Potensi Nanokomposit Sengoksida-Perak (ZnO-Ag) Metode Gelombang Mikro dalam Menghambat Pertumbuhan Bakteri Escherichia Coli Penghasil Extxtended Spectrum Beta Lactamases (ESBLs)

Prasetya, Yulianto Ade; Nisyak, Khoirun; Hisbiyah, A'yunil

dc.contributor.author	Prasetya, Yulianto Ade
dc.contributor.author	Nisyak, Khoirun
dc.contributor.author	Hisbiyah, A'yunil
dc.date.accessioned	2021-01-06T09:06:18Z
dc.date.available	2021-01-06T09:06:18Z
dc.date.issued	2020-07
dc.identifier.citation	Agarwal H., S.V.Kumar, and S.Rajeshkumar. (2017) A Review on Green Synthesis of Zinc Oxide Nanoparticles – An Eco Friendly Approach, Resources–Efficient Technologies, In Press. Ahmed, S., M.Ahmad, B.L.Swami, and S.Ikram(2016) A Review on Plants Extract Mediated Synthesis of Silver Nanoparticles for Antimicrobial Applications: A Green Expertise, Journal of Advanced Research, 7(2016): 17 – 28. Azam, A., A.S. Ahmed, M. Oves, M.S. Khan, S.S. Habib, and A. Memic (2011) Antimicrobial Activity of Metal Oxide Nanoparticles Against Gram Positive- Gram Negative Bacteria: A Comparative Study, International Journal of Nanomedicine, 7 (2011): 6003 – 6009. Azizi, S., R. Mohammad, R.A. Rahim, A.B. Moghaddam, M. Moniri, A. Ariff, W.Z. Saad, and F.Namvab (2016) ZnO-Ag Core Shell Nanocomposite Formed by Green Method Using Essential Oil of Wild Ginger and Their Bactericidal and Cytotoxic Effects, Applied Surface Science, 384 (2016):517-524. Bobo, D., K.J. Robinson, J. Islam, K.J. Thurecht, and S.R. Corrie (2016) Nanoparticles-Based Medicines: A Review of FDA Approved Materials and Clinical Trials to Date, Pharmaceutical Research, 33(10): 2373 – 2387. Fatimah, I. (2016) Green Synthesis of Silver Nanoparticles Using Extract of Parkia speciosa Hassk Pods Assisted by Microwave Irradiation, Journal of Advanced Research, 7 (2016): 961 – 969. Hadiyawarman, A., B.W. Rijal, M.A. Nuryadin, and Khairurrijal (2018) Fabrikasi Material Nanokomposit Superkuat, Ringan, dan Transparan Menggunakan Metode Simple Mixing, Jurnal Nano Sains & Teknologi, 1 (1): 14 – 21. Hisbiyah, A., K. Nisyak, Y.A Prasetya (2020) Synthesis of ZnO-Ag Nanocomposites trough Ultrasonication-Microwave with Leaf Oil. IOP Confrence Series: Material Science and Enginerring. 833 (1): 012070 Iravani, S., H. Korbekandi, S.V. Mirmohammadi, and B. Zolfaghari (2014) Synthesis of Silver Nanoparticles: Chemical, Physical, and Biological Methods, Research in Pharmaceutical Sciences, 9 (6): 385 – 406. Jacobsen, S.M., D.J Stickler, H.L. Mobley, and M.E. Shirtliff (2018) Complicated Cateter-Asosiated Urinary Tract Infections Due to Escherichia coli and Proteus mirabilis, Clinical Microbiolgy Review, 21: 26-59. Jamdagni, P., P. Katri, and J.S. Rana, 2016, Nanoparticles based DNA Conjugates for Detection of Pathogenic Microorganism, International Nano Letter, 6 (2016): 139-146. Nisyak, K., Y.A Prasetya, A. Hisbiyah (2020) Synthesis of ZnO-Ag with Clove oil using Ultrasonication Method and Its Antibiofilm Activity Againts Klebsiella pneumoniae. IOP Confrence Series: Material Science and Enginerring. 833 (1): 012081 Prasetya, Y.A (2017) Identifikasi Gen CTX-M pada Escherichia coli Penghasil Extended Spectrum Beta Lactamases (ESBLs) di RSUD Dr.Soetomo Surabaya. Jurnal Teknologi Laboratorium. 6 (2): 56-60. Prasetya, YA.,K.Nisyak, ER Amanda (2019) Aktivitas antibakteri Nanoemulsi Minyak Lengkuas (Alpinia galangal L. Willd) dalam menghambat pertumbuhan Helicobacter pylori. Biotropika: Journal of Tropical Biology. 7 (3): 136-142. Soto, S.M, 2014, Importance of Biofilms in Urinary Tract Infections: New Therapeutic Approaches, Advances in Biology, 2014: 13. Thema, F.T., E. Manikandan, M. Maaza, and A.F. Gurib, 2016, Single Phase Bunsenite NiO Nanoparticles Green Synthesis by Agathosma betulina Natural Extract, Journal of Alloys Compounds, 657 (2016): 655 – 661.	id_ID
dc.identifier.issn	2685-8770
dc.identifier.uri	http://hdl.handle.net/11617/12337
dc.description.abstract	Escherichia coli penghasil Extended Spectrum Beta Lactamases (ESBLs) merupakan bakteri yang mampu menghidrolisis antibiotik golongan beta laktam generasi kedua dan ketiga serta monobaktam. Bakteri ini menyebabkan insidensi tertinggi infeksi saluran kemih (ISK) yang utama di seluruh dunia. Seng oksida (ZnO) terbukti mampu melawan resistensi bakteri sedangkan perak (Ag) mampu melawan bakteri dengan menghambat sintesis dinding sel, protein, dan metabolisme sel. Nanokomposit merupakan penggabungan antara ZnO dan Ag yang berukuran nanometer (nm) dengan bantuan instrumen berupa microwave termodifikasi. Nanokomposit yang terbentuk dikarakterisasi dengan X-Ray Diffractometer (XRD) untuk mengetahui ukuran dan kristanilitas yang terbentuk. Uji aktivitas nanokomposit ZnO-Ag dilakukan dengan metode difusi sumuran menggunakan cock borer pada media Mueller-Hinton agar. Hasil yang didapatkan menunjukkan bahwa nanokomposit yang terbentuk berukuran 124,71 nm. Nanokomposit ZnO-Ag mampu menghambat bakteri E. coli penghasil ESBLs dengan diameter zona hambat yakni 11,35 mm. Nanokomposit ZnO-Ag berpotensi untuk dikembangkan sebagai alat medis berbasis nanokomposit ZnO-Ag dalam melawan bakteri penyebab infeksi nosokomial, salah satunya E. coli penghasil Extended Spectrum Beta Lactamases (ESBLs).	id_ID
dc.language.iso	other	id_ID
dc.publisher	Prosiding SNPBS (Seminar Nasional Pendidikan Biologi dan Saintek) Ke-5	id_ID
dc.title	Potensi Nanokomposit Sengoksida-Perak (ZnO-Ag) Metode Gelombang Mikro dalam Menghambat Pertumbuhan Bakteri Escherichia Coli Penghasil Extxtended Spectrum Beta Lactamases (ESBLs)	id_ID
dc.type	Article	id_ID

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