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confs_page:seaker_list [2021/06/10 11:31]
nbuisard created
confs_page:seaker_list [2021/06/14 15:41]
nbuisard
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-====== SPEAKERS ======+z====== SPEAKERS ====== 
 +----  \\  ​
  
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-Sir Michael Brady FRS FREng FMedsci+**Sir Michael Brady FRS FREng FMedsci**
  
 Emeritus Professor of Oncological Imaging, University of Oxford Emeritus Professor of Oncological Imaging, University of Oxford
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 Founder Director: Volpara Health Technologies,​ Mirada Medical Founder Director: Volpara Health Technologies,​ Mirada Medical
 Chairman: Optellum Chairman: Optellum
-(Membre Étranger de l’Académie des Sciences)+(Membre Étranger de l’Académie des Sciences) ​ ​\\ ​   \\    \\    \\  ​
  
-​Title: ​+​Title: ​ ​\\ ​  
 Quantitative and Intelligent Imaging for Clinical Decision Support Quantitative and Intelligent Imaging for Clinical Decision Support
  
-Abstract: +Abstract: ​ ​\\  ​ 
-We discuss a number of important developments in CARS primarily by reference to innovations in some of the medical image analysis companies of which I am a Founder. ​ First, image analysis can be quantitative,​ each pixel measuring a physical quantity. ​ We first illustrate this by quantitative MRI of the liver, measuring proton density fat fraction; iron content; and fibroinflammation (units of time). ​ This is applied to (non-alcoholic) fatty liver disease, steatohepatitis (NASH), and therapeutic interventions,​ both measuring the effect of anti-NASH drugs and supporting liver surgery. ​ Then, we show how breast density may be measured and applied to estimate x-ray dose in mammography. ​ Second, image analysis can be intelligent based on methods developed in AI and Machine Learning (a branch of AI). We illustrate this both in MRI analysis of the liver and in a decision support system for mammography. ​ This offers opportunities in work flow and we show how the combination of all radiologists working with Transpara decision support software can out-perform either working individually. ​ Finally, we discuss some of the strengths and limitations of machine learning applied to medical imaging.+We discuss a number of important developments in CARS primarily by reference to innovations in some of the medical image analysis companies of which I am a Founder. ​ First, image analysis can be quantitative,​ each pixel measuring a physical quantity. ​ We first illustrate this by quantitative MRI of the liver, measuring proton density fat fraction; iron content; and fibroinflammation (units of time). ​ This is applied to (non-alcoholic) fatty liver disease, steatohepatitis (NASH), and therapeutic interventions,​ both measuring the effect of anti-NASH drugs and supporting liver surgery. ​ Then, we show how breast density may be measured and applied to estimate x-ray dose in mammography. ​ Second, image analysis can be intelligent based on methods developed in AI and Machine Learning (a branch of AI). We illustrate this both in MRI analysis of the liver and in a decision support system for mammography. ​ This offers opportunities in work flow and we show how the combination of all radiologists working with Transpara decision support software can out-perform either working individually. ​ Finally, we discuss some of the strengths and limitations of machine learning applied to medical imaging. ​ ​\\ ​   \\  ​
  
 +{{:​confs_page:​speaker2.png?​140 |}}
 +**Dr. Bibb Allen Jr., MD, FACR**
  
- 
-Dr. Bibb Allen Jr., MD, FACR 
  
 Chief Medical Officer Chief Medical Officer
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 Diagnostic Radiology Diagnostic Radiology
 Grandview Medical Center Grandview Medical Center
-Birmingham, Alabama USA+Birmingham, Alabama USA  ​\\ ​   \\    \\    \\    \\  ​
  
-Title:+Title: ​ ​\\  ​
 Fostering A Strong Ecosystem For Artificial Intelligence In Medical Imaging Fostering A Strong Ecosystem For Artificial Intelligence In Medical Imaging
  
  
-Abstract: +Abstract: ​ ​\\  ​ 
-Fueled by the ever-increasing amount of data generated by the healthcare system applications for artificial intelligence in healthcare, especially within diagnostic imaging, are rapidly proliferating. Currently, no well-defined framework exists for determining how great ideas for AI algorithms in healthcare will advance from development to integrated clinical practice. Healthcare stakeholders including physicians, patients, medical societies, hospital systems, software developers, the health information technology industry and governmental regulatory agencies all comprise a community that will need to function as an ecosystem system in order for AI algorithms to be deployed, monitored, and improved in widespread clinical practice. Radiologists can play an important role in promoting this AI ecosystem by delineating structured AI use cases for diagnostic imaging and standardizing data elements and workflow integration interfaces. By developing structured AI use cases based on the needs of the physician community, radiologists and radiology specialty societies can assist developers in creating the tools that will advance the practice of medicine. If these use cases specify how datasets for algorithm training, testing and validation can be developed as well as specifying parameters for clinical integration and pathways for assessing algorithm performance in clinical practice, the likelihood of bringing safe and effective algorithms to clinical practice will increase dramatically. The development of an active AI ecosystem will facilitate the development and deployment of AI tools for healthcare that will help physicians solve medicine’s important problems. +Fueled by the ever-increasing amount of data generated by the healthcare system applications for artificial intelligence in healthcare, especially within diagnostic imaging, are rapidly proliferating. Currently, no well-defined framework exists for determining how great ideas for AI algorithms in healthcare will advance from development to integrated clinical practice. Healthcare stakeholders including physicians, patients, medical societies, hospital systems, software developers, the health information technology industry and governmental regulatory agencies all comprise a community that will need to function as an ecosystem system in order for AI algorithms to be deployed, monitored, and improved in widespread clinical practice. Radiologists can play an important role in promoting this AI ecosystem by delineating structured AI use cases for diagnostic imaging and standardizing data elements and workflow integration interfaces. By developing structured AI use cases based on the needs of the physician community, radiologists and radiology specialty societies can assist developers in creating the tools that will advance the practice of medicine. If these use cases specify how datasets for algorithm training, testing and validation can be developed as well as specifying parameters for clinical integration and pathways for assessing algorithm performance in clinical practice, the likelihood of bringing safe and effective algorithms to clinical practice will increase dramatically. The development of an active AI ecosystem will facilitate the development and deployment of AI tools for healthcare that will help physicians solve medicine’s important problems. ​ ​\\ ​   \\    \\    \\  
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