Artificial intelligence for basal cell carcinoma: diagnosis and distinction from histological mimics

O’Brien, Blake; Zhao, Kaixuan; Gibson, Tingting; Smith, Dianne; Ryan, David; Whitfield, Joey; Smith, Christopher D.; Bromley, Mark

doi:10.1016/j.pathol.2022.10.004

Cited by 4 publications

(13 citation statements)

References 19 publications

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“…Such a combination is similar to pathologist's diagnostic thinking and is expected to be applied in clinical practice. When dealing with common clinical problem (hesitation between BCC and TE), the differentiation classifier can discriminate BCC from TE in model setting with comparable performance to some of previous studies 17,19 . The performance of the this classifiers is above mean level (sensitivity = 89.2%, specificity = 81.1%) for machine learning in the diagnosis of non‐melanoma skin cancers, but under the top level to differentiate BCC from TE (recall = 100%) 17,19 .…”

Section: Discussionmentioning

confidence: 79%

“…17,19 However, the later model was trained only on 5 sections of TE and test on one slide to differentiate BCC from TE. 17 The small sample size of TE and single center study reduced its confidence of differentiation, while our differentiation classifier is or surrounding tumor nodules. 5 The most suggestive indicator of minimum distance between tumor nuclei is T-T_meanEdgeLength.…”

Section: Discussionmentioning

confidence: 99%

“…In the daily pathological diagnostic workflow of BCC, distinguishing BCC from potential mimics and stating aggressive (HR‐BCC) or nonaggressive types (LR‐BCC) are essential skills for dermatopathologists 15 . Deep learning models have been applied separately for the differentiation and risk stratification of BCC, but not yet been used to construct a pathological framework to accomplish such clinical procedure for daily dermatopathological diagnosis 16,17 . In addition, the importance of nuclear and TME features which have been proved to be important factors among other cancer types, and have been used to predict tumor prognosis, benign and malignant judgment, and disease risk classification in non‐dermatopathological area, although these characteristics are often underestimated in dermatopathology 18–21 .…”

Section: Discussionmentioning

confidence: 99%

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Differentiation and risk stratification of basal cell carcinoma with deep learning on histopathologic images and measuring nuclei and tumor microenvironment features

Lan,

Guo,

Wang

et al. 2024

Skin Research and Technology

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BackgroundNuclear pleomorphism and tumor microenvironment (TME) play a critical role in cancer development and progression. Identifying most predictive nuclei and TME features of basal cell carcinoma (BCC) may provide insights into which characteristics pathologists can use to distinguish and stratify this entity.ObjectivesTo develop an automated workflow based on nuclei and TME features from basaloid cell tumor regions to differentiate BCC from trichoepithelioma (TE) and stratify BCC into high‐risk (HR) and low‐risk (LR) subtypes, and to identify the nuclear and TME characteristics profile of different basaloid cell tumors.MethodsThe deep learning systems were trained on 161 H&E ‐stained sections which contained 51 sections of HR‐BCC, 50 sections of LR‐BCC and 60 sections of TE from one institution (D1), and externally and independently validated on D2 (46 sections) and D3 (76 sections), from 2015 to 2022. 60%, 20% and 20% of D1 data were randomly splitted for training, validation and testing, respectively. The framework comprised four stages: tumor regions identification by multi‐head self‐attention (MSA) U‐Net, nuclei segmentation by HoVer‐Net, quantitative feature by handcrafted extraction, and differentiation and risk stratification classifier construction. Pixel accuracy, precision, recall, dice score, intersection over union (IoU) and area under the curve (AUC) were used to evaluate the performance of tumor segmentation model and classifiers.ResultsMSA‐U‐Net model detected tumor regions with 0.910 precision, 0.869 recall, 0.889 dice score and 0.800 IoU. The differentiation classifier achieved 0.977 ± 0.0159, 0.955 ± 0.0181, 0.885 ± 0.0237 AUC in D1, D2 and D3, respectively. The most discriminative features between BCC and TE contained Homogeneity, Elongation, T‐T_meanEdgeLength, T‐T_Nsubgraph, S‐T_HarmonicCentrality, S‐S_Degrees. The risk stratification model can well predict HR‐BCC and LR‐BCC with 0.920 ± 0.0579, 0.839 ± 0.0176, 0.825 ± 0.0153 AUC in D1, D2 and D3, respectively. The most discriminative features between HR‐BCC and LR‐BCC comprised IntensityMin, Solidity, T‐T_minEdgeLength, T‐T_Coreness, T‐T_Degrees, T‐T_Betweenness, S‐T_Degrees.ConclusionsThis framework hold potential for future use as a second opinion helping inform diagnosis of BCC, and identify nuclei and TME features related with malignancy and tumor risk stratification.

