Your search keyword '"Dorigatti, Ilaria"' showing total 11 results

1. Estimating the effects of non-pharmaceutical interventions on COVID-19 in Europe

Author

Flaxman, Seth, Mishra, Swapnil, Gandy, Axel, Unwin, H. Juliette T., Mellan, Thomas A., Coupland, Helen, Whittaker, Charles, Zhu, Harrison, Berah, Tresnia, Eaton, Jeffrey W., Monod, Mélodie, Perez-Guzman, Pablo N., Schmit, Nora, Cilloni, Lucia, Ainslie, Kylie E. C., Baguelin, Marc, Boonyasiri, Adhiratha, Boyd, Olivia, Cattarino, Lorenzo, Cooper, Laura V., Cucunubá, Zulma, Cuomo-Dannenburg, Gina, Dighe, Amy, Djaafara, Bimandra, Dorigatti, Ilaria, van Elsland, Sabine L., FitzJohn, Richard G., Gaythorpe, Katy A. M., Geidelberg, Lily, Grassly, Nicholas C., Green, William D., Hallett, Timothy, Hamlet, Arran, Hinsley, Wes, Jeffrey, Ben, Knock, Edward, Laydon, Daniel J., Nedjati-Gilani, Gemma, Nouvellet, Pierre, Parag, Kris V., Siveroni, Igor, Thompson, Hayley A., Verity, Robert, Volz, Erik, Walters, Caroline E., Wang, Haowei, Wang, Yuanrong, Watson, Oliver J., Winskill, Peter, Xi, Xiaoyue, Walker, Patrick G. T., Ghani, Azra C., Donnelly, Christl A., Riley, Steven, Vollmer, Michaela A. C., Ferguson, Neil M., Okell, Lucy C., Bhatt, Samir, Medical Research Council (MRC), and Wellcome Trust

Subjects

0301 basic medicine, medicine.medical_specialty, General Science & Technology, Population, Pooling, Psychological intervention, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Case fatality rate, Pandemic, Epidemiology, Imperial College COVID-19 Response Team, Medicine, 030212 general & internal medicine, education, education.field_of_study, Science & Technology, Multidisciplinary, business.industry, Multidisciplinary Sciences, 030104 developmental biology, Transmission (mechanics), Science & Technology - Other Topics, business, Basic reproduction number, Demography

Abstract

Following the detection of the new coronavirus1 severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and its spread outside of China, Europe has experienced large epidemics of coronavirus disease 2019 (COVID-19). In response, many European countries have implemented non-pharmaceutical interventions, such as the closure of schools and national lockdowns. Here we study the effect of major interventions across 11 European countries for the period from the start of the COVID-19 epidemics in February 2020 until 4 May 2020, when lockdowns started to be lifted. Our model calculates backwards from observed deaths to estimate transmission that occurred several weeks previously, allowing for the time lag between infection and death. We use partial pooling of information between countries, with both individual and shared effects on the time-varying reproduction number (Rt). Pooling allows for more information to be used, helps to overcome idiosyncrasies in the data and enables more-timely estimates. Our model relies on fixed estimates of some epidemiological parameters (such as the infection fatality rate), does not include importation or subnational variation and assumes that changes in Rt are an immediate response to interventions rather than gradual changes in behaviour. Amidst the ongoing pandemic, we rely on death data that are incomplete, show systematic biases in reporting and are subject to future consolidation. We estimate that-for all of the countries we consider here-current interventions have been sufficient to drive Rt below 1 (probability Rt

Published

2020

2. Temperature and population density influence SARS-CoV-2 transmission in the absence of nonpharmaceutical interventions.

Author

Smith, Thomas P., Flaxman, Seth, Gallinat, Amanda S., Kinosian, Sylvia P., Stemkovski, Michael, Unwin, H. Juliette T., Watson, Oliver J., Whittaker, Charles, Cattarino, Lorenzo, Dorigatti, Ilaria, Tristem, Michael, and Pearse, William D.

