Biofilms, structured communities of microorganisms, have emerged as a subject of significant interest across various industries due to their unique biodegradable and sustainable characteristics. Hair waste is an incredibly rich source of keratin, and this abundance makes it a promising candidate as a fundamental building block for the development of biodegradable plastics. This study focuses on sustainable biofilms derived from biodegradable materials, specifically a unique combination of starch and hair waste. Machine Learning models, implemented in RapidMiner, were utilized to predict the tensile strength of these biofilms, with the goal of enhancing quality control in their production. Neural Networks and Deep Learning methods were employed to compare their predictive capabilities, assessing both their strengths and limitations. Through rigorous data collection, feature identification, and detailed data analysis, critical factors influencing the quality of the biofilms were identified. The results revealed the remarkable predictive accuracy of the Neural Net model, particularly for Ratio 40, while the performance of the Deep Learning model varied across different ratios. The lower RMSE of the Neural Net model indicated a more precise alignment between the predicted and actual values, distinguishing it as the superior model. This research contributes to the advancement of sustainable biofilm development, offering eco-friendly solutions through the use of unconventional materials. Both models offer valuable predictive capabilities, and the choice between them may depend on the specific requirements and contexts of the application. In conclusion, the performance of the Neural Net and Deep Learning models in predicting stress in tensile strength varies across different ratios.

Al-Kharusi, G., Dunne, N. J., Little, S., & Levingstone, T. J. (2022). The Role of Machine Learning and Design of Experiments in the Advancement of Biomaterial and Tissue Engineering Research. Bioengineering, 9(10). https://doi.org/10.3390/bioengineering9100561

Calegari, E. P., Smidt, J. P., Angrizani, C. C., Oliveira, B. F. de, Duarte, L. da C., & Amico, S. C. (2017). Composites From Renewable Resources with Thermoplastic Starch Matrix. In Biocomposites: Properties, Performance and Applications (hal. 47–75). https://mail.google.com/mail/u/0/?pli=1%5Cnpapers3://publication/uuid/D84FC782-E317-4880-B951-0697213436E1

Chilakamarry, C. R., Mahmood, S., Saffe, S. N. B. M., Arifin, M. A. Bin, Gupta, A., Sikkandar, M. Y., Begum, S. S., & Narasaiah, B. (2021). Extraction and application of keratin from natural resources: a review. 3 Biotech, 11(5), 1–12. https://doi.org/10.1007/s13205-021-02734-7

Elmi, K., Heny, H., & Endang, Y. P. (2017). POTENSI PENGEMBANGAN PLASTIK BIODEGRADABLE BERBASIS PATI SAGU DAN UBIKAYU DI INDONESIA The Development Potential of Sago and Cassava Starch-Based Biodegradable Plastic in Indonesia. Jurnal Litbang Pertanian, 36(2), 67–76. https://doi.org/10.21082/jp3.v36n2.2017.p67-76

Jayarathna, S., Andersson, M., & Andersson, R. (2022). Recent Advances in Starch-Based Blends and Composites for Bioplastics Applications. Polymers, 14(21), 1–24. https://doi.org/10.3390/polym14214557

Kinza, Y. (2007). Neural Network. TechTarget. https://doi.org/10.1007/978-3-030-97645-3_11

Marimuthu, M., Savithri, V., & Prathikshana, B. M. (2022). the Implementation of Decision Tree Algorithm C4.5 Using Rapidminer in Analyzing Heart Disease of Patients. International Research Journal of Modernization in Engineering Technology and Science, 4(07), 2582–5208. www.irjmets.com

Mastrolia, C., Giaquinto, D., Gatz, C., Pervez, M. N., Hasan, S. W., Zarra, T., Li, C. W., Belgiorno, V., & Naddeo, V. (2022). Plastic Pollution: Are Bioplastics the Right Solution? Water (Switzerland), 14(22), 1–13. https://doi.org/10.3390/w14223596

Rapidminer, S. (2011). Neural Net. SpringerReference. https://doi.org/10.1007/springerreference_19703

Shineh, G., Mobaraki, M., Perves Bappy, M. J., & Mills, D. K. (2023). Biofilm Formation, and Related Impacts on Healthcare, Food Processing and Packaging, Industrial Manufacturing, Marine Industries, and Sanitation–A Review. Applied Microbiology, 3(3), 629–665. https://doi.org/10.3390/applmicrobiol3030044

Stergiou, K., Ntakolia, C., Varytis, P., Koumoulos, E., Karlsson, P., & Moustakidis, S. (2023). Enhancing property prediction and process optimization in building materials through machine learning: A review. Computational Materials Science, 220(August 2022), 112031. https://doi.org/10.1016/j.commatsci.2023.112031

Sudirman, Windarto, A. P., & Wanto, A. (2018). K-means method on clustering of rice crops by province as efforts to stabilize food crops in Indonesia. IOP Conference Series: Materials Science and Engineering, 420(1), 1–8. https://doi.org/10.1088/1757-899X/420/1/012089

Utami, H. H., Ardiansah, A., Munira, M., Nurfadilah, N., Rahmi, R., & Setiawan, I. (2021). Karakterisasi Ekstraksi Pelarut dari Keratin Limbah Rambut sebagai Bahan Dasar Pembuatan Plastik Biodegradable. Indonesian Journal of Fundamental Sciences, 7(1), 1–7.

Utami, H. H., Fitrah, M. A., Husna, S., Yusriadi, Y., & Nurlaida, N. (2022). Analisa Area, Diameter dan Kekasaran dari Hasil Ekstraksi Limbah Rambut sebagai Bahan Dasar Plastik Biodegradable. Taman Vokasi, 10(2), 197–203. https://doi.org/10.30738/jtvok.v10i2.13480