uri,href,identifier,attrs.Abstract,attrs.Author,"attrs.Author Address",attrs.ISSN,attrs.Issue,attrs.Journal,attrs.Keywords,attrs.Language,attrs.Notes,attrs.Pages,attrs.Title,attrs.URL,attrs.Volume,attrs.Year,attrs.\.reference_type,attrs._record_number,attrs._uuid,attrs.reftype,child_publication
/reference/1c917926-3eba-452b-bd2b-f9e88b374312,https://data.globalchange.gov/reference/1c917926-3eba-452b-bd2b-f9e88b374312,1c917926-3eba-452b-bd2b-f9e88b374312,"The main characteristics of the Quercus pollination season were studied in 14 different localities of the Iberian Peninsula from 1992-2004. Results show that Quercus flowering season has tended to start earlier in recent years, probably due to the increased temperatures in the pre-flowering period, detected at study sites over the second half of the 20th century. A Growing Degree Days forecasting model was used, together with future meteorological data forecast using the Regional Climate Model developed by the Hadley Meteorological Centre, in order to determine the expected advance in the start of Quercus pollination in future years. At each study site, airborne pollen curves presented a similar pattern in all study years, with different peaks over the season attributable in many cases to the presence of several species. High pollen concentrations were recorded, particularly at Mediterranean sites. This study also proposes forecasting models to predict both daily pollen values and annual pollen emission. All models were externally validated using data for 2001 and 2004, with acceptable results. Finally, the impact of the highly-likely climate change on Iberian Quercus pollen concentration values was studied by applying RCM meteorological data for different future years, 2025, 2050, 2075 and 2099. Results indicate that under a doubled CO(2) scenario at the end of the 21st century Quercus pollination season could start on average one month earlier and airborne pollen concentrations will increase by 50 % with respect to current levels, with higher values in Mediterranean inland areas.","Garcia-Mozo, H.; Galán, C.; Jato, V.; Belmonte, J.; de la Guardia, C.D.; Fernández, D.; Gutiérrez, M.; Aira, M.J.; Roure, J.M.; Ruiz, L.; Trigo, M.M.; Domínguez-Vilches, E.","Departamento de Biologia Vegetal, Campus de Rabanales, Universidad de Cordoba, Spain. bv2gamoh@uco.es",1232-1966,2,"Annals of Agricultural and Environmental Medicine","Air Pollutants/*analysis; Air Pollution/*analysis; Allergens/*analysis; Climate; Environmental Monitoring/*methods; Forecasting; Humans; Hypersensitivity/prevention & control; *Pollen; *Quercus; Retrospective Studies; Seasons; Spain",eng,"Garcia-Mozo, Herminia Galan, Carmen Jato, Victoria Belmonte, Jordina de la Guardia, Consuelo Fernandez, Delia Gutierrez, Montserrat Aira, M Roure, Joan Ruiz, Luis Trigo, Mar Dominguez-Vilches, Eugenio Journal Article Research Support, Non-U.S. Gov't Poland Ann Agric Environ Med. 2006;13(2):209-24.",209-224,"Quercus pollen season dynamics in the Iberian peninsula: Response to meteorological parameters and possible consequences of climate change",http://www.uco.es/aerobiologia/publicaciones/modelling/climate_change/Quercus_AAEM_def.pdf,13,2006,0,18483,1c917926-3eba-452b-bd2b-f9e88b374312,"Journal Article",/article/pmid-17195993
/reference/1ca7e70d-66b3-42e1-9a68-31b976d2622f,https://data.globalchange.gov/reference/1ca7e70d-66b3-42e1-9a68-31b976d2622f,1ca7e70d-66b3-42e1-9a68-31b976d2622f,,"Wu, F.
Bhatnagar, D.
Bui-Klimke, T.
Carbone, I.
Hellmich, R.
Munkvold, G.
Paul, P.
Payne, G.