Subjects

SARS-CoV-2, POPULATION density, COVID-19, SEASONS

Abstract

As COVID-19 continues to spread across the world, it is increasingly important to understand the factors that influence its transmission. Seasonal variation driven by responses to changing environment has been shown to affect the transmission intensity of several coronaviruses. However, the impact of the environment on severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) remains largely unknown, and thus seasonal variation remains a source of uncertainty in forecasts of SARS-CoV-2 transmission. Here we address this issue by assessing the association of temperature, humidity, ultraviolet radiation, and population density with estimates of transmission rate (R). Using data from the United States, we explore correlates of transmission across US states using comparative regression and integrative epidemiological modeling. We find that policy intervention ("lockdown") and reductions in individuals' mobility are the major predictors of SARS-CoV-2 transmission rates, but, in their absence, lower temperatures and higher population densities are correlated with increased SARS-CoV-2 transmission. Our results show that summer weather cannot be considered a substitute for mitigation policies, but that lower autumn and winter temperatures may lead to an increase in transmission intensity in the absence of policy interventions or behavioral changes. We outline how this information may improve the forecasting of COVID-19, reveal its future seasonal dynamics, and inform intervention policies. [ABSTRACT FROM AUTHOR]

Published

2021

3. The epidemiology of Mayaro virus in the Americas: A systematic review and key parameter estimates for outbreak modelling.

Author

Caicedo, Edgar-Yaset, Charniga, Kelly, Rueda, Amanecer, Dorigatti, Ilaria, Mendez, Yardany, Hamlet, Arran, Carrera, Jean-Paul, and Cucunubá, Zulma M.

Subjects

BASIC reproduction number, EPIDEMIOLOGY, YELLOW fever, TROPICAL forests, PHYTOPLASMAS

Abstract

Mayaro virus (MAYV) is an arbovirus that is endemic to tropical forests in Central and South America, particularly within the Amazon basin. In recent years, concern has increased regarding MAYV's ability to invade urban areas and cause epidemics across the region. We conducted a systematic literature review to characterise the evolutionary history of MAYV, its transmission potential, and exposure patterns to the virus. We analysed data from the literature on MAYV infection to produce estimates of key epidemiological parameters, including the generation time and the basic reproduction number, R0. We also estimated the force-of-infection (FOI) in epidemic and endemic settings. Seventy-six publications met our inclusion criteria. Evidence of MAYV infection in humans, animals, or vectors was reported in 14 Latin American countries. Nine countries reported evidence of acute infection in humans confirmed by viral isolation or reverse transcription-PCR (RT-PCR). We identified at least five MAYV outbreaks. Seroprevalence from population based cross-sectional studies ranged from 21% to 72%. The estimated mean generation time of MAYV was 15.2 days (95% CrI: 11.7–19.8) with a standard deviation of 6.3 days (95% CrI: 4.2–9.5). The per-capita risk of MAYV infection (FOI) ranged between 0.01 and 0.05 per year. The mean R0 estimates ranged between 2.1 and 2.9 in the Amazon basin areas and between 1.1 and 1.3 in the regions outside of the Amazon basin. Although MAYV has been identified in urban vectors, there is not yet evidence of sustained urban transmission. MAYV's enzootic cycle could become established in forested areas within cities similar to yellow fever virus. Author summary: Each year, diseases that are transmitted by mosquitoes cause substantial deaths and disability across the world. We performed a systematic literature review of Mayaro virus (MAYV) and estimated key epidemiological parameters that can be used to improve future outbreak response. We estimated the generation time and basic reproduction number for a historical outbreak. Our results suggest that the force-of-infection of MAYV in endemic settings is low. We did not find evidence of substantial urban transmission of MAYV. Nevertheless, similarities between MAYV and yellow fever virus epidemiology suggest that MAYV could emerge in urban areas. Local transmission of MAYV has never been reported outside of Central and South America. Our results highlight the need to continue monitoring emerging arboviruses in the Americas. [ABSTRACT FROM AUTHOR]

Published

2021

4. Correction: The epidemiology of Mayaro virus in the Americas: A systematic review and key parameter estimates for outbreak modelling.

Author

Caicedo, Edgar-Yaset, Charniga, Kelly, Rueda, Amanecer, Dorigatti, Ilaria, Mendez, Yardany, Hamlet, Arran, Carrera, Jean-Paul, and Cucunubá, Zulma M.

