Digital Image Colorimetric Detection of H2O2 Utilizing PEG/Ag/AgO Nanoparticles Derived from Tangerine Leaf Extract

Emre Yılmazoğlu

doi:10.18596/jotcsa.1439951

Araştırma Makalesi

Digital Image Colorimetric Detection of H2O2 Utilizing PEG/Ag/AgO Nanoparticles Derived from Tangerine Leaf Extract

Yıl 2024, Cilt: 11 Sayı: 3, 1303 - 1312, 30.08.2024

Emre Yılmazoğlu

https://doi.org/10.18596/jotcsa.1439951

Öz

Recent developments in biosensors based on digital platforms have primarily focused on enhancing rapid detection, flexibility, and selectivity through the utilization of nanomaterials. Despite these advances, the complexity of image colorimetric measurements continues to be a subject of interest. This study focused on the development of a new digital image colorimetric biosensor for real-time quantification of hydrogen peroxide (H2O2). The designed nanostructure-based sensor showed excellent selectivity and sensitivity, utilizing polyethylene glycol/Silver/Silver(II) oxide nanoparticles obtained from tangerine leaf extract (TLE/PEG/Ag/AgO NPs). The sensor's performance was validated using Ag/AgO NPs derived from tangerine leaf extract (TLE), demonstrating remarkable selectivity and sensitivity using a Red-Green-Blue (RGB)--based approach. Based on digital image colorimetric measurements of TLE/PEG/Ag/AgO NPs, a system for determining H2O2 was established in a linear range of 2.0–100.0 μmol/L with a low limit of detection (LOD) of 1.82 μmol/L. This study not only presented a facile strategy for the design of the digital image colorimetric TLE/PEG/Ag/AgO NPs-based biosensor but also shed light on the remarkable potential of smartphone sensing devices based on nanosensor technology. These sensors offer fresh perspectives and multidisciplinary approaches to visually sensitive sensing in a range of applications, such as biomedical diagnostics, security screening, and environmental monitoring.

