世界蜥蜴消化道吸虫初步名录

doi:10.17520/biods.2024059

生物多样性 ›› 2024, Vol. 32 ›› Issue (9): 24059. DOI: 10.17520/biods.2024059 cstr: 32101.14.biods.2024059

世界蜥蜴消化道吸虫初步名录

阎晓菲¹^,²^,^*^,^#()(), 王涛¹^,²^,^#, 王旖旎¹^,², 赵怡阳³, 陈胜涛¹^,², 孙鑫¹^,², 王楠¹^,²

1.新疆农业大学生命科学学院, 乌鲁木齐 830052
2.新疆极端环境生物生态适应与进化重点实验室, 乌鲁木齐 830052
3.新疆农业大学动物医学学院, 乌鲁木齐 830052

收稿日期:2024-02-16 接受日期:2024-07-07 出版日期:2024-09-20 发布日期:2024-09-23
通讯作者: * E-mail: yanxf83@163.com
作者简介:
^#共同第一作者
基金资助:
新疆维吾尔自治区自然科学基金(2022D01A194);新疆维吾尔自治区人才发展基金“天池英才”引进计划项目;国家寄生虫资源库开放课题(NPRC-2019-194-30);第三次新疆综合科学考察项目(2022xjkk1200)

Preliminary species checklist for gastrointestinal trematodes of lizards in the world

Xiaofei Yan¹^,²^,^*^,^#()(), Tao Wang¹^,²^,^#, Yini Wang¹^,², Yiyang Zhao³, Shengtao Chen¹^,², Xin Sun¹^,², Nan Wang¹^,²

1. College of Life Sciences, Xinjiang Agricultural University, Urumqi 830052, China
2. Key Laboratory of Ecological Adaptation and Evolution of Extreme Environment Biology in Xinjiang, Urumqi 830052, China
3. College of Veterinary Medicine, Xinjiang Agricultural University, Urumqi 830052, China

Received:2024-02-16 Accepted:2024-07-07 Online:2024-09-20 Published:2024-09-23
Contact: * E-mail: yanxf83@163.com
About author:
^#Co-first authors
Supported by:
Xinjiang Uyghur Autonomous Region Natural Science Foundation Project(2022D01A194);Talent Development Fund of the Xinjiang Uyghur Autonomous Region “Tianchi Talents” Introduction Plan Project;National Parasite Resource Bank Open Subject(NPRC-2019-194-30);Third Xinjiang Scientific Expedition Program(2022xjkk1200)

1. 附录.pdf(1274KB)

摘要/Abstract

摘要：

蜥蜴消化道吸虫隶属于扁形动物门吸虫纲, 主要寄生于其肝脏、胆囊、胆管、胃肠道等, 严重感染会导致蜥蜴消化道吸虫病发生。为了全面掌握蜥蜴消化道吸虫的种类及地理分布, 本文参照《中国吸虫学》的分类系统, 收集1919-2023年以来的蜥蜴消化道吸虫研究资料, 并结合最新研究结果, 系统整理其分类地位、拉丁文学名和中文学名、宿主的拉丁文学名和中文学名、寄生部位、分布地区, 形成世界蜥蜴消化道吸虫初步名录。结果表明: 本文共记录世界范围内的蜥蜴消化道吸虫2目25科52属124种, 以前口目的斜睾科和双腔科为主。亚洲和美洲消化道吸虫种类分布最多, 其中亚洲印度记录的虫种最多, 其次是南美洲的巴西。鬣蜥科及其飞蜥亚科, 避役科的避役属(Chamaeleo)感染吸虫种类最多。在初步名录的基础上, 本文讨论了名录的组成特点, 对争议分类阶元进行了分析, 表明世界蜥蜴消化道吸虫今后需开展针对性相关研究和调查, 以期为蜥蜴保护、寄生虫生态学、公共安全提供基础资料。