Takle, E.",,1875-0710,1,"World Mycotoxin Journal",,,,79-93,"Climate change impacts on mycotoxin risks in US maize",,4,2011,0,3489,1ca7e70d-66b3-42e1-9a68-31b976d2622f,"Journal Article",/article/10.3920/WMJ2010.1246
/reference/1cc2707a-810e-4599-bea2-ad8bf6f5b5dc,https://data.globalchange.gov/reference/1cc2707a-810e-4599-bea2-ad8bf6f5b5dc,1cc2707a-810e-4599-bea2-ad8bf6f5b5dc,,"Gooch, JA; DePaola, A; Bowers, J; Marshall, DL",,,6,"Journal of Food Protection",,,,911-1053,"Growth and survival of Vibrio parahaemolyticus in postharvest American oysters",,65,2002,0,17953,1cc2707a-810e-4599-bea2-ad8bf6f5b5dc,"Journal Article",/article/pmid-12092730
/reference/1d452b5c-bb39-46e3-a497-0ef775e3461c,https://data.globalchange.gov/reference/1d452b5c-bb39-46e3-a497-0ef775e3461c,1d452b5c-bb39-46e3-a497-0ef775e3461c,,"Wescoat, J.L., Jr.,; Headington, Lisa; Theobald, Rebecca",,0016-7185,5,Geoforum,,,,801-814,"Water and poverty in the United States",,38,2007,0,19326,1d452b5c-bb39-46e3-a497-0ef775e3461c,"Journal Article",/article/10.1016/j.geoforum.2006.08.007
/reference/1dad28b6-fe27-4e03-9630-8fda36305ec5,https://data.globalchange.gov/reference/1dad28b6-fe27-4e03-9630-8fda36305ec5,1dad28b6-fe27-4e03-9630-8fda36305ec5,,"Bell, P.A.; Greene, T.C.; Fisher, J.D.; Baum, A.",,,,,,,,,"Environmental Psychology",,,2001,9,16527,1dad28b6-fe27-4e03-9630-8fda36305ec5,Book,/book/012d6f7b-9a6e-4473-a334-a12fa730c4ab
/reference/1dd1dce1-0102-4440-9451-e630b6d49128,https://data.globalchange.gov/reference/1dd1dce1-0102-4440-9451-e630b6d49128,1dd1dce1-0102-4440-9451-e630b6d49128,,"Lin, Shao; Liu, Xiu; Le, Linh H.; Hwang, Syni-An",,1552-9924,12,"Environmental Health Perspectives",,,,1725-1730,"Chronic exposure to ambient ozone and asthma hospital admissions among children",,116,2008,0,17866,1dd1dce1-0102-4440-9451-e630b6d49128,"Journal Article",/article/10.1289/ehp.11184
/reference/1dd6cf74-00ed-4f20-b4a1-9858955ad077,https://data.globalchange.gov/reference/1dd6cf74-00ed-4f20-b4a1-9858955ad077,1dd6cf74-00ed-4f20-b4a1-9858955ad077,,"Sarche, M.
Spicer, P.",,1749-6632,1,"Annals of the New York Academy of Sciences",,,,126-136,"Poverty and health disparities for American Indian and Alaska Native children",http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2567901/pdf/nihms58363.pdf,1136,2008,0,2748,1dd6cf74-00ed-4f20-b4a1-9858955ad077,"Journal Article",/article/10.1196/annals.1425.017
/reference/1dd78be0-0355-46a2-81b7-9a55154cc564,https://data.globalchange.gov/reference/1dd78be0-0355-46a2-81b7-9a55154cc564,1dd78be0-0355-46a2-81b7-9a55154cc564,,"Lee, Mihye; Nordio, Francesco; Zanobetti, Antonella; Kinney, Patrick; Vautard, Robert; Schwartz, Joel",,1476-069X,1,"Environmental Health",,,,89,"Acclimatization across space and time in the effects of temperature on mortality: A time-series analysis",,13,2014,0,19130,1dd78be0-0355-46a2-81b7-9a55154cc564,"Journal Article",/article/10.1186/1476-069X-13-89
/reference/1dd93561-606a-43ea-a054-c2626750c5f0,https://data.globalchange.gov/reference/1dd93561-606a-43ea-a054-c2626750c5f0,1dd93561-606a-43ea-a054-c2626750c5f0,,"Peeters, Frank; Straile, Dietmar; Lorke, Andreas; Livingstone, David M.",,1365-2486,9,"Global Change Biology","climate warming; lake; mixing; modelling; phytoplankton; spring bloom; stratification",,,1898-1909,"Earlier onset of the spring phytoplankton bloom in lakes of the temperate zone in a warmer climate",,13,2007,0,19055,1dd93561-606a-43ea-a054-c2626750c5f0,"Journal Article",/article/10.1111/j.1365-2486.2007.01412.x
/reference/1dfd14e0-eae8-46d9-9c3e-0fa3f0c37da4,https://data.globalchange.gov/reference/1dfd14e0-eae8-46d9-9c3e-0fa3f0c37da4,1dfd14e0-eae8-46d9-9c3e-0fa3f0c37da4,,"Kibler, S.R.; Tester, P.A.; Kunkel, K.E.; Moore, S.K.; Litaker, R.W.",,1872-7026,,"Ecological Modelling",,,,194-210,"Effects of ocean warming on growth and distribution of dinoflagellates associated with ciguatera fish poisoning in the Caribbean",,316,2015,0,18815,1dfd14e0-eae8-46d9-9c3e-0fa3f0c37da4,"Journal Article",/article/10.1016/j.ecolmodel.2015.08.020
