Your search keyword '"Gibb, Rory"' showing total 6 results

1. Differing taxonomic responses of mosquito vectors to anthropogenic land-use change in Latin America and the Caribbean.

Author

Fletcher, Isabel K., Gibb, Rory, Lowe, Rachel, and Jones, Kate E.

Subjects

*AEDES aegypti, *MOSQUITO vectors, *URBAN biodiversity, *AGRICULTURE, *DISEASE vectors, *SPECIES diversity

Abstract

Anthropogenic land-use change, such as deforestation and urban development, can affect the emergence and re-emergence of mosquito-borne diseases, e.g., dengue and malaria, by creating more favourable vector habitats. There has been a limited assessment of how mosquito vectors respond to land-use changes, including differential species responses, and the dynamic nature of these responses. Improved understanding could help design effective disease control strategies. We compiled an extensive dataset of 10,244 Aedes and Anopheles mosquito abundance records across multiple land-use types at 632 sites in Latin America and the Caribbean. Using a Bayesian mixed effects modelling framework to account for between-study differences, we compared spatial differences in the abundance and species richness of mosquitoes across multiple land-use types, including agricultural and urban areas. Overall, we found that mosquito responses to anthropogenic land-use change were highly inconsistent, with pronounced responses observed at the genus- and species levels. There were strong declines in Aedes (-26%) and Anopheles (-35%) species richness in urban areas, however certain species such as Aedes aegypti, thrived in response to anthropogenic disturbance. When abundance records were coupled with remotely sensed forest loss data, we detected a strong positive response of dominant and secondary malaria vectors to recent deforestation. This highlights the importance of the temporal dynamics of land-use change in driving disease risk and the value of large synthetic datasets for understanding changing disease risk with environmental change. Author summary: An understanding of the response of disease vectors to anthropogenic activities can aid in the control of mosquito-borne disease transmission. However, regional assessments of these responses are lacking, especially in areas where mosquito-borne diseases are emerging and re-emerging. We assembled a synthetic dataset of mosquito abundance and species richness across multiple land-use types in Latin America and the Caribbean, using data from peer-reviewed published studies. We then used this dataset to explore whether mosquito abundance and species richness changed, compared to a baseline of minimal anthropogenic activity, depending on the type of land use. Overall, we observed a decline in mosquito biodiversity in urban areas. We detected distinct species-specific responses in abundance to land use, with some important disease vectors, such as Aedes aegypti, increasing in abundance in anthropogenic environments. Finally, we also demonstrated by coupling our dataset with forest loss data that the abundance of dominant malaria vectors in the region increases with deforestation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Data Proliferation, Reconciliation, and Synthesis in Viral Ecology.

Author

Gibb, Rory, Albery, Gregory F, Becker, Daniel J, Brierley, Liam, Connor, Ryan, Dallas, Tad A, Eskew, Evan A, Farrell, Maxwell J, Rasmussen, Angela L, Ryan, Sadie J, Sweeny, Amy, Carlson, Colin J, and Poisot, Timothée

Subjects

*VIRAL ecology, *RECONCILIATION, *MACROECOLOGY, *WORK structure, *ZOONOSES

Abstract

The fields of viral ecology and evolution are rapidly expanding, motivated in part by concerns around emerging zoonoses. One consequence is the proliferation of host–virus association data, which underpin viral macroecology and zoonotic risk prediction but remain fragmented across numerous data portals. In the present article, we propose that synthesis of host–virus data is a central challenge to characterize the global virome and develop foundational theory in viral ecology. To illustrate this, we build an open database of mammal host–virus associations that reconciles four published data sets. We show that this offers a substantially richer view of the known virome than any individual source data set but also that databases such as these risk becoming out of date as viral discovery accelerates. We argue for a shift in practice toward the development, incremental updating, and use of synthetic data sets in viral ecology, to improve replicability and facilitate work to predict the structure and dynamics of the global virome. [ABSTRACT FROM AUTHOR]