关键词: 蜥蜴, 消化道, 吸虫, 多样性, 名录

Abstract

Aims: Lizards represent the most diverse group of reptiles, and recently, the number of threatened lizard species has been increasing significantly. One contributing factor to the endangerment of lizards is trematode infection. The trematodes that infect lizards belong to the kingdom Animalia, phylum Platyhelminthes, and class Trematoda, primarily parasitizing the liver, gallbladder, bile duct, and gastrointestinal tract of lizards. Severe infections caused by these organisms can lead to gastrointestinal trematode disease in lizards. Therefore, there is an urgent need for a comprehensive understanding of the parasites that infect lizards. The objective is to provide essential information for the future conservation of lizards, the ecology of parasites, and public health.
Method: Utilizing the classification system of “Trematolgoy in China”, we compiled data on lizard gastrointestinal trematodes from 1919 to 2023. The latest research findings systematically organize the trematodes according to their taxonomic status, as well as their scientific names in both Latin and Chinese, along with the scientific names of their lizard hosts in Latin and Chinese. Additionally, the impact of these trematodes on lizards was examined by cataloging infection sites within the lizards and mapping the geographic distribution of the trematodes. This work serves as a preliminary reference for lizard gastrointestinal trematodes worldwide.
Results: The gastrointestinal trematodes found in lizards worldwide belong to 2 orders, 25 families, and 52 genera, comprising a total of 124 species. The primary orders are Plagiorchiidae and Dicrocoeliida, which fall under the class Prosostomata. The continents with the highest diversity of gastrointestinal trematode species are Asia and South America, with India exhibiting the greatest diversity in Asia, followed closely by Brazil in South America. The largest number of trematode species has been identified in the Agamidae and its Draconinae, as well as in the genera Chamaeleo (Chamaeleonidae).
Conclusion: This paper examines the compositional characteristics of the preliminary list of gastrointestinal trematodes found in lizards and analyzes their contentious classification levels. Furthermore, this study emphasizes the scarcity of research on lizard digestive tract trematodes globally. This study synthesizes previous research on gastrointestinal trematodes in lizards worldwide, presenting a preliminary list of these parasites. This list provides essential theoretical data and serves as a reference for understanding the diversity of parasites in lizards. Furthermore, it offers insights into the impact of climate change on parasite infections and establishes a framework for investigating parasitic threats to other species.

Key words: lizard, gastrointestinal, trematodes, diversity, checklist

中图分类号:

Q959.1

阎晓菲, 王涛, 王旖旎, 赵怡阳, 陈胜涛, 孙鑫, 王楠 (2024) 世界蜥蜴消化道吸虫初步名录. 生物多样性, 32, 24059. DOI: 10.17520/biods.2024059.

Xiaofei Yan, Tao Wang, Yini Wang, Yiyang Zhao, Shengtao Chen, Xin Sun, Nan Wang (2024) Preliminary species checklist for gastrointestinal trematodes of lizards in the world. Biodiversity Science, 32, 24059. DOI: 10.17520/biods.2024059.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2024059

