Aminah Zawedde scite author profile

Aminah Zawedde

5Publications

33Citation Statements Received

33Citation Statements Given

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Makerere University

Publications

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Mobile-Aware Deep Learning Algorithms for Malaria Parasites and White Blood Cells Localization in Thick Blood Smears

Nakasi

Mwebaze²,

Zawedde

2021

Algorithms

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Effective determination of malaria parasitemia is paramount in aiding clinicians to accurately estimate the severity of malaria and guide the response for quality treatment. Microscopy by thick smear blood films is the conventional method for malaria parasitemia determination. Despite its edge over other existing methods of malaria parasitemia determination, it has been critiqued for being laborious, time consuming and equally requires expert knowledge for an efficient manual quantification of the parasitemia. This pauses a big challenge to most low developing countries as they are not only highly endemic but equally low resourced in terms of technical personnel in medical laboratories This study presents an end-to-end deep learning approach to automate the localization and count of P.falciparum parasites and White Blood Cells (WBCs) for effective parasitemia determination. The method involved building computer vision models on a dataset of annotated thick blood smear images. These computer vision models were built based on pre-trained deep learning models including Faster Regional Convolutional Neural Network (Faster R-CNN) and Single Shot Multibox Detector (SSD) models that help process the obtained digital images. To improve model performance due to a limited dataset, data augmentation was applied. Results from the evaluation of our approach showed that it reliably detected and returned a count of parasites and WBCs with good precision and recall. A strong correlation was observed between our model-generated counts and the manual counts done by microscopy experts (posting a spear man correlation of ρ = 0.998 for parasites and ρ = 0.987 for WBCs). Additionally, our proposed SSD model was quantized and deployed on a mobile smartphone-based inference app to detect malaria parasites and WBCs in situ. Our proposed method can be applied to support malaria diagnostics in settings with few trained Microscopy Experts yet constrained with large volume of patients to diagnose.

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A new approach for microscopic diagnosis of malaria parasites in thick blood smears using pre-trained deep learning models

et al. 2020

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One of the deadly endemic diseases in sub-Saharan Africa is malaria. Its prevalence is promoted by lack of sufficient expertise to carry out accurate and timely diagnosis using the standard microscopy method. Where lab technicians are available, the results are usually subjective due to variations in expert judgement. To address this challenge, prompt interventions to improve disease control are needed. The emerging technologies of machine learning that can learn complex image patterns have accelerated research in medical image analysis. In this study, on a dataset of thick blood smear images, we evaluate and compare performance of three pre-trained deep learning architectures namely; faster regional convolutional neural network (faster R-CNN), single-shot multi-box detector (SSD) and RetinaNet through a Tensorflow object detection API. Data augmentation method was applied to optimise performance of the meta architectures. The possibility for mobile phone detector deployment was also investigated. The results revealed that faster R-CNN was the best trained model with a mean average precision of over 0.94 and SSD, was the best model for mobile deployment. We therefore deduce that faster R-CNN is best suited for obtaining high rates of accuracy in malaria detection while SDD is best suited for mobile deployment.

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A web-based intelligence platform for diagnosis of malaria in thick blood smear images: a case for a developing country

Nakasi

Tusubira

Zawedde

et al. 2020

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Dynamics of software systems projects during the requirements process improvement

Zawedde

Williams

2014

IJSPM

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Error Quantification Tool of Health Records for Developing Countries

Nakasi¹,

Mwebaze²,

Zawedde³

et al. 2019

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In developing countries, the greatest information sources for disease prevalence are official Electronic Health Records (EHR). However, data is usually affected by human error which flaws decisions by stakeholders. The previous reviews considered data quality findings at only an aggregated level, however, this method is vulnerable to errors if wrong data is aggregated and therefore hard to trace the error. This exploratory study though limited, utilized a statistical approach for computing differences between paper and EHR records. A sample of selected health facilities was used as a base study and results indicated varying errors at each level of reporting tool.

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Aminah Zawedde

Mobile-Aware Deep Learning Algorithms for Malaria Parasites and White Blood Cells Localization in Thick Blood Smears

A new approach for microscopic diagnosis of malaria parasites in thick blood smears using pre-trained deep learning models

A web-based intelligence platform for diagnosis of malaria in thick blood smear images: a case for a developing country

Dynamics of software systems projects during the requirements process improvement

Error Quantification Tool of Health Records for Developing Countries

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