Unsupervised machine learning for identifying important visual features through bag-of-words using histopathology data from chronic kidney disease

Lee, Joon Sang; Warner, Elisa; Shaikhouni, Salma; Bitzer, Markus; Kretzler, Matthias; Gipson, Debbie S.; Pennathur, Subramaniam; Bellovich, Keith; Bhat, Zeenat; Gadegbeku, Crystal A.; Massengill, Susan F.; Perumal, Kalyani; Saha, Jharna; Yang, Yong; Luo, Jinghui; Zhang, Xin; Mariani, Laura; Hodgin, Jeffrey B.; Rao, Arvind

doi:10.1038/s41598-022-08974-8

Cited by 18 publications

(14 citation statements)

References 46 publications

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“…Previously, we have shown that unsupervised machine-learned clustering features are potential surrogates of predicting eGFR and can be used as tools for prognosis as well as for objective assessment of the level of kidney function in CKD 45 . In the present study, our results demonstrate that the addition of spatial information improves the model's performance by 2.4% and 5.1% of AUC at the biopsy and one-year prediction, respectively, compared to the previous study.…”

Section: Discussionmentioning

confidence: 99%

“…In order to cluster image patterns on image patches, we extracted features from each image patch for the clustering using pre-trained DeepLab V3+ with ResNet-18 model. 38,45 Then, all 172 biopsy cores on images were tiled into 107,471 patches. Then, those patches were clustered through K-means clustering to group similar image patterns together (Figure 3a).…”

Section: Unsupervised Machine Learning To Cluster Image Patterns Over...mentioning

confidence: 99%

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CluSA: Clustering-based Spatial Analysis framework through Graph Neural Network for Chronic Kidney Disease Prediction using Histopathology Images

Lee

Warner

Shaikhouni

et al. 2022

Preprint

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Machine learning applied to digital pathology has been increasingly used to assess kidney function and diagnose the underlying cause of chronic kidney disease (CKD). We developed a novel computational framework, Clustering-based Spatial Analysis (CluSA), that leverages unsupervised learning to learn spatial relationships between local visual patterns in kidney tissue. This framework minimizes the need for time-consuming and impractical expert annotations. To incorporate spatial information over the clustered image patterns on the biopsy sample, we spatially encoded clustered patterns with colors and performed spatial analysis through graph neural network. A random forest classifier with various groups of features were used to predict CKD. For predicting high/low eGFR at the biopsy, we achieved a sensitivity of 0.97, specificity of 0.90, and accuracy of 0.95. AUC was 0.96. For predicting eGFR changes in one-year, we achieved a sensitivity of 0.83, specificity of 0.85, and accuracy of 0.84. AUC was 0.85. This study presents the first spatial analysis based on unsupervised machine learning algorithms. Without expert annotation, CluSA framework can not only accurately classify and predict the degree of kidney function at the biopsy and in one year, but also identify novel predictors of kidney function and renal prognosis.

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Section: Discussionmentioning

confidence: 99%

Section: Unsupervised Machine Learning To Cluster Image Patterns Over...mentioning

confidence: 99%

CluSA: Clustering-based Spatial Analysis framework through Graph Neural Network for Chronic Kidney Disease Prediction using Histopathology Images

Lee

Warner

Shaikhouni

et al. 2022

Preprint

Self Cite

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“…Based on the comprehensive morphological features extracted from 161 renal biopsies, along with patient clinical information, the AUC of the prediction model for eGFR at biopsy time reached 0.93, while that for 1-year eGFR was 0.80. These results indicated the potential of visual-feature-based algorithms for predicting CKD progression [ 113 ].…”

Section: Application Of Ai In Nephropathologymentioning

confidence: 95%

Artificial Intelligence-Assisted Renal Pathology: Advances and Prospects

Wang

Wen

Jin

et al. 2022

JCM

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Digital imaging and advanced microscopy play a pivotal role in the diagnosis of kidney diseases. In recent years, great achievements have been made in digital imaging, providing novel approaches for precise quantitative assessments of nephropathology and relieving burdens of renal pathologists. Developing novel methods of artificial intelligence (AI)-assisted technology through multidisciplinary interaction among computer engineers, renal specialists, and nephropathologists could prove beneficial for renal pathology diagnoses. An increasing number of publications has demonstrated the rapid growth of AI-based technology in nephrology. In this review, we offer an overview of AI-assisted renal pathology, including AI concepts and the workflow of processing digital image data, focusing on the impressive advances of AI application in disease-specific backgrounds. In particular, this review describes the applied computer vision algorithms for the segmentation of kidney structures, diagnosis of specific pathological changes, and prognosis prediction based on images. Lastly, we discuss challenges and prospects to provide an objective view of this topic.

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“…The challenges in deep learning for cancer or disease diagnosis on histopathological images include the use of large amounts of accurately annotated data and the generalization limitations of WSIs due to multiple variants and the intricate cellular structure of histopathology data. Publicly available WSIs with accurate annotation or label information are fewer as compared to natural image datasets because acquiring WSIs is a difficult and costly task owing to the specific nature of medical imaging modalities [ 2 , 3 , 4 , 5 ]. To address this issue, previous researchers used pre-trained models based on previously acquired knowledge from different domain image datasets and then applied them to the medical imaging domain.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised Learning Based on Multiple Descriptors for WSIs Diagnosis

et al. 2022

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An automatic pathological diagnosis is a challenging task because histopathological images with different cellular heterogeneity representations are sometimes limited. To overcome this, we investigated how the holistic and local appearance features with limited information can be fused to enhance the analysis performance. We propose an unsupervised deep learning model for whole-slide image diagnosis, which uses stacked autoencoders simultaneously feeding multiple-image descriptors such as the histogram of oriented gradients and local binary patterns along with the original image to fuse the heterogeneous features. The pre-trained latent vectors are extracted from each autoencoder, and these fused feature representations are utilized for classification. We observed that training with additional descriptors helps the model to overcome the limitations of multiple variants and the intricate cellular structure of histopathology data by various experiments. Our model outperforms existing state-of-the-art approaches by achieving the highest accuracies of 87.2 for ICIAR2018, 94.6 for Dartmouth, and other significant metrics for public benchmark datasets. Our model does not rely on a specific set of pre-trained features based on classifiers to achieve high performance. Unsupervised spaces are learned from the number of independent multiple descriptors and can be used with different variants of classifiers to classify cancer diseases from whole-slide images. Furthermore, we found that the proposed model classifies the types of breast and lung cancer similar to the viewpoint of pathologists by visualization. We also designed our whole-slide image processing toolbox to extract and process the patches from whole-slide images.

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Unsupervised machine learning for identifying important visual features through bag-of-words using histopathology data from chronic kidney disease

Cited by 18 publications

References 46 publications

CluSA: Clustering-based Spatial Analysis framework through Graph Neural Network for Chronic Kidney Disease Prediction using Histopathology Images

CluSA: Clustering-based Spatial Analysis framework through Graph Neural Network for Chronic Kidney Disease Prediction using Histopathology Images

Artificial Intelligence-Assisted Renal Pathology: Advances and Prospects

Unsupervised Learning Based on Multiple Descriptors for WSIs Diagnosis

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