Published

2021

3. Bat detective—Deep learning tools for bat acoustic signal detection.

Author

Mac Aodha, Oisin, Gibb, Rory, Barlow, Kate E., Browning, Ella, Firman, Michael, Freeman, Robin, Harder, Briana, Kinsey, Libby, Mead, Gary R., Newson, Stuart E., Pandourski, Ivan, Parsons, Stuart, Russ, Jon, Szodoray-Paradi, Abigel, Szodoray-Paradi, Farkas, Tilova, Elena, Girolami, Mark, Brostow, Gabriel, and Jones, Kate E.

Subjects

*BATS, *ACOUSTIC signal detection, *MAMMALS, *SIGNAL detection, *ARTIFICIAL neural networks

Abstract

Passive acoustic sensing has emerged as a powerful tool for quantifying anthropogenic impacts on biodiversity, especially for echolocating bat species. To better assess bat population trends there is a critical need for accurate, reliable, and open source tools that allow the detection and classification of bat calls in large collections of audio recordings. The majority of existing tools are commercial or have focused on the species classification task, neglecting the important problem of first localizing echolocation calls in audio which is particularly problematic in noisy recordings. We developed a convolutional neural network based open-source pipeline for detecting ultrasonic, full-spectrum, search-phase calls produced by echolocating bats. Our deep learning algorithms were trained on full-spectrum ultrasonic audio collected along road-transects across Europe and labelled by citizen scientists from . When compared to other existing algorithms and commercial systems, we show significantly higher detection performance of search-phase echolocation calls with our test sets. As an example application, we ran our detection pipeline on bat monitoring data collected over five years from Jersey (UK), and compared results to a widely-used commercial system. Our detection pipeline can be used for the automatic detection and monitoring of bat populations, and further facilitates their use as indicator species on a large scale. Our proposed pipeline makes only a small number of bat specific design decisions, and with appropriate training data it could be applied to detecting other species in audio. A crucial novelty of our work is showing that with careful, non-trivial, design and implementation considerations, state-of-the-art deep learning methods can be used for accurate and efficient monitoring in audio. [ABSTRACT FROM AUTHOR]

Published

2018

4. Relaxation of anti-COVID-19 measures reveals new challenges for infectious disease outbreak forecasting.

Author

Brady, Oliver J, Hofmann, Barbara, Colón-González, Felipe J, Gibb, Rory, Lowe, Rachel, Tsarouchi, Gina, Harpham, Quillon, Lumbroso, Darren, Lan, Phan Trong, and Nam, Vu Sinh

Subjects

*EMERGING infectious diseases, *DISEASE outbreaks, *FORECASTING

Published

2023

5. Joint spatiotemporal modelling reveals seasonally dynamic patterns of Japanese encephalitis vector abundance across India.

Author

Franklinos, Lydia H. V., Redding, David W., Lucas, Tim C. D., Gibb, Rory, Abubakar, Ibrahim, and Jones, Kate E.

Subjects

*JAPANESE B encephalitis, *VECTOR data, *LAND surface temperature, *MOSQUITO vectors, *RESOURCE allocation, *BIOSPHERE, *RICE quality

