ABSTRAK

Budi daya ikan badut (Amphiprion ocellaris) skala massal dalam wadah terkontrol dilakukan untuk meningkatkan produksi dengan aplikasi skimmer protein dan filter ultraviolet. Penggunaan skimmer protein dan filter ultraviolet untuk pemeliharaan ikan badut dilakukan dengan tujuan mengevaluasi pertumbuhan mutlak, kualitas warna, kepadatan bakteri dan perubahan kualitas air selama pemeliharaan ikan badut. Hasil penelitian menunjukkan pertumbuhan panjang dan berat mutlak ikan badut terbaik pada pemeliharaan dengan menggunakan skimmer protein dan filter ultraviolet. Kualitas warna ikan badut yang dipelihara menggunakan skimmer protein dan filter ultraviolet cepat berubah menjadi lebih merah gelap dan konsisten dipertahankan sampai selesai pemeliharaan. Kepadatan bakteri total, Vibrio pigmen kuning dan hijau berkurang dengan menggunakan skimmer protein dan filter ultraviolet. Fluktuasi kualitas air pemeliharaan ikan badut pada perekayasaan ini sangat besar dan tidak memenuhi persyaratan budi daya ikan-ikan laut karena baku mutu air laut diperairan Teluk Lampung yang telah menurun drastis kualitasnya.

Kata kunci: ikan nemo, protein skimmer, UV filter, angka lempeng total, Vibrio, warna

ABSTRACT

Mass scale culture of clownfish (Amphirion ocellaris) to enhance production with foam fractionator and ultraviolet filter was revealed. Application of foam fractionator and ultraviolet filter in clownfish study aimed to evaluate absolute growth, color quality, total bacterial density, and water quality fluctuations. Results showed that total length and body weight of clownfish high performance with applied foam fractionator and ultraviolet filter. Color quality of clownfish with foam fractionator and ultraviolet filter drastically change to dark red and endure consistently within study. Vibrio total with yellow and green pigment reduce with application of foam fractionator and ultraviolet filter. High water quality fluctuations in clownfish culture and not suitable for mariculture requirement due to reducing Lampung Bay water quality.

Keywords: anemone fish, protein skimmer, UV filtration, total plate number, Vibrio, color  

Gullian, M., Espinosa‐Faller, F. J., Núñez, A., & López‐Barahona, N. (2012). Effect of turbidity on the ultraviolet disinfection performance in recirculating aquaculture systems with low water exchange. Aquaculture Research, 43(4), 595-606.

Hayashi, K., & Reimer, J. D. (2020). Five-year study on the bleaching of anemonefish-hosting anemones (Cnidaria: Anthozoa: Actiniaria) in subtropical Okinawajima Island. Regional Studies in Marine Science, 35, 101240.

Hayashi, K., Tachihara, K., & Reimer, J. D. (2021). Loss of natural coastline influences species diversity of anemonefish and host anemones in the Ryukyu Archipelago. Aquatic Conservation: Marine and Freshwater Ecosystems, 31(1), 15-27.

Hébert, N., Gagné, F., Cejka, P., Bouchard, B., Hausler, R., Cyr, D. G., ... & Fournier, M. (2008). Effects of ozone, ultraviolet and peracetic acid disinfection of a primary-treated municipal effluent on the immune system of rainbow trout (Oncorhynchus mykiss). Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology, 148(2), 122-127.

Mak, K. K., Yanase, H., & Renneberg, R. (2005). Cyanide fishing and cyanide detection in coral reef fish using chemical tests and biosensors. Biosensors and Bioelectronics, 20(12), 2581-2593.

Romero-Martínez, L., Moreno-Andrés, J., Acevedo-Merino, A., & Nebot, E. (2016). Evaluation of ultraviolet disinfection of microalgae by growth modeling: application to ballast water treatment. Journal of applied phycology, 28(5), 2831-2842.

Mizuno, S., Urawa, S., Miyamoto, M., Hatakeyama, M., Koide, N., & Ueda, H. (2019). Experimental evidence on prevention of infection by the ectoparasitic protozoans Ichthyobodo salmonis and Trichodina truttae in juvenile chum salmon using ultraviolet disinfection of rearing water. Journal of fish diseases, 42(1), 129-140.

Palmtag, M.R. (2017). The Marine Ornamental Species Trade. In Marine Ornamental Species Aquaculture. Eds: Calado, R., Olivotto, I., Oliver, M.P., & Holt, G.J. Wiley Blackwell. United Kingdom. 1-14 pp.

Prama, E.A., Supriyono, E., Nirmala, K., & Adiyana, K. (2017). Dampak penggunaan sistem filtrasi fiisk yang berbeda terhadap kadar glukosa hemolymph dan tingkat kelangsungan hidup juvenil lobster pasir Panulirus homarus. Jurnal Ilmu dan Teknologi Kelautan Tropis 9(2), 569-575.

Roselet, M., Roselet, F., & Abreu, P. C. (2019). Foam fractionator as a tool to remove dissolved organic matter and improve the flocculation of the marine microalga Nannochloropsis oceanica. Journal of Applied Phycology, 31(5), 2911-2919.

Roux, N., Salis, P., Lambert, A., Logeux, V., Soulat, O., Romans, P., ... & Laudet, V. (2019). Staging and normal table of postembryonic development of the clownfish (Amphiprion ocellaris). Developmental Dynamics, 248(7), 545-568.

Salis, P., Lee, S.-H., Roux, N., Lecchini, D., & Laudet, V. (2021). The real Nemo movie: Description of embryonic development in Amphirion ocellaris from first division to hatching. Development Dynamics 250(11),1651-1667.

Susanto, A., Herjayanto, M., Budiaji, W., Priyantono, E., & Guna, N. A. (2021, March). The Development Design of Venturi Type Protein Skimmer for Mariculture Land Base System. In IOP Conference Series: Earth and Environmental Science (Vol. 715, No. 1, p. 012063). IOP Publishing.

Timmons, M. B., Chen, S., & Weeks, N. C. (1995). Mathematical model of a foam fractionator used in aquaculture. Journal of the World Aquaculture Society, 26(3), 225-233.

Umar, M., Roddick, F., & Fan, L. (2019). Moving from the traditional paradigm of pathogen inactivation to controlling antibiotic resistance in water-Role of ultraviolet irradiation. Science of the Total Environment, 662, 923-939.