老鹳河大型底栖无脊椎动物群落结构特征及其水质评价

doi:10.14088/j.cnki.issn0439-8114.2026.03.011

湖北农业科学 ›› 2026, Vol. 65 ›› Issue (3): 72-77.doi: 10.14088/j.cnki.issn0439-8114.2026.03.011

老鹳河大型底栖无脊椎动物群落结构特征及其水质评价

刘佳璇¹, 丁森², 郝振林¹

1.大连海洋大学水产与生命学院,辽宁大连 116023;
2.中国环境科学研究院环境基准标准与风险评估全国重点实验室,北京 100012

收稿日期:2025-10-09 出版日期:2026-03-25 发布日期:2026-04-09
通讯作者: 郝振林（1980-）,男,山东青岛人,教授,博士,主要从事水产动物繁育及其生理生态学研究,（电子信箱）haozhenlin@dlou.edu.cn。
作者简介:刘佳璇（2002-）,女,辽宁锦州人,在读硕士研究生,研究方向为水生生物多样性保护,（电子信箱）liujx54@163.com。
基金资助:
2025年辽宁省科技重大专项（2025JH1/11700001）

Structural characteristics of the macrozoobenthos community and water quality assessment in the Laoguan River

LIU Jia-xuan¹, DING Sen², HAO Zhen-lin¹

1. College of Fisheries and Life Science, Dalian Ocean University, Dalian 116023, Liaoning, China;
2. State Key Laboratory of Environmental Criteria and Risk Assessment, Chinese Research Academy of Environmental Sciences, Beijing 100012, China

Received:2025-10-09 Published:2026-03-25 Online:2026-04-09

摘要/Abstract

摘要： 为探究老鹳河大型底栖无脊椎动物群落结构特征及其与环境因子的关系,于2024年11—12月对老鹳河8个样点开展调查,运用层次聚类、非度量多维尺度分析（NMDS）和冗余分析（RDA）,并结合生物指数（BI）、生物监测工作组记分（BMWP）及EPT类群指数(EPT)开展水质评价。结果表明,老鹳河中共鉴定出大型底栖无脊椎动物3门34种,以节肢动物门为主。群落空间分布可划分为3组,与人类干扰强度高度一致;上游A组采样点（对照）以EPT等敏感类群为主,群落结构较完整;中、下游采样点受矿山开采和城镇建设影响,耐污类群（如摇蚊科、蚬属）占优,群落结构趋于单一。前两个排序轴（RDA1 和 RDA2）累计解释了73.5%的大型底栖无脊椎动物群落结构变异,表明环境因子对群落结构变异具有较强的解释力,其中,温度和电导率是影响群落结构的关键环境因子。老鹳河上游水质状况良好,但中、下游水质明显下降,水生生物群落出现明显退化,具体表现为敏感水生昆虫类群数量下降,耐污类群数量增加。B3采样点因距干扰源较远且具一定自净能力,呈现局部恢复趋势,但EPT仍偏低（13.2%）,反映水质轻微退化。不同指数评价结果存在差异,需要结合多个指数综合评价,以准确掌握河流水质的真实状况。

关键词: 大型底栖无脊椎动物, 群落结构, 特征, 水质评价, 老鹳河

Abstract: To investigate the characteristics of the macrozoobenthos community structure and their relationship with environmental factors in the Laoguan River, a survey was conducted at eight sampling sites from November to December 2024. Hierarchical clustering, non-metric multidimensional scaling (NMDS), and redundancy analysis (RDA) were employed, along with the biological index(BI), the Biological Monitoring Working Party (BMWP) score, and the Ephemeroptera, Plecoptera, and Trichoptera (EPT) index for water quality assessment. The results showed that a total of 34 macrozoobenthos species belonging to 3 phyla were identified in the river, with Arthropoda being the dominant phylum. The spatial distribution of the community structure could be classified into three groups, which was highly consistent with the intensity of anthropogenic disturbance. The upstream Group A sampling sites (control) were dominated by sensitive taxa such as EPT, exhibiting a relatively intact community structure. The midstream and downstream sampling sites, affected by mining and urban construction, were dominated by pollution-tolerant taxa (e.g., Chironomidae, Corbicula), leading to a simplified community structure. The first two ordination axes (RDA1 and RDA2) cumulatively explained 73.5% of the variation in the macrozoobenthos community structure, indicating that environmental factors had strong explanatory power for the community structure variation, with water temperature and conductivity being the key influencing factors. The water quality in the upstream was good, but it declined significantly in the midstream and downstream, accompanied by marked degradation of the aquatic community, specifically manifested as a decrease in the abundance of sensitive aquatic insect taxa and an increase in pollution-tolerant taxa. Sampling site B3 showed a local recovery trend due to its greater distance from disturbance sources and certain self-purification capacity, but the EPT abundance remained relatively low (13.2%), reflecting slight water quality degradation. The assessment results differed among the various indices, highlighting the need for a comprehensive evaluation combining multiple indices to accurately ascertain the true status of the river water quality.