https://www.biodiversity-science.net/CN/Y2024/V32/I9/24059

图/表 1

参考文献 42

[1]	Almeida WO, Guedes TB, Freire EMX, Vasconcellos A (2008) Pentastomid infection in Philodryas nattereri Steindachner, 1870 and Oxybelis aeneus (Wagler, 1824) (Squamata: Colubridae) in a caatinga of northeastern Brazil. Brazilian Journal of Biology, 68, 193-197. PMID
[2]	Araújo Filho JA, Teixeira AAM, Teles DA, Rocha SM, Almeida WO, Mesquita DO, Lacerda ACF (2020) Using lizards to evaluate the influence of average abundance on the variance of endoparasites in semiarid areas: Dispersion and assemblage structure. Journal of Helminthology, 94, e121.
[3]	Ávila RW, Silva RJ (2010) Checklist of helminths from lizards and Amphisbaenians (Reptilia, Squamata) of South America. Journal of Venomous Animals and Toxins Including Tropical Diseases, 16, 543-572.
[4]	Booth DT, Clayton DH, Block BA (1993) Experimental demonstration of the energetic cost of parasitism in free-ranging hosts. Proceedings of the Royal Society of London Series B: Biological Sciences, 253, 125-129.
[5]	Braun MV (1901) Zur Kenntniss der Trematoden der Saugethiere. Zoologische Jahrbücher. Abteilung für Systematik, Geographie und Biologie der Tiere, 14, 311-348.
[6]	Bursey CR, Goldberg SR, Telford SR Jr (2007) Gastrointestinal helminths of 14 species of lizards from Panama with descriptions of five new species. Comparative Parasitology, 74, 108-140.
[7]	Bursey CR, Goldberg SR, Vitt LJ (2005) New species of Allopharynx (Digenea: Plagiorchiidae) and other helminths in Uranoscodon superciliosus (Squamata: Tropiduridae) from Amazonian Brazil. Journal of Parasitology, 91, 1395-1398.
[8]	Chen FX (1985) Fauna Sinica∙Platyhelminthes∙Trematoda∙Digenea. Science Press, Beijing. (in Chinese)
	[陈发心 (1985) 中国动物志∙扁形动物门∙吸虫纲∙复殖目. 科学出版社, 北京.]
[9]	Cheng TC (1960) The life history of Brachycoelium obesum Nicoll 1914, with a discussion of the systematic status of the trematode family Brachycoellidae Johnston 1912. Journal of Parasitology, 46, 464-474.
[10]	Dare OK, Forbes MR (2008) Rates of development in male and female wood frogs and patterns of parasitism by lung nematodes. Parasitology, 135, 385-393. PMID
[11]	Dias Silva G, Martins Teixeira AA, Dellefrate Franzini L, Oliveira Mesquita D, Vieira Brito S (2023) Temporal variation in diet and helminth abundance in the spiny-tailed lizard, Strobilurus torquatus Wiegmann, 1834 (Squamata: Tropiduridae) from the Brazilian Atlantic Forest. Acta Herpetologica, 18, 105-114.
[12]	Dollfus RP (1929) Helmintha I. Trematoda et Acanthocephala. Faune des Colonies Françaises, 3, 74-114.
[13]	Dollfus RP (1950) Anatomical variations in the Distomum cloacicola Max Lühe 1909. Annales De Parasitologie Humaine et Comparee, 25, 141-149.
[14]	Elmahy R, Harras S (2019) Gastrointestinal helminths of lizards (Reptilia: Squamata) from Egypt. Parasitologists United Journal, 12, 139-146.
[15]	Fernandes B, Kohn A, Diniz HMN, Fernandes B, Kohn A (2014) South American Trematodes Parasites of Amphibians and Reptiles. Oficina de livros, Rio de Janeiro.
[16]	Fischthal JH, Kuntz RE (1975) Some trematodes of amphibians and reptiles from Taiwan. Biology, Environmental Science, 42, 1-13.
[17]	Friesen OC, Goellner S, Poulin R, Lagrue C (2020) Parasites shape community structure and dynamics in freshwater crustaceans. Parasitology, 147, 182-193. DOI PMID
[18]	Goldberg SR, Bursey CR, Telford SR Jr (2005) Metazoan endoparasites of four species of lizards, Gehyra mutilata, Hemidactylus frenatus (Gekkonidae), Mabuya cumingi, Mabuya multifasciata (Scincidae), and one species of snake, Ramphotyphlops braminus (Typhlopidae), from the Philippine Islands. Comparative Parasitology, 72, 88-101.
[19]	Hallinger MJ, Taubert A, Hermosilla C, Mutschmann F (2019) Captive agamid lizards in Germany: Prevalence, pathogenicity and therapy of gastrointestinal protozoan and helminth infections. Comparative Immunology, Microbiology and Infectious Diseases, 63, 74-80.
[20]	Hudson P, Greenman J (1998) Competition mediated by parasites: Biological and theoretical progress. Trends in Ecology & Evolution, 13, 387-390.
[21]	Hughes RC, Higginbotham JW, Clary JW (1942) The Trematodes of reptiles, part I, Systematic section. American Midland Naturalist, 27, 109-134.
[22]	Johnston SJ (1912) On some trematode parasites of Australian frogs. Proceedings of The Linnean Society of New South Wales, 37, 285-362.
[23]	Kong FY (2010) Domestic Animal Parasitology. China Agricultural University Press, Beijing. (in Chinese)
	[孔繁瑶 (2010) 家畜寄生虫学. 中国农业大学出版社, 北京.]
[24]	Kose M, Møller AP (1999) Sexual selection, feather breakage and parasites: The importance of white spots in the tail of the barn swallow (Hirundo rustica). Behavioral Ecology and Sociobiology, 45, 430-436.
[25]	Lafferty KD (1999) The evolution of trophic transmission. Parasitology Today, 15, 111-115. PMID
[26]	Lafferty KD, Allesina S, Arim M, Briggs CJ, De Leo G, Dobson AP, Dunne JA, Johnson PTJ, Kuris AM, Marcogliese DJ, Martinez ND, Memmott J, Marquet PA, McLaughlin JP, Mordecai EA, Pascual M, Poulin R, Thieltges DW (2008) Parasites in food webs: The ultimate missing links. Ecology Letters, 11, 533-546. DOI PMID
[27]	Liu W, Li QK, Shi XH, Zhao ZQ (2002) Meristocotyle provitellaria sp. nov. (Digenea: Meristocotylidae) from Varanus salvator in China. Zoological Studies, 41, 283-287.
[28]	Norval G, Bursey CR, Goldberg SR, Sharrad RD, Ross KE, Gardner MG (2021) New host and locality records for gastrointestinal helminths of five reptile species from the Mid North Region of South Australia. Transactions of the Royal Society of South Australia, 145, 45-59.
[29]	Okulewicz A, Kaźmierczak M, Hildebrand J, Adamczyk M (2015) Endoparasites of lizards (Lacertilia) from captive breeding and trade networks. Helminthologia, 52, 34-40.
[30]	Roca V (2023) Islands, saurians and parasites. Basic and Applied Herpetology, 37, 5-27.
[31]	Rocha CFD, Vrcibradic D (2003) Nematode assemblages of some insular and continental lizard hosts of the genus Mabuya Fitzinger (Reptilia, Scincidae) along the eastern Brazilian coast. Revista Brasileira De Zoologia, 20, 755-759.
[32]	Rogers ME, Bates PA (2007) Leishmania manipulation of sand fly feeding behavior results in enhanced transmission. PLoS Pathogens, 3, e91.
[33]	Sewell RBS (1920) On Mesocoelium sociale Lühe. Records of the Zoological Survey of India, 19, 81-95.
[34]	Simha SS (1958) Studies on the trematode parasites of reptiles found in Hyderabad State. Zeitschrift Fur Parasitenkunde, 18, 161-218.
[35]	Skrjabin KI (1964) Trematodes of animals and man. Essentials of trematodology. Volume XVII. Israel Program for Scientific Translations.
[36]	Sun XD, Jiang PZ (1986) Trematodes of the reptile in some parts of Zhejiang Province. Hangzhou Teachers College Journal (Natural Science), (S1), 102-106. (in Chinese)
	[孙希达, 江浦珠 (1986) 浙江部分地区爬行类的寄生吸虫. 杭州师院学报(自然科学版), (S1), 102-106.]
[37]	Tang CT, Tang ZZ (2005) Trematology in China. Fujian Science and Technology Press, Fuzhou. (in Chinese)
	[唐崇惕, 唐仲璋 (2005) 中国吸虫学. 福建科学技术出版社, 福州.]
[38]	Teixeira AAM, Riul P, Brito SV, Araujo-Filho JA, Teles DA, Almeida WO, Mesquita DO (2020) Ecological release in lizard endoparasites from the Atlantic Forest, northeast of the Neotropical Region. Parasitology, 147, 491-500. DOI PMID
[39]	Wang PQ, Wang YY (1992) Parasitic flukes and nematodes of amphibians and reptiles in China. Wuyi Science Journal, 9, 49-66. (in Chinese)
	[汪溥钦, 汪彦愔 (1992) 我国两栖、爬行动物寄生的吸虫和线虫. 武夷科学, 9, 49-66.]
[40]	Yang GY, Zhang ZH (2013) Parasitic Diseases of Wildlife. Science Press, Beijing. (in Chinese)
	[杨光友, 张志和 (2013) 野生动物寄生虫病学. 科学出版社, 北京.]
[41]	Yildirimhan HS, Sümer N (2019) Studies on gastrointestinal helminth of three lacertid lizard species, Podarcis muralis, Podarcis siculus and Ophisops elegans (Sauria: Lacertidae) from Bursa, north-western Turkey. Helminthologia, 56, 310-318. DOI PMID
[42]	Zhao EM, Jiang YM, Huang QY, Hu SQ, Fei L, Ye CY (1998) Latin Chinese English Names for Amphibians and Reptiles. Science Press, Beijing. (in Chinese)
	[赵尔宓, 江跃明, 黄庆云, 胡淑琴, 费梁, 叶昌媛 (1998) 拉汉英两栖爬行动物名称. 科学出版社, 北京.]

