Spatial and temporal distribution of Ixodes scapularis and tick-borne pathogens across the northeastern United States.

IF 3 2区医学 Q1 PARASITOLOGY

Parasites & Vectors Pub Date : 2024-11-22 DOI:10.1186/s13071-024-06518-9

Lucas E Price, Jonathan M Winter, Jamie L Cantoni, Duncan W Cozens, Megan A Linske, Scott C Williams, Griffin M Dill, Allison M Gardner, Susan P Elias, Thomas F Rounsville, Robert P Smith, Michael W Palace, Christina Herrick, Melissa A Prusinski, Patti Casey, Eliza M Doncaster, Joseph D T Savage, Dorothy I Wallace, Xun Shi

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引用次数: 0

Abstract

Background: The incidence of tick-borne diseases is increasing across the USA, with cases concentrated in the northeastern and midwestern regions of the country. Ixodes scapularis is one of the most important tick-borne disease vectors and has spread throughout the northeastern USA over the past four decades, with established populations in all states of the region.

Methods: To better understand the rapid expansion of I. scapularis and the pathogens they transmit, we aggregated and analyzed I. scapularis abundance and pathogen prevalence data from across the northeastern USA, including the states of Connecticut, Maine, New Hampshire, New York and Vermont, from 1989 to 2021. Maine was the only state to collect data during the entire time period, with the other states collecting data during a subset of this time period starting in 2008 or later. We harmonized I. scapularis abundance by county and tick season, where the nymph season is defined as May to September and the adult season is October to December, and calculated I. scapularis pathogen infection prevalence as the percentage of ticks that tested positive for Anaplasma phagocytophilum, Babesia microti, Borrelia burgdorferi, and Borrelia miyamotoi. We then explored temporal trends in I. scapularis abundance and pathogen prevalence data using linear models.

Results: The resulting dataset is one of the most spatially and temporally comprehensive records of tick abundance and pathogen prevalence in the USA. Using linear models, we found small or insignificant changes in the abundance of nymphs and adults over time; however, A. phagocytophilum, B. microti and B. burgdorferi prevalence in both nymphs and adults has increased over time. For the period 2017-2021, the statewide average prevalence of B. burgdorferi ranged from 19% to 25% in I. scapularis nymphs and from to 49% to 54% in I. scapularis adults. The statewide average prevalence of all other pathogens in I. scapularis for 2017-2021, including A. phagocytophilum (4-6% for nymphs, 4-9% for adults), B. microti (4-8% for nymphs, 2-13% for adults) and B. miyamotoi (1-2% for nymphs, 1-2% for adults), was considerably less.

Conclusions: Our efforts revealed the complications of creating a comprehensive dataset of tick abundance and pathogen prevalence across time and space due to variations in tick collection and pathogen testing methods. Although tick abundance has not changed along the more southern latitudes in our study over this time period, and only gradually changed in the more northern latitudes of our study, human risk for exposure to tick-borne pathogens has increased due to increased pathogen prevalence in I. scapularis. This dataset can be used in future studies of I. scapularis and pathogen prevalence across the northeastern USA and to evaluate models of I. scapularis ecology and population dynamics.

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美国东北部蜱虫和蜱传病原体的时空分布。

背景：蜱传疾病的发病率在美国各地不断上升，病例主要集中在美国东北部和中西部地区。黄斑伊蚊是最重要的蜱媒疾病传播媒介之一，在过去的四十年中已遍布美国东北部，并在该地区的所有州都建立了种群：为了更好地了解白头蜱的快速扩张及其传播的病原体，我们汇总并分析了从 1989 年到 2021 年美国东北部各州（包括康涅狄格州、缅因州、新罕布什尔州、纽约州和佛蒙特州）的白头蜱数量和病原体流行率数据。缅因州是唯一一个在整个时间段内都收集数据的州，其他各州从 2008 年或更晚的时间段开始收集数据。我们统一了各州和蜱虫季节（若虫季节定义为 5 月至 9 月，成虫季节为 10 月至 12 月）的黄肤蝇数量，并计算了黄肤蝇病原体感染率，即噬细胞细胞嗜性无形体（Anaplasma phagocytophilum）、细小巴贝西亚原虫（Babesia microti）、布氏杆菌（Borrelia burgdorferi）和宫本氏杆菌（Borrelia miyamotoi）检测呈阳性的蜱虫百分比。然后，我们利用线性模型探讨了恙虫丰度和病原体流行率数据的时间趋势：结果：由此产生的数据集是美国蜱虫数量和病原体流行在空间和时间上最全面的记录之一。利用线性模型，我们发现若虫和成虫的丰度随着时间的推移变化很小或不明显；但是，若虫和成虫中的噬细胞嗜血杆菌、微小蜱和勃氏蜱的流行率随着时间的推移有所增加。在 2017-2021 年期间，全州范围内黄斑蝶若虫中 B. burgdorferi 的平均流行率介于 19% 到 25% 之间，而黄斑蝶成虫中 B. burgdorferi 的流行率介于 49% 到 54% 之间。2017-2021年，全州范围内所有其他病原体在白髭鳞蝉体内的平均感染率要低得多，包括噬细胞甲虫（若虫4-6%，成虫4-9%）、小喙螨（若虫4-8%，成虫2-13%）和宫本螨（若虫1-2%，成虫1-2%）：我们的工作表明，由于蜱虫采集和病原体检测方法的不同，要建立一个跨时空的蜱虫数量和病原体流行的综合数据集非常复杂。虽然在我们的研究中，蜱虫的数量在较南的纬度地区没有发生变化，而在较北的纬度地区才逐渐发生变化，但由于恙虫病原体流行率的增加，人类接触蜱虫病原体的风险也增加了。该数据集可用于未来对美国东北部黄髭鳞螨和病原体流行情况的研究，以及对黄髭鳞螨生态学和种群动态模型的评估。

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

Parasites & Vectors 医学-寄生虫学

CiteScore

6.30

自引率

9.40%

发文量

433

审稿时长

1.4 months

期刊介绍： Parasites & Vectors is an open access, peer-reviewed online journal dealing with the biology of parasites, parasitic diseases, intermediate hosts, vectors and vector-borne pathogens. Manuscripts published in this journal will be available to all worldwide, with no barriers to access, immediately following acceptance. However, authors retain the copyright of their material and may use it, or distribute it, as they wish. Manuscripts on all aspects of the basic and applied biology of parasites, intermediate hosts, vectors and vector-borne pathogens will be considered. In addition to the traditional and well-established areas of science in these fields, we also aim to provide a vehicle for publication of the rapidly developing resources and technology in parasite, intermediate host and vector genomics and their impacts on biological research. We are able to publish large datasets and extensive results, frequently associated with genomic and post-genomic technologies, which are not readily accommodated in traditional journals. Manuscripts addressing broader issues, for example economics, social sciences and global climate change in relation to parasites, vectors and disease control, are also welcomed.