NASA. Vital signs of the planet. URL: https://climatenasagov/vital-signs/global-temperature/(dataobrashhenija:25122019). 2018.

IPCC. Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty. 2018.

NRDC. Global climate change: what you need to know 2021 [cited 2022 June 25]. Available from: https://climatenasagov/vital-signs/global-temperature/(dataobrashhenija:25122019). 2018

El-Sayed A, Kamel M. Climatic changes and their role in emergence and re-emergence of diseases. Environ Sci Pollut Res Int. 2020;27(18):22336–52.

CAS  Google Scholar 

Gubler DJ. The global threat of emergent/re-emergent vector-borne diseases. Vector Biology, Ecology and Control: Springer Netherlands; 2010. p. 39–62.

Balogun EO, Nok AJ, Kita K. Global warming and the possible globalization of vector-borne diseases: a call for increased awareness and action. Tropical Medicine and Health. 2016;44(1):1–3.

Google Scholar 

Christofferson RC, Parker DM, Overgaard HJ, et al. Current vector research challenges in the greater Mekong subregion for dengue, Malaria, and Other Vector-Borne Diseases: a report from a multisectoral workshop March 2019. PLoS Negl Trop Dis. 2020;14(7):e0008302–e0008302.

Google Scholar 

Dudley JP, Hoberg EP, Jenkins EJ, et al. Climate change in the North American Arctic: a one health perspective. EcoHealth. 2015;12(4):713–25.

Google Scholar 

Otranto D, Dantas-Torres F, Breitschwerdt EB. Managing canine vector-borne diseases of zoonotic concern: part one. Trends in Parasitology. 2009;4:157–63.

Google Scholar 

Ostfeld RS, Brunner JL. Climate change and Ixodes tick-borne diseases of humans. Philos Trans R Soc Lond B Biol Sci. 2015;370(1665):20140051.

Google Scholar 

Artigas P, Reguera-Gomez M, Valero MA, et al. Aedes albopictus diversity and relationships in south-western Europe and Brazil by rDNA/mtDNA and phenotypic analyses: ITS-2, a useful marker for spread studies. Parasit Vectors. 2021;14(1):333–333.

CAS  Google Scholar 

Shuman EK. Global climate change and infectious diseases. New Eng J Medicine. 2010;362(12):1061–3.

CAS  Google Scholar 

Betts R. Met Office: Atmospheric CO2 now hitting 50% higher than pre-industrial levels. Carbon Brief. 2021.

IPCC. Climate change 2021: the physical science basis. Contribution of working group I to the sixth assessment report of the intergovernmental panel on climate change2021. p. 2.

Bach W. Fossil fuel resources and their impacts on environment and climate. Int J Hydrogen Energy. 1981;6(2):185–201.

CAS  Google Scholar 

Lynch J, Cain M, Frame D, et al. Agriculture’s contribution to climate change and role in mitigation is distinct from predominantly fossil CO2-emitting sectors. Frontiers in sustainable food systems. 2021:300.

Bala G, Caldeira K, Wickett M, et al. Combined climate and carbon-cycle effects of large-scale deforestation. Proc Natl Acad Sci. 2007;104(16):6550–5.

CAS  Google Scholar 

Moomaw WR. Industrial emissions of greenhouse gases. Energy Policy. 1996;24(10–11):951–68.

Google Scholar 

WHO. Climate change and health 2021 [cited 2022 June 25]. Available from: https://www.who.int/news-room/fact-sheets/detail/climate-change-and-health

Lacetera N. Impact of climate change on animal health and welfare. Anim Front. 2019;9(1):26–31.

Google Scholar 

Luterbacher J, Dietrich D, Xoplaki E, et al. European seasonal and annual temperature variability, trends, and extremes since 1500. Science. 2004;303(5663):1499–503.

CAS  Google Scholar 

Vitali A, Felici A, Esposito S, et al. The effect of heat waves on dairy cow mortality. J Dairy Sci. 2015;98(7):4572–9.

