The growth and survival of Penaeus monodon and other commercial species and the production performance of Integrated Multitrophic Aquaculture (IMTA) system were evaluated in a 500 m² experimental grow-out ponds of Mindanao State University at Naawan for 120 days. Three triplicated treatments, monoculture (P. monodon only), polyculture (P. monodon and Chanos chanos) and IMTA (P. monodon, C. chanos, Perna viridis and Gracilaria verrucosa) were evaluated in a semi-intensive pond culture operation. Salinity (24.3 to 34.36‰), temperature (28 to 40.64°C) and pH (7.5 to 9.49) exceeded the maximum ideal limit for the cultured organisms in all treatments. Dissolved oxygen levels (2.76-5.43) were within the optimal range of some cultured organisms. Growth of shrimp (5.33±0.02 %SGR P <0.05) and milkfish (4.49±0.03 %SGR P <0.05) were significantly better in IMTA than in polyculture. Shrimp’s survival was also significantly higher in IMTA (24.13%±3.95, P <0.05) than in the other treatments. Shrimp-milkfish biomass was highest in IMTA (89.67 kg), followed by polyculture (57.72 kg) and lowest in monoculture (11.33 kg). The higher biomass and survival of shrimp and milkfish in IMTA ponds could be attributed to the cultured organisms' synergistic interaction, such as shading and nutrient remediation by G. verrucosa and bioremediation by P. viridis. Revenue and profit followed a similar trend, with IMTA revealing profitability over the polyculture and monoculture. Hence, the results demonstrate the efficiency of the IMTA systems over monoculture and polyculture in the growth and survival of the high-valued jumbo tiger shrimp, P. monodon and the overall production and profitability.

Anh, N. T. N., An, B. N. T., Lan, L. M., & Hai, T. N. (2019). Integrating different densities of white leg shrimp Litopenaeus vannamei and red seaweed Gracilaria tenuistipitata in the nursery phase: effects on water quality and shrimp performance. Journal of Applied Phycology, 31(5), 3223-3234.

Anka, I. Z., Faruk, M. A. R., Hasan, M. M., & Azad, M. A. K. (2014). Environmental issues of emerging pangas (Pangasianodon hypophthalmus) farming in Bangladesh. Progressive Agriculture, 24(1-2), 159-170.

Annas, H., Cokrowati, N., & Marzuki, M. (2019). Gracilaria verrucosa growth rate cultivated using bottom off method. In AIP Conference Proceedings (Vol. 2120, No. 1). AIP Publishing.

Arriesgado, E. M., dela Peña, M. A., Pinaso Jr, R. D., Tering, J. D., Navarro, V. R., Eballe, R. C., & Arriesgado, D. M. (2022). Identifying the Suitable Integrated Multitrophic Aquaculture (IMTA) Species Combination for Penaeus monodon (Fabricius, 1798) for a Sustainable Pond Aquaculture. Philippine Journal of Science, 151(6B), 2497-2507.

Balasubramanian, C. P., Mhaskar, S. S., Sukumaran, K., Panigrahi, A., Vasagam, K., Kumararaja, P., Thigale, D., Sawant, R., Vijayan, K.K. & Vasudevan, N. (2018). Development of integrated multi-trophic aquaculture (IMTA) for tropical brackishwater species in Sindhudurg District, Maharashtra, west coast of India. Indian Journal of Fisheries, 65(1), 59-64.

Bautista-Teruel, M. N., Eusebio P. S., & Welsh T. P. (2003). Utilization of feed pea, Pisum sativum, meal as a protein source practical diets for juvenile tiger shrimp, P. monodon. Aquaculture, 225, 121-131.

Biswas, G., Kumar, P., Ghoshal, T. K., Kailasam, M., De, D., Bera, A., & Vijayan, K. K. (2020). Integrated multitrophic aquaculture (IMTA) outperforms conventional polyculture with respect to environmental remediation, productivity and economic return in brackishwater ponds. Aquaculture, 516, 734626.

Bertrand, A., Lengaigne, M., Takahashi, K., Avadí, A., Poulain, F., & Harrod, C. (2020). El Niño Southern Oscillation (ENSO) effects on fisheries and aquaculture (Vol. 660). FAO Fisheries and Aquaculture Technical Paper No. 660. Rome, FAO.

Chopin, T. (2006). Integrated Multitrophic Aquaculture. What it is and why you should care and don’t confuse it with polyculture. Northern Aquaculture, 12 (4), 4.

Chopin, T., Robinson, S.M.C., Troell, M., Neori, A., Buschmann, A.H., & Fang, J. (2008). Multi-trophic integration for sustainable marine aquaculture. In:Jorgensen, S.E., Fath, B.D. (Eds.), Encyclopedia of Ecology. Elsevier, Oxford, UK. pp.2463–2475.

Food and Agriculture Organization of the United Nations (2020). Global Forest Resources Assessment 2020 (FRA 2020), Food and Agriculture Organization of the United Nations, Food and Agriculture Organization of the United Nations, Rome(URL: https://doi.org/10.4060/ca9825en).

Fang, J.G. (2018). Training Module for Integrated Multitrophic Aquaculture in PR China. UNDP/GEF Yellow Sea Large Marine Ecosystem (YSLME) Phase II Project, Incheon, RO Korea.

Fleurence, J., Morançais, M., Dumay, J., Decottignies, P., Turpin, V., Munier, M., Nuria, G., & Jaouen, P. (2012). What are the prospects for using seaweed in human nutrition and for marine animals raised through aquaculture?. Trends in Food Science & Technology 27(1):57-61.

