| Nome |
# |
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Environmental drivers of West Nile virus in Europe: a modelling approach, file e1dbfeac-1726-4ac9-e053-1705fe0a1c61
|
762
|
|
Exploring vector-borne infection ecology in multi-host communities: a case study of West Nile virus, file e1dbfeaa-e0e4-4ac9-e053-1705fe0a1c61
|
685
|
|
Quantitative impacts of temperature on mosquito dynamics and their transmitted pathogens: a modelling approach, file e1dbfeab-e667-4ac9-e053-1705fe0a1c61
|
685
|
|
Recent increase of Dobrava-Belgrade virus (DOBV) in yellow-necked mice in northern Italy, file e1dbfeaa-8257-4ac9-e053-1705fe0a1c61
|
537
|
|
Why account for biodiversity for mitigating tick-borne disease risk? Insights and perspectives from eastern Italian Alps, file 2a8e1548-4a1f-4e8b-839f-69d7189fe4d5
|
423
|
|
Modeling the West Nile virus incidence and seroprevalence in the avian host population in northern Italy, file 86adfa89-f3d3-41d8-ae9b-3cb7951c6660
|
315
|
|
Il ruolo dei modelli deterministici nella prevenzione delle malattie endemiche: il caso del West Nile Virus, file e1dbfeac-00cf-4ac9-e053-1705fe0a1c61
|
284
|
|
Modelling the human force of infection of West Nile virus in Europe, file 1210aa98-216d-4d56-a614-c1fd16a0baf7
|
279
|
|
Temporal variation of Dobrava-Belgrade virus (Bunyaviridae, Hantavirus) seroprevalence in a yellow-necked mice population in northern Italy, file e1dbfeaa-a277-4ac9-e053-1705fe0a1c61
|
267
|
|
The effect of interspecific competition between Culex pipiens and Aedes albopictus in northern Italy, file e1dbfeaa-e7a5-4ac9-e053-1705fe0a1c61
|
267
|
|
Early warning of West Nile virus mosquito vector: climate and land use models successfully explain phenology and abundance of Culex pipiens mosquitoes in north-western Italy, file e1dbfeaa-7c53-4ac9-e053-1705fe0a1c61
|
231
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|
Bayesian statistical models to evaluate the efficacy of traditional and innovative mosquito control interventions, file e1dbfeac-00cd-4ac9-e053-1705fe0a1c61
|
229
|
|
The effect of interspecific competition on the temporal dynamics of Aedes albopictus and Culex pipiens, file e1dbfeaa-fe9e-4ac9-e053-1705fe0a1c61
|
226
|
|
West Nile virus transmission and human infection risk in Veneto (Italy): a modelling analysis, file e1dbfeab-81c1-4ac9-e053-1705fe0a1c61
|
223
|
|
Identifying the environmental conditions favouring West Nile virus outbreaks in Europe, file e1dbfeaa-8102-4ac9-e053-1705fe0a1c61
|
204
|
|
Temporal patterns of Culex pipiens and Aedes albopictus in northern Italy: the effect of interspecific competition, file e1dbfeaa-e67e-4ac9-e053-1705fe0a1c61
|
201
|
|
Mapping of Aedes albopictus abundance at a local scale in Italy, file e1dbfeab-3ae3-4ac9-e053-1705fe0a1c61
|
190
|
|
A spatio-temporal predictive model inferring the year-to-year probability of occurrence of TBE human cases in Europe, file a39da54a-52ae-4e29-8673-e43412148b9a
|
177
|
|
AIMSurv: First pan-European harmonized surveillance of Aedes invasive mosquito species of relevance for human vector-borne diseases, file e1dbfeac-1cb2-4ac9-e053-1705fe0a1c61
|
177
|
|
Effectiveness of Ultra-Low Volume insecticide spraying to prevent dengue in a non-endemic metropolitan area of Brazil, file e1dbfeab-9e20-4ac9-e053-1705fe0a1c61
|
174
|
|
The role of climatic and density dependent factors in shaping mosquito population dynamics: the case of Culex pipiens in Northwestern Italy, file e1dbfeaa-d989-4ac9-e053-1705fe0a1c61
|
172
|
|
First outbreak of Zika virus in the continental United States: a modelling analysis, file e1dbfeab-41b3-4ac9-e053-1705fe0a1c61
|
164
|
|
A quantitative comparison of West Nile virus incidence from 2013 to 2018 in Emilia-Romagna, Italy, file e1dbfeab-b93d-4ac9-e053-1705fe0a1c61
