the frequency range of 1 Hz to 1 MHz was employed for chemical sensing applications using an electrochemical workstation. The IDE sensors demonstrated good nitrite quantification abilities, detecting a low concentration of 1 ppm. Taste simulating chemicals were used to experimentally analyze the ability of the developed sensor to detect and quantify tastes as perceived by humans. The performance of the inkjet-printed IDE sensor was compared with that of the IDEs fabricated using maskless direct laser writing (DLW)-based photolithography. The DLW–photolithography-based fabrication approach produces IDE sensors with excellent geometric tolerances and better sensing performance. However, inkjet printing provides IDE sensors at a fraction of the cost and time. The inkjet printing-based IDE sensor, fabricated in under 2 min and costing less than USD 0.3, can be adapted as a suitable IDE sensor with rapid and scalable fabrication process capabilities.

Published

2021

25. Micro Electromechanical Systems (MEMS) : Practical Lab Manual

Author

Sanket Goel and Sanket Goel

Abstract

Practical lab manual on the stepwise description of the experimental procedures of micro electromechanical systems (MEMS) devices Micro Electromechanical Systems (MEMS) is a highly practical lab manual on the relevant experimental procedures of MEMS devices, covering technical aspects including simulations and modeling, practical steps involved in fabrication, thorough characterizations of developed MEMS sensors, and leveraging these sensors in real-time targeted applications. The book provides in-depth coverage of multi-physics modeling for various sensors, as well as fabrication methodologies for photolithography, soft lithography, 3D printing, and laser processing-based experimental details for the realization of MEMS devices. It also covers characterization techniques from morphological to compositional, and applications of MEMS devices in contemporary fields such as microfluidics, wearables, and energy harvesters. The text also includes a foundational introduction to the subject. The book covers additional topics such as: Basic fluid flow and heat transfer in microfabrication, Y and T channel mixing, and simulation processes for Droplet generationSimulations based on cyclic voltammetry and electrochemical impedance spectroscopy, screen and ink-jet printing, laser-induced graphene, reduced graphene oxide, and 3D printingX-ray diffraction, scanning electron microscopy, optical microscopy, Raman spectroscopy, energy dispersive spectroscopy, and Fourier Transform Infrared (FTIR) Spectroscopy Experimental stepwise details to enable students to perform the experiments in the practical laboratory and future outlooks on the direction of the field A practical guidebook on the subject, Micro Electromechanical Systems (MEMS) is a must-have resource for students, academicians, and lab technicians seeking to conduct experiments in real-time.

Published

2025

26. 3D Printed Smart Sensors and Energy Harvesting Devices : Concepts, Fabrication and Applications

Author

Sanket Goel, Sohan Dudala, Sanket Goel, and Sohan Dudala

Abstract

The book,'3D Printed Smart Sensors and Energy Harvesting Devices: Concepts, Fabrication, and Applications'aims to explore the state-of-the-art integration of 3D printing technology in smart sensing and energy harvesting systems. By presenting a comprehensive overview of the field, the book seeks to bridge the gap between theoretical knowledge and practical applications, serving as a valuable resource for researchers, engineers, and students. The scope encompasses the entire value chain of 3D-printing-based sensors and devices development. Practical insights into designing and fabricating smart devices are provided, particularly emphasizing integrating chemical functionalities, electrodes, and advanced circuitry. This approach showcases state-of-the-art research and identifies challenges and future opportunities, fostering innovation in this dynamic field. Key Features: Reviews recent research by leveraging 3D printing in various smart sensing domains. A thorough introduction to 3D-printed smart sensors, energy harvesters and related devices Focus on applications

Published

2024

27. Droplet and Digital Microfluidics : Ideation to Implementation

Author

Sanket Goel, Sohan Dudala, Sanket Goel, and Sohan Dudala

Subjects

Microfluidics

Abstract

Droplet and Digital Microfluidics: Ideation to Implementation is a detailed introduction to the dynamics of droplet and digital microfluidics, also featuring coverage of new methods and applications. The explosion of applications of microelectromechanical systems (MEMS) in recent years has driven demand for expertise and innovation in fluid flow in the microchannels they contain. In this book, detailed descriptions of methods for biological and chemical applications of microfluidics are provided, along with supporting foundational knowledge. In addition, the principles of droplet and digital microfluidics are explained, along with their different applications and governing physics. New additions to the technological knowledgebase that enable advances in droplet and digital microfluidics include machine learning and exciting future avenues for research. - Provides step-by-step fabrication, testing, and characterization instructions in each chapter to support implementation - Includes explanations of applications and methods in biological and chemical settings - Describes the path to automation of digital and droplet microfluidic platforms

