Alginate – Gamat Gel Hydrogel Films as the Potential Wound Dressing

Authors

  • Kaalisya Elodi Satria Diponegoro University Author
  • Sri Sedjati Diponegoro University Author
  • Ervia Yudiati Diponegoro University Author

DOI:

https://doi.org/10.61741/ks8q3f15

Keywords:

Alginate film dressing, gamat gel, marine biomaterial, alginate film degradation, cross-linking

Abstract

Alginate is a biopolymer that is biodegradable, non-antigenic, non-toxic, and has high biocompatibility. Gamat gels of sea cucumber Stichopus horrens are used to treat pain, wounds, and other ailments. Victims suffering from burn wounds frequently complain of pain and discomfort while being bandaged. This study aims to analyze the characteristics of alginate as the base biomaterial for hydrogel films and its interaction with gamat gels bioactive components. Antioxidant activity assay was done to the gamat gels using DPPH assay. Hydrogel films were prepared with different alginate concentrations of 1% w/v, 3% w/v, and 5% w/v. Film degradation was analyzed using stereo microscope. Mechanical characteristics were evaluated based on tensile strength, brittleness, elasticity, adhesion capacity, and the ease when handling the films. Hydrolytic stability was evaluated based on swelling capacity and matrix stability. Antibacterial activity assay was carried out using disk diffusion on Staphylococcus aureus. Results show that gamat gels have DPPH inhibition capacity of IC50 = 2937.5 ppm. The alginate concentrations treatment resulted in films with different morphology. Films with 5% w/v alginate concentration exhibit a rough surface, the better tensile strength, capability to conform to various surfaces, good adhesion (average detachment time of 60 seconds), swelling capacity of 11,96 ± 13,80%, and matrix stability with the average weight loss of 33,26%. FTIR spectroscopy confirmed that alginate was able to bond with Ca2+ ions and the gamat gels. Gamat gels show inhibition zone of ≤ 5 mm. Films with 5% w/v alginate concentration were able to release bioactive compounds.

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Author Biographies

  • Kaalisya Elodi Satria , Diponegoro University

    Department of Marine Science, Diponegoro University, Jalan Prof Jacub Rais, SH, Tembalang – Semarang

  • Sri Sedjati , Diponegoro University

    Department of Marine Science, Diponegoro University, Jalan Prof Jacub Rais, SH, Tembalang – Semarang

  • Ervia Yudiati, Diponegoro University

    Department of Marine Science, Diponegoro University, Jalan Prof Jacub Rais, SH, Tembalang – Semarang

References

Abka-Khajouei, R., L. Tounsi, N. Shahabi, A. K. Patel, S. Abdelkafi, & P. Michaud. 2022. Structures, Properties and Applications of Alginates. Marine Drugs, 20(6): 364.

Adam, M., H. Achmad, M. Tanumihardja, S. Oktawati, S. R. J. Ramadhan, A. Afriani, A. Adhawanty, & N. Masyta. 2023. The Effectiveness of Deproteinized Golden Sea Cucumber (Stichopus Hermanii) Combination of Deproteinized Bovine Bone Xenograft in Stimulating the Formation of Bmp-2 and Opg in the Process of Bone Tissue Regeneration. Journal of International Dental and Medical Research, 16(2): 117 – 123.

Adam, M., H. Achmad, M. Tanumihardja, S. R. J. Ramadhan, A. Afriani, A. Adhawanty, & N. Masyta. 2022. The Benefits of Golden Sea Cucumber (Stichopus hermanni) as an Alternative Antimicrobial Material in Oral Health. Journal of International Dental and Medical Research, 15(4): 1806 – 1815.

Aderibigbe, B. A. & B. Buyana. 2018. Alginate in Wound Dressings. Pharmaceutics, 10(2): 42.

Althunibat, O. Y., R. B. Hashim, M. Taher, J. M. Daud, M. A. Ikeda, & Zali B. I. 2009. In Vitro Antioxidant and Antiproliferative Activities of Three Malaysian Sea Cucumber Species. European Journal of Scientific Research, 37(3): 376 – 387.

Althunibat, O. Y., R. B. Hashim, M. Taher, J. M. Daud, S. J. A. Ichwan, & H. Qaralleh. 2013. Antioxidant and Cytotoxic Properties of Two Sea Cucumbers, Holothuria edulis lesson and Stichopus horrens Selenka. Acta Biologica Hungarica, 64(1): 10 – 20.

Alzarea, A. I., N. K. Alruwaili, M. M. Ahmad, M. U. Munir, A. M. Butt, Z. A. Alrowaili, M. S. B. Shahari, Z. S. Almalki, S. S. Alqahtani, A. V. Zolzhenko, & N. Ahmad. 2022. Development and Characterization of Gentamicin-Loaded Arabinoxylan-Sodium Alginate Films as Antibacterial Wound Dressing. International Journal of Molecular Science, 23(5): 2899.

