Deep learning outperformed 11 pathologists in the classification of histopathological melanoma images

Hekler, Achim; Utikal, Jochen; Enk, Alexander; Solaß, Wiebke; Schmitt, Max; Klode, Joachim; Schadendorf, Dirk; Sondermann, Wiebke; Franklin, Cindy; Bestvater, Felix; Flaig, Michael J.; Krahl, Dieter; Kalle, Christof von; Fröhling, Stefan; Brinker, Titus J.

doi:10.1016/j.ejca.2019.06.012

Cited by 197 publications

(122 citation statements)

References 21 publications

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“…Whole-genome sequencing, as well as whole-exome sequencing plus transcriptome analysis, is applied for the exploration of unknown cancer drivers, and the development of novel therapeutics for known but intractable targets with the aid of human intelligence, cognitive computing and artificial intelligence in basic and translational oncology (205)(206)(207)(208). Moreover, artificial intelligence is also applied for computer-aided diagnostic approaches (209,210), such as chest computed tomography (211), dermoscopy (212), gastrointestinal endoscopy (213), mammography (214) and histopathological diagnosis (215)(216)(217)(218). To avoid the lack of transparency associated with black box artificial intelligence based on deep learning technologies, the development of explainable artificial intelligence is necessary (219).…”

Section: Sahm1mentioning

confidence: 99%

Precision medicine for human cancers with Notch signaling dysregulation (Review)

Katoh¹,

Katoh

2019

Int J Mol Med

107

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NOTcH1, NOTcH2, NOTcH3 and NOTcH4 are transmembrane receptors that transduce juxtacrine signals of the delta-like canonical Notch ligand (dLL)1, dLL3, dLL4, jagged canonical Notch ligand (JAG)1 and JAG2. canonical Notch signaling activates the transcription of BMI1 proto-oncogene polycomb ring finger, cyclin D1, CD44, cyclin dependent kinase inhibitor 1A, hes family bHLH transcription factor 1, hes related family bHLH transcription factor with YRPW motif 1, MYC, NOTCH3, RE1 silencing transcription factor and transcription factor 7 in a cellular context-dependent manner, while non-canonical Notch signaling activates NF-κB and Rac family small GTPase 1. Notch signaling is aberrantly activated in breast cancer, non-small-cell lung cancer and hematological malignancies, such as T-cell acute lymphoblastic leukemia and diffuse large B-cell lymphoma. However, Notch signaling is inactivated in small-cell lung cancer and squamous cell carcinomas. Loss-of-function NOTCH1 mutations are early events during esophageal tumorigenesis, whereas gain-of-function NOTCH1 mutations are late events during T-cell leukemogenesis and B-cell lymphomagenesis. Notch signaling cascades crosstalk with fibroblast growth factor and WNT signaling cascades in the tumor microenvironment to maintain cancer stem cells and remodel the tumor microenvironment. The Notch signaling network exerts oncogenic and tumor-suppressive effects in a cancer stage-or (sub)type-dependent manner. Small-molecule γ-secretase inhibitors (AL101, MRK-560, nirogacestat and others) and antibody-based biologics targeting Notch ligands or receptors [ABT-165, AMG 119, rovalpituzumab tesirine (Rova-T) and others] have been developed as investigational drugs. The dLL3-targeting antibody-drug conjugate (Adc) Rova-T, and dLL3-targeting chimeric antigen receptor-modified T cells (CAR-Ts), AMG 119, are promising anti-cancer therapeutics, as are other Adcs or cARTs targeting tumor necrosis factor receptor superfamily member 17, cd19, cd22, cd30, cd79B, cd205, claudin 18.2, fibroblast growth factor receptor (FGFR)2, FGFR3, receptor-type tyrosine-protein kinase FLT3, HER2, hepatocyte growth factor receptor, NEcTIN4, inactive tyrosine-protein kinase 7, inactive tyrosine-protein kinase transmembrane receptor ROR1 and tumor-associated calcium signal transducer 2. Adcs and cARTs could alter the therapeutic framework for refractory cancers, especially diffuse-type gastric cancer, ovarian cancer and pancreatic cancer with peritoneal dissemination. Phase III clinical trials of Rova-T for patients with small-cell lung cancer and a phase III clinical trial of nirogacestat for patients with desmoid tumors are ongoing. Integration of human intelligence, cognitive computing and explainable artificial intelligence is necessary to construct a Notch-related knowledge-base and optimize Notch-targeted therapy for patients with cancer.

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Section: Sahm1mentioning

confidence: 99%

Precision medicine for human cancers with Notch signaling dysregulation (Review)

Katoh¹,

Katoh

2019

Int J Mol Med

107

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“…The authors view their work in this new field as what it is, the first two pilot studies implementing deep learning into the histopathologic analysis of melanoma. They are no definitive studies, and the limitations have been extensively discussed in both manuscripts [1,2]. While we agree that the data are preliminary data and acknowledge this in both manuscripts, we argue that our studies are important as they reveal the potential of deep learning in this field and introduce a new application.…”

mentioning

confidence: 52%

Reply to the letter to the editor: ‘Deep learning outperformed 11 pathologists in the classification of histopathological melanoma images’

Hekler

Utikal

Solaß

et al. 2020

European Journal of Cancer

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“…Hekler and colleagues claimed that a CNN which they tested outperformed 11 pathologists in the classification of histopathological melanoma images [73]. In this study, 695 lesions were classified by one expert histopathologist using tissue slides stained with hematoxylin and eosin.…”

Section: Dermatopathologymentioning

confidence: 91%

“…Chief physicians had the highest mean specificity of 69.2% and a mean sensitivity of 73.3%. At the same mean specificity of 69.2%, the CNN had a mean sensitivity of 84.5% [73].…”

Section: Dermatopathologymentioning

confidence: 92%

Machine Learning in Dermatology: Current Applications, Opportunities, and Limitations

Chan

Reddy

Myers

et al. 2020

Dermatol Ther (Heidelb)

147

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Machine learning (ML) has the potential to improve the dermatologist's practice from diagnosis to personalized treatment. Recent advancements in access to large datasets (e.g., electronic medical records, image databases, omics), faster computing, and cheaper data storage have encouraged the development of ML algorithms with human-like intelligence in dermatology. This article is an overview of the basics of ML, current applications of ML, and potential limitations and considerations for further development of ML. We have identified five current areas of applications for ML in dermatology: (1) disease classification using clinical images; (2) disease classification using dermatopathology images; (3) assessment of skin diseases using mobile applications and personal monitoring devices; (4) facilitating large-scale epidemiology research; and (5) precision medicine. The purpose of this review is to provide a guide for dermatologists to help demystify the fundamentals of ML and its wide range of applications in order to better evaluate its potential opportunities and challenges.

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Deep learning outperformed 11 pathologists in the classification of histopathological melanoma images

Cited by 197 publications

References 21 publications

Precision medicine for human cancers with Notch signaling dysregulation (Review)

Precision medicine for human cancers with Notch signaling dysregulation (Review)

Reply to the letter to the editor: ‘Deep learning outperformed 11 pathologists in the classification of histopathological melanoma images’

Machine Learning in Dermatology: Current Applications, Opportunities, and Limitations

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