Design of novel Surfactant Modified Carbon Nanotube PasteElectrochemical Sensor for the Sensitive Investigation of Tyrosineas a Pharmaceutical Drug

Nagarajappa Hareesha ¹, Jamballi Gangadharappa Gowda Manjunatha ¹ * , Chenthattil Raril ¹, Girish Tigari ¹

Cited by CrossRef: 48

1- Manjunatha J, Raril C, Hareesha N, Charithra M, Pushpanjali P, Tigari G, Ravishankar D, Mallappaji S, Gowda J. Electrochemical Fabrication of Poly (niacin) Modified Graphite Paste Electrode and its Application for the Detection of Riboflavin. TOCENGJ. 2020;14(1):90 [Crossref]

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4- Hareesha N, Manjunatha J. Surfactant and polymer layered carbon composite electrochemical sensor for the analysis of estriol with ciprofloxacin. Materials Research Innovations. 2020;24(6):349 [Crossref]

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6- Hussein O, Elzanfaly E, Zaazaa H, Abdelkawy M, Atty S. Analytical Eco-Scale for Evaluating the Greenness of Advanced Voltammetric Method Used for the Simultaneous Analysis of Combined Urinary Tract Infection Drugs in Different Matrices. J Electrochem Soc. 2022;169(4):043507 [Crossref]

7- Mahmoud A, Mahnashi M, Abu-Alrub S, Alkahtani S, El-Wekil M. Indirect Differential Pulse Voltammetric Determination of Fluoride Ions at Carbon Paste Electrode Modified with Porous and Electroactive Fe3+/Fe2+Based-Metal Organic Frameworks Type MIL-101(Fe). J Electrochem Soc. 2021;168(12):126525 [Crossref]

8- Liu Y, Lu Y, Zhang S, Li X, Zhang Z, Ge L, Chang M, Liu Y, Lisak G, Deng S. Amphiphilic ligand in situ assembly of uranyl active sites and selective interactions of molybdenum disulfide. Journal of Hazardous Materials. 2023;442:130089 [Crossref]

9- Fekry A, Azab S, Abou Attia F, Ibrahim N, Mohamed G. An innovative sensor for the electrochemical determination of the new melatonergic antidepressant drug agomelatine. Measurement. 2021;186:110160 [Crossref]

10- Veseli A, Švorc Ľ, Sopaj F. Additional Studies on the Electrochemical Behaviour of Three Macrolides on Pt and Carbon Based Electrodes. Electroanalysis. 2021;33(10):2196 [Crossref]

11- Housaindokht M, Janati‐Fard F, Ashraf N. Recent advances in applications of surfactant‐based voltammetric sensors. J Surfact & Detergents. 2021;24(6):873 [Crossref]

12- Zhou T, Li H, Shang M, Sun D, Liu C, Che G. Recent analytical methodologies and analytical trends for riboflavin (vitamin B2) analysis in food, biological and pharmaceutical samples. TrAC Trends in Analytical Chemistry. 2021;143:116412 [Crossref]

13- Prinith N, Manjunatha J. Surfactant modified electrochemical sensor for determination of Anthrone – A cyclic voltammetry. Materials Science for Energy Technologies. 2019;2(3):408 [Crossref]

14- Narouie S, Rounaghi G, Saravani H, Shahbakhsh M. Multiwalled Carbon Nanotubes/4,4′‐Dihydroxybiphenyl Nanolayered Composite for Voltammetric Detection of Phenol. Electroanalysis. 2022;34(5):798 [Crossref]

15- Santhosh A, Sandeep S, James Bound D, Nandini S, Nalini S, Suresh G, Swamy N, Rajabathar J, Selvaraj A. A multianalyte electrochemical sensor based on cellulose fibers with silver nanoparticles composite as an innovative nano-framework for the simultaneous determination of ascorbic acid, dopamine and paracetamol. Surfaces and Interfaces. 2021;26:101377 [Crossref]

