Evaluating the performance of an artificial intelligence-based electronic reader for malaria rapid diagnostic tests across Benin, Côte d’Ivoire, Nigeria and Uganda
Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outc...
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| Published in | Malaria journal Vol. 24; no. 1; pp. 302 - 12 |
|---|---|
| Main Authors | , , , , , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
London
BioMed Central
30.09.2025
BioMed Central Ltd BMC |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1475-2875 1475-2875 |
| DOI | 10.1186/s12936-025-05522-3 |
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| Abstract | Background
The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application’s performance characteristics.
Methods
In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d’Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer’s instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies.
Results
Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16).
Conclusions
The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. |
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| AbstractList | Abstract Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application’s performance characteristics. Methods In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d’Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer’s instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies. Results Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16). Conclusions The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application's performance characteristics. Methods In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d'Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer's instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies. Results Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16). Conclusions The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. Keywords: Malaria, Rapid diagnostic test, Artificial intelligence, Digital health, Diagnostic accuracy, Electronic RDT reader Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application’s performance characteristics. Methods In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d’Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer’s instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies. Results Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16). Conclusions The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application's performance characteristics.BACKGROUNDThe introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application's performance characteristics.In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d'Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer's instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies.METHODSIn 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d'Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer's instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies.Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16).RESULTSOf the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16).The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance.CONCLUSIONSThe HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application's performance characteristics. In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d'Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer's instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies. Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16). The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in sub-Saharan Africa, improving case management and surveillance. However, concerns persist regarding healthcare worker adherence to RDT outcomes and the accuracy of RDT results recorded in health facility registers. Electronic RDT readers have been proposed to improve the consistency of interpretation and reporting. The HealthPulse smartphone application (Audere, Seattle, WA, USA), an RDT reader using an artificial intelligence (AI) computer vision algorithm, was assessed against a trained human panel interpreting RDT results from photographs to determine the application's performance characteristics. In 2023, the Malaria Rapid Diagnostic Test Capture and Reporting Assessment (MaCRA) was implemented in health facilities in Benin, Côte d'Ivoire, Nigeria, and Uganda. Study staff photographed malaria RDTs using the HealthPulse application after healthcare workers performed and interpreted the tests. A trained panel of external reviewers interpreted the RDT images and served as the reference standard. RDTs in the images were classified according to the manufacturer's instructions as positive, negative or invalid (i.e., no visible control line) or labelled as uninterpretable (i.e., visibility was impeded). The performance of the HealthPulse AI algorithm was evaluated using percent accuracy, recall (i.e., sensitivity and specificity), precision (i.e., positive and negative predictive values), and F1 scores (harmonic mean of recall and precision) weighted by the number of each outcome. Logistic regression was applied to assess factors influencing recall across countries, RDT products, presence of faint lines, and anomalies. Of the 110,843 RDT images collected, 106,877 (96.4%) were included in the analysis. The AI algorithm demonstrated high accuracy (96.8%; 95% confidence interval (CI) 96.7%, 96.9%) compared with the panel interpretation and an overall F1 score of 96.6. Recall and precision were > 97% for positive and negative outcomes but much lower for invalid (recall: 84.8%; precision: 42.8%) and uninterpretable (recall: 0.8%; precision: 2.3%) classifications. AI performance varied by country, RDT product, the presence of faint lines and the quality of the image. When test lines were faint, the AI algorithm was significantly less likely to recall both positive results (adjusted odds ratio (aOR) 0.02; 95% CI 0.02, 0.02) and negative results (aOR 0.10; 95% CI 0.07, 0.16). The HealthPulse AI algorithm demonstrated strong agreement with a trained panel in interpreting malaria RDT images across diverse settings. However, the reduced performance for invalid outcomes and varying performance by country, RDT product and faint lines highlight the need for further research and refinement. The HealthPulse application shows potential as a supportive tool in research, training, surveillance, and quality assurance. |