Anis, M., D. Ahmed, & N. Anis. 2022. Green Extraction of Bioactive Compounds from Azadirachta indica in Aqueous Glycerol and Modelling and Optimisation by Response Surface Methodology. Folia Horticulturae, 34(2): 249 – 262.

Arfani, A., A. Raif, C. N. Ginting, & R. Ikhtiari. 2021. Evaluation of Wound Healing Potential of a Sea Cucumber (Actinopyga mauritiana) Extract in Mice (Mus musculus). Jurnal Natural, 21(3): 168 – 174.

Ascenzi, A. & E. Bonucci. 1964. The Ultimate Tensile Strength of Single Osteons. Acta Anatomica, 58(1): 160 – 183

Azeredo, H. M. C., U. S. Magalhães, S. A. Oliveira, H. L. Ribeiro, E. S. Brito, & M. R. De Moura. 2012. Tensile and Water Vapour Properties of Calcium-Crosslinked Alginate-Cashew Tree Gum Films. International Journal of Food Science & Technology, 47(4): 710 – 715.

Badita, C. R., D. Aranghel, C. Burducea, & P. Mereuta. 2020. Characterization of Sodium Alginate Based Films. Romanian Journal of Physics, 65(602): 1 – 8.

Bagheri, F., M. Radi, & S. Amiri. 2019. Drying Conditions Highly Influence the Characteristics of Glycerol – Plasticized Alginate Films. Food Hydrocolloids, 90: 162 – 171.

Banerjee, A., N. Dasgupta, & B. De. 2005. In Vitro Study of Antioxidant Activity of Syzygium cumini Fruit. Food Chemistry, 90(4): 727 – 733.

Berger, M. M., M. Baines, W. Raffoul, M. Benathan, L. R. Chiolero, C. Reeves, J. P. Revelly, M. C. Cayeux, I. Sénéchaud, & A. Shenkin. 2007. Trace Elemt Supplementation after Major Burns Modulates Antioxidant Status and Clinical Course by way of Increased Tissue Trace Element Concentration. Nutrition, 85(5): 1293 – 1300.

Bordbar, S., F. Anwar, & N. Saari. 2011. High-Value Components and Bioactives from Sea Cucumbers for Functional Foods—A Review. Marine Drugs, 9(10): 1761 – 1805.

Chen, M., Y. Wu, B. Chen, A. M. Tucker, A. Jagota, & S. Yang. 2022. Fast, Strong, and Reversible Adhesives with Dynamic Covalent Bonds for Potential Use in Wound Dressing. PNAS, 119(29): 1 – 9.

Comaposada, J., P. Gou, B. Marcos, & J. Arnau. 2015. Physical Properties of Sodium Alginate Solutions and Edible Wet Calcium Alginate Coatings. LWT – Food Science and Technology, 64(1): 212 – 219.

Comino-Sanz, I. M., M. D. López-Franco, B. Castro, & P. L. Pancorbo-Hidalgo. 2021. The Role of Antioxidants on Wound Healing: A Review of the Current Evidence. Journal of Clinical Medicine, 10(16): 3558.

Devi, M. P., M. Sekar, M. Chamundeswari, A. Moorthy, G. Krithiga, N. S. Murugan, & T. P. Sastry. 2012. A Novel Wound Dressing Material—Fibrin-Chitosan-Sodium Alginate Composite Sheet. Bulletin of Materials Science, 35(7): 1157 – 1163.

Diba, G., S. Jamili, & E. Rameszani-Fard. 2017. Evaluation of the Antioxidant Activity of Dried (Rehydrate) and Fresh Sea Cucumber, Holothuria parva. Iranian Fisheries Science Journal, 25(4): 77 – 86.

Doh, H., K. D. Dunno, & W. S. Whiteside. 2020. Cellulose Nanocrystal Effects on the Biodegradability with Alginate and Crude Seaweed Extract Nanocomposite Films. Food Bioscience, 38: 100795.

Drápalová, E., L. Michlovská, H. Poštulková, I. Chamradová, B. Lipový, J. Holoubek, L. Vacek, F. Růžička, M. Michlovská, T. Svobodová, E. Černá, B. Hrdličková, & L. Vojtová. 2023. Antimicrobial Cost-Effective Transparent Hydrogel Films from Renewable Gum Karaya/Chitosan Polysaccharides for Modern Wound Dressings. ACS Applied Polymer Materials, 5(4): 2774 – 2786.

Duckworth, P. F., S. E. Maddocks, S. S. Rahatekar, & M. E. Barbour. 2020. Alginate Films Augmented with Chlorhexidine Hexametaphosphate Particles Provie Sustained Antimicrobial Properties for Application in Wound Care. Journal of Materials Science: Materials in Medicine, 31(33): 1 – 9.