Published

2024

28. Miniaturized Electrochemical Devices : Advanced Concepts, Fabrication, and Applications

Author

Sanket Goel, Khairunnisa Amreen, Sanket Goel, and Khairunnisa Amreen

Subjects

R857.E52

Abstract

Evidently, electrochemical sensing has revolutionized the electroanalytical detections in the world. Since the 19th century, a huge amount of growth has been visible on various fronts, such as biosensors, energy devices, semiconductor devices, communication, embedded systems, sensors etc. However, the major research gap lies in the fact that most of the reported literatures are bulk systems; hence there are limitations for practical applications.Research in these domains has been carried out by both academia and industry, whereby academics is the backbone whose intellectual outputs have been widely adopted by the industry and implemented for consumers at large. In order to impart portability to the electrochemical sensors for point-of-care application, the collaboration of electrochemistry, microfluidics, electronics and communication as an interdisciplinary forum is crucial. The miniaturization, automation, IoT enabling and integration are the requirements for building the mentioned research gap. The conversion of electrochemical sensing theoretical concepts to practical applications in real time via miniaturization and integration of microfluidics will enhance this domain. In this context, of lately, several research groups have developed miniaturized microdevices as electrochemical-sensing platforms. This has led to a demand of offering a reference book as a guideline for the PhD programs in electrochemistry, MEMS, electronics and communication. Undoubtedly, this will have a huge impact for R&D in industries, public-funded research institutes and academic institutions.The book will provide a single forum to understand the current research trends and future perspectives of various electrochemical sensors and their integration in microfluidic devices, automation and point-of-care testing. For students, the book will become a motivation for them to explore these areas for their career standpoints. For the professionals, the book will become a thought-provoking stage to manoeuvre the next-generation devices/processes for commercialization.

Published

2023

29. Automated pencil electrode formation platform to realize uniform and reproducible graphite electrodes on paper for microfluidic fuel cells

Author

Prakash Rewatkar, Satish Kumar Dubey, Lanka Tata Rao, Sanket Goel, and Arshad Javed

Subjects

Materials for devices, Materials science, Fabrication, Science, Microfluidics, Nanotechnology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, Article, Techniques and instrumentation, Graphite, Power density, Multidisciplinary, 021001 nanoscience & nanotechnology, Electrical and electronic engineering, Mechanical engineering, 0104 chemical sciences, Pencil (optics), Electrode, Medicine, 0210 nano-technology, Current density, Materials for energy and catalysis

Abstract

Graphite pencil stroked electrodes for paper-based Microfluidic devices are gaining immense attention due to their electrochemical properties, cost efficiency, and ease-of-use. However, their widespread use has been hindered by the challenges associated with their manual fabrication such as non-uniformity in graphite deposition, applied pressure, etc. This work presents the design and development of an automated graphite pencil stroking device for graphite electrode fabrication with high efficiency through a compact, inexpensive and automatic process, with reduced fabrication time and human intervention leading to more uniformity. The motion platform of Graphtec plotter was used to create multiple strokes with the help of the proposed device. Such inexpensive graphite electrodes (less than the US $1) have been observed to be porous in nature, acting as diffusion agents. The automated graphite electrodes were used to study the performance of microfluidic paper fuel cells (MPFCs) with formic acid, oxygen, and sulphuric acid acting as fuel, oxidising agent and electrolyte respectively. From this configuration, the maximum current density and power density were measured to be 1,305.5 µA cm−2 and 135.5 µW cm−2, respectively at 0.3 V stable OCP at 100 strokes. Overall, the study enumerates the development of an automated pencil stroke device for fabricating graphite electrodes, which can potentially be harnessed in numerous miniaturized paper based applications.