16- Moradi O. Electrochemical sensors based on carbon nanostructures for the analysis of bisphenol A—A review. Food and Chemical Toxicology. 2022;165:113074 [Crossref]

17- Jeba Sagana P, Swarnalatha K. Grafting of -Electroactive Probe onto the glassy carbon electrode for the Detection of Tetracycline in Milk sample. International Journal of Environmental Analytical Chemistry. 2024;:1 [Crossref]

18- Unal D, Yıldırım S, Kurbanoglu S, Uslu B. Current trends and roles of surfactants for chromatographic and electrochemical sensing. TrAC Trends in Analytical Chemistry. 2021;144:116418 [Crossref]

19- Bhimaraya K, Manjunatha J, Nagarajappa H, Aljuwayid A, Habila M, Sillanpaa M. Enhanced voltammetric detection of estriol hormone using poly(l-arginine)-modified carbon nanotube paste as a responsive electrochemical sensor. J IRAN CHEM SOC. 2024;21(1):129 [Crossref]

20- Zhang L, Liu X, Luo L, Hu C, Fu J, Chang X, Gan T. A high-performance voltammetric methodology for the ultra-sensitive detection of riboflavin in food matrices based on graphene oxide-covered hollow MnO2 spheres. Food Chemistry. 2021;352:129368 [Crossref]

21- Fukuda T, Muguruma H, Iwasa H, Tanaka T, Hiratsuka A, Shimizu T, Tsuji K, Kishimoto T. Electrochemical determination of uric acid in urine and serum with uricase/carbon nanotube /carboxymethylcellulose electrode. Analytical Biochemistry. 2020;590:113533 [Crossref]

22- Shashanka R, Kumara Swamy B. Simultaneous electro-generation and electro-deposition of copper oxide nanoparticles on glassy carbon electrode and its sensor application. SN Appl Sci. 2020;2(5) [Crossref]

23- Teradale A, Ganesh P, Lamani S, Swamy B, Das S. Electrochemical investigation of allopurinol polymerised carbon paste electrode interface for epinephrine and folic acid sensing in pharmaceutical samples. Materials Research Innovations. 2022;26(5):295 [Crossref]

24- Nasimi H, Madsen J, Zedan A, Malmendal A, Osther P, Alatraktchi F. Electrochemical sensors for screening of tyrosine and tryptophan as biomarkers for diseases: A narrative review. Microchemical Journal. 2023;190:108737 [Crossref]

25- Prasanna S, Bahajjaj A, Lee Y, Lin Y, Dhawan U, Sakthivel R, Chung R. Highly responsive and sensitive non-enzymatic electrochemical sensor for the detection of β-NADH in food, environmental and biological samples using AuNP on polydopamine/titanium carbide composite. Food Chemistry. 2023;426:136609 [Crossref]

26- Hareesha N, Manjunatha J. Elevated and rapid voltammetric sensing of riboflavin at poly(helianthin dye) blended carbon paste electrode with heterogeneous rate constant elucidation. J IRAN CHEM SOC. 2020;17(6):1507 [Crossref]

27- Prinith N, Manjunatha J, Hareesha N. Electrochemical validation of L-tyrosine with dopamine using composite surfactant modified carbon nanotube electrode. J IRAN CHEM SOC. 2021;18(12):3493 [Crossref]

28- Hendawy H, Amin A, Moalla S, Aish M. Nano-Iron Oxide Supported on the Printed Electrode for Voltammetric Determination of Manidipine on a Very Small Sample in Different Media: Analytical and Clinical Purposes. J Electrochem Soc. 2021;168(12):126520 [Crossref]

29- Alam M, Uddin M, Asiri A, Rahman M, Islam M. Detection of L-Tyrosine by electrochemical method based on binary mixed CdO/SnO2 nanoparticles. Measurement. 2020;163:107990 [Crossref]