|
141
|
|
Parasites and wildlife in a changing world: the vector-host- pathogen interaction as a learning case, file e1dbfeab-aca3-4ac9-e053-1705fe0a1c61
|
136
|
|
First report of the influence of temperature on the bionomics and population dynamics of Aedes koreicus, a new invasive alien species in Europe, file e1dbfeab-bfd0-4ac9-e053-1705fe0a1c61
|
129
|
|
Associazione tra fattori ambientali e insorgenza di una malattia a trasmissione vettoriale in aree
temperate: il caso studio dell’ultima epidemia di Chikungunya in Italia, file b7cf026a-dc55-4214-9af8-5997780cad4f
|
125
|
|
The role of climatic factors in shaping mosquito population dynamics: the case of Culex pipiens in Northwestern Italy, file e1dbfeaa-9cfd-4ac9-e053-1705fe0a1c61
|
124
|
|
Environmental and landscape factors associated with West Nile vector population dynamics in North-western Italy, file e1dbfeaa-79b0-4ac9-e053-1705fe0a1c61
|
123
|
|
Dynamics and Distribution of the Invasive Mosquito Aedes koreicus in a Temperate European City, file e1dbfeab-cf8e-4ac9-e053-1705fe0a1c61
|
119
|
|
Mosquito-borne infections in Europe: Assessment of public health risks via temperature-driven mathematical models, file e1dbfeab-e9cc-4ac9-e053-1705fe0a1c61
|
81
|
|
Estimating rodent population abundance using early climatic predictors, file e4a9bcd3-a4f6-4a2a-bb7f-6879dec45069
|
77
|
|
Does high habitat diversity reduce the risk of TBE in Europe?, file 231cc856-7328-41c0-897f-07c670716901
|
70
|
|
Influence of temperature on the life-cycle dynamics of Aedes albopictus population established at temperate latitudes: a laboratory experiment, file e1dbfeab-eae3-4ac9-e053-1705fe0a1c61
|
68
|
|
The importance of climatic and ecological factors for vector-borne infections: Culex pipiens and West Nile virus, file e1dbfeab-149e-4ac9-e053-1705fe0a1c61
|
62
|
|
Modelling West Nile virus transmission and human infection risk in Veneto (Italy), file e1dbfeab-75dd-4ac9-e053-1705fe0a1c61
|
62
|
|
Influence of temperature on the biology of Aedes koreicus: an experimental and modelling study, file e1dbfeab-8292-4ac9-e053-1705fe0a1c61
|
60
|
|
Epidemiology of West Nile virus in Africa: an underestimated threat, file e1dbfeac-10e5-4ac9-e053-1705fe0a1c61
|
60
|
|
High habitat richness limits the risk of tick-borne encephalitis in Europe: a multi-scale study, file be40b716-29bc-4d3b-9e71-b9a7e840c8bc
|
56
|
|
Disentangling the ecological conditions favouring West Nile virus hazard in the Old World, file e1dbfeaa-7c7b-4ac9-e053-1705fe0a1c61
|
55
|
|
Understanding the dynamics of West Nile virus in Emilia-Romagna, Italy, file e1dbfeab-43eb-4ac9-e053-1705fe0a1c61
|
51
|
|
Understanding the environmental drivers of West Nile Virus (WNV) emergence in Europe, file e1dbfeaa-74ab-4ac9-e053-1705fe0a1c61
|
44
|
|
Mathematical modelling of mosquito dispersal, file e1dbfeab-cb6a-4ac9-e053-1705fe0a1c61
|
41
|
|
Early warning signals of tick-borne encephalitis risk, file b42da5f4-9e4c-4f4b-849e-462e44c413c1
|
40
|
|
West Nile virus Lineage 2 overwintering in Italy, file ef719a94-3eae-4039-87b5-7b95901647c4
|
40
|
|
Recent increase in prevalence of antibodies to Dobrava-Belgrade virus (DOBV) in yellow-necked mice in northern Italy, file e1dbfeaa-82ac-4ac9-e053-1705fe0a1c61
|
38
|
|
Modelling the first outbreak of Zika virus in continental USA, file e1dbfeab-4247-4ac9-e053-1705fe0a1c61
|
36
|
|
Temporal patterns of Culex pipiens and Aedes albopictus in northern Italy: the effect of interspecific competition, file e1dbfeaa-f020-4ac9-e053-1705fe0a1c61
|
35
|
|
Spatial and temporal dynamics of West Nile virus between Africa and Europe, file 1e10ebc2-679b-4597-8b05-5761d233d334
|
33
|
|
