Inverse Trend Between Tree Pollen and Fungal Concentrations With Allergic Sensitization Rates in Seoul for 25 Years.

IF 4.1 2区医学 Q2 ALLERGY

Allergy, Asthma & Immunology Research Pub Date : 2024-11-01 DOI:10.4168/aair.2024.16.6.571

Young-Jin Choi, Kyung-Suk Lee, Jae-Won Oh

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引用次数: 0

Abstract

A growing number of individuals are developing allergic diseases due to pollen exposure. Seasonal variations and increased pollen concentrations have occurred with the increased rates of allergic sensitization among both children and adults. Temperature significantly influences pollination, particularly in spring- and early summer-flowering plants, with weather conditions affecting pollen allergen levels. Human activities, including agriculture and deforestation, increase carbon emissions, leading to higher atmospheric CO₂ levels that may enhance allergenic plant productivity. Climate change affects the range of allergenic plant species and length of pollen season. Studies indicate that higher CO₂ and temperature levels are linked to increased pollen concentrations and allergenicity, whereas atmospheric fungal concentrations have declined annually over the past 25 years. Despite more intense precipitation in summer and autumn, the number of rainy days has decreased across all seasons. This concentration of rainfall over shorter periods likely prolongs the dry season and shortens the period of fungal sporulation. Future climate changes, including atmospheric dryness, drought, and desertification could further decrease allergenic fungal sporulation. It remains unclear whether the inverse relationship between pollen and fungal concentrations and distributions directly results from climate change. It is crucial to evaluate the patterns of aeroallergens and their associated health risks.

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25年来首尔树木花粉和真菌浓度与过敏致敏率的反比趋势

越来越多的人正在发展过敏性疾病，由于花粉暴露。季节变化和花粉浓度的增加在儿童和成人中都发生了过敏性致敏率的增加。温度显著影响授粉，特别是在春季和初夏开花植物，天气条件影响花粉过敏原水平。包括农业和森林砍伐在内的人类活动增加了碳排放，导致大气中二氧化碳水平升高，从而可能提高致敏植物的生产力。气候变化影响致敏植物种类的范围和花粉季节的长度。研究表明，较高的CO₂和温度水平与花粉浓度和过敏原性的增加有关，而大气真菌浓度在过去25年中每年都在下降。尽管夏季和秋季降水较强，但雨季的天数在所有季节都有所减少。这种短时间内降雨的集中可能延长了旱季，缩短了真菌产孢的时间。未来的气候变化，包括大气干燥、干旱和荒漠化，可能会进一步减少致敏真菌孢子的产生。目前尚不清楚花粉与真菌浓度和分布之间的反比关系是否直接源于气候变化。评估空气过敏原的类型及其相关的健康风险至关重要。

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来源期刊

Allergy, Asthma & Immunology Research ALLERGY-IMMUNOLOGY

CiteScore

6.10

自引率

6.80%

发文量

审稿时长

>12 weeks

期刊介绍： The journal features cutting-edge original research, brief communications, and state-of-the-art reviews in the specialties of allergy, asthma, and immunology, including clinical and experimental studies and instructive case reports. Contemporary reviews summarize information on topics for researchers and physicians in the fields of allergy and immunology. As of January 2017, AAIR do not accept case reports. However, if it is a clinically important case, authors can submit it in the form of letter to the Editor. Editorials and letters to the Editor explore controversial issues and encourage further discussion among physicians dealing with allergy, immunology, pediatric respirology, and related medical fields. AAIR also features topics in practice and management and recent advances in equipment and techniques for clinicians concerned with clinical manifestations of allergies and pediatric respiratory diseases.