国家 Country	虫种数量 Number of species (%)
亚洲 Asia	50 (40.32)
缅甸 Myanmar	9 (7.26)
斯里兰卡 Sri Lanka	3 (2.42)
菲律宾 Philippines	10 (8.06)
印度 India	19 (15.32)
中国 China	11 (8.87)
印度尼西亚 Indonesia	5 (4.03)
巴基斯坦 Pakistan	2 (1.61)
马来西亚 Malaysia	3 (2.42)
约旦 Jordan	1 (0.81)
泰国 Thailand	1 (0.81)
日本 Japan	1 (0.81)
欧洲 Europe	18 (14.52)
西班牙 Spain	3 (2.42)
英国 United Kingdom	3 (2.42)
希腊 Greece	1 (0.81)
意大利 Italy	2 (1.61)
乌克兰 Ukraine	8 (6.45)
保加利亚 Bulgaria	4 (3.23)
土耳其 Türkiye	4 (3.23)
俄罗斯 Russia	4 (3.23)
捷克 Czech	1 (0.81)
比利时 Belgium	1 (0.81)
白俄罗斯 Belarus	1 (0.81)
非洲 Africa	19 (15.32)
国家不明 Country unknown	6 (4.84)
尼日利亚 Nigeria	2 (1.61)
南非 South Africa	1 (0.81)
马达加斯加 Madagascar	2 (1.61)
喀麦隆 Cameroon	1 (0.81)
埃及 Egypt	7 (5.65)
突尼斯 Tunisia	1 (0.81)
刚果 Congo	1 (0.81)
美洲 Americas	37 (31.45)
巴西 Brazil	16 (12.90)
厄瓜多尔 Ecuador	6 (4.84)
阿根廷 Argentina	3 (2.42)
委内瑞拉 Venezuela	1 (0.81)
墨西哥 Mexico	3 (2.42)
美国 USA	4 (4.03)
哥斯达黎加 Costa Rica	2 (1.61)
尼加拉瓜 Nicaragua	2 (1.61)
危地马拉 Guatemala	1 (0.81)
巴拿马 Panama	2 (1.61)
大洋洲 Oceania	7 (5.65)
澳大利亚 Australia	4 (3.23)
萨摩亚 Samoa	1 (0.81)
密克罗尼西亚 Micronesia	1 (0.81)
巴布亚新几内亚 Papua New Guinea	1 (0.81)

