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Main Authors: Gupta, Ravi Kant, Dharani, Dadi, Shanker, Shambhavi, Sethi, Amit
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.08530
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author Gupta, Ravi Kant
Dharani, Dadi
Shanker, Shambhavi
Sethi, Amit
author_facet Gupta, Ravi Kant
Dharani, Dadi
Shanker, Shambhavi
Sethi, Amit
contents The advancement of digital pathology, particularly through computational analysis of whole slide images (WSI), is poised to significantly enhance diagnostic precision and efficiency. However, the large size and complexity of WSIs make it difficult to analyze and classify them using computers. This study introduces a novel method for WSI classification by automating the identification and examination of the most informative patches, thus eliminating the need to process the entire slide. Our method involves two-stages: firstly, it extracts only a few patches from the WSIs based on their pathological significance; and secondly, it employs Fisher vectors (FVs) for representing features extracted from these patches, which is known for its robustness in capturing fine-grained details. This approach not only accentuates key pathological features within the WSI representation but also significantly reduces computational overhead, thus making the process more efficient and scalable. We have rigorously evaluated the proposed method across multiple datasets to benchmark its performance against comprehensive WSI analysis and contemporary weakly-supervised learning methodologies. The empirical results indicate that our focused analysis of select patches, combined with Fisher vector representation, not only aligns with, but at times surpasses, the classification accuracy of standard practices. Moreover, this strategy notably diminishes computational load and resource expenditure, thereby establishing an efficient and precise framework for WSI analysis in the realm of digital pathology.
format Preprint
id arxiv_https___arxiv_org_abs_2411_08530
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Efficient Whole Slide Image Classification through Fisher Vector Representation
Gupta, Ravi Kant
Dharani, Dadi
Shanker, Shambhavi
Sethi, Amit
Computer Vision and Pattern Recognition
Machine Learning
The advancement of digital pathology, particularly through computational analysis of whole slide images (WSI), is poised to significantly enhance diagnostic precision and efficiency. However, the large size and complexity of WSIs make it difficult to analyze and classify them using computers. This study introduces a novel method for WSI classification by automating the identification and examination of the most informative patches, thus eliminating the need to process the entire slide. Our method involves two-stages: firstly, it extracts only a few patches from the WSIs based on their pathological significance; and secondly, it employs Fisher vectors (FVs) for representing features extracted from these patches, which is known for its robustness in capturing fine-grained details. This approach not only accentuates key pathological features within the WSI representation but also significantly reduces computational overhead, thus making the process more efficient and scalable. We have rigorously evaluated the proposed method across multiple datasets to benchmark its performance against comprehensive WSI analysis and contemporary weakly-supervised learning methodologies. The empirical results indicate that our focused analysis of select patches, combined with Fisher vector representation, not only aligns with, but at times surpasses, the classification accuracy of standard practices. Moreover, this strategy notably diminishes computational load and resource expenditure, thereby establishing an efficient and precise framework for WSI analysis in the realm of digital pathology.
title Efficient Whole Slide Image Classification through Fisher Vector Representation
topic Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2411.08530