Anahtar Kelimeler

digital biosensor, image colorimetric sensor, silver nanoparticles, green sensor

Kaynakça

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4. Zhang W, Hong C, Pan C. Polymerization‐Induced Self‐Assembly of Functionalized Block Copolymer Nanoparticles and Their Application in Drug Delivery. Macromol Rapid Commun [Internet]. 2019 Jan 2;40(2):1800279. Available from: <URL>.
5. Hulsey S, Absar S, Choi H. Investigation of simultaneous ultrasonic processing of polymer-nanoparticle solutions for electrospinning of nanocomposite nanofibers. J Manuf Process [Internet]. 2018 Aug;34:776–84. Available from: <URL>.
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7. Alavi M, Varma RS. Phytosynthesis and modification of metal and metal oxide nanoparticles/nanocomposites for antibacterial and anticancer activities: Recent advances. Sustain Chem Pharm [Internet]. 2021 Jun;21:100412. Available from: <URL>.
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9. Dissanayake NM, Arachchilage JS, Samuels TA, Obare SO. Highly sensitive plasmonic metal nanoparticle-based sensors for the detection of organophosphorus pesticides. Talanta [Internet]. 2019 Aug;200:218–27. Available from: <URL>.
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12. Gholami M, Koivisto B. A flexible and highly selective non-enzymatic H2O2 sensor based on silver nanoparticles embedded into Nafion. Appl Surf Sci [Internet]. 2019 Feb;467–468:112–8. Available from: <URL>.
13. Teodoro KBR, Migliorini FL, Christinelli WA, Correa DS. Detection of hydrogen peroxide (H2O2) using a colorimetric sensor based on cellulose nanowhiskers and silver nanoparticles. Carbohydr Polym [Internet]. 2019 May;212:235–41. Available from: <URL>.
14. Ismail M, Khan MI, Akhtar K, Khan MA, Asiri AM, Khan SB. Biosynthesis of silver nanoparticles: A colorimetric optical sensor for detection of hexavalent chromium and ammonia in aqueous solution. Phys E Low-dimensional Syst Nanostructures [Internet]. 2018 Sep;103:367–76. Available from: <URL>.
15. Mohammed GM, Hawar SN. Green Biosynthesis of Silver Nanoparticles from Moringa oleifera Leaves and Its Antimicrobial and Cytotoxicity Activities. Ali S, editor. Int J Biomater [Internet]. 2022 Sep 19;2022:4136641. Available from: <URL>.
16. Judith Vijaya J, Jayaprakash N, Kombaiah K, Kaviyarasu K, John Kennedy L, Jothi Ramalingam R, et al. Bioreduction potentials of dried root of Zingiber officinale for a simple green synthesis of silver nanoparticles: Antibacterial studies. J Photochem Photobiol B Biol [Internet]. 2017 Dec;177:62–8. Available from: <URL>.
17. Aldosary SK, El-Rahman SNA, Al-Jameel SS, Alromihi NM. Antioxidant and antimicrobial activities of Thymus vulgaris essential oil contained and synthesis thymus (Vulgaris) silver nanoparticles. Brazilian J Biol [Internet]. 2023;83:e244675. Available from: <URL>.
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20. Singh A, Jain D, Upadhyay MK, Khandelwal N, Verma HN. Green synthesis of silver nanoparticles using Argemone Mexicana leaf extract and evaluation of their antimicrobial activities. Dig J Nanomater Biostructures [Internet]. 2010;5(2):483–9. Available from: <URL>.
21. He Y, Wei F, Ma Z, Zhang H, Yang Q, Yao B, et al. Green synthesis of silver nanoparticles using seed extract of Alpinia katsumadai, and their antioxidant, cytotoxicity, and antibacterial activities. RSC Adv [Internet]. 2017;7(63):39842–51. Available from: <URL>.
22. Malabadi RB, Mulgund GS, Meti NT, Nataraja K, Vijaya Kumar S. Antibacterial activity of silver nanoparticles synthesized by using whole plant extracts of Clitoria ternatea. Res Pharm [Internet]. 2012;2(4):10–21. Available from: <URL>.
23. Anushaa A, Pushpa A, Vijaya KG, Thippareddy K. Green synthesis of non-cytotoxic silver nanoparticles using Solanum nigrum leaves extract with antibacterial properties. GSC Biol Pharm Sci [Internet]. 2021 Jun 30;15(3):262–71. Available from: <URL>.
24. Lu L, Zhuang Z, Fan M, Liu B, Yang Y, Huang J, et al. Green formulation of Ag nanoparticles by Hibiscus rosa-sinensis: Introducing a navel chemotherapeutic drug for the treatment of liver cancer. Arab J Chem [Internet]. 2022 Feb;15(2):103602. Available from: <URL>.