Evaluation of Bacillus thuringiensis subsp. Israelensis and Bacillus sphaericus combination against Culex pipiens in highly vegetated ditches, file e1dbfeac-1e69-4ac9-e053-1705fe0a1c61
|
33
|
|
Quantifying the force of infection of West Nile virus in the European human population, file 3dbf82f9-a90d-410a-8307-eb026de34cf0
|
31
|
|
Aedes koreicus, a vector on the rise: Pan-European genetic patterns, mitochondrial and draft genome sequencing, file 74874387-81af-4725-9ec1-9e0364c5299b
|
28
|
|
Estimating the potential risk of transmission of arboviruses in the Americas and Europe: a modeling study, file 7b79f296-f1c6-4039-aeae-1b46f47ea0ea
|
28
|
|
A modelling analysis of West Nile virus transmission and human infection risk in Veneto (Italy), file e1dbfeab-8e8a-4ac9-e053-1705fe0a1c61
|
27
|
|
Predicting rodent population dynamics as early warning for zoonotic disease transmission, file e1dbfeac-1fa1-4ac9-e053-1705fe0a1c61
|
27
|
|
Population dynamics of endemic mosquito species and their epidemiological implications in Northern Italy, file e1dbfeab-345c-4ac9-e053-1705fe0a1c61
|
25
|
|
Identifying the most relevant covariates for the development of tick-borne encephalitis (TBE) hazard models at continental scale, file e1dbfeac-20ea-4ac9-e053-1705fe0a1c61
|
25
|
|
La concentrazione di polline in atmosfera per la previsione del rischio di encefalite da zecca, file bde89602-cdbf-4cff-8039-328a5f5df451
|
23
|
|
Modelling the transmission dynamics of West Nile virus in Emilia-Romagna region (Italy), file e1dbfeab-cb69-4ac9-e053-1705fe0a1c61
|
23
|
|
Understanding the environmental drivers of West Nile Virus (WNV) emergence in Europe, file e1dbfeaa-79ad-4ac9-e053-1705fe0a1c61
|
22
|
|
West Nile Virus in Africa: current epidemiological situation and knowledge gaps, file e1dbfeac-1faa-4ac9-e053-1705fe0a1c61
|
22
|
|
Epidemiological and evolutionary analysis of West Nile Virus lineage 2 in Italy, file ae3adeb3-c83d-4aa7-8367-b72425aeca51
|
21
|
|
First report of the blood-feeding pattern in Aedes koreicus, a new invasive species in Europe, file 07a75df4-eea7-4ba9-8d41-302e3cc96056
|
20
|
|
Modelling the West Nile virus force of infection in the European human population, file 2a1ee7f5-a01c-4322-9219-1c13e092926d
|
20
|
|
Understanding West Nile virus transmission: mathematical modelling to quantify the most critical parameters to predict infection dynamics, file 6a9dc9fd-c2f3-43c2-afc2-cc9512476aa0
|
20
|
|
How habitat factors affect an Aedes mosquitoes driven outbreak at temperate latitudes: the case of the Chikungunya virus in Italy, file d1bc3306-9fe6-4eb9-8c9d-8d25f5b814de
|
19
|
|
Understanding the dynamics of West Nile virus in Emilia-Romagna, Italy, file e1dbfeab-43ea-4ac9-e053-1705fe0a1c61
|
18
|
|
Assessing the ecological covariates related to tick-borne encephalitis emergence in Europe., file 5793ba3e-d6c3-49f5-9fdb-9990a3f99488
|
13
|
|
Assessing the ecological covariates related to tick-borne encephalitis emergence in Europe., file 57dd56d7-808e-4b0a-9c0d-7ed020dfd7d2
|
13
|
|
Airborne pollen: a potential warning alert for tickborne encephalitis risk, file 785b9eb9-08d4-4c79-9f51-ae0763206e4e
|
13
|
|
Correlation between airborne pollen data and the risk of tick-borne encephalitis in northern Italy, file 869a81e9-602d-4e0f-b660-ccbd033f292b
|
12
|
|
High habitat richness reduces the risk of tick-borne encephalitis in Europe: a multi-scale study, file fed643af-b565-4ede-be13-224905269206
|
12
|
|
Contribution of climate change to the emergence of West Nile virus in Europe, file de510b42-8998-4ff4-b905-c6525d830fa1
|
9
|
|
Reporting delays of chikungunya cases during the 2017 outbreak in Lazio region, Italy, file f0ceda1d-f192-4a83-ad49-ee08ca03b449
|
9
|
|
