Natural nitrogen sources derived from the extracts of green beans, soybeans, and peanuts used for making sugarcane juice have been studied. Organoleptic quality for nata was analyzed by indicators of color, texture, aroma, and taste. The level of community preference for sugarcane juice on sugarcane juice is observed in the community. The data analysis method used single classification Variance Analysis for selection using descriptive analysis, fiber content using proximate analysis, and protein content using the Kjeldahl method. The single classification variant analysis results show significant differences in the aspects of color and texture. The results of the community preference test were selected nata using ZA protein. The amounts of fiber and protein in the sugarcane juice and green bean extract samples were 0.79% and 24.319%, respectively, as best results. Other sugarcane juice's fiber and protein content is lowest than 0.68% and 5.359%, respectively. The best quality organoleptic qualities were samples with fertilization using ZA and green beans. The observation results showed that the sugar cane juice with green bean extract was more acceptable to the community and had better nutritional content.

Anam, C. (2019). Mengungkap senyawa pada nata de coco sebagai pangan fungsional. Jurnal Ilmu Pangan dan Hasil Pertanian, 3(1), 42-53.

Arifiani, N., Sani, T. A., & Utami, A. S. (2015). Peningkatan kualitas nata de cane dari limbah nira tebu metode Budchips dengan penambahan ekstrak tauge sebagai sumber nitrogen. Bioteknologi, 12(2), 29-33.

Asri, M. T., Ducha, N., Ratnasari, E., & Bashri, A. (2018, November). Application of Acetobacter Xylinum in The Production of Nata De Legen From Palmyra Palm Neera. In Journal of Physics: Conference Series (Vol. 1108, No. 1, p. 012098). IOP Publishing.

Basalamah, N. A., Nurlaelah, I., & Handayani, H. (2018). Pengaruh Subtitusi Ekstrak Kedelai Terhadap Karakteristik Selulosa Bakteri Acetobacter xylinum Dalam Pembuatan Nata De Sweet Potato. Quagga: Jurnal Pendidikan dan Biologi, 10(01), 24-31.

Bhuiyan, F. R., & Rahim, A. T. M. (2015). Consumer’s sensory perception of food attributes: A survey on flavor. Journal of Food and Nutrition Sciences, 3(1-2), 157-160.

Choi, S. M., & Shin, E. J. (2020). The nanofication and functionalization of bacterial cellulose and its applications. Nanomaterials, 10(3), 406.

Hamad, A., Handayani, N. A., & Puspawiningtyas, E. (2014). Pengaruh umur starter Acetobacter xylinum terhadap produksi nata de coco. Techno (Jurnal Fakultas Teknik, Universitas Muhammadiyah Purwokerto), 15(1), 37-49.

Jagannath, A., Kalaiselvan, A., Manjunatha, S. S., Raju, P. S., & Bawa, A. S. (2008). The effect of pH, sucrose and ammonium sulphate concentrations on the production of bacterial cellulose (Nata-de-coco) by Acetobacter xylinum. World Journal of Microbiology and Biotechnology, 24(11), 2593-2599.

Juda, S. N., Suharno, S., & Nugraha, D. A. (2018). Development of nata de coco with natural dyes using value engineering method. KnE Life Sciences, 96-109.

Phisalaphong, M., Chiaoprakobkij, N., Gama, M., Gatenholm, P., & Klemm, D. (2012). Applications and products—Nata de Coco. Bacterial nanocellulose: a sophisticated multifunctional material, 143-156.

Mandey, L. C., Tarore, D., Kandou, J. E., & Dumais, N. M. (2020). Teknologi Produksi Nata De Coco Berbahan Baku Organik. Pro Food, 6(2), 665-672.

Masri, M., Irhamniah, I., Latif, U. T. A., & Rusny, R. (2020). Comparison of Nata Quality From Cassava Peels (Manihot esculenta), Ladyfinger Bananas Peels (Musa acuminata Colla), and Durian Peels (Durio zibethinus). Elkawnie: Journal of Islamic Science and Technology, 6(1), 146-155.

Naja, H. L., Sari, A. M., & Zaman, M. Z. (2019, October). Nata de cincau: Pacitan’s black cincau (Mesona palustris BL) product innovation with respect to its physical, chemical and sensory characteristics. In IOP Conference Series: Materials Science and Engineering (Vol. 633, No. 1, p. 012009). IOP Publishing.

Phisalaphong, M., Chiaoprakobkij, N., Gama, M., Gatenholm, P., & Klemm, D. (2012). Applications and products—Nata de Coco. Bacterial nanocellulose: a sophisticated multifunctional material, 143-156.

Safitri, M. P., Caronge, M. W., & Kadirman, K. (2018). Pengaruh Pemberian Sumber Nitrogen dan Bibit Bakteri Acetobacter Xylinum Terhadap Kualitas Hasil Nata De Tala. Jurnal Pendidikan Teknologi Pertanian, 3(2), 95-106.

Shagti, I. (2017). Peningkatan Protein dan Vitamin B melalui Pemberian Whey dan Lerry pada Produk Nata. Jurnal Info Kesehatan, 15(2), 495-507.