Ertesvåg, H. 2015. Alginate-Modifying Enzymes: Biological Roles and Biotechnological Uses. Frontiers in Microbiology, 6(523).

Eskridge, S. L., C. A. Macera, M. R. Galarneau, T. L. Holbrook, S. I. Woodruff, A. J. MacGregor. D. J. Morton, & R. A. Shaffer. 2012. Injuries from Combat Explosions in Iraq: Injury Type, Location, and Severity. Injury: International Journal of the Care of the Injured, 43(10): 1678 – 1682.

Eslami, Z., S. Elkoun, M. Robert, & K. Adjallé. 2023. A Review of the Effect of Plasticizers on the Physical and Mechanical Properties of Alginate-Based Films. Molecules, 28(18): 6637.

Faeiz, P. M., J. S. Norazlina, A. M. Nikman, & G. F. Che. 2018. Effects of Glycosaminoglycans Extract from Sea Cucumber Stichopus vastus on Inflammatory Mediators and Tissue Healing on Rodents with Full Thickness Burn Injury. Research Journal of Pharmacy and Technology, 11(9): 3874 – 3880.

Fahmy, H. M., A. A. Aly, S. M. Sayed, & A. Abou-Okeil. 2021. K-Carrageenan/Na-Alginate Wound Dressing with Sustainable Drug Delivery Properties. Polymers for Advanced Technologies, 32(4): 1793 – 1801.

Fan, X., Y. Ma, M. Li, X. Sang, & Q. Zhao. 2022. Thermal Treatments and Their Influence on Physicochemical Properties of Sea Cucumbers: A Comprehensive Review. International Journal of Food Science & Technology, 57(9): 5790-5800.

Fernando, I. P. S., K. Kim, D. Kim, & Y. Jeon. 2019. Algal Polysaccharides: Potential Bioactive Substances for Cosmeceutical Applications. Critical Reviews in Biotechnology, 39(1): 99 – 113.

Fiske, S. T., D. T. Gilbert, & G. Lindzey. 2010. Handbook of Social Psychology Volume 1. Ed. 5, John Wiley & Sons, New Jersey, USA, 896 pg.

Furness, P. J., I. Phelan, N. T. Babiker, O. Fehily, S. A. Lindley, & A. R. Thompson. 2019. Reducing Pain During Wound Dressings in Burn Care Using Virtual Reality: A Study of Perceived Impact and Usability with Patients and Nurses. Journal of Burn Care & Research, 40 (6): 878 – 885.

Ghomi, E. R., S. Khalili, S. N. Khorasani, R. E. Reisiany, & S. Ramakrishna. 2018. Wound Dressings: Current Advances and Future Directions. Journal of Applied Polymer Science, 136(27): 47738.

Guo, X., X. Ye, Y. Sun, D. Wu, N. Wu, Y. Hu, & S. Chen. 2014. Ultrasound Effects on the Degradation Kinetics, Structure, and Antioxidant Activity of Sea Cucumber Fucoidan. Journal of Agricultural and Food Chemistry, 62(5): 1088 – 1095.

Hariyadi, D. M. & N. Islam. 2020. Current Status of Alginate in Drug Delivery. Advances in Pharmacological and Pharmaceutical Sciences, 2020(8886095): 1 – 16.

Haryono, W., A. Wibianto, & T. S. N. Hidayat. 2021. Epidemiologi dan Karakteristik Pasien Luka Bakar di RSUD Cibabat dalam Periode 5 Tahun (2015 – 2020): Studi Retrospektif. Cermin Dunia Kedokteran., 48(4): 208 – 210.

Hidayati, D., G. R. Sabiyla, E. N. Prasetyo, N. N. Sa’adah, & F. Kurniawan. 2021. The Characteristics of Gelatin Extracted from the Skin of Adult and Sub-Adult Striped Catfish (Pangasius hypophthalmus) Using Acid-Base Pretreatment: pH and FTIR. IOP Conf. Ser.: Earth and Environmental Science, 755: 012018.

Hossain, A., J. Yeo, D. Dave, & F. Shahidi. 2022. Phenolic Compounds and Antioxidant Capacity of Sea Cucumber (Cucumaria frondosa) Processing Discards as Affected by High-Pressure Processing (HPP). Antioxidants, 11(2): 337.

Hou, L. & P. Wu. 2019. Exploring the Hydrogen-Bond Structures in Sodium Alginate through Two-Dimensional Correlation Infrared Spectroscopy. Carbohydrate Polymers, 205: 420 – 426.

Ibrahim, N. M., A. Alias, N. N. Noraini, S. S. Kamarudin, A. R. Li, & M. K. M. Hasan. 2018. Sea Cucumber as Inhibitor of Bacterial Adhesion in Dental Plaque: Would This Be a Possible Reality?. International Journal for Studies on Children, Women, Elderly and Disabled, 4: 140 – 149.

