1 / 48

Models for Implementing Artificial Intelligence in Pathology Practice

Explore an evolving model for diagnostics in pathology, integrating AI. Learn how the diagnostic cockpit impacts workflow and patient outcomes. Discover challenges, objectives, and action items shaping the future of pathology practice.

jhammons
Download Presentation

Models for Implementing Artificial Intelligence in Pathology Practice

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Models for Implementing Artificial Intelligence in Pathology Practice May 6, 2019 Douglas J. Hartman, MD

  2. Disclosures • Philips = honorarium for educational presentation

  3. Objectives • Describe an evolving model for the diagnostic cockpit and how that applies to pathology • Demonstrate a sample diagnostic signout workflow • Describe how artificial intelligence can be integrated into the pathology diagnostic workflow

  4. Pathology Cockpit • Early discussions of a pathology cockpit in 2010 • Very little literature about this exists DiagnPathol. 2014;9 Suppl 1:S12. doi: 10.1186/1746-1596-9-S1-S12. Epub 2014 Dec 19. iPathology cockpit diagnostic station: validation according to College of American Pathologists Pathology and Laboratory Quality Center recommendation at the Hospital Trust and University of Verona. Brunelli M, Beccari S, Colombari R, Gobbo S, Giobelli L, Pellegrini A, Chilosi M, Lunardi M, Martignoni G, Scarpa A, Eccher A.

  5. Cockpit Evolution • Forum sponsored by the Academy for Radiology and Biomedical Imaging Research • Brought together stakeholders from: • Urology • Oncology • Pathology • Neurology • Cardiology • Emergency Medicine • Molecular Diagnostics • Informatics

  6. Goals of the Symposium • Elevate the profile of medical imaging technologies • Ensures its value and impact are broadly recognized • Facilitate collaborations • Highlight content experts • Provide critical voice of the imaging community

  7. Drivers for convening symposium • Errors and imprecision in medical diagnosis • Leads to poor patient outcomes • Two common diagnostic errors • Ordering the wrong imaging test • Misinterpretation of imaging test findings

  8. Cockpit = “Integrated Diagnostics” • Current Obstacles: • Limited dissemination of valuable diagnostic technologies • Siloed electronic health records • Few available data analytic tools • Variable data inputs and outputs • Lack of coordinated effort to improve diagnostics across all stakeholders

  9. Symposium Composition • Presentations from key stakeholders (“consumers”) • Presentations from the “Cockpit Crew” (users) • Multidisciplinary groups to identify models and prioritize the next steps in constructing a prototype Cockpit

  10. High Priority Tasks • Develop national standards • Catalog available data analytic methods • Develop advanced analytic methods • Develop environment to host the analytic methods • Create an environment to enable and facilitate communication/cooperation • Catalyze the construction of the prototype Cockpit

  11. Advancing the Diagnostic Cockpit • May 2018 • Four objectives: • Standardization/interoperability • Application of advanced computation • Acceleration of development and translation of new techniques • Promotion of best practices in medical imaging

  12. Challenges • Lack of standardized measurement and techniques • Lack of standard interchange mechanism • Need for more standardized reference studies

  13. Action Items from Symposium • Identify neutral third party to validate de-identification, manage datasets and ensure interoperability • Collect 100 complete datasets from 10 different institutions • Create compendium of existing standards • Refine core functional requirements of the diagnostic cockpit • Identify potential funding sources for any initiative

  14. So what does this mean for pathology?

  15. Digital Pathology Background • Very few labs in the USA have gone entirely digital for primary diagnosis • UPMC is restarting their conversion to a digital pathology platform for primary diagnosis sign out • Vendors have been regulated by Food Drug Administration – WSI considered Class III device • First FDA approved system – Philips – April 2017

  16. UPMC Clinical Use Cases • Retrospective Slide Scanning (passive encouragement of slide scanning – archival use case) • Internal (UPMC) & external consults • IHC core lab (centralization) • Breast marker image analysis • Philips Tutor (formerly PathXL) education partnership • To do: • Archive outside consults, frozen section, tumor board, etc.

