Leveraging mathematical models of disease dynamics and machine learning to improve development of novel malaria interventions

Golumbeanu, Monica; Yang, Guo-Jing; Stuckey, Erin M.; Hamon, Nicholas; Mondy, Mathias; Rees, Sarah; Chitnis, Nakul; Cameron, Ewan; Penny, Melissa A.

doi:10.1186/s40249-022-00981-1

Cited by 9 publications

(9 citation statements)

References 54 publications

(54 reference statements)

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“…Our analysis then applied a mathematical framework for predicting determinants of intervention impact and defining minimum drug profile criteria. This framework has been previously described, 28 and was demonstrated in a proof-of-concept study 27 (as summarised in appendix 1.4). In brief, we used the individual-based malaria transmission model to simulate scenarios over a wide range of input values for intervention coverage and drug initial efficacy and duration of protection.…”

Section: Methodsmentioning

confidence: 99%

Design and selection of drug properties to increase the public health impact of next-generation seasonal malaria chemoprevention: a modelling study

Braunack-Mayer,

Malinga,

Masserey

et al. 2023

Preprint

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BackgroundSeasonal malaria chemoprevention (SMC) is recommended for disease control in settings with moderate to highPlasmodium falciparumtransmission and currently depends on administration of sulfadoxine-pyrimethamine with amodiaquine. However, poor regimenadherence and the increasedfrequencyof sulfadoxine-pyrimethamine resistant parasite mutations may threaten SMC’s effectiveness. We need guidance to de-risk the development of drug compounds for malaria prevention.MethodsWe combined an individual-based malaria transmission model that has explicit parasite growth with drug pharmacokinetic/pharmacodynamic models. We modelled SMC drug attributes for several possible modes-of-action, linked to their potential public health impact. Global sensitivity analyses identified trade-offs between drug elimination half-life, maximum killing effect, and SMC coverage, and optimisation identified minimum requirements to maximise malaria burden reductions.FindingsModel predictions show that preventing infection for the entire period between SMC cycles is more important than drug curative efficacy for clinical disease effectiveness outcomes, but similarly important for impact on prevalence. When four SMC cycles are deployed to children under five years with high levels of coverage (69% of children receiving all cycles), drug candidates require a duration of protection half-life of >23 days (elimination half-life >10 days) to achieve >75% clinical incidence and severe disease reductions (measured over the intervention period in the target population, compared with no intervention across a range of modelled scenarios). High coverage is critical to achieve these targets, requiring >60% of children received all SMC cycles and >90% of children at least one cycle regardless of the drug’s duration.InterpretationWhile efficacy is crucial for malaria prevalence reductions, chemoprevention development should select drug candidates for their duration of protection to maximise burden reductions, with the duration half-life determiningcycle timing. Explicitlydesigning or selectingdrug properties to increase communityuptake is paramount.FundingBill & Melinda Gates Foundation and the Swiss National Science Foundation.

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Section: Methodsmentioning

confidence: 99%

Design and selection of drug properties to increase the public health impact of next-generation seasonal malaria chemoprevention: a modelling study

Braunack-Mayer,

Malinga,

Masserey

et al. 2023

Preprint

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“…Therefore, we trained an HGP ( Binois and Gramacy, 2021 ) on a limited set of OpenMalaria simulations (3500–11,500 simulations). We then used the trained emulator to predict the output of OpenMalaria for a large number of simulations and used these outputs to perform the global sensitivity analysis ( Figure 1C ), adapting a similar approach to Golumbeanu et al, 2022 and Reiker et al, 2021 . Our approach involved: (i) randomly sampling combinations of parameters; (ii) simulating and estimating the rate of spread of the resistant genotype for each parameter combination in OpenMalaria; (iii) training an HGP to learn the relationship between the input (for the different drivers) and output (the rate of spread) with iterative improvements to fitting through adaptive sampling; and (iv) performing a global sensitivity analysis based on the Sobol variance decomposition using the trained emulator ( Kilian et al, 2000 ).…”

Section: Methodsmentioning

confidence: 99%

“…We trained the HGP on the training dataset using the function mleHetGPfrom the R package ‘hetGP’ ( Binois and Gramacy, 2021 ). We chose to use HGP as it was successfully used in two previous studies that performed global sensitivity analyses of OpenMalaria ( Reiker et al, 2021 ; Golumbeanu et al, 2022 ). In addition, Reiker et al, 2021 tested different emulators and found that HGP provided the best fit with a limited number of simulations (analysis not shown in the published study).…”