国家 Country	虫种数量 Number of species (%)
亚洲 Asia	50 (40.32)
缅甸 Myanmar	9 (7.26)
斯里兰卡 Sri Lanka	3 (2.42)
菲律宾 Philippines	10 (8.06)
印度 India	19 (15.32)
中国 China	11 (8.87)
印度尼西亚 Indonesia	5 (4.03)
巴基斯坦 Pakistan	2 (1.61)
马来西亚 Malaysia	3 (2.42)
约旦 Jordan	1 (0.81)
泰国 Thailand	1 (0.81)
日本 Japan	1 (0.81)
欧洲 Europe	18 (14.52)
西班牙 Spain	3 (2.42)
英国 United Kingdom	3 (2.42)
希腊 Greece	1 (0.81)
意大利 Italy	2 (1.61)
乌克兰 Ukraine	8 (6.45)
保加利亚 Bulgaria	4 (3.23)
土耳其 Türkiye	4 (3.23)
俄罗斯 Russia	4 (3.23)
捷克 Czech	1 (0.81)
比利时 Belgium	1 (0.81)
白俄罗斯 Belarus	1 (0.81)
非洲 Africa	19 (15.32)
国家不明 Country unknown	6 (4.84)
尼日利亚 Nigeria	2 (1.61)
南非 South Africa	1 (0.81)
马达加斯加 Madagascar	2 (1.61)
喀麦隆 Cameroon	1 (0.81)
埃及 Egypt	7 (5.65)
突尼斯 Tunisia	1 (0.81)
刚果 Congo	1 (0.81)
美洲 Americas	37 (31.45)
巴西 Brazil	16 (12.90)
厄瓜多尔 Ecuador	6 (4.84)
阿根廷 Argentina	3 (2.42)
委内瑞拉 Venezuela	1 (0.81)
墨西哥 Mexico	3 (2.42)
美国 USA	4 (4.03)
哥斯达黎加 Costa Rica	2 (1.61)
尼加拉瓜 Nicaragua	2 (1.61)
危地马拉 Guatemala	1 (0.81)
巴拿马 Panama	2 (1.61)
大洋洲 Oceania	7 (5.65)
澳大利亚 Australia	4 (3.23)
萨摩亚 Samoa	1 (0.81)
密克罗尼西亚 Micronesia	1 (0.81)
巴布亚新几内亚 Papua New Guinea	1 (0.81)