Kedare, S. B. & R. P. Singh. 2011. Genesis and Development of DPPH Method of Antioxidant Assay. Journal of Food Science and Technology, 48(4): 412 – 422.

Kelishomi, Z. H., B. Goliaei, H. Mahdavi, A. Nikoofar, M. Rahimi, A. A. Moosavi-Movahedi, F. Mamashli, & B. Bigdeli. 2016. Antioxidant Activity of Low Molecular Weight Alginate Produced by Thermal Treatment. Food Chemistry, 196: 897 – 902.

Khan, T. A., K. K. Peh, & H. S. Ch’ng. 2000. Mechanical, Bioadhesive Strength and Biological Evaluations of Chitosan films for Wound Dressing. Journal of Pharmacy & Pharmaceutical Sciences, 3(3): 303 – 311.

Kothale, D., U. Verma, N. Dewangan, P. Jana, A. Jain, & D. Jain. 2020. Alginate as Promising Natural Polymer for Pharmaceutical, Food, and Biomedical Applications. Current Drug Delivery, 17(9): 755 – 775.

Kujath, P. & A. Michelsen. 2008. Wounds – From Physiology to Wound Dressing. Deutsches Ärzteblatt International, 105(13): 239 – 248.

Kumara, P., Sunil K., & A. Kumar B. 2018. Determination of DPPH Free Radical Scavenging Activity by RP-HPLC, Rapid Sensitive Method for the Screening of Berry Fruit Juice Freeze Dried Extract. Natural Products Chemistry & Research, 6(5): 1 – 7.

Kundu, J., J. Shim, J. Jang, S. Kim, & D. Cho. 2013. An Additive Manufacturing-Based PCL-Alginate-Chondrocyte Bioprinted Scaffold for Cartilage Tissue Engineering. Journal of Tissue Engineering and Regenerative Medicine, 9(11): 1286 – 1297.

Lee, K. Y. & D. J. Mooney. 2012. Alginate: Properties and Biomedical Applications. Progress in Polymer Science, 37(1): 106 – 126.

Lee, W., J. Park, K. Kim, S. Kim, D. Park, M. Chae, S. Suh, S. Jeong, & K. Park. 2009. The Biological Effects of Topical Alginate Treatment in an Animal Model of Skin Wound Healing. Wound Repair and Regeneration, 17: 505 – 510.

Li, J., Y. Wu, J. He, & Y. Huang. 2016. A New Insight to the Effect of Calcium Concentration on Gelation Process and Physical Properties of Alginate Films. Journal of Materials Science, 51: 5791 – 5801.

Li, R., K. Liu, X. Huang, D. Li, J. Ding, B. Liu, & X. Chen. 2022. Bioactive Materials Promote Wound Healing through Modulation of Cell Behaviors. Advanced Science, 9(10).

Liu, Y., C. J. Zhang, J. C. Zhao, Y. Guo, P. Zhu, & D. Y. Wang. 2016. Bio-Based Barium Alginate Film: Preparation, Flame Retardancy and Thermal Degradation Behavior. Carbohydrate Polymers, 139: 106 – 114.

Loira-Pastoriza, C., J. Todoroff, & R. Vanbever. 2014. Delivery Strategies for Sustained Drug Release in the Lungs. Advanced Drug Delivery Reviews, 75: 81 – 19.

Lu, H., J. A. Butler, N. S. Britten, P. D. Venkatraman, & S. S. Rahatekar. 2021. Natural Antimicrobial Nano Composite Fibres Manufactured from a Combination of Alginate and Oregano Essential Oil. Nanomaterials, 11(8): 2062.

Makarova, A. O., S. R. Derkach, T. Khair, M. A. Kazantseva, Y. F. Zuev, & O. S. Zueva. 2023. Ion-Induced Polysaccharide Gelation: Peculiarities of Alginate Egg-Box Association with Different Divalent Cations. Polymers, 15(5): 1243.

Marliana, S. D., V. Suryanti, & S. Suryono. 2005. Skrining Fitokimia dan Analisis Kromatografi Lapis Tipis Komponen Kimia Buah Labu Siam (Sechium edule Jacq. Swartz.) dalam Ekstrak Etanol. Biofarmasi, 3(1): 26 – 31.

Martin, S. 2021. Sintesa dan Karakterisasi Hidrogel dari Natrium Alginat dan Ekstrak Belimbing Wuluh pada Textile Wound Dressing. Arena Tekstil, 36(1): 1 – 6.

Merrell, J. G., S. W. McLaughlin, L. Tie, C. T. Laurencin, A. F. Chen, & L. S. Nair. 2009. Curcumin Loaded Poly(ε-Caprolactone) Nanofibers: Diabetic Wound Dressing with Antioxidant and Anti-inflammatory Properties. Clinical and Experimental Pharmacology and Physiology, 36(12): 1149 – 1156.