25. Zayed MF, Mahfoze RA, El-kousy SM, Al-Ashkar EA. In-vitro antioxidant and antimicrobial activities of metal nanoparticles biosynthesized using optimized Pimpinella anisum extract. Colloids Surfaces A Physicochem Eng Asp [Internet]. 2020 Jan;585:124167. Available from: <URL>.
26. Yasmin H. M, Veerendra C. Y. Synthesis of Coccinia grandis (L.) Voigt extract’s silver nanoparticles and it’s in vitro antidiabetic activity. J Appl Pharm Sci [Internet]. 2021 Aug 5;11(8):108–15. Available from: <URL>.
27. Renuka R, Devi KR, Sivakami M, Thilagavathi T, Uthrakumar R, Kaviyarasu K. Biosynthesis of silver nanoparticles using phyllanthus emblica fruit extract for antimicrobial application. Biocatal Agric Biotechnol [Internet]. 2020 Mar;24:101567. Available from: <URL>.
28. Niluxsshun MCD, Masilamani K, Mathiventhan U. Green Synthesis of Silver Nanoparticles from the Extracts of Fruit Peel of Citrus tangerina, Citrus sinensis, and Citrus limon for Antibacterial Activities. Ciccarella G, editor. Bioinorg Chem Appl [Internet]. 2021 Feb 2;2021:695734. Available from: <URL>.
29. Hussain M, Raja NI, Mashwani Z, Naz F, Iqbal M, Aslam S. Green synthesis and characterisation of silver nanoparticles and their effects on antimicrobial efficacy and biochemical profiling in Citrus reticulata. IET Nanobiotechnology [Internet]. 2018 Jun 21;12(4):514–9. Available from: <URL>.
30. Mogole L, Omwoyo W, Viljoen E, Moloto M. Green synthesis of silver nanoparticles using aqueous extract of Citrus sinensis peels and evaluation of their antibacterial efficacy. Green Process Synth [Internet]. 2021 Dec 7;10(1):851–9. Available from: <URL>.
31. Basavegowda N, Rok Lee Y. Synthesis of silver nanoparticles using Satsuma mandarin (Citrus unshiu) peel extract: A novel approach towards waste utilization. Mater Lett [Internet]. 2013 Oct;109:31–3. Available from: <URL>.
32. Sekkat A, Liedke MO, Nguyen VH, Butterling M, Baiutti F, Sirvent Veru J de D, et al. Chemical deposition of Cu2O films with ultra-low resistivity: correlation with the defect landscape. Nat Commun [Internet]. 2022 Sep 9;13(1):5322. Available from: <URL>.
33. Engel L, Benito-Altamirano I, Tarantik KR, Pannek C, Dold M, Prades JD, et al. Printed sensor labels for colorimetric detection of ammonia, formaldehyde and hydrogen sulfide from the ambient air. Sensors Actuators B Chem [Internet]. 2021 Mar;330:129281. Available from: <URL>.
34. Thompson NBA, O’Sullivan SE, Howell RJ, Bailey DJ, Gilbert MR, Hyatt NC. Objective colour analysis from digital images as a nuclear forensic tool. Forensic Sci Int [Internet]. 2021 Feb;319:110678. Available from: <URL>.
35. Karakuş S, Özbaş F, Baytemir G, Taşaltın N. Cubic-shaped corylus colurna extract coated Cu2O nanoparticles-based smartphone biosensor for the detection of ascorbic acid in real food samples. Food Chem [Internet]. 2023 Aug;417:135918. Available from: <URL>.
36. Boughendjioua H, Mezedjeri NEH, Idjouadiene I. Chemical constituents of Algerian mandarin ( Citrus reticulata ) essential oil by GC-MS and FT-IR analysis. Curr Issues Pharm Med Sci [Internet]. 2020 Dec 1;33(4):197–201. Available from: <URL>.
37. Georgieva M, Gospodinova Z, Keremidarska-Markova M, Kamenska T, Gencheva G, Krasteva N. PEGylated Nanographene Oxide in Combination with Near-Infrared Laser Irradiation as a Smart Nanocarrier in Colon Cancer Targeted Therapy. Pharmaceutics [Internet]. 2021 Mar 22;13(3):424. Available from: <URL>.
38. Rita A, Sivakumar A, Dhas SSJ, Dhas SAMB. Structural, optical and magnetic properties of silver oxide (AgO) nanoparticles at shocked conditions. J Nanostructure Chem [Internet]. 2020 Dec 24;10(4):309–16. Available from: <URL>.
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42. Kumar V, Gupta RK, Gundampati RK, Singh DK, Mohan S, Hasan SH, et al. Enhanced electron transfer mediated detection of hydrogen peroxide using a silver nanoparticle–reduced graphene oxide–polyaniline fabricated electrochemical sensor. RSC Adv [Internet]. 2018;8(2):619–31. Available from: <URL>.
43. Dodevska T, Vasileva I, Denev P, Karashanova D, Georgieva B, Kovacheva D, et al. Rosa damascena waste mediated synthesis of silver nanoparticles: Characteristics and application for an electrochemical sensing of hydrogen peroxide and vanillin. Mater Chem Phys [Internet]. 2019 Jun;231:335–43. Available from: <URL>.
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Yıl 2024, Cilt: 11 Sayı: 3, 1303 - 1312, 30.08.2024

