Modeling of malaria vaccine effectiveness on disease burden and drug resistance in 42 African countries

Alisa Hamilton; Fardad Haghpanah; Mateusz Hasso-Agopsowicz; Isabel Frost; Gary Lin; Emily Schueller; Eili Klein; Ramanan Laxminarayan

doi:10.1038/s43856-023-00373-y

Modeling of malaria vaccine effectiveness on disease burden and drug resistance in 42 African countries

Commun Med (Lond). 2023 Oct 13;3(1):144. doi: 10.1038/s43856-023-00373-y.

Authors

Alisa Hamilton¹, Fardad Haghpanah¹, Mateusz Hasso-Agopsowicz², Isabel Frost^{2

3}, Gary Lin¹, Emily Schueller¹, Eili Klein^{1

4}, Ramanan Laxminarayan^{5

6

7

8}

Affiliations

¹ One Health Trust, Washington, D.C., USA.
² World Health Organization, Geneva, Switzerland.
³ Imperial College London, London, UK.
⁴ Johns Hopkins University, Department of Emergency Medicine, Baltimore, MD, USA.
⁵ One Health Trust, Washington, D.C., USA. ramanan@onehealthtrust.org.
⁶ One Health Trust, New Delhi, India. ramanan@onehealthtrust.org.
⁷ Princeton University, Princeton, NJ, USA. ramanan@onehealthtrust.org.
⁸ University of Washington, Seattle, WA, USA. ramanan@onehealthtrust.org.

Abstract

Background: The emergence of antimalarial drug resistance poses a major threat to effective malaria treatment and control. This study aims to inform policymakers and vaccine developers on the potential of an effective malaria vaccine in reducing drug-resistant infections.

Methods: A compartmental model estimating cases, drug-resistant cases, and deaths averted from 2021 to 2030 with a vaccine against Plasmodium falciparum infection administered yearly to 1-year-olds in 42 African countries. Three vaccine efficacy (VE) scenarios and one scenario of rapidly increasing drug resistance are modeled.

Results: When VE is constant at 40% for 4 years and then drops to 0%, 235.7 (Uncertainty Interval [UI] 187.8-305.9) cases per 1000 children, 0.6 (UI 0.4-1.0) resistant cases per 1000, and 0.6 (UI 0.5-0.9) deaths per 1000 are averted. When VE begins at 80% and drops 20 percentage points each year, 313.9 (UI 249.8-406.6) cases per 1000, 0.9 (UI 0.6-1.3) resistant cases per 1000, and 0.9 (UI 0.6-1.2) deaths per 1000 are averted. When VE remains 40% for 10 years, 384.7 (UI 311.7-496.5) cases per 1000, 1.0 (0.7-1.6) resistant cases per 1000, and 1.1 (UI 0.8-1.5) deaths per 1000 are averted. Assuming an effective vaccine and an increase in current levels of drug resistance to 80% by 2030, 10.4 (UI 7.3-15.8) resistant cases per 1000 children are averted.

Conclusions: Widespread deployment of a malaria vaccine could substantially reduce health burden in Africa. Maintaining VE longer may be more impactful than a higher initial VE that falls rapidly.

Plain language summary

Malaria can become resistant to the drugs used to treat it, posing a major threat to malaria treatment and control. An effective vaccine has the potential to reduce both resistant infections and antimalarial drug use. However, how successfully a vaccine can protect against infection (vaccine efficacy) and the impact of increasing drug resistance remain unclear. Using a mathematical model, we estimate the impact of malaria vaccination in 42 African countries over a 10-year period in multiple scenarios with differing vaccine efficacy and drug resistance. Our model suggests that a moderately effective vaccine with sustained protection over a long period could avert more resistant infections and deaths than a vaccine that is highly protective initially but lowers in efficacy over time. Nevertheless, implementation of an effective malaria vaccine should be accelerated to mitigate the health and economic burden of drug resistance.

Abstract

Plain language summary

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