A Reproducible Deep Learning Pipeline for Augmentation-Enhanced Classification of Anemia-Related Blood-Cell Images

R. Remya; M. Janani; P. Thilakavathy; Mitha Rachel Jose; R. Reji; L. P. Supriya; Mohammad Asim; Lekshmi R. Nair; Dheeraj Tiger; Divya Saleela

doi:10.48084/etasr.19533

Authors

R. Remya Providence College of Engineering, Kerala, India
M. Janani St. Joseph's College of Engineering, Tamil Nadu, India
P. Thilakavathy Vels Institute of Science Technology and Advanced Studies, Tamil Nadu, India
Mitha Rachel Jose Laurea University of Applied Sciences, Espoo, Finland
R. Reji Thangal Kunju Musaliar Institute of Technology, Kerala, India
L. P. Supriya Saveetha School of Engineering, Saveetha Institute of Medical and Technical Sciences, Saveetha University, Tamil Nadu, India
Mohammad Asim Sharda University, Uttar Pradesh, India
Lekshmi R. Nair Cochin University of Science and Technology, Kerala, India
Dheeraj Tiger The NorthCap University, Gurugram, Haryana, India
Divya Saleela University of Southampton, United Kingdom

Volume: 16 | Issue: 4 | Pages: 37862-37868 | August 2026 | https://doi.org/10.48084/etasr.19533

Received: 24 April 2026 | Revised: 13 May 2026, 24 May 2026, 25 May 2026, 3 June 2026, and 4 June 2026 | Accepted: 5 June 2026 | Online: 26 June 2026

Corresponding author: Divya Saleela

Abstract

This study presents a reproducible end-to-end deep learning pipeline for proof-of-concept classification of anemia-related and control-like blood cell images using a publicly accessible online dataset. The workflow integrates online data download, automatic extraction, dataset restructuring, class balancing, augmentation-enhanced preprocessing, transfer-learning-based model training, visualization, and structured metric generation within a single executable framework. A balanced binary dataset was constructed to reduce the effect of severe class imbalance, and augmentation strategies, including flipping, rotation, color jitter, and affine transformation, were applied only during training. A ResNet18-based classifier showed strong convergence under a fixed random seed and single train-validation-test split. On a small held-out test subset of 32 images, all images were correctly classified. However, this result should be interpreted cautiously because the test subset was small, no cross-validation or external validation was performed, and performance on limited balanced data may overestimate generalizability. Class-distribution plots, representative sample panels, learning curves, confusion matrices, prediction files, and metric summaries support transparent inspection and reproducibility. The main contribution of this study is a reproducible engineering workflow for blood-cell image classification, rather than a claim of algorithmic novelty or clinical readiness.

Keywords:

blood cell image classification, deep learning, reproducible pipeline, data augmentation, class balancing, ResNet18, hematology imaging, medical image analysis

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