Subjects

EPIDEMIOLOGY, CUMULATIVE distribution function, PROBABILITY density function

Abstract

The text says, "We estimated a mean incubation period SB IP sb of 3.0 (95% CrI: 2.2-3.8) days and a standard deviation SB IP sb of 1.2 (95% CrI: 1.0-1.7) days." Table E. Characteristics of Mayaro fever cases included in the intrinsic incubation period analysis (N = 15). It should say, "We estimated a mean incubation period SB IP sb of 3.0 (95% CrI: 2.4-4.1) days and a standard deviation SB IP sb of 0.3 (95% CrI: 0.0-2.1) days.". [Extracted from the article]

Published

2023

5. Modelling the impact of co-circulating low pathogenic avian influenza viruses on epidemics of highly pathogenic avian influenza in poultry.

Author

Nickbakhsh, Sema, Hall, Matthew D., Dorigatti, Ilaria, Lycett, Samantha J., Mulatti, Paolo, Monne, Isabella, Fusaro, Alice, Woolhouse, Mark E.J., Rambaut, Andrew, and Kao, Rowland R.

Abstract

It is well known that highly pathogenic avian influenza (HPAI) viruses emerge through mutation of precursor low pathogenic avian influenza (LPAI) viruses in domestic poultry populations. The potential for immunological cross-protection between these pathogenic variants is recognised but the epidemiological impact during co-circulation is not well understood. Here we use mathematical models to investigate whether altered flock infection parameters consequent to primary LPAI infections can impact on the spread of HPAI at the population level. First we used mechanistic models reflecting the co-circulatory dynamics of LPAI and HPAI within a single commercial poultry flock. We found that primary infections with LPAI led to HPAI prevalence being maximised under a scenario of high but partial cross-protection. We then tested the population impact in spatially-explicit simulations motivated by a major avian influenza A(H7N1) epidemic that afflicted the Italian poultry industry in 1999–2001. We found that partial cross-protection can lead to a prolongation of HPAI epidemic duration. Our findings have implications for the control of HPAI in poultry particularly for settings in which LPAI and HPAI frequently co-circulate. [ABSTRACT FROM AUTHOR]

Published

2016

6. Estimating transmission probability in schools for the 2009 H1N1 influenza pandemic in Italy.

Author

Clamer, Valentina, Dorigatti, Ilaria, Fumanelli, Laura, Rizzo, Caterina, and Pugliese, Andrea

Subjects

H1N1 influenza, MONTE Carlo method, SCHOOL children, EPIDEMIOLOGY, DIAGNOSIS, INFECTIOUS disease transmission, JUVENILE diseases

Abstract

Background: Epidemic models are being extensively used to understand the main pathways of spread of infectious diseases, and thus to assess control methods. Schools are well known to represent hot spots for epidemic spread; hence, understanding typical patterns of infection transmission within schools is crucial for designing adequate control strategies. The attention that was given to the 2009 A/H1N1pdm09 flu pandemic has made it possible to collect detailed data on the occurrence of influenza-like illness (ILI) symptoms in two primary schools of Trento, Italy. Results: The data collected in the two schools were used to calibrate a discrete-time SIR model, which was designed to estimate the probabilities of influenza transmission within the classes, grades and schools using Markov Chain Monte Carlo (MCMC) methods. We found that the virus was mainly transmitted within class, with lower levels of transmission between students in the same grade and even lower, though not significantly so, among different grades within the schools. We estimated median values of R0 from the epidemic curves in the two schools of 1.16 and 1.40; on the other hand, we estimated the average number of students infected by the first school case to be 0.85 and 1.09 in the two schools. Conclusions: The discrepancy between the values of R0 estimated from the epidemic curve or from the within-school transmission probabilities suggests that household and community transmission played an important role in sustaining the school epidemics. The high probability of infection between students in the same class confirms that targeting within-class transmission is key to controlling the spread of influenza in school settings and, as a consequence, in the general population. [ABSTRACT FROM AUTHOR]

Published

2016

7. Estimating Dengue Transmission Intensity from Case-Notification Data from Multiple Countries.

Author

Imai, Natsuko, Dorigatti, Ilaria, Cauchemez, Simon, and Ferguson, Neil M.

