@kuvempu university
PROFESSOR in the Department of Post-Graduate Studies in Teaching and Research in Industrial Chemistry
Kuvempu University
Prof. B.E,Kumara Swamy has obtained his Ph.D degree in Industrial Chemistry from Kuvempu University and Post-Doctoral Research Associate from Southern Methodist University, Dallas, Texas and University of Virginia, Virginia, USA. Presently working as, a Professor of Industrial Chemistry at Department of Post-Graduate Studies in Industrial Chemistry, Kuvempu University. His research areas are Development of Electrochemical Sensor for some neurotransmitters, Biosensors, Nanosensors and Nanochemistry. He has published more than 332 research papers in peer-reviewed journals of having h index 48with citations more than 8500. He completed four major research projects from different fundning agencies as Principal and Co-Investigator. He is in Associate Editor in Science Letters Journal, World Research Journal of Analytical Chemistry, Academic Editor to Journal of Chemistry, Advisory Board member in Biopublications and worked as Guest Editor in Special Issue on Nanoparticle and Cancer Treatme
M.Sc., Ph.D., Post Doc (USA)
Electrochemistry, Materials Science
Scopus Publications
Scholar Citations
Scholar h-index
Scholar i10-index
Nandini Robin Nadar, J. Deepak, S.C. Sharma, B.R. Radha Krushna, Puneeth, R. Sowjanya, V. Sureka Varalakshmi, Samir Sahu, B. Sargunam, H. Nagabhushana,et al.
Elsevier BV
E. Vinay Kumar, T.L. Soundarya, B.E. Kumara Swamy, Anitha, and G. Nagaraju
Elsevier BV
E. Vinay Kumar, T.L. Soundarya, Anitha, B.E. Kumara Swamy, and G. Nagaraju
Elsevier BV
Rajeshwari Yemmi, B.E. Kumara Swamy, S.C. Sharma, C. Sridhar, and Basudev Kar
Elsevier BV
Manjunatha L.S., B.E.Kumara Swamy, S.C. Sharma, and C. Krithika
Elsevier BV
L.S. Manjunatha, B.E. Kumara Swamy, S.C. Sharma, C. Sridhar, M.R. Sanjana, and S. Kumar
Elsevier BV
E. Vinay Kumar, Anitha, B.E. Kumara Swamy, G.R. Suma, and G. Nagaraju
Elsevier BV
K.G. Manjunatha, B.E. Kumara Swamy, G.K. Jayaprakash, H.D. Madhuchandra, and K.A. Vishnumurthy
Elsevier BV
S. D. Sukanya, B. E. Kumara Swamy, J. K. Shashikumara, S. C. Sharma, and S. A. Hariprasad
Springer Science and Business Media LLC
AbstractA simple, novel, and less cost yellow (Erythrosine) modified pencil graphite electrode (Po-ERY/MGPE) was successfully fabricated via electropolymerization method using cyclic voltammetric techniques. The fabricated Po-ERY/MGPE opted as a sensor for the detection of Adrenaline (ADR) in 0.2 M PBS (7.4 pH). This reported senor displayed excellent electrocatalytic activity, increased sensitivity, high stability, superior electron transfer kinetics in the oxidation of ADR once relative to BGPE. The significance of pH, scan rate, and impact of concentration was assessed at the sensor. As per the pH and scan rate study, redox routes carry the same number of electrons and protons, and electro-oxidation of ADR was adsorption controlled respectively. The LOD of ADR was found to be 0.499 µM. The DPV data indicate that there is a significant peak divergence among ADR and uric acid (UA) which could make it easier to determine them alone and simultaneously on the sensor. The described method has been employed for the determination of ADR in injection sample. Good recovery values indicate the efficacy and applicability of the sensor in detecting ADR.
E. Vinay kumar, B.S. Niveditha, L. Sushmitha, B.K. Usha, B.E. Kumara swamy, Anitha, and G. Nagaraju
Elsevier BV
G.S. Sumanth, B.E. Kumara Swamy, and K. Chetankumar
Elsevier BV
S.B. Arpitha, B.E. Kumara Swamy, and J.K. Shashikumara
Elsevier BV
M. Shruthi Vishwanath, B.E. Kumara Swamy, and K.A. Vishnumurthy
Elsevier BV
L.S. Manjunatha, B.E. Kumara Swamy, and K.G. Manjunatha
Elsevier BV
G.S. Sumanth, B.E. Kumara Swamy, and K. Chetankumar
Elsevier BV
Rukaya Banu, B.E. Kumara Swamy, and Anup Pandith
Bentham Science Publishers Ltd.
Abstract: In the present investigation, an electrochemical sensing approach based on the electropolymerization modulation of brilliant green on a glassy carbon electrode has been introduced for rapid and sensitive identification of serotonin (SE) and epinephrine (EP) by cyclic and differential pulse voltammetric procedures. Under adequate circumstances, the analytical variable like the pH of the supporting solution, was maintained between the range of 6.2-8.0. Furthermore, the electro-kinetic parameter was surveyed, and the electrode depicted the proportionality between the current intensities with the concentration of analytes with a low detection limit (0.74×10-6 M for SE and 0.58×10-6 M for EP). The modulated sensor portrayed the supreme electrocatalytic characteristics toward the simultaneous quantification of SE and EP in a sample mixture.
Gururaj Kudur Jayaprakash, B. E. Kumara Swamy, Roberto Flores-Moreno, and Kayim Pineda-Urbina
MDPI AG
The molecular dynamics and density functional theory (DFT) can be applied to discriminate electrocatalyst’s electron transfer (ET) properties. It will be interesting to discriminate the ET properties of green electrocatalysts such as amino acids. Here, we have used DFT to compare the electrocatalytic abilities of asparagine and glutamine at the carbon paste electrode interface. Cyclic voltammetric results reveal that the electrocatalytic activities of aspargine are higher than glutamine for dopamine sensing. Dopamine requires less energy to bind with asparagine when compared to glutamine. Additionally, asparagine has higher electron-donating and accepting powers. Therefore, asparagine has a higher electrocatalytic activity than glutamine—the ability for the asparagine and glutamine carbon electrodes to detect dopamine in commercial injection, and to obtain satisfactory results. As a part of the work, we have also studied dopamine interaction with the modified carbon surface using molecular dynamics.
J. K. Shashi Kumara, B. E. Kumara Swamy, G. K. Jayaprakash, S. C. Sharma, Roberto Flores.-Moreno, Kaustubha Mohanty, and S. A. Hariprasad
Springer Science and Business Media LLC
AbstractDopamine (DA) is one of the chief neurotransmitters present in the central nervous system of mammals. Therefore detection of DA in presence of various analytes like paracetamol has great importance. In the current work, we are proposing that Triton X-100 (TX-100) pretreated carbon paste electrode (CPE) can be useful to detect the DA selectively in presence of PA. After the pretreatment CPE can detect DA in presence of PA effectively. Cyclic voltammetry was employed to observe the amplified electron transfer reaction between the modified CPE and DA. To understand electron transfer regioselectivity at the TX-100 pretreated CPE, a dual descriptor was used. The prepared electrode showed satisfactory stability when kept under ambient conditions. The proposed approach also showed excellent analytical applicability to identify DA and PA in commercial formulations. The scope of the work is limited to detecting DA in presence of PA. We will consider the other interferes for future works.
Rukaya banu, B.E. Kumara Swamy, and Eno Ebenso
Elsevier BV