| ArticleNumber | 302 |
| Audience | Academic |
| Author | Konaté-Toure, Abibatou Atobatele, Sunday Opigo, Jimmy Zobrist, Stephanie Griffith, Kevin Humes, Michael Ahogni, Idelphonse Tanoh, Antoine Mea Ngufor, Corine Ssewante, Nelson Lindblade, Kim A. Yavo, William Mpimbaza, Arthur Ntadom, Godwin Kpemasse, Augustin Akpiroroh, Ese |
| Author_xml | – sequence: 1 givenname: Kim A. surname: Lindblade fullname: Lindblade, Kim A. email: kalindblade@gmail.org organization: PATH – sequence: 2 givenname: Corine surname: Ngufor fullname: Ngufor, Corine organization: Centre de Recherche Entomologique de Cotonou – sequence: 3 givenname: William surname: Yavo fullname: Yavo, William organization: Institut National de Santé Publique – sequence: 4 givenname: Sunday surname: Atobatele fullname: Atobatele, Sunday organization: Sydani Group – sequence: 5 givenname: Arthur surname: Mpimbaza fullname: Mpimbaza, Arthur organization: Child Health and Development Centre, Makerere University – sequence: 6 givenname: Nelson surname: Ssewante fullname: Ssewante, Nelson organization: Child Health and Development Centre, Makerere University – sequence: 7 givenname: Ese surname: Akpiroroh fullname: Akpiroroh, Ese organization: Sydani Group – sequence: 8 givenname: Abibatou surname: Konaté-Toure fullname: Konaté-Toure, Abibatou organization: Institut National de Santé Publique – sequence: 9 givenname: Idelphonse surname: Ahogni fullname: Ahogni, Idelphonse organization: Centre de Recherche Entomologique de Cotonou – sequence: 10 givenname: Augustin surname: Kpemasse fullname: Kpemasse, Augustin organization: Programme National de Lutte Contre Le Paludisme – sequence: 11 givenname: Antoine Mea surname: Tanoh fullname: Tanoh, Antoine Mea organization: Programme National de Lutte Contre Le Paludisme – sequence: 12 givenname: Godwin surname: Ntadom fullname: Ntadom, Godwin organization: National Malaria Elimination Programme – sequence: 13 givenname: Jimmy surname: Opigo fullname: Opigo, Jimmy organization: National Malaria Control Division – sequence: 14 givenname: Stephanie surname: Zobrist fullname: Zobrist, Stephanie organization: PATH – sequence: 15 givenname: Kevin surname: Griffith fullname: Griffith, Kevin organization: U.S. President’s Malaria Initiative – sequence: 16 givenname: Michael surname: Humes fullname: Humes, Michael organization: U.S. President’s Malaria Initiative |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/41029407$$D View this record in MEDLINE/PubMed |
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| Keywords | Rapid diagnostic test Digital health Malaria Artificial intelligence Diagnostic accuracy Electronic RDT reader |
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| References | EE Agbemafle (5522_CR15) 2023; 18 AS Jegede (5522_CR7) 2016; 63 T Saito (5522_CR26) 2015; 10 5522_CR3 T Visser (5522_CR19) 2021; 20 H Ntuku (5522_CR10) 2025; 111 5522_CR22 A Berhane (5522_CR11) 2018; 24 C Oyet (5522_CR28) 2017; 16 D Koko (5522_CR16) 2024; 110 SA Hicks (5522_CR25) 2022; 12 AN Kabaghe (5522_CR8) 2016; 15 KA Lindblade (5522_CR13) 2025; 24 RM Boyce (5522_CR4) 2015; 14 MI Masanja (5522_CR5) 2010; 83 5522_CR24 S Shekalaghe (5522_CR20) 2013; 12 J Cunningham (5522_CR2) 2019; 18 R Altaras (5522_CR14) 2024; 110 X Martiáñez-Vendrell (5522_CR27) 2020; 19 SD Roche (5522_CR23) 2024; 12 WHO (5522_CR1) 2024 M Aidoo (5522_CR6) 2021; 106 R Altaras (5522_CR12) 2016; 15 J Karemere (5522_CR21) 2025; 112 5522_CR18 5522_CR17 L Wu (5522_CR9) 2015; 528 |
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The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems... The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems in... Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health systems... Abstract Background The introduction of malaria rapid diagnostic tests (RDTs) has expanded the parasitological confirmation of malaria at all levels of health... |
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| SubjectTerms | Adult Algorithms Anopheles Artificial Intelligence Benin Biomedical and Life Sciences Biomedicine Computer-aided medical diagnosis Cote d'Ivoire Diagnosing the Data: Malaria RDT Recording and Reporting Accuracy in Four African Countries and Implications for Surveillance Diagnosis Diagnostic accuracy Diagnostic Tests, Routine - instrumentation Diagnostic Tests, Routine - methods Digital health Electronic RDT reader Entomology Female Health care reform Humans Infectious Diseases Machine vision Malaria Malaria - diagnosis Male Medical care Medical tests Methods Microbiology Molecular diagnostic techniques Nigeria Parasitology Public Health Quality management Rapid diagnostic test Rapid Diagnostic Tests Sensitivity and Specificity Tropical Medicine Uganda |
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| Title | Evaluating the performance of an artificial intelligence-based electronic reader for malaria rapid diagnostic tests across Benin, Côte d’Ivoire, Nigeria and Uganda |
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