Mohaved, M. M., S. A. Hosseini, P. Akbary, A. Hajimoradloo, & S. A. A. Hedayati. 2020. Antibacterial Activity of Muscle Wall Extracts Stichopus horrens Sea Cucumber of the Chabahar Coasts, Iran Against some Rainbow Trout (Oncorhynchus mykiss) Pathogenic Bacteria Using Disk Diffusion and Well Diffusion Methods. Int. Conf. Oceanography for West Asia, 2: 132 – 139.

Mutia, T., R. Eriningsih, & R. Safitri. 2011. Membran Alginat Sebagai Pembalut Luka Primer dan Media Penyampaian Obat Topikal untuk Luka yang Terinfeksi. Jurnal Riset Industri, 5(2): 161 – 174.

Myron, P., S. Siddiquee, & S. Al Azad. 2017. Partial Structural Studies of Fucosylated Chondroitin Sulfate (FuCS) Using Attenuated Total Reflection Fourier Transform Infrared Spectroscopy (ATR-FTIR) and Chemometrics. Vibrational Spectroscopy, 89: 26 – 36.

Nagarwal, R. C., R. Kumar, & J. K. Pandit. 2012. Chitosan Coated Sodium Alginate-Chitosan Nanoparticles Loaded with 5-FU for Ocular Delivery: In Vitro Characterization and In Vivo Study in Rabbit Eye. European Journal of Pharmaceutical Sciences, 47(4): 678 – 685.

Najm, H. Y. & R. N. Hussein. 2018. Assessment of Wound Dressing Practices Among Nurses at the Emergency Hospitals in Erbil City. Zanco Journal of Medical Sciences, 22(1): 96 – 103.

Nuutila, K. & E. Eriksson. 2021. Moist Wound Healing with Commonly Available Dressings. Advances in Wound Care, 10(12): 685 – 698.

Obagi, Z., G. Damiani, A. Grada, & V. Falanga. 2019. Principles of Wound Dressings: A Review. Surgical Technology International, 35(5): 1 – 8.

Pagano, C., D. Puglia, F. Luzi, A. Di Michele, S. Scuota, S. Primavilla, M. R. Ceccarini, T. Beccari, C. A. V. Iborra, D. Ramella, M. Ricci, & L. Perioli. 2021. Development and Characterization of Xanthan Gum and Alginate Based Bioadhesive Film for Pycnogenol Topical Use in Wound Treatment. Pharmaceutics, 13(3): 324.

Paixão, L. C., I. Lopes, A. K. D. B. Fihlo, & A. A. Santana. 2019. Alginate Biofilms Plasticized with Hydrophilic and Hydrophobic Plasticizers for Application in Food Packaging. Journal of Applied Polymer Science, 136(48263).

Patrisia, E. E., N. Aprilyadi, W. D. A. Wibowo, & S. Wijaya. 2023. Perawatan Luka Menggunakan Kalsium Alginat sebagai Dressing Primer untuk Mengatasi Gangguan Integritas Jaringan pada Pasien DM Tipe II. SURYA: Jurnal Media Komunikasi Ilmu Kesehatan, 15(2): 57 – 63.

Peng, W., D. Li, K. Dai, Y. Wang, P. Song, H. Li, P. Tang, Z. Zhang, Z. Li, Y. Zhou, & C. Zhou. 2022. Recent Progress of Collagen, Chitosan, Alginate and Other Hydrogels in Skin Repair and Wound Dressing Applications. International Journal of Biological Macromolecules, 208: 400 – 408.

Pereira, L. & J. Cotas. 2020. Alginates: Recent Uses of This Natural Polymer. IntechOpen, London, 150 hlm.

Pereira, R., A. Carvalho, D. C. Vaz, M. H. Gil, A. Mendes, & P. Bártolo. 2013. Development of Novel Alginate Based Hydrogel Films for Wound Healing Applications. International Journal of Biological Macromolecules, 52: 221 – 230.

Periyasamy, N., S. Murugan, & P. Bharadhirajan. 2013. Anticoagulant Activity of Marine Gastropods Babylonia spirata Lin, 1758 and Phalium glaucum Lin, 1758 Collected from Cuddalore, Southeast Cost of India. International Journal of Pharmacy and Pharmaceutical Sciences, 5(4): 117 – 121.

Perkasa, D. P., E. Erizal, T. Purwanti, & A. E. Tontowi. 2018. Characterization of Semi-Interpenetrated Network Alginate/Gelatin Wound Dressing Crosslinked at Sol Phase. Indonesian Journal of Chemistry, 18(2): 367 – 375.

Pongjanyakul, T. & S. Puttipipatkhachorn. 2007. Xanthan-Alginate Composite Gel Beads: Molecular Interaction and In Vitro Characterization. International Journal of Pharmaceutics, 331(1): 61 – 71.

