Development Of Polyethylene Oxide Film Hydrogels With The Addition Of Banana Sap For Wound Dressing Applications

Authors

  • Fena Retyo Titani Universitas Muhammadiyah Purwokerto
  • Haryanto Haryanto Universitas Muhammadiyah Purwokerto

DOI:

https://doi.org/10.30595/techno.v21i1.4894

Abstract

Hydrogels having been developed so far are those with polymer bases without any additives.  For the acceleration of wound healing, it can be developed hydrogels with the addition of banana sap (Musa Paradisiaca) as a drug that is expected to accelerate the wound healing process. The preparation of Banana PEO-PEGDMA-Hydrogel Banana was made using a new method of dissolving banana juice with PEO-PEGDMA before crosslinking. The formulations of banana sap concentration used ranged from 0% to 15% (volume) and they were irradiated with gamma rays. The characteristics measured include gel fraction, swelling ratio, velocity of water vapor transmission and mechanical properties. The chemical and morphological structures were analyzed using the Fourier Transform Infrared Spectroscopy (FTIR) and Scanning Electron Microscope (SEM). The acceleration of wound healing speed was analyzed by invivo test. The results showed that the value of gel fraction, swelling ratio and velocity of water transmission of PEO-PEGDMA-Banana Gum hydrogel increased at a concentration of 0-15%. Hydrogel tensile strength decreased with the addition of banana sap and conversely the percentage of elongation of hydrogel increased with it. PEO-PEGDMA hydrogel film with the addition of banana sap has been proven to accelerate the wound healing through the Invivo Test. This shows that hydrogels can be developed from PEO-PEGDMA- Banana Sap which can be used as wound dressing.

 

References

[1] Erizal,2006. Imobilisasi Antibiotik pada Matriks Hidrogel Poli(vinil) Alkohol dengan Metode Induksi Iradiasi. Prosiding Simposium Nasional Polimer VI. 111-115.

[2] Swasono, R.T., Erizal, Dan Hendriyanto, 2007. Pengaruh Iradiasi Gamma dan Konsentrasi Polivinilpirrolidon pada Pembuatan Hidrogel serta Kemampuan Imobilisasi dan Pelepasan Kembali Propanolol HCL. Jurnal Sains dan Teknologi Nuklir Indonesia. VIII, 1, 1-16.

[3] Erizal, 2006. Imobilisasi Eugenol pada Matriks TMPT dengan Induksi Radiasi. Jurnal Materi Indonesia. 124-128

[4] Erizal, Hasan, R., Silvia, S., dan Rahayu, C., 1997. Pengekangan Obat dalam Matriks Hidrogel PVA-ko-NIPAAm Hasil Radiasi. Risalah Pertemuan Ilmiah Penelitian dan Pengembangan Aplikasi Isotop dan Radiasi. 121-128

[5] Kaetsu, I. 1979. Immobilization of Enzymes by Radiation, Radiat. Phys. Chem., 14, 595-602.

[6] Kumakura, M., and Kaetsu, I., 1984. Behaviour of Enzymes Activity in Immobilized Proteases, Int. J. Biochem, 16 (11), 1159-1161

[7] Darwin, D. 2013. Pengembangan Bahan Biomaterial untuk Pemakaian di Bidang Kesehatan dengan Teknik Radiasi Pengion. Pusat Aplikasi Teknologi Isotop dan Radiasi, BATAN. Hal: 251-275.

[8] Abdelrahman, T & H. Newton. 2011. Wound Dressing: Principles and Practice. Surgery. 29: 491-495.

[9] Rajendran, S. & S. C. Anand. 2002. Development in Medical Textile. The Textile Institue. Manchester.

[10] Yoshii, F. et al..1999. Electron Beam Crosslinked PEO and PEO/PVA Hydrogels for Wound Dressing. Radiation Physics and Chemistry. 55: 133-138.

[11] A Ibnu Atoillah. 2007. Studi Kasus Lama Waktu Koagulasi. Golongan Darah

“B” http://karyailmiah.um.ac.ad/index.phb/biologi/article/view/934.

[12] Haryanto & Nunuk A. N..2015. Polietilena Oksida – Polietilena Glikol Dimetakrilat Hidrogel Film untuk Aplikasi Pembuatan Pembalut Luka. LPPM Universitas Muhammadiyah Purwokerto.

[13] Gupta, B. Textile-based smart wound dressings. Indian Journal of Fibre &

Textile Research. 2010. 35: 175-6

[14] Abidin, A. Z. Et al., 2012. Hidrogel Mikrokomposit Berbasis Polivinil Alkohol/ Bentonit. LIPI.

[15] Erizal, 2009. Sintesis Hidrogel Polietilen Oksida Berikatan Silang dan Imobilisasi Antibiotik dengan Cara Induksi Radiasi Gamma untuk Aplikasi Pembalut Luka. PAIR,BATAN.

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Published

2020-04-29