CAS  Google Scholar 

• Ebi KL, Vanos J, Baldwin JW, et al. Extreme weather and climate change: population health and health system implications. Annual review of public health. 2021;42:293–315. Describes the effects of extreme weather conditions on health system and concludes that the only panacea to climate change is the establishment of climate-resilient health systems with improved risk reduction, preparation, response, and recovery.

Froment R, Below R. Disaster* year in review 2019. Centre for Research on the Epidemiology of Disasters (CRED) Louvain; 2020.

Langner J, Bergström R, Foltescu V. Impact of climate change on surface ozone and deposition of sulphur and nitrogen in Europe. Atmos Environ. 2005;39(6):1129–41.

CAS  Google Scholar 

Racherla PN, Adams PJ. Sensitivity of global tropospheric ozone and fine particulate matter concentrations to climate change. Journal of Geophysical Research: Atmospheres. 2006;111(D24).

NRC. Advancing the science of climate change. National Academies Press; 2011.

Parker ER. The influence of climate change on skin cancer incidence–a review of the evidence. Int J Women’s Dermatol. 2021;7(1):17–27.

Google Scholar 

USEPA. Climate impacts on water quality 2022 [cited 2022 June 25]. Available from: https://www.epa.gov/arc-x/climate-impacts-water-quality

D’Amato G, Chong-Neto HJ, Monge Ortega OP, et al. The effects of climate change on respiratory allergy and asthma induced by pollen and mold allergens. Allergy. 2020;75(9):2219–28.

Google Scholar 

Perrone G, Ferrara M, Medina A, et al. Toxigenic fungi and mycotoxins in a climate change scenario: ecology, genomics, distribution, prediction and prevention of the risk. Microorganisms. 2020;8(10):1496.

CAS  Google Scholar 

Kim K-H, Kabir E, Ara JS. A review of the consequences of global climate change on human health. J Environ Sci Health C. 2014;32(3):299–318.

Google Scholar 

Hotez PJ. Southern Europe’s coming plagues: vector-borne neglected tropical diseases. CA USA: Public Library of Science San Francisco; 2016. p. e0004243.

Google Scholar 

WHO. Global Vector Control Response 2017–2030. 2017.

Wuebbles D, Fahey D, Hibbard K, et al. US Global Change Research Program: Washington. DC, USA. 2017;1.

•• Rocklöv J, Dubrow R. Climate change: an enduring challenge for vector-borne disease prevention and control. Nat Immunol. 2020;21(5):479–483. Triangulates how meteorological variables affect the incidence, transmission- season duration, and spread of vector-borne diseases; and models effects of future climate change that can aid long-term planning for the prevention and control of vector-borne diseases.

Liu-Helmersson J, Stenlund H, Wilder-Smith A, et al. Vectorial capacity of Aedes aegypti: effects of temperature and implications for global dengue epidemic potential. PLoS ONE. 2014;9(3):e89783–e89783.

Google Scholar 

Rocklöv J, Tozan Y, Ramadona A, et al. Using big data to monitor the introduction and spread of Chikungunya, Europe, 2017. Emerg Infect Dis. 2019;25(6):1041–9.

Google Scholar 

Morin CW, Comrie AC, Ernst K. Climate and dengue transmission: evidence and implications. Environ Health Perspect. 2013;121(11–12):1264–72.

Google Scholar 

Paz S. Effects of climate change on vector-borne diseases: an updated focus on West Nile virus in humans. Emerging Topics in Life Sci. 2019;3(2):143–52.

Google Scholar 

Colón-González FJ, Sewe MO, Tompkins AM, et al. Projecting the risk of mosquito-borne diseases in a warmer and more populated world: a multi-model, multi-scenario intercomparison modelling study. Lancet Planet Health. 2021;5(7):e404–14.

