Literature DB >> 25620875

Predicting Onset and Duration of Airborne Allergenic Pollen Season in the United States.

Yong Zhang1, Leonard Bielory2, Ting Cai3, Zhongyuan Mi4, Panos Georgopoulos5.   

Abstract

Allergenic pollen is one of the main triggers of Allergic Airway Disease (AAD) affecting 5% to 30% of the population in industrialized countries. A modeling framework has been developed using correlation and collinearity analyses, simulated annealing, and stepwise regression based on nationwide observations of airborne pollen counts and climatic factors to predict the onsets and durations of allergenic pollen seasons of representative trees, weeds and grass in the contiguous United States. Main factors considered are monthly, seasonal and annual mean temperatures and accumulative precipitations, latitude, elevation, Growing Degree Day (GDD), Frost Free Day (FFD), Start Date (SD) and Season Length (SL) in the previous year. The estimated mean SD and SL for birch (Betula), oak (Quercus), ragweed (Ambrosia), mugwort (Artemisia) and grass (Poaceae) pollen season in 1994-2010 are mostly within 0 to 6 days of the corresponding observations for the majority of the National Allergy Bureau (NAB) monitoring stations across the contiguous US. The simulated spatially resolved maps for onset and duration of allergenic pollen season in the contiguous US are consistent with the long term observations.

Entities:  

Keywords:  Allergy; Model; Pollen season; Season length; Start date

Year:  2015        PMID: 25620875      PMCID: PMC4302955          DOI: 10.1016/j.atmosenv.2014.12.019

Source DB:  PubMed          Journal:  Atmos Environ (1994)        ISSN: 1352-2310            Impact factor:   4.798


  18 in total

1.  Two statistical approaches to forecasting the start and duration of the pollen season of Ambrosia in the area of Lyon (France).

Authors:  Mohamed Laaidi; Michel Thibaudon; Jean-Pierre Besancenot
Journal:  Int J Biometeorol       Date:  2003-05-29       Impact factor: 3.787

Review 2.  Incorporating uncertainty in predictive species distribution modelling.

Authors:  Colin M Beale; Jack J Lennon
Journal:  Philos Trans R Soc Lond B Biol Sci       Date:  2012-01-19       Impact factor: 6.237

3.  Recent warming by latitude associated with increased length of ragweed pollen season in central North America.

Authors:  Lewis Ziska; Kim Knowlton; Christine Rogers; Dan Dalan; Nicole Tierney; Mary Ann Elder; Warren Filley; Jeanne Shropshire; Linda B Ford; Curtis Hedberg; Pamela Fleetwood; Kim T Hovanky; Tony Kavanaugh; George Fulford; Rose F Vrtis; Jonathan A Patz; Jay Portnoy; Frances Coates; Leonard Bielory; David Frenz
Journal:  Proc Natl Acad Sci U S A       Date:  2011-02-22       Impact factor: 11.205

4.  Allergenic pollen season variations in the past two decades under changing climate in the United States.

Authors:  Yong Zhang; Leonard Bielory; Zhongyuan Mi; Ting Cai; Alan Robock; Panos Georgopoulos
Journal:  Glob Chang Biol       Date:  2014-11-07       Impact factor: 10.863

5.  Predicting tree pollen season start dates using thermal conditions.

Authors:  Dorota Myszkowska
Journal:  Aerobiologia (Bologna)       Date:  2014-02-20       Impact factor: 2.410

6.  Climate change effect on Betula (birch) and Quercus (oak) pollen seasons in the United States.

Authors:  Yong Zhang; Leonard Bielory; Panos G Georgopoulos
Journal:  Int J Biometeorol       Date:  2013-06-21       Impact factor: 3.787

7.  A numerical model of birch pollen emission and dispersion in the atmosphere. Description of the emission module.

Authors:  M Sofiev; P Siljamo; H Ranta; T Linkosalo; S Jaeger; A Rasmussen; A Rantio-Lehtimaki; E Severova; J Kukkonen
Journal:  Int J Biometeorol       Date:  2012-03-13       Impact factor: 3.787

8.  Bayesian Analysis of Climate Change Effects on Observed and Projected Airborne Levels of Birch Pollen.

Authors:  Yong Zhang; Sastry Isukapalli; Leonard Bielory; Panos Georgopoulos
Journal:  Atmos Environ (1994)       Date:  2012-11-12       Impact factor: 4.798

9.  Use of phenological and pollen-production data for interpreting atmospheric birch pollen curves.

Authors:  Victoria Jato; F Javier Rodríguez-Rajo; M Jesús Aira
Journal:  Ann Agric Environ Med       Date:  2007       Impact factor: 1.447

10.  Development of a regional-scale pollen emission and transport modeling framework for investigating the impact of climate change on allergic airway disease.

Authors:  Rui Zhang; Tiffany Duhl; Muhammad T Salam; James M House; Richard C Flagan; Edward L Avol; Frank D Gilliland; Alex Guenther; Serena H Chung; Brian K Lamb; Timothy M VanReken
Journal:  Biogeosciences       Date:  2013-03-01       Impact factor: 4.295
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  5 in total

Review 1.  Impact of Climate Change on Pollen and Respiratory Disease.

Authors:  Charles S Barnes
Journal:  Curr Allergy Asthma Rep       Date:  2018-09-20       Impact factor: 4.806

2.  Regional forecast model for the Olea pollen season in Extremadura (SW Spain).

Authors:  Santiago Fernández-Rodríguez; Pablo Durán-Barroso; Inmaculada Silva-Palacios; Rafael Tormo-Molina; José María Maya-Manzano; Ángela Gonzalo-Garijo
Journal:  Int J Biometeorol       Date:  2016-02-19       Impact factor: 3.787

3.  Development of a semi-mechanistic allergenic pollen emission model.

Authors:  Ting Cai; Yong Zhang; Xiang Ren; Leonard Bielory; Zhongyuan Mi; Christopher G Nolte; Yang Gao; L Ruby Leung; Panos G Georgopoulos
Journal:  Sci Total Environ       Date:  2018-10-18       Impact factor: 7.963

4.  Pollen antigens and atmospheric circulation driven seasonal respiratory viral outbreak and its implication to the Covid-19 pandemic.

Authors:  Michael G Wallace; Yifeng Wang
Journal:  Sci Rep       Date:  2021-08-20       Impact factor: 4.996

5.  Impacts of oak pollen on allergic asthma in the United States and potential influence of future climate change.

Authors:  Susan C Anenberg; Kate R Weinberger; Henry Roman; James E Neumann; Allison Crimmins; Neal Fann; Jeremy Martinich; Patrick L Kinney
Journal:  Geohealth       Date:  2017-05-03
  5 in total

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