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A privacy-preserving approach to effectively utilize distributed data for Malaria image detection

A privacy-preserving approach to effectively utilize distributed data for Malaria image detection
A privacy-preserving approach to effectively utilize distributed data for Malaria image detection
Malaria is one of the life-threatening diseases caused by the parasite known as Plasmodium falciparum, affecting the human red blood cells. Therefore, it is an important to have an effective computer-aided system in place for early detection and treatment. The visual heterogeneity of the malaria dataset is highly complex and dynamic, therefore higher number of images are needed to train the machine learning (ML) models effectively. However, hospitals as well as medical institutions do not share the medical image data for collaboration due to general data protection regulations (GDPR) and the data protection act (DPA). To overcome this collaborative challenge, our research utilised real-time medical image data in the framework of federated learning (FL). We have used state-of-the-art ML models that include the ResNet-50 and DenseNet in a federated learning framework. We have experimented both models in different settings on a malaria dataset constituting 27,560 publicly available images and our preliminary results showed that the DenseNet model performed better in accuracy (75%) in contrast to ResNet-50 (72%) while considering eight clients, while the trend was observed as common in four clients with the similar accuracy of 94%, and six clients showed that the DenseNet model performed quite well with the accuracy of 92%, while ResNet-50 achieved only 72%. The federated learning framework enhances the accuracy due to its decentralised nature, continuous learning, and effective communication among clients, as well as the efficient local adaptation. The use of federated learning architecture among the distinct clients for ensuring the data privacy and following GDPR is the contribution of this research work.
2306-5354
Kareem, Amer
812714c5-84fd-4d79-8d4b-9ecc586a3a8f
Liu, Haiming
3ed791e3-9f1e-417e-a531-7faf19cca547
Velisavljevic, Vladan
3a00dca1-bcae-4925-80a4-e6adb25c700d
Kareem, Amer
812714c5-84fd-4d79-8d4b-9ecc586a3a8f
Liu, Haiming
3ed791e3-9f1e-417e-a531-7faf19cca547
Velisavljevic, Vladan
3a00dca1-bcae-4925-80a4-e6adb25c700d

Kareem, Amer, Liu, Haiming and Velisavljevic, Vladan (2024) A privacy-preserving approach to effectively utilize distributed data for Malaria image detection. Bioengineering, 11 (4), [340]. (doi:10.3390/bioengineering11040340).

Record type: Article

Abstract

Malaria is one of the life-threatening diseases caused by the parasite known as Plasmodium falciparum, affecting the human red blood cells. Therefore, it is an important to have an effective computer-aided system in place for early detection and treatment. The visual heterogeneity of the malaria dataset is highly complex and dynamic, therefore higher number of images are needed to train the machine learning (ML) models effectively. However, hospitals as well as medical institutions do not share the medical image data for collaboration due to general data protection regulations (GDPR) and the data protection act (DPA). To overcome this collaborative challenge, our research utilised real-time medical image data in the framework of federated learning (FL). We have used state-of-the-art ML models that include the ResNet-50 and DenseNet in a federated learning framework. We have experimented both models in different settings on a malaria dataset constituting 27,560 publicly available images and our preliminary results showed that the DenseNet model performed better in accuracy (75%) in contrast to ResNet-50 (72%) while considering eight clients, while the trend was observed as common in four clients with the similar accuracy of 94%, and six clients showed that the DenseNet model performed quite well with the accuracy of 92%, while ResNet-50 achieved only 72%. The federated learning framework enhances the accuracy due to its decentralised nature, continuous learning, and effective communication among clients, as well as the efficient local adaptation. The use of federated learning architecture among the distinct clients for ensuring the data privacy and following GDPR is the contribution of this research work.

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bioengineering-11-00340-v2 - Version of Record
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Accepted/In Press date: 17 March 2024
Published date: 30 March 2024
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Identifiers

Local EPrints ID: 503468
URI: http://eprints.soton.ac.uk/id/eprint/503468
DOI: doi:10.3390/bioengineering11040340
ISSN: 2306-5354
PURE UUID: 007c9505-7e7a-4164-9004-abdf7bfdd44f
ORCID for Haiming Liu: ORCID iD orcid.org/0000-0002-0390-3657

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Date deposited: 01 Aug 2025 16:45
Last modified: 22 Aug 2025 02:35

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Contributors

Author: Amer Kareem
Author: Haiming Liu ORCID iD
Author: Vladan Velisavljevic

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