Abstract

Predicting vector abundance and seasonality, key components of mosquito-borne disease (MBD) hazard, is essential to determine hotspots of MBD risk and target interventions effectively. Japanese encephalitis (JE), an important MBD, is a leading cause of viral encephalopathy in Asia with 100,000 cases estimated annually, but data on the principal vector Culex tritaeniorhynchus is lacking. We developed a Bayesian joint-likelihood model that combined information from available vector occurrence and abundance data to predict seasonal vector abundance for C. tritaeniorhynchus (a constituent of JE hazard) across India, as well as examining the environmental drivers of these patterns. Using data collated from 57 locations from 24 studies, we find distinct seasonal and spatial patterns of JE vector abundance influenced by climatic and land use factors. Lagged precipitation, temperature and land use intensity metrics for rice crop cultivation were the main drivers of vector abundance, independent of seasonal, or spatial variation. The inclusion of environmental factors and a seasonal term improved model prediction accuracy (mean absolute error [MAE] for random cross validation = 0.42) compared to a baseline model representative of static hazard predictions (MAE = 0.51), signalling the importance of seasonal environmental conditions in predicting JE vector abundance. Vector abundance varied widely across India with high abundance predicted in northern, north-eastern, eastern, and southern regions, although this ranged from seasonal (e.g., Uttar Pradesh, West Bengal) to perennial (e.g., Assam, Tamil Nadu). One-month lagged predicted vector abundance was a significant predictor of JE outbreaks (odds ratio 2.45, 95% confidence interval: 1.52–4.08), highlighting the possible development of vector abundance as a proxy for JE hazard. We demonstrate a novel approach that leverages information from sparse vector surveillance data to predict seasonal vector abundance–a key component of JE hazard–over large spatial scales, providing decision-makers with better guidance for targeting vector surveillance and control efforts. Author summary: Japanese encephalitis (JE) is the leading cause of viral encephalopathy in Asia with an estimated 100,000 annual cases and 25,000 deaths. However, insufficient data on the predominant mosquito vector Culex tritaeniorhynchus–a key component of JE hazard–precludes hazard estimation required to target public health interventions. Previous studies have provided limited estimates of JE hazard, often predicting geographic distributions of potential vector occurrence without accounting for vector abundance, seasonality, or uncertainty in predictions. This study details a novel approach to predict spatiotemporal patterns in JE vector abundance using a joint-likelihood modelling technique that leverages information from sparse vector surveillance data. We showed that patterns in JE vector abundance were driven by seasonality and environmental factors and so demonstrated the limitations of previously available static vector distribution maps in estimating the vector population component of JE hazard. One-month lagged vector abundance predictions showed a positive relationship with JE outbreaks, signalling the potential use of vector abundance as a proxy for JE hazard. While vector surveillance data are limited, joint-likelihood models offer a useful approach to inform vector abundance predictions. This study provides decision-makers with a more complete picture of the distribution of JE vector abundance and can be used to target vector surveillance and control efforts and enhance the allocation of resources. [ABSTRACT FROM AUTHOR]

Published

2022

6. The future of zoonotic risk prediction.

Author

Carlson, Colin J., Farrell, Maxwell J., Grange, Zoe, Han, Barbara A., Mollentze, Nardus, Phelan, Alexandra L., Rasmussen, Angela L., Albery, Gregory F., Bett, Bernard, Brett-Major, David M., Cohen, Lily E., Dallas, Tad, Eskew, Evan A., Fagre, Anna C., Forbes, Kristian M., Gibb, Rory, Halabi, Sam, Hammer, Charlotte C., Katz, Rebecca, and Kindrachuk, Jason

Subjects

*COVID-19 pandemic, *MACHINE learning, *WORLD health, *TECHNOLOGY assessment, *VIRAL ecology, *PANDEMICS, *ZOONOSES

Abstract

In the light of the urgency raised by the COVID-19 pandemic, global investment in wildlife virology is likely to increase, and new surveillance programmes will identify hundreds of novel viruses that might someday pose a threat to humans. To support the extensive task of laboratory characterization, scientists may increasingly rely on data-driven rubrics or machine learning models that learn from known zoonoses to identify which animal pathogens could someday pose a threat to global health. We synthesize the findings of an interdisciplinary workshop on zoonotic risk technologies to answer the following questions. What are the prerequisites, in terms of open data, equity and interdisciplinary collaboration, to the development and application of those tools? What effect could the technology have on global health? Who would control that technology, who would have access to it and who would benefit from it? Would it improve pandemic prevention? Could it create new challenges? [ABSTRACT FROM AUTHOR]

Published

2021