Subjects

*DENGUE viruses, *SEROPREVALENCE, *DISEASE prevalence, *DENGUE hemorrhagic fever, *DENGUE, *DIAGNOSIS of fever, *INFECTIOUS disease transmission

Abstract

Background: Despite being the most widely distributed mosquito-borne viral infection, estimates of dengue transmission intensity and associated burden remain ambiguous. With advances in the development of novel control measures, obtaining robust estimates of average dengue transmission intensity is key for assessing the burden of disease and the likely impact of interventions. Methodology/Principle Findings: We estimated the force of infection (λ) and corresponding basic reproduction numbers (R0) by fitting catalytic models to age-stratified incidence data identified from the literature. We compared estimates derived from incidence and seroprevalence data and assessed the level of under-reporting of dengue disease. In addition, we estimated the relative contribution of primary to quaternary infections to the observed burden of dengue disease incidence. The majority of R0 estimates ranged from one to five and the force of infection estimates from incidence data were consistent with those previously estimated from seroprevalence data. The baseline reporting rate (or the probability of detecting a secondary infection) was generally low (<25%) and varied within and between countries. Conclusions/Significance: As expected, estimates varied widely across and within countries, highlighting the spatio-temporally heterogeneous nature of dengue transmission. Although seroprevalence data provide the maximum information, the incidence models presented in this paper provide a method for estimating dengue transmission intensity from age-stratified incidence data, which will be an important consideration in areas where seroprevalence data are not available. [ABSTRACT FROM AUTHOR]

Published

2016

8. Modelling Virus and Antibody Dynamics during Dengue Virus Infection Suggests a Role for Antibody in Virus Clearance.

Author

Clapham, Hannah E, Quyen, Than Ha, Kien, Duong Thi Hue, Dorigatti, Ilaria, Simmons, Cameron P, and Ferguson, Neil M

Subjects

DENGUE viruses, DENGUE, IMMUNOGLOBULINS, VIROLOGY, EPIDEMIOLOGY, IMMUNE response, PATIENTS

Abstract

Dengue is an infection of increasing global importance, yet uncertainty remains regarding critical aspects of its virology, immunology and epidemiology. One unanswered question is how infection is controlled and cleared during a dengue infection. Antibody is thought to play a role, but little past work has examined the kinetics of both virus and antibody during natural infections. We present data on multiple virus and antibody titres measurements recorded sequentially during infection from 53 Vietnamese dengue patients. We fit mechanistic mathematical models of the dynamics of viral replication and the host immune response to these data. These models fit the data well. The model with antibody removing virus fits the data best, but with a role suggested for ADCC or other infected cell clearance mechanisms. Our analysis therefore shows that the observed viral and antibody kinetics are consistent with antibody playing a key role in controlling viral replication. This work gives quantitative insight into the relationship between antibody levels and the efficiency of viral clearance. It will inform the future development of mechanistic models of how vaccines and antivirals might modify the course of natural dengue infection. [ABSTRACT FROM AUTHOR]

Published

2016

9. Potential Biases in Estimating Absolute and Relative Case-Fatality Risks during Outbreaks.

Author

Lipsitch, Marc, Donnelly, Christl A., Fraser, Christophe, Blake, Isobel M., Cori, Anne, Dorigatti, Ilaria, Ferguson, Neil M., Garske, Tini, Mills, Harriet L., Riley, Steven, Van Kerkhove, Maria D., and Hernán, Miguel A.

Subjects

EMERGING infectious diseases, MORTALITY, EPIDEMIOLOGY, PROGRESSION-free survival, PREVENTION of communicable diseases, CRISIS management

Abstract

Estimating the case-fatality risk (CFR)—the probability that a person dies from an infection given that they are a case—is a high priority in epidemiologic investigation of newly emerging infectious diseases and sometimes in new outbreaks of known infectious diseases. The data available to estimate the overall CFR are often gathered for other purposes (e.g., surveillance) in challenging circumstances. We describe two forms of bias that may affect the estimation of the overall CFR—preferential ascertainment of severe cases and bias from reporting delays—and review solutions that have been proposed and implemented in past epidemics. Also of interest is the estimation of the causal impact of specific interventions (e.g., hospitalization, or hospitalization at a particular hospital) on survival, which can be estimated as a relative CFR for two or more groups. When observational data are used for this purpose, three more sources of bias may arise: confounding, survivorship bias, and selection due to preferential inclusion in surveillance datasets of those who are hospitalized and/or die. We illustrate these biases and caution against causal interpretation of differential CFR among those receiving different interventions in observational datasets. Again, we discuss ways to reduce these biases, particularly by estimating outcomes in smaller but more systematically defined cohorts ascertained before the onset of symptoms, such as those identified by forward contact tracing. Finally, we discuss the circumstances in which these biases may affect non-causal interpretation of risk factors for death among cases. [ABSTRACT FROM AUTHOR]