Published

2020

30. Microelectronics and Signal Processing : Advanced Concepts and Applications

Author

Sanket Goel and Sanket Goel

Subjects

Signal processing, Microelectronics

Abstract

This book is about general and specific areas involved in electrical and electronics engineering which comprises broad subjects such as MEMS and Microfluidics, VLSI, Communication and Signal Processing. This book discusses the recent trends in various aspects of research areas for diverse applications like biomedical, biochemical, and power source systems. It also discusses modelling, simulating, and prototyping of the different electronic-based systems for carrying out varied applications. With this book, the readers will understand the multiplatform fundamentals guiding electrical and biomedical devices that form the current features such as automation, integration, and miniaturization of a particular device. This book showcases a unique platform as it covers the different areas of research in this trending era as a benchmark. This book is a link between the electronics and cutting-edge technologies that are being used for numerous applications representing the physical and virtual developments of electronic devices. Therefore, this book will mostly uphold the innovation and originality involved in the development of miniaturized devices, and proposing new methods, emphasizing with different areas of electrical and electronics engineering. This book entitles various approaches involved in electrical, biomedical, and electronics for modern distribution of research strategies and covers the state-of-art research themes. These include signal sensing, signal simulators, 3D printing technology, power systems, data acquisition systems, instrumentation, electrochemical sensing, electromechanical measurements, and signal analysis. The book will provide the academic perspectives of the cutting-edge R&D outputs from the faculty members and Ph.D. students, amalgamating the newer cross-dimensional areas, such as cyber-physical systems, nanoelectronics, smart-sensors, point-of-need devices, etc. The book will become a benchmark to the readers to understand the academic aspect of the contemporary work and the way forward on how this will lead to help the society-at-large.

Published

2021

31. Microfluidic paper based membraneless biofuel cell to harvest energy from various beverages

Author

Sanket Goel and Prakash Rewatkar

Subjects

beverages, 020209 energy, Buckypaper, 02 engineering and technology, Carbon nanotube, law.invention, lcsh:Chemistry, Colloid and Surface Chemistry, law, 0202 electrical engineering, electronic engineering, information engineering, Electrochemistry, Materials Chemistry, Chemical Engineering (miscellaneous), Glucose oxidase, Paper based enzymatic biofuel cell (P-EBFC), Enzymatic biofuel cell, carbon nanotubes (CNT), buckypaper (BP), cyclic voltammetry, Laccase, biology, Cyclic Voltammetry (CV), Chemistry, Carbon nanotube (CNT), 021001 nanoscience & nanotechnology, lcsh:QD1-999, Chemical engineering, Biofuel, Buckypaper (BP), Electrode, biology.protein, Cyclic voltammetry, 0210 nano-technology

Abstract

The present work establishes the cost-effective and miniature microfluidic self-pumping paper based enzymatic biofuel cell (P-EBFC). The developed Y-shaped P-EBFC consists of buckeye composite multiwall carbon nanotube (MWCNT) buckypaper (BP) based bio-anode and bio-cathode that were immobilized with electro-biocatalytic enzymes glucose oxidase (GOx) and laccase, respectively. The electrocatalytic activity of enzymes on electrode surface is confirmed using cyclic voltammetry (CV) technique. Such immobilized bio-anode and bio-cathode show exquisite electrocatalytic activity towards glucose and O2, respectively. Most appealingly, P-EBFC can directly harvest energy from widely available beverages containing glucose such as Mountain Dew, Pepsi, 7up and fresh watermelon juice. This could provide potential application of P-EBFC as a portable power device.

Published

2020

32. Enzymatic fuel cells in a microfluidic environment: Status and opportunities. A mini review

Author

Vivek Pratap Hitaishi, Elisabeth Lojou, Sanket Goel, Prakash Rewatkar, Birla Institute of Technology and Science (BITS Pilani), Bioénergétique et Ingénierie des Protéines (BIP ), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), and ANR-16-CE05-0024,Enzymor,Bases moléculaires de l'immobilisation fonctionnelle d'enzymes pour des biopiles performantes(2016)