Qin, Y., H. Hu, & A. Luo. 2006. The Conversion of Calcium Alginate Fibers into Alginic Acid Fibers and Sodium Alginate Fibers. Journal of Applied Polymer Science, 101: 4216 – 4221.

Rasyid, A., M. Y. Putra, & Y. Yasman. 2023. Antibacterial and Antioxidant Activity of Sea Cucumber Extracts Collected from Lampung Waters, Indonesia. Kuwait Journal of Science, 50(4): 615 – 621.

Rasyid, A., T. Wahyuningsih, & A. Ardiansyah. 2018. Profil Metabolit Sekunder, Aktivitas Antibakteri dan Komposisi Senyawa yang Terkandung dalam Ekstrak Metanol Teripang Stichopus horrens. Jurnal Ilmu Kelautan dan Teknologi Kelautan Tropis, 10(2): 333 – 340.

Ridhowati, S., F. R. Zakaria, D. Syah, & E. Chasanah. 2018. Anticancer and Antioxidant Activities from Sea Cucumber (Stichopus variegatus) Flour Dried Vacuum Oven. Pertanika Journals of Tropical Agriculture Science, 41(3): 1125 – 1138.

Ridzwan, B. H., T. C. Leong, & S. Z. Idid. 2003. The Antinociceptive Effects of Water Extracts from Sea Cucumbers Holothuria leucospilota Brandt, Bohadschia marmorata vitiensis Jaeger and Coelomic Fluid from Stichopus hermanii. Pakistan Journal of Biological Sciences, 6(24): 2068 – 2072.

Rinaudo, M. 2014. Biomaterials Based on a Natural Polysaccharide: Alginate. 2014. TIP Revista Especializada en Ciencias Químico-Biológicas, 17(1): 92 – 96.

Saberian, M., E. Seyedjafari, S. J. Zargar, F. S. Mahdavi, & P. Sanaei-rad. 2021. Fabrication and Characterization of Alginate/Chitosan Hydrogel Combined with Honey and Aloe Vera for Wound Dressing Applications. Journal of Applied Polymer Science, 138(47): 51398.

Safari, R. & Z. Yaghoubzadeh. 2020. Antioxidant Activity of Bioactive Peptides Extracted from Sea Cucumber (Holothuria leucospilata). International Journal of Peptide Research and Theraupeutics, 26: 2393 – 2398.

Sahib, A. S., F. H. Al-Jawad, & A. A. Alkaisy. 2010. Effect of Antioxidants on the Incidence of Wound Infection in Burn Patients. Ann Burns Fire Disasters, 23(4): 199 – 205.

Salama, H. E., M. S. A. Aziz, & M. W. Sabaa. 2018. Novel Biodegradable and Antibacterial Edible Films Based on Alginate and Chitosan Biguanidine Hydrochloride. International Journal of Biological Macromolecules, 116: 443 – 450.

Sari, R. P., D. I. D. Larashati, C. Aldiana, N. Nafi’ah, D. W. Damaiyanti, & A. Kurniawati. 2023. Application of Stichopus hermanni Nanocaparticle Gel in the Healing of Traumatic Ulcers. European Journal of Dentistry, 17(2): 330 – 336.

Sarpooshi, H. R., M. Haddadi, M. Siavoshi, & R. Borghabani. 2017. Wound Healing with Vitamin C. Translational Biomedicine, 8(4): 139.

Schiefer, J. L., G. F. Aretz, P. C. Fuchs, M. Bagheri, M. Funk, A. Schulz, & M. Daniels. 2021. Comparison of Wound Healing Patient Comfort in Partial-Thickness Burn Wounds Treated with SUPRATHEL and epictehydro Wound Dressings. International Wound Journal, 19(4): 782 – 790.

Sedjati, S., S. Suryono, A. Santosa, E. Supriyantini, & A. Ridho. 2017. Aktivitas Antioksidan dan Kandungan Senyawa Fenolik Makroalga Coklat Sargassum sp. Jurnal Kelautan Tropis, 20(2): 117 – 123.

Sendih, S. & G. Gunawan. 2006. AgroMedia Pustaka, Jakarta, 64 hlm.

Shalapy, A., S. Zhao, C. Zhang, Y. Li, H. Geng, S. Ullah, G. Wang, S. Huang, & Y. Liu. Adsorption of Deoxynivalenol (DON) from CornSteep Liquor (CSL) by the Microsphere Adsorbent SA/CMC Loaded with Calcium. Toxins, 12(208): 1 – 16.

Siregar, M. S. A., E. Bachtiar, A. Nurhayati, & M. W. Lewaru. 2023. Antioxidant Activity of Gamat (Stichopus variegatus) and Milk Sea Cucumbers (Holothuria fuscocinerea) from the Thousand Islands National Park Waters. Journal of Aquaculture and Fish Health, 12(3): 390 – 404.