Hafiz, M.B., Hidayah, M., Yusdianatu, A.Y., Ambak, M.A., Abol-Munafi A.B., & Ikhwanuddin, M. (2012). Effect of oestrogen hormone, 17β-estradiol on feminization, survival rate and growth rate of tiger shrimp, P. monodon (Fabricius, 1798) postlarvae. Borneo Science. 30, 70-80.

Haque, M. M., Belton, B., Alam, M. M., Ahmed, A. G., & Alam, M. R. (2016). Reuse of fish pond sediments as fertilizer for fodder grass production in Bangladesh: Potential for sustainable intensification and improved nutrition. Agriculture, Ecosystems & Environment, 216, 226-236.

Hossain, A., Senff, P., & Glaser, M. (2022). Lessons for coastal applications of IMTA as a way towards sustainable development: A review. Applied Sciences, 12(23), 11920.

Huo, Y. Z., Xu, S. N., Wang, Y. Y., Zhang, J. H., Zhang, Y. J., Wu, W. N., ... & He, P. M. (2011). Bioremediation efficiencies of Gracilaria verrucosa cultivated in an enclosed sea area of Hangzhou Bay, China. Journal of Applied Phycology, 23, 173-182.

Irisarri, J., Fernández-Reiriz, M. J., Labarta, U., Cranford, P. J., & Robinson, S. M. (2015). Availability and utilization of waste fish feed by mussels Mytilus edulis in a commercial integrated multitrophic aquaculture (IMTA) system: a multi-indicator assessment approach. Ecological indicators, 48, 673-686.

Janakiram, P., Loka, J., & Madhavi, R. (2011). Survival, Growth and Production of Penaeus monodon in Modified-Extensive and Semi Intensive Culture Systems of Andhra Pradesh, India. Asian Journal of Experimental Science, 25(2), 53-61.

Largo, D. B., Diola, A. G., & Marababol, M. S. (2016). Development of an integrated multi-trophic aquaculture (IMTA) system for tropical marine species in southern Cebu, Central Philippines. Aquaculture reports, 3, 67-76.

Liutkus, M., Robinson, S., MacDonald, B., & Reid, G. (2012). Quantifying the effects of diet and mussel size on the biophysical properties of the blue mussel, Mytilus spp., feces egested under simulated imta conditions. Journal of Shellfish Research, 31(1), 69-77.

Neori, A., Chopin, T., Troell, M., Buschmann, A.H., Kraemer, G.P., Halling, C., Shpigel, M., & Yarish, C. (2004). Integrated aquaculture: Rationale, evolution and state of the art emphasizing seaweed biofiltration in modern mariculture. Aquaculture 231:361–391.

Nobre, A. M., Robertson-Andersson, D., Neori, A., & Sankar, K. (2010). Ecological–economic assessment of aquaculture options: comparison between abalone monoculture and integrated multi-trophic aquaculture of abalone and seaweeds. Aquaculture, 306(1-4), 116-126.

Palanca-Tan, R. (2018). Aquaculture, poverty and environment in the Philippines. The Journal of Social, Political, and Economic Studies, 43(3/4), 294-315.

Penniman, C. A., Mathieson A. C., & Penniman, C. E. (1986). Reproductive phenology and growth of Gracillaria tikvahiae McLachlan (Gigartinales, Rhodophyta) in the Great Bay Estuary, New Hampshire. Botanica Marina, 29, 147-154.

Philippine Statistics Authority (PSA). (2017). Philippines’ Shrimp Production in 1996-2016.

Sabbir, W., Sultana, T., Khan, M. N., Das, M., & Bazlur Rahaman, S. M. (2018). Production performance tiger shrimp (Penaeus monodon) semi-intensive freshwater pond. International Journal of Business, Social and Scientific Research, 5(1), 1-6 ISSN:2309-7892.

Simão, B. R., Brito, L. O., Maia, A. S. C., Miranda, L. C., & Azevedo, C. M. D. S. B. (2013). Stocking densities and feeding strategies in shrimp and tilapia polyculture in tanks. Pesquisa Agropecuária Brasileira, 48, 1088-1095.

Shi, H., Zheng, W., Zhang, X., Zhu, M., & Ding, D. (2013). Ecological–economic assessment of monoculture and integrated multitrophic aquaculture in Sanggou Bay of China. Aquaculture, 410, 172-178.

Tahiluddin, A., & Terzi, E. (2021). An overview of fisheries and aquaculture in the Philippines. Journal of Anatolian Environmental and Animal Sciences, 6(4), 475-486.

Tan, K. S., & Ransangan, J. (2019). Extrinsic Factors and Marine Bivalve Mass Mortalities: An Overview. Journal of Shellfish Research, 38, 223-232.

Troell, M., Hallling, C., Neori, A., Chopin, T., Buschmann, A.H., Kautsky, N., & Yarish, C. (2003). Integrated mariculture: Asking the right questions. Aquaculture 226:69– 90.

Van Khoi, L., & Fotedar, R. (2012). Integration of blue mussel (Mytilus edulis Linnaeus, 1758 with western king prawn (Penaeus latisulcatus, Kishinouye, 1896) in a closed recirculating aquaculture system under laboratory conditions. Aquaculture, 345–355, 84–90.

Ye, L., Jiang, S., Zhu, X., Yang, Q., Wen, W., & Wu, K. (2009). Effects of salinity on growth and energy budget of juvenile Penaeus monodon. Aquaculture, 290(1-2), 140-144.

Zaikov, A., Iliev, I., & Hubenova, T. (2008). Investigation on growth rate and food conversion ratio of wels (Silurus glanis L.) in controlled conditions. Bulgarian Journal of Agricultural Science, 14(2), 171-175.