Published

2015

10. Increased transmissibility explains the third wave of infection by the 2009 H1N1 pandemic virus in England.

Author

Dorigatti, Ilaria, Cauchemez, Simon, and Ferguson, Neil M.

Subjects

*H1N1 influenza, *DISEASE susceptibility, *PANDEMICS, *EPIDEMIOLOGY, *IMMUNITY, *VIROLOGY, *MATHEMATICAL models, *INFECTIOUS disease transmission, *PREVENTION

Abstract

In the 2009 H1N1 pandemic, the United Kingdom experienced two waves of infection, the first in the late spring and the second in the autumn. Given the low level of susceptibility to the pandemic virus expected to be remaining in the population after the second wave, it was a surprise that a substantial third epidemic occurred in the UK population between November 2010 and February 2011, despite no evidence for any significant antigenic evolution of the pandemic virus. Here, we use a mathematical model of influenza transmission embedded within a Bayesian synthesis inferential framework to jointly analyze syndromic, virological, and serological surveillance data collected in England in 2009-2011 and thereby assess epidemiological mechanisms which might have generated the third wave. We find that substantially increased transmissibility of the H1N1pdm09 virus is required to reproduce the third wave, suggesting that the virus evolved and increased fitness in the human host by the end of 2010, or that the very cold weather experienced in the United Kingdom at that time enhanced transmission rates. We also find some evidence that the preexisting heterologous immunity which reduced attack rates in adults during 2009 had substantially decayed by the winter of 2010, thus increasing the susceptibility of the adult population to infection. Finally, our analysis suggests that a pandemic vaccination campaign targeting adults and school-age children could have mitigated or prevented the third wave even at moderate levels of coverage. [ABSTRACT FROM AUTHOR]

Published

2013

11. Rapid SARS-CoV-2 Intra-Host and Within-Household Emergence of Novel Haplotypes.

Author

Manuto, Laura, Grazioli, Marco, Spitaleri, Andrea, Fontana, Paolo, Bianco, Luca, Bertolotti, Luigi, Bado, Martina, Mazzotti, Giorgia, Bianca, Federico, Onelia, Francesco, Lorenzin, Giovanni, Simeoni, Fabio, Lazarevic, Dejan, Franchin, Elisa, Vecchio, Claudia Del, Dorigatti, Ilaria, Tonon, Giovanni, Cirillo, Daniela Maria, Lavezzo, Enrico, and Crisanti, Andrea

Subjects

HAPLOTYPES, COVID-19, VIRAL genomes, SARS-CoV-2, VIRAL transmission, SMALL cities, IMMUNODEFICIENCY

Abstract

In February 2020, the municipality of Vo', a small town near Padua (Italy) was quarantined due to the first coronavirus disease 19 (COVID-19)-related death detected in Italy. To investigate the viral prevalence and clinical features, the entire population was swab tested in two sequential surveys. Here we report the analysis of 87 viral genomes, which revealed that the unique ancestor haplotype introduced in Vo' belongs to lineage B, carrying the mutations G11083T and G26144T. The viral sequences allowed us to investigate the viral evolution while being transmitted within and across households and the effectiveness of the non-pharmaceutical interventions implemented in Vo'. We report, for the first time, evidence that novel viral haplotypes can naturally arise intra-host within an interval as short as two weeks, in approximately 30% of the infected individuals, regardless of symptom severity or immune system deficiencies. Moreover, both phylogenetic and minimum spanning network analyses converge on the hypothesis that the viral sequences evolved from a unique common ancestor haplotype that was carried by an index case. The lockdown extinguished both the viral spread and the emergence of new variants. [ABSTRACT FROM AUTHOR]

Published

2022