泥蚶动态能量收支模型参数的测定

doi:10.16378/j.cnki.1003-1111.21091

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摘要以泥蚶为试验对象,测定动态能量收支模型的6个关键基本参数。采用贝类壳长与软体组织湿质量回归拟合计算泥蚶形状系数;通过循环水控温法测定10、15、20、25、30、35 ℃ 6个温度条件下泥蚶干质量耗氧率,计算阿伦纽斯温度;通过连续测定泥蚶饥饿过程中软体部干质量和耗氧率的变化,计算形成单位体积结构物质所需的能量、单位时间单位体积维持生命所需的能量、单位体积最大储存能量和储备能量。试验结果表明,泥蚶壳长(L)与软体部湿质量(m_W)回归分析呈幂函数关系:m_W =0.0556L^3.1831(r²=0.9256),形状系数δ_m=0.405。泥蚶阿伦纽斯温度为(4830±586) K。泥蚶饥饿试验计算得知:泥蚶单位体积所需能量和单位体积最大储存能分别为5475 J/cm³和2026 J/cm³;泥蚶维持生命所需的能量为32.2 J/(cm³·d);储备能量为23 376 J/g。试验结果可为泥蚶动态能量收支模型的构建提供数据支撑,并为进一步利用动态能量收支模型指导贝类养殖生产和渔业管理和养殖容量评估奠定基础。

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关键词 ：泥蚶, 动态能量收支, 动态能量收支模型, 贝类代谢

Abstract：In this paper, six key parameters for the dynamic energy budget (DEB) model were obtained in mud cockle Tegillarca granosa with shell length of 1.848—3.902 cm and soft part of 0.755—1.466 g in a laboratory, including shape coefficient (δ_m) estimated by a method of line regression of shell length and soft tissue wet weight of mud cockle, and Arrhenius temperature (T_A) estimated by a method of measuring the dry weight oxygen consumption rate of mud cockle at watert temperature of 10 ℃, 15 ℃, 20 ℃, 25 ℃, 30 ℃, and 35 ℃. The another key parameters, such as volume-specific costs for growth ([E_G]), volume-specific maintenance costs per unit of time ([P·_M]), maximum storage density ([E_M]) and reserve energy μ_E were estimated by measuring the oxygen consumption rate and changes in dry tissue weight of mud cockle. The results showed that the cubic functional relations between shell length (L) and soft part wet weight (m_M) was expressed as m_M=0.0556L^3.1831 (r²=0.9256), with linear regression between cube root of the shell length and the wet weight of the soft body, the slope as the shape coefficient (δ_m=0.405) and with T_A of (4830±586) K. The starvation test for 35 days revealed that dry flesh weight of mud cockle was maintained at 0.3 g, and soft organic matter was decreased from 87.3％ to 77.7％, with [E_G] of 5475 J/cm³ and [E_M] of 2026 J/cm³. After 49 days, dry flesh weight was found to be decreased by 41.2％ and oxygen consumption rate to be decreased by 75.2％. Meanwhile, the oxygen consumption rate was de- creased from 0.89 mg/(g·h) to 0.22 mg/(g·h), and [P·_M] was estimated to be 32.2 J/(cm³·d). The reserve energy was described as the ratio of the maximum energy storage per unit volume to the difference between the initial dry weight and the final dry weight, and was 23 376 J/g. The finding provides data support for the construction of a dynamic energy budget model for mud cockle, and lays a foundation for further use of dynamic energy budget model to guide shellfish production, fishery management and aquaculture capacity assessment.

Key words： Tegillarca granosa dynamic energy budget dynamic energy budget model shellfish metabolism

收稿日期: 2021-05-20

PACS:

S968.31

基金资助:国家重点研发计划项目(2020YFD0900802);财政部和农业农村部国家现代农业产业技术体系资助项目;浙江省重点研发计划项目(2019C02054).

通讯作者: 何琳(1984—),男,副教授;研究方向:生态养殖. E-mail:hlwithyou@qq.com.

作者简介: 姜波(1996—),男,硕士研究生;研究方向:生态养殖. E-mail:865768876@qq.com

引用本文:

姜波, 何京, 郑侠飞, 何琳, 林志华. 泥蚶动态能量收支模型参数的测定[J]. 水产科学, 2023, 42(1): 57-64.
JIANG Bo, HE Jing, ZHENG Xiafei, HE Lin, LIN Zhihua. Estimation of Dynamic Energy Budget (DEB) Model Parameters for Mud Cockle Tegillarca granosa. Fisheries Science, 2023, 42(1): 57-64.

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http://www.shchkx.com/CN/10.16378/j.cnki.1003-1111.21091 或 http://www.shchkx.com/CN/Y2023/V42/I1/57

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