Section: Methodsmentioning

confidence: 99%

The influence of biological, epidemiological, and treatment factors on the establishment and spread of drug-resistant Plasmodium falciparum

Masserey

Lee

Golumbeanu

et al. 2022

eLife

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The effectiveness of artemisinin-based combination therapies (ACTs) to treat Plasmodium falciparum malaria is threatened by resistance. The complex interplay between sources of selective pressure—treatment properties, biological factors, transmission intensity, and access to treatment—obscures understanding how, when, and why resistance establishes and spreads across different locations. We developed a disease modelling approach with emulator-based global sensitivity analysis to systematically quantify which of these factors drive establishment and spread of drug resistance. Drug resistance was more likely to evolve in low transmission settings due to the lower levels of (i) immunity and (ii) within-host competition between genotypes. Spread of parasites resistant to artemisinin partner drugs depended on the period of low drug concentration (known as the selection window). Spread of partial artemisinin resistance was slowed with prolonged parasite exposure to artemisinin derivatives and accelerated when the parasite was also resistant to the partner drug. Thus, to slow the spread of partial artemisinin resistance, molecular surveillance should be supported to detect resistance to partner drugs and to change ACTs accordingly. Furthermore, implementing more sustainable artemisinin-based therapies will require extending parasite exposure to artemisinin derivatives, and mitigating the selection windows of partner drugs, which could be achieved by including an additional long-acting drug.

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“…Modelling captures these dynamics to link individual and community benefits, allowing clinical trial evidence to be integrated into updated models or public health estimates, and can also support translating clinical trial results into implementation considerations. In early product development stages, population-level modelling can provide quantitative evidence linking an intervention’s minimum key performance criteria, such as efficacy or duration with its projected public health impact and benefit to communities towards meeting health targets, thus contributing to a robust evidence base 8 . While clinical evidence is essential to inform efficacy estimates and eventual registration and funding decisions for products, clinical evidence also informs model parameters, and modelling evidence in turn can improve clinical trial planning and design.…”

Section: Establishing An Iterative Approach and Framework To Generate...mentioning

confidence: 99%

“…The collaborative framework generates modelling evidence using dynamic, individual-based malaria transmission models, such as the OpenMalaria model that was developed over a period of 15 years. Detailed models are coupled with additional analytical and statistical approaches to enable rapid and computationally efficient searches of multi-dimensional parameter spaces spanning a wide range of intervention characteristics and settings 8 . Modelling the mechanisms of individual-level factors and population-level transmission dynamics links predictions of public health burden reduction to key intervention characteristics.…”

Section: Building a Collaborative Framework In Practicementioning

confidence: 99%

Modelling to inform next-generation medical interventions for malaria prevention and treatment

et al. 2023

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Global progress against malaria has stagnated and novel medical interventions to prevent malaria are needed to fill gaps in existing tools and improve protection against infection and disease. Candidate selection for next-generation interventions should be supported by the best available evidence. Target product profiles and preferred product characteristics play a key role in setting selection criteria requirements and early endorsement by health authorities. While clinical evidence and expert opinion often inform product development decisions, integrating modelling evidence early and iteratively into this process provides an opportunity to link product characteristics with expected public health outcomes. Population models of malaria transmission can provide a better understanding of which, and at what magnitude, key intervention characteristics drive public health impact, and provide quantitative evidence to support selection of use-cases, transmission settings, and deployment strategies. We describe how modelling evidence can guide and accelerate development of new malaria vaccines, monoclonal antibodies, and chemoprevention.

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Leveraging mathematical models of disease dynamics and machine learning to improve development of novel malaria interventions

Cited by 9 publications

References 54 publications

Design and selection of drug properties to increase the public health impact of next-generation seasonal malaria chemoprevention: a modelling study

Design and selection of drug properties to increase the public health impact of next-generation seasonal malaria chemoprevention: a modelling study

The influence of biological, epidemiological, and treatment factors on the establishment and spread of drug-resistant Plasmodium falciparum

Modelling to inform next-generation medical interventions for malaria prevention and treatment

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