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Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Differentiation and risk stratification of basal cell carcinoma with deep learning on histopathologic images and measuring nuclei and tumor microenvironment features

Lan,

Guo,

Wang

et al. 2024

Skin Research and Technology

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“…[11][12][13][14][15][16][17][18][19][20][21][22][23][24] Numerous studies were concerned with the use of DL models for detection of basal cell carcinomas. [25][26][27][28][29][30][31] As the most common human malignant skin tumor in Central Europe with annually increasing incidence rates, basal cell carcinoma (BCC) represents a major portion of samples submitted to dermatopathology labs. 32 At the same time, BCCs are well suited for establishing automated AI-based image recognition due to their clear histological criteria.…”

Section: Introductionmentioning

confidence: 99%

Applying an artificial intelligence deep learning approach to routine dermatopathological diagnosis of basal cell carcinoma

Duschner,

Baguer,

Schmidt

et al. 2023

J Deutsche Derma Gesell

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SummaryBackgroundInstitutes of dermatopathology are faced with considerable challenges including a continuously rising numbers of submitted specimens and a shortage of specialized health care practitioners. Basal cell carcinoma (BCC) is one of the most common tumors in the fair‐skinned western population and represents a major part of samples submitted for histological evaluation. Digitalizing glass slides has enabled the application of artificial intelligence (AI)‐based procedures. To date, these methods have found only limited application in routine diagnostics. The aim of this study was to establish an AI‐based model for automated BCC detection.Patients and MethodsIn three dermatopathological centers, daily routine practice BCC cases were digitalized. The diagnosis was made both conventionally by analog microscope and digitally through an AI‐supported algorithm based on a U‐Net architecture neural network.ResultsIn routine practice, the model achieved a sensitivity of 98.23% (center 1) and a specificity of 98.51%. The model generalized successfully without additional training to samples from the other centers, achieving similarly high accuracies in BCC detection (sensitivities of 97.67% and 98.57% and specificities of 96.77% and 98.73% in centers 2 and 3, respectively). In addition, automated AI‐based basal cell carcinoma subtyping and tumor thickness measurement were established.ConclusionsAI‐based methods can detect BCC with high accuracy in a routine clinical setting and significantly support dermatopathological work.

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“…Dabei zeigten DL‐Algorithmen gute Ergebnisse bei der Diagnose von Onychomykosen, entzündlichen Dermatosen und kutanen Lymphomen, melanozytären Läsionen sowie Tumoren aus der Gruppe der nichtmelanotischen Hautkrebserkrankungen (NMSC) 11–24 . Zahlreiche Untersuchungen beschäftigten sich mit der Anwendung von DL‐Modellen zur Erkennung von Basalzellkarzinomen 25–31 . Das Basalzellkarzinom (BCC) stellt als häufigster maligner Hauttumor des Menschen in Zentraleuropa mit jährlich steigenden Inzidenzraten einen Großteil des Einsendeguts von dermatopathologischen Laboren dar 32 .…”

Section: Introductionunclassified

Einsatz künstlicher Intelligenz mittels Deep Learning in der dermatopathologischen Routinediagnostik des Basalzellkarzinoms

Duschner,

Baguer,

Schmidt

et al. 2023

J Deutsche Derma Gesell

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ZusammenfassungHintergrundDermatopathologische Institute stehen aufgrund immer höherer Anforderungen bei andererseits schwindenden Ressourcen vor zunehmenden Herausforderungen. Basalzellkarzinome stellen einen Großteil des Einsendeguts mit entsprechendem Arbeitsaufwand dar. Gleichzeitig ermöglicht die Digitalisierung von Glasobjektträgern den Einsatz künstlicher Intelligenz (KI)‐basierter Verfahren in der Dermatopathologie. Bislang haben diese Verfahren keinen Einzug in die Routinediagnostik gefunden. Ziel dieser Studie war daher, den Einsatz eines KI‐basierten Modells zur automatisierten Basalzellkarzinom‐Erkennung zu etablieren.Patienten und MethodikIn drei dermatopathologischen Zentren wurden während des täglichen Routinebetriebs Basalzellkarzinom‐Fälle digitalisiert und sowohl klassisch am Mikroskop als auch mittels KI‐basierter Methodik basierend auf neuronalen Netzen mit U‐Net‐Architektur befundet.ErgebnisseIm Routinebetrieb erzielte das Modell eine Sensitivität von 98,23 % und eine Spezifität von 98,51 % (Zentrum 1). Das Modell konnte übergangslos in den anderen Zentren Einsatz finden und erreichte ähnlich hohe Genauigkeiten in der Basalzellkarzinom‐Erkennung (Sensitivität von 97,67 % beziehungsweise 98,57 %, Spezifität von 96,77 % beziehungsweise 98,73 %). Zusätzlich wurden eine automatisierte, KI‐basierte Basalzellkarzinom‐Subtypisierung und Tumordickenmessung etabliert.SchlussfolgerungenKI‐basierte Verfahren können mit einer hohen Genauigkeit im Routinebetrieb Basalzellkarzinome erkennen und signifikant die dermatopathologische Arbeit unterstützen.

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Artificial intelligence for basal cell carcinoma: diagnosis and distinction from histological mimics

Cited by 4 publications

References 19 publications

Differentiation and risk stratification of basal cell carcinoma with deep learning on histopathologic images and measuring nuclei and tumor microenvironment features

Differentiation and risk stratification of basal cell carcinoma with deep learning on histopathologic images and measuring nuclei and tumor microenvironment features

Applying an artificial intelligence deep learning approach to routine dermatopathological diagnosis of basal cell carcinoma

Einsatz künstlicher Intelligenz mittels Deep Learning in der dermatopathologischen Routinediagnostik des Basalzellkarzinoms

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