Growth Characteristics of Largemouth Bass Micropterus salmoides Cultured in Land-Based Container with Recycling Water
JIA Songpeng1,2, WANG Lei1,2, XU Shuangyang1,2, WANG Haoran1,2, CHENG Tao3, WANG Yong3, LIANG Zhongjun3, SHANG Qinlei3, QIAO Zhigang1,2, LI Xuejun1,2
1.College of Fisheries, Henan Normal University, Xinxiang 453002, China; 2.Engineering Technology Reasearch Center of Henan Province for Aquatic Animal Cultivation, Xinxiang 453002, China; 3.Xinxiang High-Tech Rural Agriculture Development Co., Ltd., Xinxiang 453002, China
Abstract:This article explored the growth characteristics of largemouth bass Micropterus salmoides in aquaculture system using land-based container with recycling water from May 1, 2020 for 180 days, and 30 fish were randomly collected from each container on the 30th, 60th, 90th, 120th, 150th and 180th days of the experiment. The fish was fed a special puffed compound feed at water temperature varying from 14.3 to 30.8 ℃, ammonia nitrogen level from 0 to 0.077 mg/L, nitrite nitrogen level from 0 to 0.089 mg/L, pH from 7.2 to 8.6, and dissolved oxygen level from 5.12 to 8.25 mg/L. The largemouth bass had initial average body weight of 31.75 g, the initial average body length of 12.15 cm, and the breeding density of 50 tail/m3. At the end of the experiment, the largemouth bass had average body weight of 369.15 g, the average body length of 24.24 cm, the average specific growth rate of body weight of 0.41%/d, the average body length specific growth rate of 0.11%/d, and the average daily growth of body length of 0.072 cm. The power function relationship between body weight (m) and body length (L) was described as m=0.0054L3.5153 (r2 =0.9928), with the b of 3.5153. The findings showed that the largemouth bass grew normally under the aquaculture system using land-based container with recycling water, which provides a reference for largemouth bass aquaculture system using land-based container with recycling water.
[1]何明,喻一峰,李小勤,等.大口黑鲈饲料中发酵豆粕营养价值的评定[J].动物营养学报,2020,32(10):4943-4955. [2]韩晓磊,王浩,高俊杰,等.工厂化循环水养殖条件下大口黑鲈生长特点分析[J].水产科学,2020,39(4):567-572. [3]白俊杰,李胜杰.我国大口黑鲈产业现状分析与发展对策[J].中国渔业经济,2013,31(5):104-108. [4]童心雨,姜森颢,葛宝明,等.我国池塘养殖业发展现状与对策[J].中国农业科技导报,2020,22(8):5-13. [5]宋超,孟顺龙,范立民,等.中国淡水池塘养殖面临的环境问题及对策[J].中国农学通报,2012,28(26):89-92. [6]陈学洲,舒锐,谢骏,等.“集装箱+生态池塘”集约养殖与尾水高效处理技术[J].中国水产,2020(8):67-70. [7]王磊,胡玉洁,李学军,等.陆基推水集装箱式水产养殖模式适养种类初探[J].中国水产,2019(11):61-63. [8]朱泽闻,舒锐,谢骏.集装箱式水产养殖模式发展现状分析及对策建议[J].中国水产,2019(4):28-30. [9]柳鹏,高春山,杜晓燕,等.中国东北山区虹鳟三倍体幼鱼生长特性研究[J].大连海洋大学学报,2020,35(2):213-217. [10]严俊丽,陈四清,王贞杰,等.基于工厂化养殖的圆斑星鲽生长初步研究[J].渔业现代化,2017,44(1):15-20. [11]张建明,姜华,田甜,等.齐口裂腹鱼苗种培育及其苗种生长特性分析[J].南方农业学报,2019,50(9):2102-2110. [12]刘晓勇,齐茜,麦丽开,等.四种引进鲟幼鱼的培育及生长特性[J].水产学杂志,2013,26(3):13-16. [13]YU A, WANG X L, ZUO Z H, et al. Tributyltin exposure influences predatory behavior, neurotransmitter content and receptor expression in Sebastiscus marmoratus[J].Aquatic Toxicology,2013,128/129:158-162. [14]徐嘉波,税春,施永海,等.池养美洲鲥1+龄鱼种生长特性的研究[J].上海海洋大学学报,2018,27(1):55-63. [15]HARRIS J E, NEWLON C, HOWELL P J, et al. Modelling individual variability in growth of bull trout in the Walla Walla River Basin using a hierarchical von Bertalanffy growth model[J].Ecology of Freshwater Fish,2018,27(1):103-115. [16]ENIN U I. Length-weight parameters and condition factor of two West African prawns[J]. Revue Dhydrobiologie Tropicale,1994,27:121-127. [17]WOOTTON R J. Fish ecology: tertiary level biology[M]. London: Blackie Academic & Professional,1992:212. [18]鲁宏申,刘建魁,王云山,等.达氏鳇1龄幼鱼生长特性的初步研究[J].水生态学杂志,2011,32(5):78-82. [19]赵晓临,徐浩然,孙玉芝,等.哲罗鱼稚、幼鱼在不同温度下的生长特性[J].水产学杂志,2018,31(5):1-5. [20]邓平平,施永海,徐嘉波,等.金钱鱼当年鱼种室内养殖生长特性研究[J].浙江海洋大学学报(自然科学版),2019,38(6):517-522. [21]祖岫杰,刘艳辉,李改娟,等.二龄拉氏鱥在池塘养殖条件下的生长特性[J].渔业现代化,2015,42(4):26-29. [22]BAUM D, LAUGHTON R, ARMSTRONG J D, et al. The effect of temperature on growth and early maturation in a wild population of Atlantic salmon parr[J].Journal of Fish Biology,2005,67(5):1370-1380. [23]IWATA N, KIKUCHI K, HONDA H, et al. Effects of temperature on the growth of Japanese flounder[J].Fisheries Science,1994,60(5):527-531. [24]BESSON M, VANDEPUTTE M, VAN ARENDONK J A M, et al. Influence of water temperature on the economic value of growth rate in fish farming:the case of sea bass (Dicentrarchus labrax) cage farming in the Mediterranean[J].Aquaculture,2016,462:47-55. [25]XIE X J, RUYUNG S. The bioenergetics of the southern catfish (Silurus meridionalis Chen):growth rate as a function of ration level, body weight, and temperature[J].Journal of Fish Biology,1992,40(5):719-730. [26]AN M I, CHOI C Y. Activity of antioxidant enzymes and physiological responses in ark shell, Scapharca broughtonii, exposed to thermal and osmotic stress:effects on hemolymph and biochemical parameters[J].Comparative Biochemistry and Physiology Part B:Biochemistry and Molecular Biology,2010,155(1):34-42. [27]李大鹏,庄平,严安生,等.施氏鲟幼鱼摄食和生长的最适水温[J].中国水产科学,2005,12(3):294-299. [28]谢刚,叶星,许淑英,等.池养广东鲂仔、稚鱼的生长和食性[J].水产科技情报,2000,27(6):246-250. [29]苏友禄,刘婵,邓益琴,等.罗非鱼无乳链球菌病的研究进展[J].大连海洋大学学报,2019,34(5):757-766. [30]DÍAZ F, RE A D, GONZÁLEZ R A, et al. Temperature preference and oxygen consumption of the largemouth bass Micropterus salmoides (Lacépède) acclimated to different temperatures[J].Aquaculture Research,2007,38(13):1387-1394. [31]欧阳力剑,郭学武.温度对鱼类摄食及生长的影响[J].海洋科学集刊,2009,49(1):87-95.