Sisican, K. M. D., V. P. M. Torreno, E. T. Yu, & M. T. Conato. 2023. Physicochemical and Biochemical Characterization of Collagen from Stichopus cf. horrens Tissues for Use as Stimuli-Responsive Thin Films. ACS Omega, 8: 35791 – 35799.

Song, S., S. Wu, C. Ai, X. Xu, Z. Zhu, C. Cao, J. Yang, & C. Wen. 2018. Compositional Analysis of Sulfated Polysaccharides from Sea Cucumber (Stichopus japonicus) Released by Autolysis Reaction. 2018. International Journal of Biological Macromolecules, 114: 420 – 425.

Srivastava, G. K., S. Martinez-Rodriguez, N. I. M. Fadilah, D. L. Q. Hao, G. Markey, P. Shukla, M. B. Fauzi, & F. Panetsos. 2024. Progress in Wound-Healing Products Based on Natural Compounds, Stem Cells, and MicroRNA-Based Biopolymers in the European, USA, and Asian Markets: Opportunities, Barriers, and Regulatory Issues. Polymers, 16(9): 1280.

Stashak, T. S., E. Farstvedt, & A. Othic. 2004. Update on Wound Dressings: Indications and Best Use. Clinical Techniques in Equine Practice. 3(2): 148 – 163.

Stiani, S. N., T. Rudiana, Y. Setiawan, E. Setyowati, & S. Ansori. 2021. Formulation and Characterization of Serum Collagen of Sea Cucumber Extract Stichopus horrens as an Antioxidant. International Journal of Applied Pharmaceutics, 13(4): 176 – 182.

Subramaniam, B. S., A. Amuthan, P. M. D’ Almeida, & Arunkumar H. D. 2013. Efficacy of Gamat Extract in Wound Healing in Albino Wistar Rats. International Journal of Pharmaceutical Sciences Review and Research, 20(1): 142 – 145.

Subramaniam, T., M. B. Fauzi, Y. Lokanathan, & J. X. Law. 2021. The Role of Calcium in Wound Healing. International Journal of Molecular Science, 22(12): 6486.

Sutar, T., P. Bangde, P. Dandekar, & R. Adivarekar. 2021. Herbal Hemostatic Biopolymeric Dressings of Alginate/Pectin Coated with Croton oblongifolius Extract. Carbohydrate Polymer Technologies and Applications, 2: 100025.

Sutardi, L. N., A. A. Mustika, A. Andriyanto, R. Januar, & A. N. Ayumi. 2022. Aktivitas Gel Kombinasi Ekstrak Rimpang Kunyit dan Gel Gamat Terhadap Penyembuhan Luka. Acta Veterinaria Indonesiana, 10(2): 193 – 200.

Teramoto, H., T. Kameda, and Y. Tamada. 2008. Preparation of Gel Film from Bombyx mori Silk Sericin and Its Characterization as a Wound Dressing. Bioscience, Biotechnology, and Biochemistry, 72(12): 3189 – 3196.

Thinh, P. D., B. M. Ly, R. V. Usoltseva, N. M. Shevchenko, A. B. Rasin, S. D. Anastyuk, O. S. Malyarenko, T. N. Zvyagintseva, P. T. San, & S. P. Ermakova. 2018. A Novel Sulfated Fucan from Viatnamese Sea Cucumber Stichopus variegatus: Isolation, Structure and Anticancer Activity In Vitro. International Journal of Biological Macromolecules, 117(1): 1101 – 1109.

This, Hervé. 2006. Molecular Gastronomy. Columbia University Press, New York, 379 p.

Tiwari, V. K. 2012. Burn Wound: How It Differs from Other Wounds?. Indian Journal of Plastic Surgery, 45(2): 364 – 373.

Ustyuzhanina, N. E., M. I. Bilan, A. S. Dmitrenok, A. S. Silchenko, B. B. Grebnev, V. A. Stonik, N. E. Nifantiev, & A. I. Usov. 2020. Fucosylated Chondroitin Sulfates from the Sea Cucumbers Paracaudina chilensis and Holothuria hilla: Structures and Anticoagulant Activity. Marine Drugs, 18(11): 540.

Wang, T., J. Wang, R. Wang, P. Yuan, Z. Fan, & S. Yang. 2019. Preparation and Properties of ZnO/Sodium Alginate Bi-Layered Hydrogel Films as Novel Wound Dressings. New Journal of Chemistry, 43: 8684.

Wang, T., X. Zhu, X. Xue, & D. Wu. 2012. Hydrogel Sheets of Chitosan, Honey and Gelatin as Burn Wound Dressings. Carbohydrate Polymers, 88(1): 75 – 83.