/reference/1e1e4a5d-8237-4a19-b90f-b666d0124d64,https://data.globalchange.gov/reference/1e1e4a5d-8237-4a19-b90f-b666d0124d64,1e1e4a5d-8237-4a19-b90f-b666d0124d64,"Global climate change (GCC) is likely to alter the degree of human exposure to pollutants and the response of human populations to these exposures, meaning that risks of pollutants could change in the future. The present study, therefore, explores how GCC might affect the different steps in the pathway from a chemical source in the environment through to impacts on human health and evaluates the implications for existing risk-assessment and management practices. In certain parts of the world, GCC is predicted to increase the level of exposure of many environmental pollutants due to direct and indirect effects on the use patterns and transport and fate of chemicals. Changes in human behavior will also affect how humans come into contact with contaminated air, water, and food. Dietary changes, psychosocial stress, and coexposure to stressors such as high temperatures are likely to increase the vulnerability of humans to chemicals. These changes are likely to have significant implications for current practices for chemical assessment. Assumptions used in current exposure-assessment models may no longer apply, and existing monitoring methods may not be robust enough to detect adverse episodic changes in exposures. Organizations responsible for the assessment and management of health risks of chemicals therefore need to be more proactive and consider the implications of GCC for their procedures and processes.","Balbus, J. M.; Boxall, A. B.; Fenske, R. A.; McKone, T. E.; Zeise, L.",,0730-7268,1,"Environmental Toxicology and Chemistry","Climate; Climate Change; Environment; Environmental Exposure/statistics & numerical data; Environmental Pollutants/analysis/ toxicity; Humans; Models, Chemical; Risk; Risk Assessment",eng,"Balbus, John M Boxall, Alistair B A Fenske, Richard A McKone, Thomas E Zeise, Lauren Research Support, U.S. Gov't, Non-P.H.S. United States Environ Toxicol Chem. 2013 Jan;32(1):62-78. doi: 10.1002/etc.2046.",62-78,"Implications of global climate change for the assessment and management of human health risks of chemicals in the natural environment",,32,2013,0,4086,1e1e4a5d-8237-4a19-b90f-b666d0124d64,"Journal Article",/article/10.1002/etc.2046
/reference/1e53dfe8-f57f-46b5-a23a-0c23910c7a3e,https://data.globalchange.gov/reference/1e53dfe8-f57f-46b5-a23a-0c23910c7a3e,1e53dfe8-f57f-46b5-a23a-0c23910c7a3e,,DOE,,,,,,,,,"Electric Disturbance Events (OE-417)",http://www.oe.netl.doe.gov/oe417.aspx,,2012,16,18302,1e53dfe8-f57f-46b5-a23a-0c23910c7a3e,"Web Page",/webpage/7021af37-e49c-4be0-8a7c-46223dc2192d
/reference/1e90a679-d2ce-4cd4-85f3-2cbb63939d35,https://data.globalchange.gov/reference/1e90a679-d2ce-4cd4-85f3-2cbb63939d35,1e90a679-d2ce-4cd4-85f3-2cbb63939d35,,"Cotrufo, M. Francesca; Ineson, Phil; Scott, AndY",,1365-2486,1,"Global Change Biology",,,,43-54,"Elevated CO2 reduces the nitrogen concentration of plant tissues",,4,1998,0,16184,1e90a679-d2ce-4cd4-85f3-2cbb63939d35,"Journal Article",/article/10.1046/j.1365-2486.1998.00101.x
/reference/1e9449c2-c2e0-4da7-acd6-526247e0523b,https://data.globalchange.gov/reference/1e9449c2-c2e0-4da7-acd6-526247e0523b,1e9449c2-c2e0-4da7-acd6-526247e0523b,,"Gould, L.H.; Walsh, K.A.; Vieira, A.R.; Herman, K.; Williams, I.T.; Hall, A.J.; Cole, D.",,1545-8636,SS02,"Morbidity and Mortality Weekly Report - Surveillance Summaries",,,,1-34,"Surveillance for foodborne disease outbreaks - United States, 1998-2008",http://www.cdc.gov/mmwr/preview/mmwrhtml/ss6202a1.htm,62,2013,0,18305,1e9449c2-c2e0-4da7-acd6-526247e0523b,"Journal Article",/article/pmid-23804024
/reference/1e9a7907-02f2-4da8-9e93-131f92515dbc,https://data.globalchange.gov/reference/1e9a7907-02f2-4da8-9e93-131f92515dbc,1e9a7907-02f2-4da8-9e93-131f92515dbc,,"Martin-Latry, K.
