Deep learning based on hematoxylin–eosin staining outperforms immunohistochemistry in predicting molecular subtypes of gastric adenocarcinoma

Flinner, Nadine; Gretser, Steffen; Quaas, Alexander; Bankov, Katrin; Stoll, Alexander; Heckmann, Lara; Mayer, Robin S.; Doering, Claudia; Demes, Melanie; Buettner, Reinhard; Rueschoff, Josef; Wild, Peter J.

doi:10.1002/path.5879

Cited by 14 publications

(7 citation statements)

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“…To now find an alternative way to decide which image patches are suited as input for a trained deep learning approach and to recognize if a prediction is uncertain, we trained bagging ensemble CNNs and had a closer look at the ensemble confidence (number of CNNs having the same prediction). Recently, we have shown that using only securely predicted image tiles can end up in low error rates ( 6 ). To avoid the problem of overconfident ensemble predictions, we inserted some label noise into the training dataset.…”

Section: Resultsmentioning

confidence: 99%

“…Next to the ideal composition of the training data, we also introduced NoisyEnsembles ( Figure 4 ), which improved the transferability to datasets with other properties by selectively inserting label noise during training. Like other ensemble methods ( 6 , 31 ), our NoisyEnsembles also have the potential to increase the overall performance of the deep learning application ( Figures 4A,B vs. Supplementary Figure S11 ). For testing, it is recommended to sample the possible image space as well as possible ( 11 ).…”

Section: Discussionmentioning

confidence: 99%

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How to learn with intentional mistakes: NoisyEnsembles to overcome poor tissue quality for deep learning in computational pathology

et al. 2022

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There is a lot of recent interest in the field of computational pathology, as many algorithms are introduced to detect, for example, cancer lesions or molecular features. However, there is a large gap between artificial intelligence (AI) technology and practice, since only a small fraction of the applications is used in routine diagnostics. The main problems are the transferability of convolutional neural network (CNN) models to data from other sources and the identification of uncertain predictions. The role of tissue quality itself is also largely unknown. Here, we demonstrated that samples of the TCGA ovarian cancer (TCGA-OV) dataset from different tissue sources have different quality characteristics and that CNN performance is linked to this property. CNNs performed best on high-quality data. Quality control tools were partially able to identify low-quality tiles, but their use did not increase the performance of the trained CNNs. Furthermore, we trained NoisyEnsembles by introducing label noise during training. These NoisyEnsembles could improve CNN performance for low-quality, unknown datasets. Moreover, the performance increases as the ensemble become more consistent, suggesting that incorrect predictions could be discarded efficiently to avoid wrong diagnostic decisions.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

How to learn with intentional mistakes: NoisyEnsembles to overcome poor tissue quality for deep learning in computational pathology

et al. 2022

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“…Interestingly, a recent work by Flinner and colleagues [ 27 ] found by comparison with OncoScan data that the distinction between GS and CIN based on E-cadherin and p53 status and Lauren morphology can lead to mislabeling. In this context, the use of microsatellite-based multiplex PCR assay for the detection of allelic imbalance or loss of heterozygosity has proved to be a simple, quantitative, and easily interpretable surrogate to identify CIN and to enable the differentiation of GS and CIN [ 28 ].…”

Section: Discussionmentioning

confidence: 99%

Molecular subtyping of gastroesophageal dysplasia heterogeneity according to TCGA/ACRG classes