  17. Precision Medicine http://www.questdiagnostics.com/home/physicians/testing-services/by-test-name/precision-medicine-offerings.html

  18. Law of Disruption

  19. The Perfect Storm “When technologies, products, and services converge in radical, creative new ways, a killer app can emerge” Dones & Mui. Unleashing the killer app. Harvard Business School Press. 2000

  20. Algorithms • Identify rare events (e.g. screening for microorganisms) • Quantitative measurements • Score biomarkers (e.g. ER, PR, Her2/neu, Ki67, CD34, PD-L1) • Tissue measurements (e.g. mitotic counts, quantify fibrosis/steatosis) • Analyze spatial patterns and feature distribution (e.g. neuroscience) • Automated grading (of tumors) • CAD (e.g. prostate cancer diagnosis, detect Barrett’s esophagus with dysplasia) • Workflow (smart) algorithm (e.g. triage cases, automate downstream steps like LCM) • Miscellaneous (research & novel) algorithms (e.g. TMAs, 3D image reconstruction)

  21. Integration in Digital Signout -1

  22. Integration in Digital Signout -2

  23. Integration in Digital Signout -3

  24. Integration in Digital Signout - 4

  25. Digital Workflow Legacy Workflow Digital Workflow

  26. Integration in Digital Signout - 5

  27. Integration in Digital Signout -6

  28. Implemented Image Analysis • Automated CD8 quantification • Digital tumor bud assessment • Automated Her2 assessment in GE junction tumors • Developing more biomarker evaluation

  29. CD8 Analysis Oropharyngeal Cases • ?Selection criteria to use • Tonsillar tissue • Resection vs biopsy vs TMA core

  30. Whole section Analysis

  31. Absolute CD8 distribution within Oropharyngeal cases

  32. Outcome Data based on Univariate Analysis (n=74)

  33. Survival based on Density of CD8 cells

  34. Digital Tumor Bud Assessment

  35. Counting Ki-67 positive cells

  36. Regulatory • Few AI-based algorithms have been cleared by the Food and Drug Administration • Use cases: • Bone fracture • Large vessel occlusion • Brain damage • Diabetic retinopathy

  37. Payment • No billing code specifically associated with artificial intelligence • Options: • Per Click • Flat fee • Other?

  38. Public Image Challenges • Image analysis challenges • Camelyon – 16 – detecting metastases • Cataloged at Grand Challenges • Public leaderboard of contestants

  39. Summary of Pathology Image Challenges • 19/169 challenges involved pathology • 15-1000 slides • Ranged from 10-40x magnification • The number of recorded participants ranged from 13-1231

  40. Summary of Pathology Image Challenges – organ area and file types • Organ sites: • Breast (9) • Cervix (2) • Neuropath (2) • Multiorgan (2) • Thyroid (1); Colorectal (1); lung (1); hemepath (1) • Most common to have a single file type (15 challenges)

  41. Image Challenges - evaluation • Various statistical methods • Dice Coefficient • Area under the curve • Weighted precision • Free response operating curve • F1 score • Sensitivity/specificity • Gold standard • One pathologist • Multiple “consensus” pathologists • Medical Experts • Oncologist • Not mentioned

  42. Future Directions • Cockpit for Pathology already forming (mostly around software system integration) • Most designs have tried to emulate current workflows • Novel interactions with whole slide images (Virtual reality/augmented reality)

  43. Conclusions • Artificial Intelligence based tools are ready for use in the diagnostic pathology workflow • Building interoperability with digital pathology systems is critical to adoption • Integrating artificial intelligence into digital pathology platforms with increase adoption and facilitate more utilization of this powerful technology

  44. Questions and Answers Douglas J. Hartman MD hartmandj@upmc.edu

  45. References • Mark D. Zarella, Douglas Bowman;, Famke Aeffner, Navid Farahani, Albert Xthona;, Syeda Fatima Absar, Anil Parwani, Marilyn Bui, and Douglas J. Hartman (2019) A Practical Guide to Whole Slide Imaging: A White Paper From the Digital Pathology Association. Archives of Pathology & Laboratory Medicine: February 2019, Vol. 143, No. 2, pp. 222-234. • Guo H, Birsa J, Farahani N, Hartman DJ, Piccoli A, O'Leary M, McHugh J, Nyman M, Stratman C, Kvarnstrom V, Yousem S, Pantanowitz L. Digital pathology and anatomic pathology laboratory information system integration to support digital pathology sign-out. J Pathol Inform. 2016 May 4;7:23. doi: 10.4103/2153-3539.181767. eCollection2016. PMID:27217973 • http://www.acadrad.org/wp-content/uploads/2019/01/Academy-White-Paper-Sympoiusm-to-Address-Standards-2018.pdf • http://www.questdiagnostics.com/home/physicians/testing-services/by-test-name/precision-medicine-offerings.html • https://grand-challenge.org/challenges/ • Ratner M. FDA backs clinician-free AI imaging diagnostic tools. Nat Biotechnol 2018 Aug 6; 36(8): 673-674.

More Related