The Characterization of the Hydrophobic Surface of Nanocomposites Aloe vera/PS for Antimicrobial Pathogens

Lathifa Zonesya Putri, Ratnawulan Ratnawulan, Ramli Ramli, Hamdi Rifai, Faridah Lisa Supian, Irna Humairah
https://doi.org/10.26554/sti.2023.8.2.212-218

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Issue
Vol. 8 No. 2 (2023): April
Keywords:
    Aloe vera, Composition, Hydrophobic, Anti-Microorganisms, Polystyrene
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Abstract

The spread of pathogenic microorganisms on a large scale creates a health disaster for the world. Modifying the surface of the fabric so that it is antimicrobial pathogens with hydrophobic properties is one solution to inhibit the spread of microorganisms. Surface modification was carried out using Aloe vera powder as filler and polystyrene matrix with Aloe vera:PS composition variations of 1:5, 2:5, and 3:5 using the dip coating method and drying temperatures of 10◦C, 50◦C, and 90◦C. The characterization results that have been carried out with the best composition variations are 3:5 and 50◦C with a layered morphology using Scanning Electron Microscopy (SEM), resulting in a surface particle size of 21.243 nm, large contact angle/WCA using a Canon D350 camera with a size of 150.23◦, Fourier Transmission Infrared Analysis (FTIR) with the dominant functional group in the vibration band 2629 cm−1 indicates the presence of a long hydroxyl chain, the vibration band 1500 cm−1 with C-H stretching of the aromatic ring is caused by the characteristics of the polystyrene polymer and the wave number is 1700 cm−1 with stretching C=O which shows the characteristics of the carbonyl group in the Aloe vera sample is a flavonoid compound. The resistance of Aloe vera/PS solution to Klebsiella pneumonia resulted in a 20.18 mm diameter barrier showing strong resistance against bacteria and X-Ray Diffraction analysis showed that the AV powder was amorphous. Thus, the AV/PS 3:5 composition with a calcination temperature of 50◦C represents the greatest variation in the synthesis and characterization of hydrophobic thin films for pathogenic antimicrobial organisms.

References

Chauhan, P. and A. Kumar (2020). Development of a Microbial Coating for Cellulosic Surface using Aloe Vera and Silane. Carbohydrate Polymer Technologies and Applications, 1; 100015

Dastan, D., S. L. Panahi, and N. B. Chaure (2016). Characterization of Titania thin Films Grown by Dip-Coating Technique. Journal of Materials Science: Materials in Electronics, 27; 12291–12296

El Fawal, G. F., A. M. Omer, and T. M. Tamer (2019). Evaluation of Antimicrobial and Antioxidant Activities for Cellulose Acetate Films Incorporated with Rosemary and Aloe Vera Essential Oils. Journal of Food Science and Technology, 56; 1510–1518

Fauzi, A. (2019). Fabrication of Superhydrophobic CuO/Polystyrene Nanocomposite Coating with Variation Concentration. In Journal of Physics: Conference Series, volume 1185. IOP Publishing, page 012014

Fauzi, A. and L. Z. Putri (2020). Optimization of Hydrophobic Nanocomposite thin Film from Silica/Polietilen. In Journal of Physics: Conference Series, volume 1481. IOP Publishing, page 012011

Gontijo, S. M. d. L., A. D. M. Gomes, A. Gala-García, R. D. Sinisterra, and M. E. Cortés (2013). Evaluation of Antimicrobial Activity and Cell Viability of Aloe vera Sponges. Electronic Journal of Biotechnology, 16(1); 2–2

Hardy, Z. and V. A. Jideani (2017). Foam-Mat Drying Technology: A Review. Critical Reviews in Food Science and Nutrition, 57(12); 2560–2572

Hendrawati, T. (2015). Aloe Vera Powder Properties Produced from Aloe Chinensis Baker, Pontianak, Indonesia. In Journal of Engineering Science and Technology Special Issue on SOMCHE 2014 & RSCE 2014 Conference, volume 47

Heng, H. C., M. H. Zulfakar, and P. Y. Ng (2018). Pharmaceutical Applications of Aloe Vera. Indonesian Journal of Pharmacy, 29(3); 101

Ho, B. T., T. K. Roberts, and S. Lucas (2018). An Overview on Biodegradation of Polystyrene and Modified Polystyrene: the Microbial Approach. Critical Reviews in Biotechnology, 38(2); 308–320

Ibrahim, N. A., N. A. Abd El-Ghany, B. M. Eid, and E. M. Mabrouk (2018). Green Options for Imparting Antibacterial Functionality to Cotton Fabrics. International Journal of Biological Macromolecules, 111; 526–533

Javed, I., A. Aleem, R. Hamad, N. Furqan, and R. Ammad (2018). A Review Paper on Foam-Mat Drying of Fruits and Vegetables to Develop Powders. MOJ Food Process Technol, 6(6); 465–467

