Society of Toxicologic Pathology Digital Pathology and Image Analysis Special Interest Group Article*: Opinion on the Application of Artificial Intelligence and Machine Learning to Digital Toxicologic Pathology

Turner, Oliver C.; Aeffner, Famke; Bangari, Dinesh S.; High, Wanda; Knight, Brian L.; Forest, Tom; Cossic, Brieuc; Himmel, Lauren E.; Rudmann, Daniel; Bawa, Bhupinder; Muthuswamy, Anantharaman; Aina, Olulanu H.; Edmondson, Elijah F.; Saravanan, Chandrassegar; Brown, Danielle L.; Sing, Tobias; Sebastian, Manu

doi:10.1177/0192623319881401

Cited by 45 publications

(60 citation statements)

References 167 publications

(229 reference statements)

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“…Moreover, the combined power of an expert pathologist and AI system has demonstrated reduced diagnostic errors and superior results compared to either pathologist or machine alone. 40 It has been predicted that researchers will endeavor to use AI to more accurately quantitatively grade immunohistochemistry stains and to reduce the time pathologists spend screening (eg, in cytopathology) by identifying ROIs. 14 This would free up pathologists' time and allow them to focus on higher-level diagnostic tasks such as integrating molecular data which can aid clinicians in treatment decision-making.…”

Section: Con Clus Ionmentioning

confidence: 99%

The use of artificial intelligence, machine learning and deep learning in oncologic histopathology

Sultan

Elgharib

Tavares

et al. 2020

J Oral Pathology Medicine

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The integration of artificial intelligence (AI), machine learning, deep learning, robotics, and Big Data into our physical daily lives has defined the Fourth Industrial Age. Clinicians are now provided with vast new opportunities to improve health care and optimize their approach to patient care. AI can be conceptualized into two main fields, namely artificial general intelligence (AGI) and artificial narrow intelligence (ANI). AGI is generally concerned with the design of machines that can mimic human intelligence with the goal of creating machines that can perform functions similar to humans or even functions that surpass what a human can do (superintelligence).

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Section: Con Clus Ionmentioning

confidence: 99%

The use of artificial intelligence, machine learning and deep learning in oncologic histopathology

Sultan

Elgharib

Tavares

et al. 2020

J Oral Pathology Medicine

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show abstract

“…The development of automated software to extract relevant data from whole slide images has resulted in the rapid expansion of computerized analysis, often referred to as quantitative digital pathology. 18,19 Whole slide images offer an advantage as they are amenable to precise and reproducible data extraction that can be efficiently analyzed with automated open-source and commercially available software developed for image analysis and stereology. For example, the accumulation of versican was measured in tissue samples obtained from the lungs of mice exposed to either vehicle control or H1N1 influenza virus strain, A/PR/8/34 (PR/8), using WSDI and image analysis ( Fig.…”

Section: Digital Imaging and Whole Slide Scanningmentioning

confidence: 99%

“…The integration of AI with image analysis for detection, segmentation, feature extraction, and tissue classification of digital images has resulted in an even more rapid evolution and expansion of digital pathology. 18,19,[56][57][58] Although the promise of AI has garnered substantial attention and excitement, it is important to point out that the use of AI to obtain objective data from cells and tissues dates back over 40 years. 59,60 AI, computer-based systems that automate decision-making processes, was initially defined as the overarching concept of the thinking machine.…”

Section: Artificial Intelligence/machine Learningmentioning

confidence: 99%

“…59,60 AI, computer-based systems that automate decision-making processes, was initially defined as the overarching concept of the thinking machine. 19,58 When first described, machine learning was defined as giving computers the ability to learn without having to be specifically programmed to provide an output. 19,58 Frequently, this is accomplished through supervised learning, wherein the AI system uses algorithms to analyze training sets of data (e.g.…”

Section: Artificial Intelligence/machine Learningmentioning

confidence: 99%

“…19,58 When first described, machine learning was defined as giving computers the ability to learn without having to be specifically programmed to provide an output. 19,58 Frequently, this is accomplished through supervised learning, wherein the AI system uses algorithms to analyze training sets of data (e.g. digital images), learns from those data and adjusts its algorithms, and then based on that learning interprets or makes predictions about new data.…”

Section: Artificial Intelligence/machine Learningmentioning

confidence: 99%

See 2 more Smart Citations

The Use of Quantitative Digital Pathology to Measure Proteoglycan and Glycosaminoglycan Expression and Accumulation in Healthy and Diseased Tissues

Davis

Chang

Brune

et al. 2020

J Histochem Cytochem.

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Advances in reagents, methodologies, analytic platforms, and tools have resulted in a dramatic transformation of the research pathology laboratory. These advances have increased our ability to efficiently generate substantial volumes of data on the expression and accumulation of mRNA, proteins, carbohydrates, signaling pathways, cells, and structures in healthy and diseased tissues that are objective, quantitative, reproducible, and suitable for statistical analysis. The goal of this review is to identify and present how to acquire the critical information required to measure changes in tissues. Included is a brief overview of two morphometric techniques, image analysis and stereology, and the use of artificial intelligence to classify cells and identify hidden patterns and relationships in digital images. In addition, we explore the importance of preanalytical factors in generating high-quality data. This review focuses on techniques we have used to measure proteoglycans, glycosaminoglycans, and immune cells in tissues using immunohistochemistry and in situ hybridization to demonstrate the various morphometric techniques. When performed correctly, quantitative digital pathology is a powerful tool that provides unbiased quantitative data that are difficult to obtain with other methods.

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Introduction to Mouse Pathology

Ward¹,

Vogel²,

Sundberg³

2021

Pathology of Genetically Engineered and Other Mutant Mice

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Society of Toxicologic Pathology Digital Pathology and Image Analysis Special Interest Group Article*: Opinion on the Application of Artificial Intelligence and Machine Learning to Digital Toxicologic Pathology

Cited by 45 publications

References 167 publications

The use of artificial intelligence, machine learning and deep learning in oncologic histopathology

The use of artificial intelligence, machine learning and deep learning in oncologic histopathology

The Use of Quantitative Digital Pathology to Measure Proteoglycan and Glycosaminoglycan Expression and Accumulation in Healthy and Diseased Tissues

Introduction to Mouse Pathology

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