30- Ettadili F, Azriouil M, Matrouf M, Laghrib F, Saqrane S, Farahi A, Bakasse M, Lahrich S, Mhammedi M. Electrochemical determination of ornidazole at silver electrode: analytical application in human blood. Chemical Data Collections. 2022;39:100850 [Crossref]

31- Pushpanjali P, Manjunatha J, Srinivas M. Highly sensitive platform utilizing poly(l-methionine) layered carbon nanotube paste sensor for the determination of voltaren. FlatChem. 2020;24:100207 [Crossref]

32- Kausar A. Polyamide/nanosilica nanocomposite: a chronicle of design and high-tech progressions. Materials Research Innovations. 2022;26(1):52 [Crossref]

33- Hareesha N, Manjunatha J, Amrutha B, Sreeharsha N, Basheeruddin Asdaq S, Anwer M. A fast and selective electrochemical detection of vanillin in food samples on the surface of poly(glutamic acid) functionalized multiwalled carbon nanotubes and graphite composite paste sensor. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2021;626:127042 [Crossref]

34- Harshitha B, Manjunatha J, Pushpanjali P, Karthik C, Sandeep S, Mallu P, D'Souza E, Sreeharsha N, Asdaq S, Anwer M. Efficient Electrochemical Determination of Catechol with Hydroquinone at Poly (L‐Serine) Layered Carbon Paste Electrode. ChemistrySelect. 2021;6(26):6764 [Crossref]

35- Sreeharsha N, Telsang M, Basavarajappa G, Pund S, Karnati R. Poly (threonine) Modified Carbon Composite Electrode as Sensor for Amoxicillin Determination. International Journal of Electrochemical Science. 2022;17(2):220229 [Crossref]

36- C, Manjunatha J, Ravishankar D, Fattepur S, Siddaraju G, Nanjundaswamy L. Validated Electrochemical Method for Simultaneous Resolution of Tyrosine, Uric Acid, and Ascorbic Acid at Polymer Modified Nano-Composite Paste Electrode. Surf Engin ApplElectrochem. 2020;56(4):415 [Crossref]

37- Darroudi A, Nazari S, Marashi S, Nazar Abad M. Determination of Simvastatin by Voltammetry Method at Screen-Printed Electrode Modified by Graphene Oxide Nanosheets and Sodium Dodecyl Sulfate. J Electrochem Soc. 2022;169(2):026501 [Crossref]

38- Dheepthi Gunavathana S, Girija S, Wilson J, Cyrac Peter A. ZnO nanorods bonded polythiophene nanocomposite: an enhanced electrochemical voltammetric biosensing of L-tryptophan. Bull Mater Sci. 2022;45(2) [Crossref]

39- Nasimi H, Madsen J, Zedan A, Schmedes A, Malmendal A, Osther P, Alatraktchi F. Correlation between stage of prostate cancer and tyrosine and tryptophan in urine samples measured electrochemically. Analytical Biochemistry. 2022;649:114698 [Crossref]

40- Tigari G, Manjunatha J, Ravishankar D, Siddaraju G. Enhanced Electrochemical Determination Of Riboflavin In Biological And Pharmaceutical Samples At Poly (Arginine) Modified Carbon Paste Electrode. MOCA. 2019;14(4):216 [Crossref]

41- Alizadeh M, Asrami P, Altuner E, Gulbagca F, Tiri R, Aygun A, Kaynak İ, Sen F, Cheraghi S. An ultra-sensitive rifampicin electrochemical sensor based on Fe3O4 nanoparticles anchored Multiwalled Carbon nanotube modified glassy carbon electrode. Chemosphere. 2022;309:136566 [Crossref]

42- Hareesha N, Manjunatha J, Raril C, Tigari G. Sensitive and Selective Electrochemical Resolution of Tyrosine with Ascorbic Acid through the Development of Electropolymerized Alizarin Sodium Sulfonate Modified Carbon Nanotube Paste Electrodes. ChemistrySelect. 2019;4(15):4559 [Crossref]