Emre Yılmazoğlu

https://doi.org/10.18596/jotcsa.1439951

Öz

Kaynakça

1. Xu J, Ma J, Peng Y, Cao S, Zhang S, Pang H. Applications of metal nanoparticles/metal-organic frameworks composites in sensing field. Chinese Chem Lett [Internet]. 2023 Apr;34(4):107527. Available from: <URL>.
2. Qanash H, Bazaid AS, Alharazi T, Barnawi H, Alotaibi K, Shater ARM, et al. Bioenvironmental applications of myco-created bioactive zinc oxide nanoparticle-doped selenium oxide nanoparticles. Biomass Convers Biorefinery [Internet]. 2024 Aug 1;14(15):17341–52. Available from: <URL>.
3. Lu N, Shao C, Li X, Miao F, Wang K, Liu Y. CuO nanoparticles/nitrogen-doped carbon nanofibers modified glassy carbon electrodes for non-enzymatic glucose sensors with improved sensitivity. Ceram Int [Internet]. 2016 Jul;42(9):11285–93. Available from: <URL>.
4. Zhang W, Hong C, Pan C. Polymerization‐Induced Self‐Assembly of Functionalized Block Copolymer Nanoparticles and Their Application in Drug Delivery. Macromol Rapid Commun [Internet]. 2019 Jan 2;40(2):1800279. Available from: <URL>.
5. Hulsey S, Absar S, Choi H. Investigation of simultaneous ultrasonic processing of polymer-nanoparticle solutions for electrospinning of nanocomposite nanofibers. J Manuf Process [Internet]. 2018 Aug;34:776–84. Available from: <URL>.
6. Afzali M, Mostafavi A, Shamspur T. Developing a novel sensor based on ionic liquid molecularly imprinted polymer/gold nanoparticles/graphene oxide for the selective determination of an anti-cancer drug imiquimod. Biosens Bioelectron [Internet]. 2019 Oct;143:111620. Available from: <URL>.
7. Alavi M, Varma RS. Phytosynthesis and modification of metal and metal oxide nanoparticles/nanocomposites for antibacterial and anticancer activities: Recent advances. Sustain Chem Pharm [Internet]. 2021 Jun;21:100412. Available from: <URL>.
8. Shashiraj KN, Hugar A, Kumar RS, Rudrappa M, Bhat MP, Almansour AI, et al. Exploring the Antimicrobial, Anticancer, and Apoptosis Inducing Ability of Biofabricated Silver Nanoparticles Using Lagerstroemia speciosa Flower Buds against the Human Osteosarcoma (MG-63) Cell Line via Flow Cytometry. Bioengineering [Internet]. 2023 Jul 10;10(7):821. Available from: <URL>.
9. Dissanayake NM, Arachchilage JS, Samuels TA, Obare SO. Highly sensitive plasmonic metal nanoparticle-based sensors for the detection of organophosphorus pesticides. Talanta [Internet]. 2019 Aug;200:218–27. Available from: <URL>.
10. Zhai D, Liu B, Shi Y, Pan L, Wang Y, Li W, et al. Highly Sensitive Glucose Sensor Based on Pt Nanoparticle/Polyaniline Hydrogel Heterostructures. ACS Nano [Internet]. 2013 Apr 23;7(4):3540–6. Available from: <URL>.
11. Ghosh G. Early detection of cancer: Focus on antibody coated metal and magnetic nanoparticle-based biosensors. Sensors Int [Internet]. 2020;1:100050. Available from: <URL>.
12. Gholami M, Koivisto B. A flexible and highly selective non-enzymatic H2O2 sensor based on silver nanoparticles embedded into Nafion. Appl Surf Sci [Internet]. 2019 Feb;467–468:112–8. Available from: <URL>.
13. Teodoro KBR, Migliorini FL, Christinelli WA, Correa DS. Detection of hydrogen peroxide (H2O2) using a colorimetric sensor based on cellulose nanowhiskers and silver nanoparticles. Carbohydr Polym [Internet]. 2019 May;212:235–41. Available from: <URL>.
14. Ismail M, Khan MI, Akhtar K, Khan MA, Asiri AM, Khan SB. Biosynthesis of silver nanoparticles: A colorimetric optical sensor for detection of hexavalent chromium and ammonia in aqueous solution. Phys E Low-dimensional Syst Nanostructures [Internet]. 2018 Sep;103:367–76. Available from: <URL>.
15. Mohammed GM, Hawar SN. Green Biosynthesis of Silver Nanoparticles from Moringa oleifera Leaves and Its Antimicrobial and Cytotoxicity Activities. Ali S, editor. Int J Biomater [Internet]. 2022 Sep 19;2022:4136641. Available from: <URL>.
