Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae

Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae

This study aimed to seek for the optimal condition for small-scale larviculture of red seabream Pagrus major larvae. We examined the effects of tank shapes and aerations, which were assumed to influence the larval survival, growth and swim bladder inflation of P. major larvae. Seawater (50-l) was fi...

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Bibliographic Details
Main Authors: Aung Naing Win, Wataru Yamazaki, Tetsuya Sumida, Atsushi Hagiwara, Yoshitaka Sakakura
Format: Article
Language:English
Published: Elsevier 2020-11-01
Series:Aquaculture Reports
Subjects:
Red seabream
Tank shape
Aeration
Survival
Flow field
Online Access:http://www.sciencedirect.com/science/article/pii/S235251342030541X
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spelling doaj-5e824db42f26493ea5a259ec217f081d2020-11-25T03:51:32ZengElsevierAquaculture Reports2352-51342020-11-0118100451Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae Aung Naing Win0Wataru Yamazaki1Tetsuya Sumida2Atsushi Hagiwara3Yoshitaka Sakakura4Graduate School of Fisheries and Environmental Sciences, Nagasaki University, 1-14 Bunkyo-machi, Nagasaki, 852-8521, JapanDepartment of Mechanical Engineering, Nagaoka University of Technology, Niigata, 940-2188, JapanShipping Technology Department, National Institute of Technology, Oshima College, Yamaguchi, 742-2193, JapanGraduate School of Fisheries and Environmental Sciences, Nagasaki University, 1-14 Bunkyo-machi, Nagasaki, 852-8521, JapanGraduate School of Fisheries and Environmental Sciences, Nagasaki University, 1-14 Bunkyo-machi, Nagasaki, 852-8521, Japan; Corresponding author at: Graduate School of Fisheries and Environmental Sciences, Nagasaki University, 1-14 Bunkyo-machi, Nagasaki, 852-8521, Japan.This study aimed to seek for the optimal condition for small-scale larviculture of red seabream Pagrus major larvae. We examined the effects of tank shapes and aerations, which were assumed to influence the larval survival, growth and swim bladder inflation of P. major larvae. Seawater (50-l) was filled into three cylindrical (CT: 1.7 × 103 cm2 water surface area, 30 cm deep) and six rectangular (RT: 1.8 × 103 cm2 water surface area, 28 cm deep) tanks. One air stone with 100 ml/min aeration rate was set at the bottom center of three CT and RT (RT1AS), and two air stones with 50 ml/min aeration rate were set at the half bottom center of three RT (RT2AS). Five hundred eggs were distributed into each experimental tank. Rotifers were fed to larvae at 10 individuals/mL on 3 days post hatching (dph) and their distribution in tanks were measured. Survival rate at 14 dph in CT (54.7 ± 11.0 %) and RT1AS (55.3 ± 6.0 %) were significantly higher than that in RT2AS (29.6 ± 9.3 %, p < 0.05). However, the growth of larvae was not significantly different between tank shapes and aerators. Swimbladder inflation rates were not different between tank shapes and aerations, however, CT (58.9±28.3 %) showed lower trend (RT1AS 94.4±6.9 %, RT2AS 92.2±10.7 %). Rotifer distribution in tanks was higher at tank bottom (p < 0.05). Low flow regions were observed along the side walls of the tanks and bottom areas in CT and RT1AS due to a single-pair vortex system and formed at the center (between air stones) and from the air stone to the tank walls in RT2AS due to two single-pair vortex systems. These low-flow areas were coincided with higher rotifer distribution areas at the tank bottom indicating that measuring rotifer density can estimate the flow in a tank. We recommend the rectangular tank with one air stone system for red seabream larvae.http://www.sciencedirect.com/science/article/pii/S235251342030541XRed seabreamTank shapeAerationSurvivalFlow field
collection DOAJ
language English
format Article
sources DOAJ
author Aung Naing Win
Wataru Yamazaki
Tetsuya Sumida
Atsushi Hagiwara
Yoshitaka Sakakura
spellingShingle Aung Naing Win
Wataru Yamazaki
Tetsuya Sumida
Atsushi Hagiwara
Yoshitaka Sakakura
Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
Aquaculture Reports
Red seabream
Tank shape
Aeration
Survival
Flow field
author_facet Aung Naing Win
Wataru Yamazaki
Tetsuya Sumida
Atsushi Hagiwara
Yoshitaka Sakakura
author_sort Aung Naing Win
title Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
title_short Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
title_full Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
title_fullStr Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
title_full_unstemmed Effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream Pagrus major larvae
title_sort effects of tank shapes and aerations on survival, growth and swim bladder inflation of red seabream pagrus major larvae
publisher Elsevier
series Aquaculture Reports
issn 2352-5134
publishDate 2020-11-01
description This study aimed to seek for the optimal condition for small-scale larviculture of red seabream Pagrus major larvae. We examined the effects of tank shapes and aerations, which were assumed to influence the larval survival, growth and swim bladder inflation of P. major larvae. Seawater (50-l) was filled into three cylindrical (CT: 1.7 × 103 cm2 water surface area, 30 cm deep) and six rectangular (RT: 1.8 × 103 cm2 water surface area, 28 cm deep) tanks. One air stone with 100 ml/min aeration rate was set at the bottom center of three CT and RT (RT1AS), and two air stones with 50 ml/min aeration rate were set at the half bottom center of three RT (RT2AS). Five hundred eggs were distributed into each experimental tank. Rotifers were fed to larvae at 10 individuals/mL on 3 days post hatching (dph) and their distribution in tanks were measured. Survival rate at 14 dph in CT (54.7 ± 11.0 %) and RT1AS (55.3 ± 6.0 %) were significantly higher than that in RT2AS (29.6 ± 9.3 %, p < 0.05). However, the growth of larvae was not significantly different between tank shapes and aerators. Swimbladder inflation rates were not different between tank shapes and aerations, however, CT (58.9±28.3 %) showed lower trend (RT1AS 94.4±6.9 %, RT2AS 92.2±10.7 %). Rotifer distribution in tanks was higher at tank bottom (p < 0.05). Low flow regions were observed along the side walls of the tanks and bottom areas in CT and RT1AS due to a single-pair vortex system and formed at the center (between air stones) and from the air stone to the tank walls in RT2AS due to two single-pair vortex systems. These low-flow areas were coincided with higher rotifer distribution areas at the tank bottom indicating that measuring rotifer density can estimate the flow in a tank. We recommend the rectangular tank with one air stone system for red seabream larvae.
topic Red seabream
Tank shape
Aeration
Survival
Flow field
url http://www.sciencedirect.com/science/article/pii/S235251342030541X
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