Key words: macrozoobenthos, community structure, characteristics, water quality assessment, Laoguan River

中图分类号:

Q958.1
X824

刘佳璇, 丁森, 郝振林. 老鹳河大型底栖无脊椎动物群落结构特征及其水质评价[J]. 湖北农业科学, 2026, 65(3): 72-77.

LIU Jia-xuan, DING Sen, HAO Zhen-lin. Structural characteristics of the macrozoobenthos community and water quality assessment in the Laoguan River[J]. HUBEI AGRICULTURAL SCIENCES, 2026, 65(3): 72-77.

参考文献

[1] 朱敏. 上海九段沙湿地大型底栖动物群落调查及管护策略[J].湿地科学与管理,2016,12(4):33-36.
[2] BENKE A C.Concepts and patterns of invertebrate production in running waters[J]. SIL proceedings, 2010, 1993, 25(1): 15-38.
[3] 陶艳茹,董稳静,罗明科,等.太湖底栖动物时空分布特征及基于底栖动物完整性指数的水生态健康评价[J].环境科学研究,2024,37(4):752-763.
[4] 金珂,秦立鹏,姬诚炜,等.山西省中部地区大型底栖动物群落结构特征与水质生物评价[J].湿地科学,2025,23(2):385-396.
[5] 彭芸,李长江.贵州山区河流健康评价大型底栖无脊椎动物指标探究[J].水利规划与设计,2024(8):37-41.
[6] 赵茜,潘福霞,李斌,等.山区河流底栖动物多样性和稳定性对土地利用方式的响应机制[J].生态学报,2024,44(17):7844-7858.
[7] HJ1295—2023,水生态监测技术指南河流水生生物监测与评价(试行)[S].
[8] 冷龙龙,渠晓东,张海萍,等.不同大型底栖动物快速生物评价指数对河流水质指示比较[J].环境科学研究,2016,29(6):819-828.
[9] 代贞伟,王磊,伏永朋,等.丹江口水库老灌河流域地下水水化学特征[J].中国地质调查,2019,6(5):43-49.
[10] 何千韵,张敏,樊仕宝,等.深圳市大鹏新区国家地质公园源头溪流大型底栖动物群落多样性[J].生态学杂志,2022, 41(12):2388-2396.
[11] 黄书雅,张玉洲,甘志文,等.低头坝对河源溪流大型底栖动物群落结构及构建机制的影响[J].生态学报,2025,45(19):9476-9489.
[12] 李艳利,李艳粉,李科.不同尺度下人类活动对浑太河流域鱼类和大型底栖动物群落特征的影响[J].环境科学研究,2016,29(8):1145-1153.
[13] WANG J, DING C Z, TAO J, et al.Damming affects riverine macroinvertebrate metacommunity dynamics: Insights from taxonomic and functional beta diversity[J]. Science of the total environment, 2021, 763: 142945.
[14] 王瀚锐. 水沙作用下梯形透空丁坝对底栖动物生境演替的影响机制[D].长沙:长沙理工大学,2022.
[15] ZHANG Y,ZHAO Q,DING S.The responses of stream fish to the gradient of conductivity:A case study from the Taizi River,China[J].Aquatic ecosystem health & management,2019,22(2):171-182.
[16] 杨晓明. 丹江口水库老鹳河大型底栖动物群落结构与水质评价[D].河南南阳:南阳师范学院,2020.
[17] 余渝,沈璐,姜滔,等.基于大型底栖无脊椎动物评价沱江流域典型支流水生态健康状况——以西江河为例[J].水上安全,2024(17):87-89.
[18] 张敏,邵美玲,蔡庆华,等.丹江口水库大型底栖动物群落结构及其水质生物学评价[J].湖泊科学,2010,22(2):281-290.

老鹳河大型底栖无脊椎动物群落结构特征及其水质评价

Structural characteristics of the macrozoobenthos community and water quality assessment in the Laoguan River

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