Muhammad Amjad Yaqoob , Xiyu Yang , Zhenming Zhang , Jiakai Liu
{"title":"Nonclassical Biomanipulation: PROS and CONS","authors":"Muhammad Amjad Yaqoob , Xiyu Yang , Zhenming Zhang , Jiakai Liu","doi":"10.1016/j.wsee.2024.10.005","DOIUrl":null,"url":null,"abstract":"<div><div>Physical, chemical, and biological techniques can be used to manage eutrophication, a global environmental hazard that might worsen. Biomanipulation is an eco-friendly, cost-effective, and potentially profitable technology for ecological restoration. This review contrasts nonclassical biomanipulation, which uses planktivorous fish to reduce algal blooms, with classical biomanipulation, which employs piscivorous fish to indirectly increase zooplankton populations to manage eutrophication. Owing to certain challenges associated with classical biomanipulation, including the elimination of planktivorous fish, the increase in the number of macrophytes, and the decrease in phosphorus (internal as well as external), preference is given to nonclassical biomanipulation. In tropical lakes with high productivity, where reducing the concentration of nutrients is nearly impossible, nonclassical biomanipulation can also be utilized to control algal blooms. In both lakes and confined water bodies, nonclassical biomanipulation altered the phytoplankton composition at the beginning of the experiment. Using nonclassical biomanipulation, 63% of the 30 studies we reviewed revealed that phytoplankton were successfully controlled. In Lakes Donghu and Qiandaohu, two planktivorous fish, <em>Hypophthalmichthys molitrix</em> and <em>Hypophthalmichthys nobilis nobilis</em>, effectively suppressed Microcystis blooms. However, <em>H. molitrix</em> and <em>H. nobilis</em> are useful for controlling eutrophic environments that do not contain enough macrozooplankton. When large herbivorous zooplankton are unable to effectively suppress nuisance algal blooms, nonclassical biomanipulation has been proven to be an effective strategy; however, it is useless when nanophytoplankton species are blooming organisms. Furthermore, experiments are needed to fully understand the effectiveness of this technique, as environmental parameters such as region and season strongly impact the behavior of water bodies.</div></div>","PeriodicalId":101280,"journal":{"name":"Watershed Ecology and the Environment","volume":"6 ","pages":"Pages 270-276"},"PeriodicalIF":0.0000,"publicationDate":"2024-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Watershed Ecology and the Environment","FirstCategoryId":"1085","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S2589471424000226","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Physical, chemical, and biological techniques can be used to manage eutrophication, a global environmental hazard that might worsen. Biomanipulation is an eco-friendly, cost-effective, and potentially profitable technology for ecological restoration. This review contrasts nonclassical biomanipulation, which uses planktivorous fish to reduce algal blooms, with classical biomanipulation, which employs piscivorous fish to indirectly increase zooplankton populations to manage eutrophication. Owing to certain challenges associated with classical biomanipulation, including the elimination of planktivorous fish, the increase in the number of macrophytes, and the decrease in phosphorus (internal as well as external), preference is given to nonclassical biomanipulation. In tropical lakes with high productivity, where reducing the concentration of nutrients is nearly impossible, nonclassical biomanipulation can also be utilized to control algal blooms. In both lakes and confined water bodies, nonclassical biomanipulation altered the phytoplankton composition at the beginning of the experiment. Using nonclassical biomanipulation, 63% of the 30 studies we reviewed revealed that phytoplankton were successfully controlled. In Lakes Donghu and Qiandaohu, two planktivorous fish, Hypophthalmichthys molitrix and Hypophthalmichthys nobilis nobilis, effectively suppressed Microcystis blooms. However, H. molitrix and H. nobilis are useful for controlling eutrophic environments that do not contain enough macrozooplankton. When large herbivorous zooplankton are unable to effectively suppress nuisance algal blooms, nonclassical biomanipulation has been proven to be an effective strategy; however, it is useless when nanophytoplankton species are blooming organisms. Furthermore, experiments are needed to fully understand the effectiveness of this technique, as environmental parameters such as region and season strongly impact the behavior of water bodies.
富营养化是一种可能恶化的全球环境危害,可利用物理、化学和生物技术进行治理。生物操纵是一种生态友好、成本效益高、潜在利润丰厚的生态修复技术。本综述将非经典生物操纵与经典生物操纵进行对比,前者利用食板鱼减少藻类大量繁殖,后者则利用食鱼间接增加浮游动物数量来治理富营养化。由于传统生物操纵法面临某些挑战,包括消除浮游鱼类、增加大型浮游植物数量以及减少磷(内磷和外磷),因此人们更倾向于采用非典型生物操纵法。在生产力较高的热带湖泊中,降低养分浓度几乎是不可能的,因此也可以利用非经典生物操纵来控制藻类大量繁殖。在湖泊和封闭水体中,非经典生物操纵都会在实验开始时改变浮游植物的组成。在我们查阅的 30 项研究中,有 63% 的研究表明使用非经典生物操纵成功控制了浮游植物。在东湖和千岛湖,两种板食性鱼类(Hypophthalmichthys molitrix 和 Hypophthalmichthys nobilis nobilis)有效抑制了微囊藻的繁殖。然而,H. molitrix 和 H. nobilis 可用于控制大型浮游动物数量不足的富营养化环境。当大型食草浮游动物无法有效抑制有害藻华时,非经典生物操纵已被证明是一种有效的策略;然而,当纳米浮游生物物种成为藻华生物时,这种策略就无能为力了。此外,由于地区和季节等环境参数对水体的行为有很大影响,因此需要进行实验才能充分了解这种技术的有效性。