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| 高盐碱环境下大口黑鲈幼鱼生长性能、血液生理指标与质构特征研究 |
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逯冠政1, 么宗利2, 来琦芳2, 高鹏程2, 周凯2, 朱浩拥3, 刘一萌2, 孙真2
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1.江苏海洋大学 江苏省海洋生物技术重点建设实验室 江苏 连云港 222052;2.中国水产科学研究院东海水产研究所 农业农村部低洼盐碱地水产养殖重点实验室 中国水产科学研究院盐碱水域渔业工程技术研究中心(上海) 上海 200090;3.江苏中洋集团股份有限公司 江苏 南通 226000
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| 摘要: |
| 盐碱水在世界范围内广泛分布,高碳酸盐碱度、高pH等是盐碱水制约养殖生物生存生长的关键因子。作为潜在的经济养殖对象,大口黑鲈(Micropterus salmoides)已在部分盐碱水域养殖成功,但其对盐碱的适应范围尚不清楚。本文研究了高盐碱环境下大口黑鲈生长性能,测定了大口黑鲈48 h碳酸盐碱度半致死浓度,设置盐水组[SW,盐度为7.50±0.07,碳酸盐碱度为(1.81± 0.12) mmol/L]、碱水组[AW,盐度为0.35±0.02,碳酸盐碱度为(9.96±0.03) mmol/L]和淡水对照组[FW,盐度为0.13±0.01,碳酸盐碱度为(1.82±0.11) mmol/L],对比研究大口黑鲈长期盐碱胁迫下生长指标、血液生理指标、肌肉质构特性指标。结果显示,大口黑鲈48 h碳酸盐碱度半致死浓度为(29.92± 3.90) mmol/L,能够在盐度10以下的水环境中安全存活;经过105 d养殖实验,FW、SW以及AW组存活率和终末体重无显著性差异;3组特定生长率(SGR)表现为波动式变化规律,15~45 d、60~75 d时,SGR持续降低,45~60 d、75~90 d时,SGR持续增高;肥满度FW组最高,SW组最低,AW组居中,但均小于3;在碱度为10 mmol/L的水环境中,24 h内血氨变化表现为先升高后降低,最后趋于稳定,在盐度为7的水环境中,渗透压维持在(319.53±29.51) mOsm/kg,淡水环境下的渗透压维持在(300.00±16.44) mOsm/kg,均保持较好的存活率;盐碱水养殖大口黑鲈在盐水组表现出较好的肌肉硬度[(34.70±4.86) N],碱水组则表现出较好肌肉弹性[(1.06±0.10) mm]。综上所述,大口黑鲈能够适应高盐碱环境,在盐度为7、碱度为10 mmol/L的盐碱水中养殖,并且表现出较好的质构特征。 |
| 关键词: 碳酸盐碱度 盐度 大口黑鲈 生长指标 血氨 质构特性 |
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| Growth performance, blood parameters and texture characteristics of juvenile largemouth bass (Micropterus salmoides) exposed to highly saline-alkaline water |
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LU Guanzheng1, YAO Zongli2, LAI Qifang2, GAO Pengcheng2, ZHOU Kai2, ZHU Haoyong3, LIU Yimeng2, SUN Zhen2
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1.Jiangsu Ocean University, Jiangsu Provincial Key Laboratory of Marine Biotechnology, Lianyungang, Jiangsu 222052, China;2.East China Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, Key Laboratory of Saline-Alkaline
Aquaculture, Ministry of Agriculture and Rural Affairs, Saline-Alkaline Water Fisheries Engineering Technology Research Center (Shanghai), Shanghai 200090, China;3.Jiangsu Zhongyang Group Co., Ltd, Nantong, Jiangsu 226000, China
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| Abstract: |
| The total saline-alkaline land area in China is approximately 99.1 million hectares, distributed throughout northern China, coastal areas, and areas along the bank of the Yellow River. About 45.9 million hectares of saline-alkaline water areas are distributed around these lands, most of which are athalassic saline water characterized by high pH and high carbonate alkalinity concentrations with various types of ion imbalances. The co-effect of high pH and high carbonate alkalinity would directly lead to the respiratory alkalosis of aquatic organisms. High pH affects the excretion of ammonia, resulting in increased blood ammonia and acid-base imbalance. High ionic coefficient affects the osmotic regulation and breaks the ion balance in aquatic organisms. Thus, saline-alkaline water has not been fully used because of its stressful environmental characteristic. Currently, the lack of suitable objects for the saline-alkaline aquaculture restricts the development of the aquaculture industry on saline-alkaline land. Largemouth bass (Micropterus salmoides) is a potential economic target that has been successfully farmed in some saline-alkaline waters. However, largemouth bass's tolerance range and response mechanism to saline-alkaline water are still unclear. This study evaluated the growth performance of juvenile largemouth bass in a saline-alkaline environment to propose excellent farming species for saline-alkaline aquaculture. First, the juvenile largemouth bass response to 48 h carbonate alkalinity and 96 h semi-lethal salinity was determined. Hereafter, the saltwater group [SW, salinity of 7.50±0.07, and carbonate alkalinity of (1.81±0.12) mmol/L], alkaline water group [AW, salinity of 0.35±0.02, and carbonate alkalinity of (9.96±0.03) mmol/L], and freshwater control group [FW, salinity of 0.13±0.01, and carbonate alkalinity of (1.82±0.11) mmol/L] were set to comparatively study the growth parameters, physiology parameters, and muscle texture characteristic indexes of largemouth bass under long-term saline-alkaline stress. For the growth experiment, largemouth basses were acclimated to and reared in FW, SW, and AW conditions for 105 days. Triplicate of 30 individuals each were set for each condition using an experimental plastic tank with 100 L of water. Each fish's body length and weight were measured every 15 days after being anesthetized with MS-222. For the physiology parameters study, five largemouth basses were randomly selected from each group at the end of the growth experiment. The fish were anesthetized with MS-222 to draw 20 μL of blood from the tail vein using a syringe moistened with lithium heparin, which was immediately centrifugated to measure osmolality. Another 30 largemouth basses were taken and subjected to 24 h carbonate alkalinity stress. The experimental conditions were the same as AW group, and the control group was the same as FW group. During the stress period, feeding was stopped, and blood was drawn from five randomly selected fish every 6 h and centrifuged immediately to determine blood ammonia (blood ammonia kit A086-1-1 by Nanjing Jiancheng). Plasma osmolality was measured using an osmometer (Wescor Vapro 5520 Vapor Pressure Osmometer, USA). For the muscle texture characteristic index study, five largemouth basses were randomly selected from each group at the end of the growth experiment. After being anesthetized with MS-222, the muscles on the fish's backside (3.01±0.14) g were taken by using a surgical scalpel and scissors, the muscles' outer skin was cut off, and the sampled muscle sizes were standardized to (2.04±0.12) cm3. After sampling, the TMS-Pro texture analyzer (Food Technology Corporation, USA) was used to measure the muscle texture characteristics, employing the TPA mode, test speed of 30 mm/min, deformation amount of 50%, and return distance of 30 mm. The results showed that in the 48 h carbonate alkalinity group, the semi-lethal concentration was (29.92± 3.90) mmol/L, while the fish could survive safely in water with salinity below 10 mmol/L. After 105 days of farming, there are no significant differences in the survival rate and final weight among different groups, in which the specific growth rate (SGR) showed a regular variation. During 15~45 days and 60~75 days, SGR decreased continuously, while it increased during 45~60 days and 75~90 days. The condition factors of the largemouth bass were less than 3 in all groups, with an increase from FW to AW and from AW to SW groups. In the AW group, the blood ammonia within 24 h showed an increase, then a decreased, and finally stabilized. In the SW group, the osmolality was (319.53±29.51) mOsm/kg, lower than the (300.00±16.44) mOsm/kg observed for the FW group. Largemouth bass raised in saline-alkaline water had better texture characteristics. Largemouth bass raised in SW group had a higher muscle hardness of (34.70±4.86) N, while a higher springiness of (1.06±0.10) mm was observed in the AW group. In summary, the largemouth bass could adapt to the relatively high saline-alkaline environment and be cultured in typical saline-alkaline water with pH from 8.84 to 8.89, carbonate alkalinity from 9.89 to 10.31 mmol/L, salinity from 6.68 to 7.21, showing good muscle quality characteristics with high muscle hardness and springiness. The success of largemouth bass in saline-alkaline water aquaculture has provided an opportunity to promote the aquaculture of this fish in a saline-alkaline stressful environment, providing the theoretical basis for the mechanisms involved in this adaptation process. Our study will broaden the scope of aquaculture in saline-alkaline water, improving the economic benefits and providing the basic parameters for the quality evaluation of fish in saline-alkaline fisheries. |
| Key words: Carbonate alkalinity Salinity Largemouth bass Growth index Blood ammonia Texture characteristics |
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