Influence of net cages on water quality and trophic status of Lake Victoria, Kenya: The case of Kadimu Bay

Q3 Environmental Science

Lakes and Reservoirs: Research and Management Pub Date : 2023-04-10 DOI:10.1111/lre.12432

Sellu Mawundu, Riziki Walumona Jacques, David Mbeva Liti, John Ouko, Achieng Alfred, Adiang’ Evans, Boaz Kaunda-Arara

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Abstract

Water quality is a critical component regulating ecosystem functioning in aquatic habitats, requiring regular monitoring for sustainable ecosystem services. Cage fish farming has the potential to affect water quality because of its rapid increase in many African waterbodies in response to dwindling wild fish stocks. Thus, there is a need for more studies to guide sustainable cage aquaculture in African lakes and reservoirs. This study evaluated the possible effects of cage farming of Nile tilapia (Oreochromis niloticus) on water quality parameters and the trophic state of Kadimu Bay, Lake Victoria, Kenya. Sampling for physicochemical and biological variables, including nutrient load, was conducted from January to October 2021, at five fish cage sites and a control site within the bay. In situ measurements of physical variables were undertaken in the field, while analysis of water samples for nutrient loads, biological and chemical variables was undertaken in the laboratory, following the methods described in APHA (American public health association standard methods for the examination of water and waste water. APHA-AWWA-WEF, 2005). The Carlson's Trophic State Index (CTSI) was used to classify the trophic state of the cage sites, while the total nitrogen:total phosphorus (TN:TP) ratio was used to determine the primary productivity limiting nutrient in the bay. The study results indicated electrical conductivity was significantly lower at the control (97.53 ± 4.17 μS/cm), compared to cage sites (105.42 ± 5.32 μS/cm at the Utonga cage site to 112.84 ± 1.94 μS/cm at the Oele cage site), indicating water of relatively lower quality at the cage sites. Similarly, the nitrite concentrations were higher at cage sites (6.35 ± .96 μg/L at the Uwaria cage site to 3.16 ± 2.25 μg/L at the Utonga cage site), and lower at the control site (2.68 ± 1.39 μg/L). In all, 14 physicochemical variables did not vary significantly between the cage and control sites, with nine variables (temperature, turbidity, electrical conductivity, total suspended solids, particulate organic matter, chlorophyll-a, TP, nitrate and TN) being within the recommended thresholds for aquatic life processes. The bay was evaluated as being in a light eutrophic state, indicating moderate influence of the fish cages on the trophic state of the sites. There was a moderate relationship between chlorophyll-a and TP concentration at the sampling sites (R² = .50), compared to a stronger relationship with ${NO}_{3}^{-}$ (R² = .78). The TN:TP ratios were <10 at the sampling sites, indicating nitrogen was the limiting factor for primary production in the bay. The calculated CTSI suggests that the bay exhibited a light eutrophic state. Overall, although the results of this study showed cage aquaculture is not a current challenge to the water quality of the bay, regular monitoring is nevertheless recommended to inform sustainable aquaculture development in the bay and lake.

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网箱对肯尼亚维多利亚湖水质和营养状况的影响——以卡迪姆湾为例

水质是调节水生栖息地生态系统功能的关键组成部分，需要定期监测可持续的生态系统服务。网箱养殖有可能影响水质，因为许多非洲水体因野生鱼类种群减少而迅速增加。因此，有必要进行更多的研究，以指导非洲湖泊和水库的可持续网箱养殖。本研究评估了尼罗罗非鱼（Oreochromis niloticus）网箱养殖对肯尼亚维多利亚湖卡迪穆湾水质参数和营养状态的可能影响。2021年1月至10月，在海湾内的五个鱼笼点和一个对照点进行了物理化学和生物变量的采样，包括营养负荷。物理变量的现场测量是在现场进行的，而营养负荷、生物和化学变量的水样分析是在实验室进行的，遵循APHA（美国公共卫生协会水和废水检测标准方法。APHA-AWWA-WEF，2005）中描述的方法。卡尔森营养状态指数（CTSI）用于对网箱位置的营养状态进行分类，而总氮：总磷（TN:TP）比率用于确定海湾中的初级生产力限制营养素。研究结果表明，对照组的电导率明显较低（97.53 ± 4.17 μS/cm），而笼位（105.42 ± 5.32 μS/cm至112.84 ± 1.94 μS/cm），表明网箱部位的水质相对较低。同样，笼子部位的亚硝酸盐浓度较高（6.35 ± .96 μg/L至3.16 ± 2.25 μg/L），对照组更低（2.68 ± 1.39 μg/L）。总的来说，14个物理化学变量在网箱和对照地点之间没有显著差异，其中9个变量（温度、浊度、电导率、总悬浮固体、颗粒有机物、叶绿素a、TP、硝酸盐和TN）在水生生物过程的推荐阈值内。该海湾被评估为轻度富营养化状态，表明网箱对该地点的营养状态有中度影响。采样点的叶绿素a和TP浓度之间存在中度关系（R2 = .50），而与NO 3−$$｛\mathrm｛NO｝｝_3^｛-｝$$（R2 = .78）。TN:TP比值为<；10，表明氮是海湾初级生产的限制因素。计算的CTSI表明该海湾呈现轻度富营养化状态。总的来说，尽管这项研究的结果表明，网箱养殖目前对海湾水质没有挑战，但建议定期监测，为海湾和湖泊的可持续水产养殖发展提供信息。

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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来源期刊

Lakes and Reservoirs: Research and Management Environmental Science-Water Science and Technology

CiteScore

2.40

自引率

0.00%

发文量

期刊介绍： Lakes & Reservoirs: Research and Management aims to promote environmentally sound management of natural and artificial lakes, consistent with sustainable development policies. This peer-reviewed Journal publishes international research on the management and conservation of lakes and reservoirs to facilitate the international exchange of results.