Modelling the impact of COVID-19-related control programme interruptions on progress towards the WHO 2030 target for soil-transmitted helminths
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L. Coffeng | F. Giardina | S. D. de Vlas | R. Anderson | K. McRae-McKee | S. Bajaj | V. Malizia | Carolin Vegvari
[1] J. Utzinger,et al. The global progress of soil-transmitted helminthiases control in 2020 and World Health Organization targets for 2030 , 2020, PLoS neglected tropical diseases.
[2] Martin Walker,et al. Modelling for policy: The five principles of the Neglected Tropical Diseases Modelling Consortium , 2020, PLoS neglected tropical diseases.
[3] L. Coffeng,et al. Insights from quantitative analysis and mathematical modelling on the proposed WHO 2030 goals for soil-transmitted helminths , 2019, Gates open research.
[4] R. Anderson,et al. The Geshiyaro Project: a study protocol for developing a scalable model of interventions for moving towards the interruption of the transmission of soil-transmitted helminths and schistosome infections in the Wolaita zone of Ethiopia , 2019, Parasites & Vectors.
[5] S. Brooker,et al. Heterogeneity in transmission parameters of hookworm infection within the baseline data from the TUMIKIA study in Kenya , 2019, Parasites & Vectors.
[6] L. Coffeng,et al. Investigating the Effectiveness of Current and Modified World Health Organization Guidelines for the Control of Soil-Transmitted Helminth Infections , 2018, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.
[7] Bryan J Weiner,et al. Evaluating the sustainability, scalability, and replicability of an STH transmission interruption intervention: The DeWorm3 implementation science protocol , 2018, PLoS neglected tropical diseases.
[8] G. Kang,et al. Assessing the feasibility of interrupting the transmission of soil-transmitted helminths through mass drug administration: The DeWorm3 cluster randomized trial protocol , 2018, PLoS neglected tropical diseases.
[9] P. Lamberton,et al. Soil-transmitted helminth infections , 2017, The Lancet.
[10] L. Moja,et al. Preventive chemotherapy to control soil-transmitted helminth infections in at-risk population groups : guideline , 2017 .
[11] L. Coffeng,et al. Comparison and validation of two mathematical models for the impact of mass drug administration on Ascaris lumbricoides and hookworm infection , 2017, Epidemics.
[12] J. McCarthy,et al. Complexities and Perplexities: A Critical Appraisal of the Evidence for Soil-Transmitted Helminth Infection-Related Morbidity , 2016, PLoS neglected tropical diseases.
[13] L. Coffeng,et al. Feasibility of controlling hookworm infection through preventive chemotherapy: a simulation study using the individual-based WORMSIM modelling framework , 2015, Parasites & Vectors.
[14] J. McCarthy,et al. Assessment of Anthelmintic Efficacy of Mebendazole in School Children in Six Countries Where Soil-Transmitted Helminths Are Endemic , 2011, PLoS neglected tropical diseases.
[15] G. Kang,et al. Assessment of the Anthelmintic Efficacy of Albendazole in School Children in Seven Countries Where Soil-Transmitted Helminths Are Endemic , 2011, PLoS neglected tropical diseases.
[16] S. Brooker,et al. Impact of hookworm infection and deworming on anaemia in non-pregnant populations: a systematic review , 2010, Tropical medicine & international health : TM & IH.
[17] G. Medley,et al. A new approach to morbidity risk assessment in hookworm endemic communities , 1992, Epidemiology and Infection.
[18] R. Imtiaz. NTD Modelling Consortium discussion group on soil-transmitted helminths , 2019 .
[19] L. Coffeng,et al. Insights from quantitative analysis and mathematical modelling on the proposed WHO 2030 goals for soil-transmitted helminths. , 2019, Gates open research.
[20] Peter J Hotez,et al. Human hookworm infection in the 21st century. , 2004, Advances in parasitology.