et al. 2022

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Gastric adenocarcinoma has recently been classified into several subtypes on the basis of molecular profiling, which has been successfully reproduced by immunohistochemistry (IHC) and in situ hybridization (ISH). A series of 73 gastroesophageal dysplastic lesions (37 gastric dysplasia and 36 Barrett dysplasia; 44 low-grade dysplasia and 29 high-grade dysplasia) was investigated for mismatch repair proteins, E-cadherin, p53, and EBER status, to reproduce The Cancer Genome Atlas (TCGA) and Asian Cancer Research Group (ACRG) molecular clustering. Overall, the dysplastic lesions were classified as follows: according to TCGA classification, EBV, 0/73 (0%), MSI, 6/73 (8.2%), GS, 4/73 (5.5%), CIN, 63/73 (86.3%); according to ACRG molecular subtyping, MSI, 6/73 (8.2%), MSS/EMT, 4/73 (5.5%), MSS/TP53−, 33/73 (45.2%), MSS/TP53+, 30/73 (41.1%). A positive association was found between MSS/TP53− and Barrett dysplasia (p = 0.0004), between MSS/TP53+ and LG dysplasia (p = 0.001) and between MSS/TP53+ and gastric dysplasia (p = 0.0018). Gastroesophageal dysplastic lesions proved to be heterogenous in terms of TCGA/ACRG classes, but with a different distribution from that of cancers, with no EBV-positive cases, an increasing presence of mismatch repair deficiency from low grade to high grade lesions, and a prevalence of p53 aberrations in Barrett dysplasia. The present study further demonstrated that gastroesophageal dysplastic lesions may be characterized by alterations in predictive/prognostic biomarkers, and this should be considered in routine diagnostic.

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“…Until now, seven studies on EBV status prediction via a deep learning approach using digitalized WSIs have been published (Supplementary Table S1 ) 25 – 31 . Of these, the most similar to our pipeline are those proposed by Zhang et al and Zheng et al 28 , 29 ; in these two previous studies, a two-step approach utilizing a tumor classifier and an EBV classifier was implemented.…”

Section: Discussionmentioning

confidence: 99%

“…Prior studies have proven to facilitate learning of morphologic feature representation, correlating to molecular alterations, from digitized whole-slide images (WSI). They have inferred genetic traits including EBV status, actionable driving mutation, microsatellite instability, gene signature, and molecular tumor subtypes, in various malignant images (Supplementary Table S1 and S2 ) 25 – 51 . These studies shed light on the morphology-molecular association or “histo-genomics” 52 , 53 , which may contribute toward the discovery of cost-effective biomarkers and improved therapeutic options 54 .…”

Section: Introductionmentioning

confidence: 99%

Deep learning model to predict Epstein–Barr virus associated gastric cancer in histology

Jeong

Cho

Kim

et al. 2022

Sci Rep

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The detection of Epstein–Barr virus (EBV) in gastric cancer patients is crucial for clinical decision making, as it is related with specific treatment responses and prognoses. Despite its importance, the limited medical resources preclude universal EBV testing. Herein, we propose a deep learning-based EBV prediction method from H&E-stained whole-slide images (WSI). Our model was developed using 319 H&E stained WSI (26 EBV positive; TCGA dataset) from the Cancer Genome Atlas, and 108 WSI (8 EBV positive; ISH dataset) from an independent institution. Our deep learning model, EBVNet consists of two sequential components: a tumor classifier and an EBV classifier. We visualized the learned representation by the classifiers using UMAP. We externally validated the model using 60 additional WSI (7 being EBV positive; HGH dataset). We compared the model’s performance with those of four pathologists. EBVNet achieved an AUPRC of 0.65, whereas the four pathologists yielded a mean AUPRC of 0.41. Moreover, EBVNet achieved an negative predictive value, sensitivity, specificity, precision, and F1-score of 0.98, 0.86, 0.92, 0.60, and 0.71, respectively. Our proposed model is expected to contribute to prescreen patients for confirmatory testing, potentially to save test-related cost and labor.

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Deep learning based on hematoxylin–eosin staining outperforms immunohistochemistry in predicting molecular subtypes of gastric adenocarcinoma

Cited by 14 publications

References 46 publications

How to learn with intentional mistakes: NoisyEnsembles to overcome poor tissue quality for deep learning in computational pathology

How to learn with intentional mistakes: NoisyEnsembles to overcome poor tissue quality for deep learning in computational pathology

Molecular subtyping of gastroesophageal dysplasia heterogeneity according to TCGA/ACRG classes

Deep learning model to predict Epstein–Barr virus associated gastric cancer in histology

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