Wang, Y., C. Wang, L. Qiao, J. Feng, Y. Zheng, Y. Caho, W. He, Y. Xie, W. Shuai, M. Li. 2018. Shape-Adaptive Composite Foams with High Expansion and Absorption Used for Massive Hemorrhage Control and Irregular Wound Treatment. Applied Materials Today, 13: 228 – 241.

Wen, A. P. Y., A. S. Halim, A. Z. M. Saad, F. M. Nor, & W. A. W. Sulaiman. 2018. A Prospective Study Evaluating Wound Healing with Sea Cucumber Gel Compared with Hydrogel in Treatment of Skin Graft Donor Sites. Complementary Therapies in Medicine, 41: 261 – 266.

Xia, Y., Z. Liu, & Z. Li. 2012. Effects of High Hydrostatic Pressure Treatment on Physicochemical Characteristics of Sea Cucumber. Journal of Food Science and Engineering, 2: 227 – 238.

Yang, M., J. Shi, & Y. Xia. 2018. Effect of SiO2, PVA and Glycerol Concentrations on Chemical and Mechanical Properties of Alginate-Based Films. International Journal of Biological Macromolecules, 107(B): 2686 – 2694.

Yuan, Y., C. Li, Q. Zheng, J. Wu, K. Zhu, X. Shen, & J. Cao. 2019. Effect of Simulated Gastrointestinal Digestion In Vitro on the Antioxidant Activity, Molecular Weight and Microstructure of Polysaccharides from a Tropical Sea Cucumber (Holothuria leucospilota). Food Hydrocolloids, 89: 735 – 741.

Zhang, M., W. Liu, & G. Li. 2009. Isolation and Characterisation of Collagens from the Skin of Largefin Longbarbel Catfish (Mystus macropterus). Food Chemistry, 115(3): 826 – 831.

Zheng, Z., M. Li, P. Jiang, N. Sun, & S. Lin. 2022. Peptide Derived from Sea Cucumber Accelerate Cells Proliferation and Migration for Wound Healing by Promoting Energy Metabolism and Upregulating the ERK/AKT Pathway. Pharmacology, 921: 174885.

Zhong, Y., M. A. Khan, & F. Shahidi. 2007. Compositional Characteristics and Antioxidant Properties of Fresh and Processed Sea Cucumber (Cucumaria frondose). Journal of Agricultural and Food Chemistry, 55(4): 1188 – 1192.

Zhou, X., P. Feng, H. Liu, & B. Song. 2022. Bioinspired Aligned Wrinkling Dressings for Monitoring Joint Motion and Promoting Joint Wound Healing. Biomaterials Science, 10(18): 5146 – 5157.

Zhu, B., X. Dong, D. Zhou, Y. Gao, J. Yang, D. Li, X. Zhao, T. Ren, W. Ye, H. Tan, H. Wu, & C. Yu. 2012. Physicochemical Properties and Radical Scavenging Capacities of Pepsin-Solubilized Collagen from Sea Cucumber Stichopus japonicus. Food Hydrocolloids, 28(1): 182 – 188.

Zhu, L., F. Ge, L. Yang, W. Li, S. Wei, Y. Tao, & G. Du. 2017. Alginate Particels with Ovalbumin (OVA) Peptide Can Serve as a Carrier and Adjuvant for Immune Therapy in B16-OVA Cancer Model. Medical Science Monitor Basic Research, 23: 166 – 172.

Zhuang, Y. & L. Sun. 2011. Anti-Melanogenic Activities of Collagen Peptides from Jellyfish (Stomolophus meleagris). Advanced Materials Research, 343 – 344: 505 – 512.

Zohdi, R. M., Z. A. B. Zakaria, N. Yusof, N. M. Mustapha, & M. N. H. Abdullah. 2011. Sea Cucumber (Stichopus hermanii) Based Hydrogel to Treat Burn Wounds in Rats. Journal of Biomedical Materials Research, 98B(1): 30 – 37.

Zou, S., R. Pan, X. Dong, M. He, & C. Wang. 2016. Physicochemical Properties and Antioxidant Activities of Two Fucosylated Chondroitin Sulfate from Sea Cucumber Acaudina Molpadioidea and Holothuria nobilis. Process Biochemistry, 51(5): 650 – 658.

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Published

2024-05-29

Data Availability Statement

The data that support the findings of this study are available from the corresponding author, upon reasonable request.

Issue

Vol. 2 No. 2 (2024): Mei 2024

Section

Marine Biotechnology and Immunology

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Copyright (c) 2024 Journal of Marine Biotechnology and Immunology

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This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

How to Cite

Satria , K. E. ., Sedjati , S. ., & Yudiati, E. (2024). Alginate – Gamat Gel Hydrogel Films as the Potential Wound Dressing. Journal of Marine Biotechnology and Immunology, 2(2), 19-31. https://doi.org/10.61741/ks8q3f15

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