Google Scholar 

Agency EE. Climate change, impacts and vulnerability in Europe 2016 : an indicator-based report. Publications Office; 2017.

Chalghaf B, Chemkhi J, Mayala B, et al. Ecological niche modeling predicting the potential distribution of Leishmania vectors in the Mediterranean basin: impact of climate change. Parasit Vectors. 2018;11(1):1–9.

Google Scholar 

Fros JJ, Geertsema C, Vogels CB, et al. West Nile virus: high transmission rate in north-western European mosquitoes indicates its epidemic potential and warrants increased surveillance. PLoS Negl Trop Dis. 2015;9(7):e0003956.

Google Scholar 

Casimiro E, Calheiros J, Santos FD, et al. National assessment of human health effects of climate change in Portugal: approach and key findings. Environ Health Perspect. 2006;114(12):1950–6.

Google Scholar 

Alves M, Fernandes P, Amaro F, et al. Clinical presentation and laboratory findings for the first autochthonous cases of dengue fever in Madeira island, Portugal, October 2012. Eurosurveillance. 2013;18(6):20398.

Google Scholar 

Marchand E, Prat C, Jeannin C, et al. Autochthonous case of dengue in France, October 2013. Eurosurveillance. 2013 18(50).

•• Semenza JC, Paz S. Climate change and infectious disease in Europe: impact, projection and adaptation. Lancet Reg Health Eur. 2021;9:100230–100230. Discusses climate change–related hazards, exposures, and vulnerabilities to infectious disease in Europe and describes observed impacts, projected risks, and policy entry points for adaptation to reduce or avoid these risks.

Fischer D, Thomas SM, Niemitz F, et al. Projection of climatic suitability for Aedes albopictus Skuse (Culicidae) in Europe under climate change conditions. Global and Planetary Change. 2011;78(1–2):54–64.

Google Scholar 

Grandadam M, Caro V, Plumet S, et al. Chikungunya virus, southeastern France. Emerg Infect Dis. 2011;17(5):910–3.

Google Scholar 

Rezza G. Dengue and chikungunya: long-distance spread and outbreaks in naïve areas. Pathog Glob Health. 2014;108(8):349–55.

Google Scholar 

Sissoko D, Giry C, Gabrie P, et al. Rift Valley fever, Mayotte, 2007–2008. Emerg Infect Dis. 2009;15(4):568–70.

Google Scholar 

Marini G, Calzolari M, Angelini P, et al. A quantitative comparison of West Nile virus incidence from 2013 to 2018 in Emilia-Romagna. Italy PLoS Negl Trop Dis. 2020;14(1):e0007953–e0007953.

Google Scholar 

Rudolf I, Betášová L, Blažejová H, et al. West Nile virus in overwintering mosquitoes, central Europe. Parasit Vectors. 2017;10(1):452–452.

Google Scholar 

Genchi C, Kramer LH. The prevalence of Dirofilaria immitis and D repens in the Old World. Veterinary Parasitology. 2020;280:108995.

Google Scholar 

Mathanga DP, Tembo AK, Mzilahowa T, et al. Patterns and determinants of malaria risk in urban and peri-urban areas of Blantyre. Malawi Malar J. 2016;15(1):590–590.

Google Scholar 

Takken W, Lindsay S. Increased threat of urban malaria from Anopheles stephensi mosquitoes. Africa Emerg Infect Dis. 2019;25(7):1431–3.

Google Scholar 

Grillet ME, Hernández-Villena JV, Llewellyn MS, et al. Venezuela’s humanitarian crisis, resurgence of vector-borne diseases, and implications for spillover in the region. The Lancet Infect Dis. 2019;19(5):e149–61.

Google Scholar 

Watts N, Amann M, Arnell N, et al. The 2019 report of The Lancet Countdown on health and climate change: ensuring that the health of a child born today is not defined by a changing climate. The Lancet. 2019;394(10211):1836–78.

