Application of Indoor Recirculation Aquaculture System for White Shrimp (Litopenaeus vannamei) Growout Super-Intensive Culture at Low Salinity Condition

Journal of Aquaculture Research and Development Pub Date : 2018-01-01 DOI:10.4172/2155-9546.1000530

G. Suantika, M. L. Situmorang, Adani Nurfathurahmi, I. Taufik, P. Aditiawati, Nasukha Yusuf, R. Aulia

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引用次数: 14

Abstract

The use of close aquaculture system including Recirculation Aquaculture System (RAS) has been implemented to allow a more stable water quality, good hygiene and efficient use of water resources in wide shrimp aquaculture production. This study aims to optimize shrimp stocking density and to evaluate microbial community profile in super-intensive culture of Pacific white shrimp (Litopenaeus vannamei) using RAS technology at low salinity. Before stocking, post larvae shrimp was gradually acclimatized from salinity level of 32 ppt to 5 ppt within 14 days. Different stocking density of 500 PL/m3, 750 PL/m3 and 1,000 PL/m3 were tested in four replicates. During 84 days grow out period, no differences in water quality parameters were observed. At the end of grow out period, significant differences were found in final body weight (14.87 ± 0.24 g, 13.09 ± 0.78 g, 11.32 ± 0.71 g), survival (70 ± 1.42%, 53.67 ± 4.16%, 44 ± 1.35%), specific growth rate (7.12%BW/day, 6.95% BW/day, 6.79% BW/day), and feed conversion ratio (1.32 ± 0.09, 1.45 ± 0.16, 2.05 ± 0.24) for the 500 PL/m3, 750 PL/m3, and 1,000 PL/m3 treatment group, respectively. However, similar total productivity of 5.20 kg/m3, 5.24 kg/m3, and 4.99 kg/m3 was observed for 500 PL/m3, 750 PL/m3, and 1,000 PL/m3 treatment group, respectively. The implementation of RAS can allow a stable community structure of culturable bacteria even at high shrimp density of up to 1,000 PL/m3, with the observed bacterial abundance of 1.28 × 103 to 5.28 × 104 CFU/mL and 9.49 × 104 to 2.27 × 106 CFU/mL in shrimp and culture water, respectively. It is suggested that the application of RAS at the optimal shrimp density of 500 PL/m3 allowed a high shrimp culture productivity of up to 5.20 kg/m3 within 84 days grow out period.

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室内循环水养殖系统在凡纳滨对虾(Litopenaeus vannamei)低盐度超集约养殖中的应用

采用包括循环水养殖系统(RAS)在内的封闭式养殖系统，使宽虾养殖生产的水质更稳定，卫生条件好，水资源得到有效利用。本研究旨在利用RAS技术优化低盐度条件下凡纳滨对虾(Litopenaeus vannamei)的放养密度和微生物群落特征。放养前，仔虾在14 d内由32 ppt逐渐适应到5 ppt。分别在500 PL/m3、750 PL/m3和1000 PL/m3的不同放养密度下进行4个重复试验。在84 d的生长期内，水质参数未见差异。生长期结束时，500 PL/m3、750 PL/m3和1000 PL/m3处理组的末重(14.87±0.24 g、13.09±0.78 g、11.32±0.71 g)、成活率(70±1.42%、53.67±4.16%、44±1.35%)、特定生长率(7.12%BW/d、6.95% BW/d、6.79% BW/d)和饲料系数(1.32±0.09、1.45±0.16、2.05±0.24)差异显著。然而，500 PL/m3、750 PL/m3和1000 PL/m3处理组的总产量分别为5.20 kg/m3、5.24 kg/m3和4.99 kg/m3。RAS的实施即使在虾密度高达1000 PL/m3的情况下也能保持稳定的可培养细菌群落结构，观察到虾和培养水中的细菌丰度分别为1.28 × 103 ~ 5.28 × 104 CFU/mL和9.49 × 104 ~ 2.27 × 106 CFU/mL。综上所述，在500 PL/m3的最佳对虾密度下施用RAS，在84 d的生长期内，对虾养殖产量可达5.20 kg/m3。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Aquaculture Research and Development

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