世界蜥蜴消化道吸虫初步名录

Preliminary species checklist for gastrointestinal trematodes of lizards in the world

RichHTML

PDF (PC)

补充材料

可视化

摘要/Abstract

引用本文

使用本文

图/表 1

参考文献 42

相关文章 15

编辑推荐

Metrics

本文评价

[1]	韩佳楠, 苏杨, 李霏, 刘君妍, 赵依林, 李琳, 赵建成, 梁红柱, 李敏. 河北省苔藓植物多样性[J]. 生物多样性, 2024, 32(9): 24096-.
[2]	何欣怡, 潘玉梅, 祝燕, 陈佳仪, 张思榕, 张乃莉. 暖温带森林外生菌根树种优势和植物多样性对土壤氮素周转的影响[J]. 生物多样性, 2024, 32(9): 24173-.
[3]	谷际岐, 陈建平, 赖江山. 大语言模型在生物多样性研究中的应用[J]. 生物多样性, 2024, 32(9): 24258-.
[4]	韩永金, 梁咏亮, 佟一杰, 丁强, 田哲豪, 李露露, 李晓娟, 申昊, 朱亚超, 刘宁, 王新谱, 白明. 基于三种被动式采集方法采集的宁夏贺兰山甲虫标本照片数据集[J]. 生物多样性, 2024, 32(9): 24054-.
[5]	靳川, 张子嘉, 底凯, 张卫荣, 乔栋, 程思源, 胡中民. 海南热带雨林植物光合荧光气体交换和叶功能性状数据集[J]. 生物多样性, 2024, 32(9): 24139-.
[6]	李蓉姣, 董江海, 郑文芳, 刘入源, 赵立娟, 高瑞贺. 关帝山不同海拔杨桦混交林土壤动物多样性特征及其影响因素[J]. 生物多样性, 2024, 32(9): 24070-.
[7]	李东红, 郝媛媛, 甘辉林, 张航, 刘耀猛, 他富源, 胡桂馨. 祁连山北麓中段不同类型草地蝗虫种类及分布[J]. 生物多样性, 2024, 32(9): 24119-.
[8]	朱芸, 王凯红, 李洪磊, 徐向龙, 段文斌, 陈浩, 邱国强, 陈卫华, 卢靖, 丁长青. 朱鹮非繁殖期行为谱及PAE编码系统[J]. 生物多样性, 2024, 32(9): 24075-.
[9]	胡志清, 董路. 城市化对鸟类参与的种间互作的影响[J]. 生物多样性, 2024, 32(8): 24048-.
[10]	段菲, 刘鸣章, 卜红亮, 俞乐, 李晟. 城市化对鸟类群落组成及功能特征的影响——以京津冀地区为例[J]. 生物多样性, 2024, 32(8): 23473-.
[11]	孙智闲, 田晨, 王鑫, 方雨田, 李博, 赵亚辉. 热带沿海城市土著鱼类面临的威胁: 以海南省三亚市为例[J]. 生物多样性, 2024, 32(8): 24165-.
[12]	牛红玉, 陈璐, 赵恒月, 古丽扎尔·阿不都克力木, 张洪茂. 城市化对动物的影响: 从群落到个体[J]. 生物多样性, 2024, 32(8): 23489-.
[13]	王秦韵, 张玉泉, 刘浩, 李明, 刘菲, 赵宁, 陈鹏, 齐敦武, 阙品甲. 成都大熊猫繁育研究基地鸟类多样性[J]. 生物多样性, 2024, 32(8): 24066-.
[14]	苏荣菲, 陈睿山, 俞霖琳, 吴婧彬, 康燕. 基于红外相机调查的上海市长宁区社区生境花园生物多样性[J]. 生物多样性, 2024, 32(8): 24068-.
[15]	白皓天, 余上, 潘新园, 凌嘉乐, 吴娟, 谢恺琪, 刘阳, 陈学业. AI辅助识别的鸟类被动声学监测在城市湿地公园中的应用[J]. 生物多样性, 2024, 32(8): 24188-.