Goumy, M.P.
Latry, P.
Gabinski, C.
Bégaud, B.
Faure, I.
Verdoux, H.",,0924-9338,6,"European Psychiatry",,,,335-338,"Psychotropic drugs use and risk of heat-related hospitalisation",,22,2007,0,1894,1e9a7907-02f2-4da8-9e93-131f92515dbc,"Journal Article",/article/10.1016/j.eurpsy.2007.03.007
/reference/1ebfdcac-9323-4232-9b1a-db5a13b09fd5,https://data.globalchange.gov/reference/1ebfdcac-9323-4232-9b1a-db5a13b09fd5,1ebfdcac-9323-4232-9b1a-db5a13b09fd5,,"Srinivasan, Shobha; O’Fallon, Liam R.; Dearry, Allen",,1541-0048,9,"American Journal of Public Health",,,,1446-1450,"Creating healthy communities, healthy homes, healthy people: Initiating a research agenda on the built environment and public health",,93,2003,0,17807,1ebfdcac-9323-4232-9b1a-db5a13b09fd5,"Journal Article",/article/10.2105/ajph.93.9.1446
/reference/1ece5a1e-f180-4940-bbe9-bbb179bc4397,https://data.globalchange.gov/reference/1ece5a1e-f180-4940-bbe9-bbb179bc4397,1ece5a1e-f180-4940-bbe9-bbb179bc4397,,"Mercer, J.B.",,0013-9351,1,"Environmental Research",,,,8-13,"Cold—an underrated risk factor for health",,92,2003,0,17611,1ece5a1e-f180-4940-bbe9-bbb179bc4397,"Journal Article",/article/10.1016/s0013-9351(02)00009-9
/reference/1ed548f5-a531-48fd-87dd-3a42334f4ce3,https://data.globalchange.gov/reference/1ed548f5-a531-48fd-87dd-3a42334f4ce3,1ed548f5-a531-48fd-87dd-3a42334f4ce3,,"Parr, Alyssa; Whitney, Ellen A.; Berkelman, Ruth L.",,1078-4659,5,"Journal of Public Health Management and Practice",,,,E17-E26,"Legionellosis on the rise: A review of guidelines for prevention in the United States",,21,2015,0,18810,1ed548f5-a531-48fd-87dd-3a42334f4ce3,"Journal Article",/article/10.1097/phh.0000000000000123
/reference/1ef4b4b9-4e5c-4ad1-b97b-b27eedf82889,https://data.globalchange.gov/reference/1ef4b4b9-4e5c-4ad1-b97b-b27eedf82889,1ef4b4b9-4e5c-4ad1-b97b-b27eedf82889,,WHO,,,,,,,,,"Dengue and Severe Dengue. Fact Sheet No. 117",http://www.who.int/mediacentre/factsheets/fs117/en/index.html,2014,2015,16,18350,1ef4b4b9-4e5c-4ad1-b97b-b27eedf82889,"Web Page",/webpage/0e40dc9b-ed77-4ea3-a1d9-0e4bcf6ebb49
/reference/1f0b5216-a12d-4731-ab23-47f9e4c24cb6,https://data.globalchange.gov/reference/1f0b5216-a12d-4731-ab23-47f9e4c24cb6,1f0b5216-a12d-4731-ab23-47f9e4c24cb6,,"Tofighi, Babak; Grossman, Ellie; Williams, Arthur R.; Biary, Rana; Rotrosen, John; Lee, Joshua D.",,1940-0640,1,"Addiction Science & Clinical Practice",,,,3,"Outcomes among buprenorphine-naloxone primary care patients after Hurricane Sandy",,9,2014,0,16416,1f0b5216-a12d-4731-ab23-47f9e4c24cb6,"Journal Article",/article/10.1186/1940-0640-9-3
/reference/1f3d783b-8f2b-484e-b391-ed42bf98b195,https://data.globalchange.gov/reference/1f3d783b-8f2b-484e-b391-ed42bf98b195,1f3d783b-8f2b-484e-b391-ed42bf98b195,"In response to a major influx of freshwater to the Mississippi Sound following the opening of the Bonnet Carre Spillway, water samples were collected from three sites along the Mississippi shoreline to assess the impact of altered salinity on three pathogenic Vibrio species. Salinity readings across the affected area during the 2011 sample period ranged from 1.4 to 12.9 ppt (mean = 7.0) and for the 2012 sample period from 14.1 to 23.6 ppt (mean = 19.8). Analyses of the data collected in 2011 showed a reduction in densities of Vibrio parahaemolyticus and Vibrio vulnificus with a concurrent increase of Vibrio cholerae numbers, with V. cholerae becoming the only Vibrio detected once