Google Scholar 

WHO. Dengue: guidelines for diagnosis, treatment, prevention and control. Geneva. 2009.

Rosen L. Dengue in Greece in 1927 and 1928 and the pathogenesis of dengue hemorrhagic fever: new data and a different conclusion. Am J Trop Med Hygiene. 1986;35(3):642–53.

CAS  Google Scholar 

Schmidt-Chanasit J, Haditsch M, Schöneberg I, et al. Dengue virus infection in a traveller returning from Croatia to Germany. Eurosurveillance. 2010;15(40).

Adalja AA, Sell TK, Bouri N, et al. Lessons learned during dengue outbreaks in the United States, 2001–2011. Emerg Infect Dis. 2012;18(4):608–14.

Google Scholar 

Ross RW. The Newala epidemic III The virus: isolation, pathogenic properties and relationship to the epidemic. J Hyg (Lond). 1956;54(2):177–91.

CAS  Google Scholar 

Ng LC, Hapuarachchi HC. Tracing the path of Chikungunya virus—evolution and adaptation. Infect Genetics Evolution. 2010;10(7):876–85.

Google Scholar 

Rezza G, Nicoletti L, Angelini R, et al. Infection with chikungunya virus in Italy: an outbreak in a temperate region. The Lancet. 2007;370(9602):1840–6.

CAS  Google Scholar 

Njenga MK, Nderitu L, Ledermann J, et al. Tracking epidemic chikungunya virus into the Indian Ocean from East Africa. J Gen Virol. 2008;89(Pt 11):2754.

CAS  Google Scholar 

Kumar NP, Joseph R, Kamaraj T, et al. A226V mutation in virus during the 2007 chikungunya outbreak in Kerala. India J General Virology. 2008;89(8):1945–8.

CAS  Google Scholar 

EFSA. Opinion of the scientific panel on animal health and welfare (AHAW) on a request from the commission related to the aspects of the biology and welfare of animals used for experimental and other scientific purposes. EFSA Journal. 2005;3(12):292.

Google Scholar 

Chevalier V, Pépin M, Plée L, et al. Rift Valley fever - a threat for Europe? Eurosurveillance. 2010;15(10).

Fortuna C, Montarsi F, Severini F, et al. The common European mosquitoes Culex pipiens and Aedes albopictus are unable to transmit SARS-CoV-2 after a natural-mimicking challenge with infected blood. Parasit Vectors. 2021;14(1):1–6.

Google Scholar 

Kilpatrick AM, Meola MA, Moudy RM, et al. Temperature, viral genetics, and the transmission of West Nile virus by Culex pipiens mosquitoes. PLoS Pathog. 2008;4(6):e1000092–e1000092.

Google Scholar 

Paz S, Semenza JC. Environmental drivers of West Nile fever epidemiology in Europe and Western Asia–a review. Int J Environ Res Public Health. 2013;10(8):3543–62.

Google Scholar 

May FJ, Davis CT, Tesh RB, et al. Phylogeography of West Nile virus: from the cradle of evolution in Africa to Eurasia, Australia, and the Americas. J Virol. 2011;85(6):2964–74.

CAS  Google Scholar 

Sambri V, Capobianchi M, Charrel R, et al. West Nile virus in Europe: emergence, epidemiology, diagnosis, treatment, and prevention. Clin Microbiol Infec. 2013;19(8):699–704.

CAS  Google Scholar 

Vlaskamp DR, Thijsen SF, Reimerink J, et al. First autochthonous human West Nile virus infections in the Netherlands, July to August 2020. Euro Surveill. 2020;25(46):2001904.

CAS  Google Scholar 

Cotar AI, Falcuta E, Prioteasa LF, et al. Transmission dynamics of the West Nile virus in mosquito vector populations under the influence of weather factors in the Danube Delta. Romania EcoHealth. 2016;13(4):796–807.

Google Scholar 

Morchón R, Carretón E,