Subjects

Engineering, [SDV.BIO]Life Sciences [q-bio]/Biotechnology, Microfluidics, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Mini review, lcsh:Chemistry, Electrochemistry, business.industry, Biofuel cell, 021001 nanoscience & nanotechnology, 0104 chemical sciences, lcsh:Industrial electrochemistry, lcsh:QD1-999, Microfluidic, Enzyme, Fuel cells, Membraneless, Microfabrication, 0210 nano-technology, business, [CHIM.OTHE]Chemical Sciences/Other, lcsh:TP250-261

Abstract

Miniaturized Enzymatic Fuel Cells (EFCs) have attracted great attention due to the possibility of integrating them with various low-powered microelectronic devices. In a flow-through system, harnessing the co-laminar property of microfluidics, membraneless microfluidic EFCs (M-MEFC) can be designed, enhancing the ease of use of bio-devices and offering opportunities for new concepts. This brief review encompasses the development, current challenges and future pathways in the field of M-MEFCs, focusing in particular on some fabrication aspects and related device performance. Keywords: Enzyme, Biofuel cell, Microfluidic, Membraneless, Microfabrication

Published

2019

33. Optical detection system for biochips using plastic fiber optics.

Author

J. N. McMullin, H. Qiao, Sanket Goel, and A. Grundmann

Subjects

OPTICAL communications, BIOCHIPS, OPTICAL fibers, MOLECULAR computers, FIBER Distributed Data Interface (Computer network standard)

Abstract

An instrument for the detection of optical signals from microfluidic biochips is described. The light detection system uses a LabView™-controlled photomultiplier tube with a programmable gain of 10[sup 4]–10[sup 7]. Plastic optical fibers (POFs) of 1 mm diameter are used to deliver light to and from the microfluidic systems. The detection system is demonstrated by detecting fluorescence from 15 μm polystyrene spheres in commercial biochips and micropipettes using a custom POF launch and detect tip. The spatial response of the tip allows dynamic measurements of the velocities of the microparticles to be made. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

34. Chemiluminiscence sensor for high-throughput DNA sequencing

Author

A R A Rahman, Shihui Foo, and Sanket Goel

Subjects

Chemistry(all), Base pair, business.industry, Computer science, Microfluidics, Analytical chemistry, General Medicine, DNA sequencing, chemiluminescence, CMOS Image sensor, pyrosequencing, Proof of concept, Chemical Engineering(all), Pyrosequencing, Fluidics, Image sensor, business, Throughput (business), Computer hardware

Abstract

The design and development of an inexpensive and customizable platform, for ultra-high throughput pyrosequenicng is presented. The platform comprises a micro-chip containing millions of reaction wells on a fiber optic platform, integrated with fluidics and a CMOS image sensor for chemiluminescence detection. Proof of concept experiments were performed to demonstrate the viability of the system for sequencing. Synthetic DNA, with various sequences, were designed and sequenced in the Pyrome sequencer. An experiment designed to test the loss of beads during long reads demonstrated that there is no appreciable loss of beads after sequencing 25 base pairs.

35. A parallel mesh chopping algorithm for a class of two-point boundary value problems

Author

C. P. Katti and Sanket Goel

Subjects

Discrete mathematics, Discretization, Parallel chopping algorithm, Parallel algorithm, Value (computer science), Division (mathematics), Combinatorics, Boundary value problems, Nonlinear system, Computational Mathematics, Hypercube, Computational Theory and Mathematics, Modeling and Simulation, Modelling and Simulation, Convergence (routing), Boundary value problem, Convergence, Mathematics

Abstract

A parallel algorithm for the class of two-point boundary value problems y ″ = f ( x , y ), y (0) = A , y (1) = B with ∂f ∂y ≥ 0 and ∂f ∂y continous on [0,1] × (−∞, ∞) is presented. Using an idea similar to that in [1], we divide [0,1] into p different divisions, each division consisting of N or ( N + 1) ( N small) unequal intervals. A high-order finite difference scheme developed for general nonuniform mesh is now applied to the above class of TPBVP's on each of the p divisions and leads to an N × N or ( N − 1) × ( N − 1) system of linear or nonlinear equations which is solved on p processors ( p a power of 2) simultaneously.

36. Performance Investigation of T-Shaped Micromixer with Different Obstacles.

Author

Lanka Tata Rao, Sanket Goel, Satish Kumar Dubey, and Arshad Javed

Published

2019