16. Judith Vijaya J, Jayaprakash N, Kombaiah K, Kaviyarasu K, John Kennedy L, Jothi Ramalingam R, et al. Bioreduction potentials of dried root of Zingiber officinale for a simple green synthesis of silver nanoparticles: Antibacterial studies. J Photochem Photobiol B Biol [Internet]. 2017 Dec;177:62–8. Available from: <URL>.
17. Aldosary SK, El-Rahman SNA, Al-Jameel SS, Alromihi NM. Antioxidant and antimicrobial activities of Thymus vulgaris essential oil contained and synthesis thymus (Vulgaris) silver nanoparticles. Brazilian J Biol [Internet]. 2023;83:e244675. Available from: <URL>.
18. Hambardzumyan S, Sahakyan N, Petrosyan M, Nasim MJ, Jacob C, Trchounian A. Origanum vulgare L. extract-mediated synthesis of silver nanoparticles, their characterization and antibacterial activities. AMB Express [Internet]. 2020 Dec 5;10(1):162. Available from: <URL>.
19. Mirzajani F, Askari H, Hamzelou S, Schober Y, Römpp A, Ghassempour A, et al. Proteomics study of silver nanoparticles toxicity on Oryza sativa L. Ecotoxicol Environ Saf [Internet]. 2014 Oct;108:335–9. Available from: <URL>.
20. Singh A, Jain D, Upadhyay MK, Khandelwal N, Verma HN. Green synthesis of silver nanoparticles using Argemone Mexicana leaf extract and evaluation of their antimicrobial activities. Dig J Nanomater Biostructures [Internet]. 2010;5(2):483–9. Available from: <URL>.
21. He Y, Wei F, Ma Z, Zhang H, Yang Q, Yao B, et al. Green synthesis of silver nanoparticles using seed extract of Alpinia katsumadai, and their antioxidant, cytotoxicity, and antibacterial activities. RSC Adv [Internet]. 2017;7(63):39842–51. Available from: <URL>.
22. Malabadi RB, Mulgund GS, Meti NT, Nataraja K, Vijaya Kumar S. Antibacterial activity of silver nanoparticles synthesized by using whole plant extracts of Clitoria ternatea. Res Pharm [Internet]. 2012;2(4):10–21. Available from: <URL>.
23. Anushaa A, Pushpa A, Vijaya KG, Thippareddy K. Green synthesis of non-cytotoxic silver nanoparticles using Solanum nigrum leaves extract with antibacterial properties. GSC Biol Pharm Sci [Internet]. 2021 Jun 30;15(3):262–71. Available from: <URL>.
24. Lu L, Zhuang Z, Fan M, Liu B, Yang Y, Huang J, et al. Green formulation of Ag nanoparticles by Hibiscus rosa-sinensis: Introducing a navel chemotherapeutic drug for the treatment of liver cancer. Arab J Chem [Internet]. 2022 Feb;15(2):103602. Available from: <URL>.
25. Zayed MF, Mahfoze RA, El-kousy SM, Al-Ashkar EA. In-vitro antioxidant and antimicrobial activities of metal nanoparticles biosynthesized using optimized Pimpinella anisum extract. Colloids Surfaces A Physicochem Eng Asp [Internet]. 2020 Jan;585:124167. Available from: <URL>.
26. Yasmin H. M, Veerendra C. Y. Synthesis of Coccinia grandis (L.) Voigt extract’s silver nanoparticles and it’s in vitro antidiabetic activity. J Appl Pharm Sci [Internet]. 2021 Aug 5;11(8):108–15. Available from: <URL>.
27. Renuka R, Devi KR, Sivakami M, Thilagavathi T, Uthrakumar R, Kaviyarasu K. Biosynthesis of silver nanoparticles using phyllanthus emblica fruit extract for antimicrobial application. Biocatal Agric Biotechnol [Internet]. 2020 Mar;24:101567. Available from: <URL>.
28. Niluxsshun MCD, Masilamani K, Mathiventhan U. Green Synthesis of Silver Nanoparticles from the Extracts of Fruit Peel of Citrus tangerina, Citrus sinensis, and Citrus limon for Antibacterial Activities. Ciccarella G, editor. Bioinorg Chem Appl [Internet]. 2021 Feb 2;2021:695734. Available from: <URL>.
29. Hussain M, Raja NI, Mashwani Z, Naz F, Iqbal M, Aslam S. Green synthesis and characterisation of silver nanoparticles and their effects on antimicrobial efficacy and biochemical profiling in Citrus reticulata. IET Nanobiotechnology [Internet]. 2018 Jun 21;12(4):514–9. Available from: <URL>.
30. Mogole L, Omwoyo W, Viljoen E, Moloto M. Green synthesis of silver nanoparticles using aqueous extract of Citrus sinensis peels and evaluation of their antibacterial efficacy. Green Process Synth [Internet]. 2021 Dec 7;10(1):851–9. Available from: <URL>.