Maan, A. A., Z. F. R. Ahmed, M. K. I. Khan, A. Riaz, and A. Nazir (2021). Aloe Vera Gel, an Excellent Base Material for Edible Films and Coatings. Trends in Food Science & Technology, 116; 329–341

Mounir, S. (2017). Foam Mat Drying FMD; Drying Technologies For Foods: Fundamentals And Applications: Part III. New Delhi, NIPA

Mpiana, P., K. Ngbolua, D. Tshibangu, J. Kilembe, B. Gbolo, D. Mwanangombo, C. Inkoto, E. Lengbiye, C. Mbadiko, and A. Matondo (2020). Aloe vera (L.) Burm. F. as a Potential Anti-COVID 19 Plant: a Mini-Review of its Antiviral Activity. European Journal of Medicinal Plants, 31(8); 86–93

Nizam, N. H. M., N. F. M. Rawi, S. F. M. Ramle, A. Abd Aziz, C. Abdullah, A. Rashedi, and M. H. M. Kassim (2021). Physical, Thermal, Mechanical, Antimicrobial and Physicochemical Properties of Starch Based Film Containing Aloe Vera: A Review. Journal of Materials Research and Technology, 15; 1572–1589

Pereira, M. M., K. A. Kurnia, F. L. Sousa, N. J. Silva, J. A. Lopes-da Silva, J. A. Coutinho, and M. G. Freire (2015). Contact Angles and Wettability of Ionic Liquids on Polar and Non-Polar Surfaces. Physical Chemistry Chemical Physics, 17(47); 31653–31661

Rahayu, F. and M. Zainuri (2016). Pengaruh Jenis Fasa SiO2 (Amorphous, Quartz, Cristobalite) Terhadap Sifat Hydrophobic pada Media Kaca

Rani, M., P. Choudhry, A. Kumar, and V. Chhokar (2021). Evaluation of Saponins in Aloe Vera by High-Performance Liquid Chromatography and Fourier Transform Infrared Spectroscopy. The Pharma Innovation Journal, 10(9); 1925–1933

Ratnawulan, R., R. Ramli, A. Fauzi, and S. Hayati AE (2020). Synthesis and Characterization of Polystyrene/CuO-Fe2O3 Nanocomposites from Natural Materials as Hydrophobic Photocatalytic Coatings. Crystals, 11(1); 31

Seifunnisha, O., R. Swathi, and J. Shanthi (2021). Non-Wettable Antibacterial Thin Film: PS/Aloe Vera and PS/Acalypha Indica. Polymers and Polymer Composites, 29(9_suppl); S622–S630

Subramani, K., B. Kolathupalayam Shanmugam, S. Rangaraj, M. Palanisamy, P. Periasamy, and R. Venkatachalam (2018). Screening the UV-Blocking and Antimicrobial Properties of Herbal Nanoparticles Prepared from Aloe vera leaves for Textile Applications. IET Nanobiotechnology, 12(4); 459–465

Tang, X. and X. Yan (2017). Dip-Coating for Fibrous Materials: Mechanism, Methods and Applications. Journal of Sol-Gel Science and Technology, 81; 378–404

Varhan, E., F. Elmas, and M. Koç (2019). Foam Mat Drying of Fig Fruit: Optimization of Foam Composition and Physicochemical Properties of Fig Powder. Journal of Food Process Engineering, 42(4); e13022

Wang, L. and Z. Dai (2016). Effects of the Natural Microstructures on the Wettability of Leaf Surfaces. Biosurface and Biotribology, 2(2); 70–74

Authors

Lathifa Zonesya Putri
Departement of Physics, Universitas Negeri Padang, Padang, 25132, Indonesia
Ratnawulan Ratnawulan
Departement of Physics, Universitas Negeri Padang, Padang, 25132, Indonesia
ratnawulan@fmipa.unp.ac.id (Primary Contact)
Ramli Ramli
Departement of Physics, Universitas Negeri Padang, Padang, 25132, Indonesia
Hamdi Rifai
Departement of Physics, Universitas Negeri Padang, Padang, 25132, Indonesia
Faridah Lisa Supian
Departement of Physics, Sultan Idris Education University, Tanjung Malim, Perak Darul Ridzuan, 35900, Malaysia
Irna Humairah
Laboratorium Lembaga Layanan Pendidikan Tinggi Wilayah X, Sumatera Barat, 25173, Indonesia
Zonesya Putri, L., Ratnawulan, R. ., Ramli, R. ., Rifai, H. ., Supian, F. L. ., & Humairah, I. . (2023). The Characterization of the Hydrophobic Surface of Nanocomposites Aloe vera/PS for Antimicrobial Pathogens. Science and Technology Indonesia, 8(2), 212–218. https://doi.org/10.26554/sti.2023.8.2.212-218
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