salinity readings dropped to 6 ppt. Follow-up samples taken in 2012 after recovery of the salinity in the sound showed that the relative densities of the three pathogenic vibrios had reverted back to normal levels. This study shows that although the spillway was open but a few weeks and the effects were therefore time limited, the Mississippi River water had a profound, if temporary, effect on Vibrio ecology in the Mississippi Sound.","Griffitt, K. J.; Grimes, D. J.",,1432-184X,3,"Microbial Ecology","Ecosystem; Rivers/chemistry/*microbiology; Salinity; Sodium Chloride/analysis/metabolism; Vibrio cholerae/*growth & development/isolation & purification/metabolism; Vibrio parahaemolyticus/growth & development/isolation & purification/metabolism; Vibrio vulnificus/*growth & development/isolation & purification/metabolism",eng,"1432-184x Griffitt, Kimberly J Grimes, D Jay Journal Article Research Support, N.I.H., Extramural Research Support, U.S. Gov't, Non-P.H.S. United States Microb Ecol. 2013 Apr;65(3):578-83. doi: 10.1007/s00248-013-0203-6. Epub 2013 Mar 14.",578-583,"Abundance and Distribution of Vibrio cholerae, V. parahaemolyticus, and V. vulnificus Following a Major Freshwater Intrusion into the Mississippi Sound",,65,2013,0,18424,1f3d783b-8f2b-484e-b391-ed42bf98b195,"Journal Article",/article/10.1007/s00248-013-0203-6
/reference/1f461bf1-02cd-49d5-973b-32961301ddff,https://data.globalchange.gov/reference/1f461bf1-02cd-49d5-973b-32961301ddff,1f461bf1-02cd-49d5-973b-32961301ddff,,"Taub, Daniel R.; Wang, Xianzhong",,1744-7909,11,"Journal of Integrative Plant Biology",,,,1365-1374,"Why are nitrogen concentrations in plant tissues lower under elevated CO2? A critical examination of the hypotheses",,50,2008,0,16214,1f461bf1-02cd-49d5-973b-32961301ddff,"Journal Article",/article/10.1111/j.1744-7909.2008.00754.x
/reference/1f4ec538-27f4-4a34-9d75-2d4cf9d2e960,https://data.globalchange.gov/reference/1f4ec538-27f4-4a34-9d75-2d4cf9d2e960,1f4ec538-27f4-4a34-9d75-2d4cf9d2e960,,"Ye, X.
Wolff, R.
Yu, W.
Vaneckova, P.
Pan, X.
Tong, S.",,1552-9924,1,"Environmental Health Perspectives",,,,19-28,"Ambient temperature and morbidity: A review of epidemiological evidence",,120,2012,0,3505,1f4ec538-27f4-4a34-9d75-2d4cf9d2e960,"Journal Article",/article/10.1289/ehp.1003198
/reference/1f4f3b0a-9fcf-4369-9857-2e3bade59a5b,https://data.globalchange.gov/reference/1f4f3b0a-9fcf-4369-9857-2e3bade59a5b,1f4f3b0a-9fcf-4369-9857-2e3bade59a5b,,"Warner, Koko; Ranger, Nicola; Surminski, Swenja; Arnold, Margaret; Linnerooth-Bayer, Joanne; Michel-Kerjan, Erwann; Kovacs, Paul; Herweijer, Celine",,,,,,,,30,"Adaptation to Climate Change: Linking Disaster Risk Reduction and Insurance",http://www.unisdr.org/files/9654_linkingdrrinsurance.pdf,,2009,10,18989,1f4f3b0a-9fcf-4369-9857-2e3bade59a5b,Report,/report/unisdr-adaptation-2009
/reference/1f6857ab-f1ab-4902-962b-253333e82750,https://data.globalchange.gov/reference/1f6857ab-f1ab-4902-962b-253333e82750,1f6857ab-f1ab-4902-962b-253333e82750,,"Adamkiewicz, Gary; Zota, Ami R.; Fabian, Patricia; Chahine, Teresa; Julien, Rhona; Spengler, John D.; Levy, Jonathan I.",,1541-0048,S1,"American Journal of Public Health",,,,S238-S245,"Moving environmental justice indoors: Understanding structural influences on residential exposure patterns in low-income communities",,101,2011,0,19280,1f6857ab-f1ab-4902-962b-253333e82750,"Journal Article",/article/10.2105/AJPH.2011.300119