31. Basavegowda N, Rok Lee Y. Synthesis of silver nanoparticles using Satsuma mandarin (Citrus unshiu) peel extract: A novel approach towards waste utilization. Mater Lett [Internet]. 2013 Oct;109:31–3. Available from: <URL>.
32. Sekkat A, Liedke MO, Nguyen VH, Butterling M, Baiutti F, Sirvent Veru J de D, et al. Chemical deposition of Cu2O films with ultra-low resistivity: correlation with the defect landscape. Nat Commun [Internet]. 2022 Sep 9;13(1):5322. Available from: <URL>.
33. Engel L, Benito-Altamirano I, Tarantik KR, Pannek C, Dold M, Prades JD, et al. Printed sensor labels for colorimetric detection of ammonia, formaldehyde and hydrogen sulfide from the ambient air. Sensors Actuators B Chem [Internet]. 2021 Mar;330:129281. Available from: <URL>.
34. Thompson NBA, O’Sullivan SE, Howell RJ, Bailey DJ, Gilbert MR, Hyatt NC. Objective colour analysis from digital images as a nuclear forensic tool. Forensic Sci Int [Internet]. 2021 Feb;319:110678. Available from: <URL>.
35. Karakuş S, Özbaş F, Baytemir G, Taşaltın N. Cubic-shaped corylus colurna extract coated Cu2O nanoparticles-based smartphone biosensor for the detection of ascorbic acid in real food samples. Food Chem [Internet]. 2023 Aug;417:135918. Available from: <URL>.
36. Boughendjioua H, Mezedjeri NEH, Idjouadiene I. Chemical constituents of Algerian mandarin ( Citrus reticulata ) essential oil by GC-MS and FT-IR analysis. Curr Issues Pharm Med Sci [Internet]. 2020 Dec 1;33(4):197–201. Available from: <URL>.
37. Georgieva M, Gospodinova Z, Keremidarska-Markova M, Kamenska T, Gencheva G, Krasteva N. PEGylated Nanographene Oxide in Combination with Near-Infrared Laser Irradiation as a Smart Nanocarrier in Colon Cancer Targeted Therapy. Pharmaceutics [Internet]. 2021 Mar 22;13(3):424. Available from: <URL>.
38. Rita A, Sivakumar A, Dhas SSJ, Dhas SAMB. Structural, optical and magnetic properties of silver oxide (AgO) nanoparticles at shocked conditions. J Nanostructure Chem [Internet]. 2020 Dec 24;10(4):309–16. Available from: <URL>.
39. Bhagyaraj S, Krupa I. Alginate-Mediated Synthesis of Hetero-Shaped Silver Nanoparticles and Their Hydrogen Peroxide Sensing Ability. Molecules [Internet]. 2020 Jan 21;25(3):435. Available from: <URL>.
40. Jaiswal KK, Banerjee I, Dutta S, Verma R, Gunti L, Awasthi S, et al. Microwave-assisted polycrystalline Ag/AgO/AgCl nanocomposites synthesis using banana corm (rhizome of Musa sp.) extract: Characterization and antimicrobial studies. J Ind Eng Chem [Internet]. 2022 Mar;107:145–54. Available from: <URL>.
41. Zhan B, Liu C, Shi H, Li C, Wang L, Huang W, et al. A hydrogen peroxide electrochemical sensor based on silver nanoparticles decorated three-dimensional graphene. Appl Phys Lett [Internet]. 2014 Jun 16;104(24):243704. Available from: <URL>.
42. Kumar V, Gupta RK, Gundampati RK, Singh DK, Mohan S, Hasan SH, et al. Enhanced electron transfer mediated detection of hydrogen peroxide using a silver nanoparticle–reduced graphene oxide–polyaniline fabricated electrochemical sensor. RSC Adv [Internet]. 2018;8(2):619–31. Available from: <URL>.
43. Dodevska T, Vasileva I, Denev P, Karashanova D, Georgieva B, Kovacheva D, et al. Rosa damascena waste mediated synthesis of silver nanoparticles: Characteristics and application for an electrochemical sensing of hydrogen peroxide and vanillin. Mater Chem Phys [Internet]. 2019 Jun;231:335–43. Available from: <URL>.
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Toplam 58 adet kaynakça vardır.

Ayrıntılar

Birincil Dil	İngilizce
Konular	Fiziksel Kimya (Diğer), Kimya Mühendisliği (Diğer)
Bölüm	ARAŞTIRMA MAKALELERİ
Yazarlar	Emre Yılmazoğlu 0000-0002-5800-873X
Erken Görünüm Tarihi	4 Ağustos 2024
Yayımlanma Tarihi	30 Ağustos 2024
Gönderilme Tarihi	19 Şubat 2024
Kabul Tarihi	1 Temmuz 2024
Yayımlandığı Sayı	Yıl 2024 Cilt: 11 Sayı: 3

Kaynak Göster

Vancouver	Yılmazoğlu E. Digital Image Colorimetric Detection of H2O2 Utilizing PEG/Ag/AgO Nanoparticles Derived from Tangerine Leaf Extract. JOTCSA. 2024;11(3):1303-12.

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