Diapause characterization in the invasive alien mosquito species Aedes koreicus: a laboratory experiment, file bcbfe49d-7b25-4601-addf-46250c6a9fde
|
8
|
|
Estimating the potential risk of transmission of arboviruses in the Americas and Europe: a modelling study, file a62d572f-8ff7-44ad-ae19-e2fad77cac83
|
7
|
|
High habitat richness reduces the risk of tickborne encephalitis in Europe: a multi-scale study, file b8a49e9c-c983-4d2f-b380-7faa108cc109
|
7
|
|
Modeling the West Nile virus force of infection in the avian host population in Northern Italy, file cda80f1f-67e6-465b-8647-601d67b5469b
|
7
|
|
Estimating rodent population abundance using early climatic predictors, file d2b69ce0-a742-4d6f-8303-46fc87782d4c
|
7
|
|
Investigating the spatiotemporal association between climate and West Nile Virus transmission, file e1dbfeac-06ad-4ac9-e053-1705fe0a1c61
|
7
|
|
dynamAedes: a unified modelling framework for invasive Aedes mosquitoes, file 04e9234c-869f-4c08-bbf1-2d5301aedcb2
|
6
|
|
Ecological and environmental factors affecting the risk of tick-borne encephalitis in Europe, 2017 to 2021, file 6c564666-3f9f-44b9-9dbc-de6545534464
|
6
|
|
Contribution of climate change to the emergence of West Nile virus in Europe, file c13cca88-46f5-4db5-abf5-4c046892b7c6
|
6
|
|
How to reduce West Nile infection risk for humans? Mathematical modelling to predict effectiveness of intervention strategies, file e1dbfeac-0677-4ac9-e053-1705fe0a1c61
|
6
|
|
Contribution of climate change to the spatial expansion of West Nile virus in Europe, file 0342e873-ef5b-4fca-86ac-83866695b87e
|
5
|
|
Combining key hazard- and exposure-related drivers to model the probability of occurrence of TBE human cases in Europe, file 3a735d3c-c7c8-4320-ab87-e57f1eb6e823
|
5
|
|
Predicting tick-borne encephalitis risk using airborne pollen data in Western Central Europe, file 51f94848-04e3-41ba-a34a-ef9e398cc354
|
5
|
|
Modelling West Nile virus transmission in Emilia-Romagna region (Italy): 2018 vs. previous seasons, file e1dbfeab-c2e9-4ac9-e053-1705fe0a1c61
|
5
|
|
Understanding West Nile spread: mathematical modelling to investigate the influence of epidemiological mechanisms on infection dynamics, file e1dbfeac-042f-4ac9-e053-1705fe0a1c61
|
5
|
|
Predicting tick-borne encephalitis risk using airborne pollen data in Western Central Europe, file 9effd7f2-4933-41fa-ac4f-b3ff6c89defa
|
4
|
|
Correlation between airborne pollen loads and tick borne encephalitis incidence in Northern Italy, file dc2eda08-b876-4107-b2fd-5f5960b2223e
|
4
|
|
West Nile virus transmission in Europe is shaped by spring temperature, file e1dbfeab-e049-4ac9-e053-1705fe0a1c61
|
4
|
|
West Nile Virus in Africa: current epidemiological situation and knowledge gaps, file e1dbfeac-042e-4ac9-e053-1705fe0a1c61
|
4
|
|
Drivers of West Nile virus human transmission risk in Europe, file 2bfe8fd1-b0dc-4841-9e62-3ad615ccc6b2
|
3
|
|
Epidemiological and evolutionary analysis of West Nile virus lineage 2 in Italy, file 8e48e57e-a412-48f1-a63a-6da2351d868b
|
3
|
|
Effectiveness of adulticides in preventing dengue transmission in temperate non endemic metropolitan areas, file e1dbfeab-a882-4ac9-e053-1705fe0a1c61
|
3
|
|
Spring temperature shapes West Nile virus transmission in Europe, file e1dbfeab-e3ce-4ac9-e053-1705fe0a1c61
|
3
|
|
Predicting rodent population dynamics as early warning for zoonotic disease transmission, file e1dbfeac-042d-4ac9-e053-1705fe0a1c61
|
3
|
|
West Nile virus transmission in Europe is critically driven by spring temperature, file e1dbfeac-1a88-4ac9-e053-1705fe0a1c61
|
3
|
|
Macroparasites as drivers of emerging disease, file 20e8fe76-626e-4611-b1b1-ab43fca1f6da
|
2
|
|
A systematic review of West Nile virus human seroprevalence in Europe, file 793cc6b7-c1b9-4cc7-bfa8-b5e5c647710f
|
2
|
| Totale |
9.421 |