来源:物理与电子科学学院

8 月12日 Hongyu An:Quantitative Cerebral Oxygen Metabolism and its application in stroke Simultaneous PET/MR imaging: challenges, opportunities and applications(物理学系列学术报告)

来源:院系讲座荟萃发布时间:2015-07-29浏览次数:172

讲座题目:Quantitative Cerebral Oxygen Metabolism and  its application in stroke Simultaneous PET/MR imaging: challenges,  opportunities and  applications

主讲人: Hongyu An

开始时间: 2015-08-12 9:00

讲座地址: 理科大楼A510

报告人简介:

Dr.  Hongyu An is an assistant professor in the department of  Radiology, and Biomedical Research Imaging Center (BRIC) at University  of North Carolina at Chapel Hill, and also the MR modality leader in the  BRIC at UNC. He has extensive experience in MR oxygen metabolic  imaging, perfusion (Dynamic Susceptibility Contrast and Arterial Spin  Labeling) imaging, susceptibility weighted imaging (SWI), diffusion  tensor imaging (DTI), phase contrast imaging, MR spectroscopy,  quantitative T1 and T2 measurements, and attenuation and motion  correction for simultaneous PET/MR measurements. He is the PI and a  co-investigator on numerous NIH, foundation and industry grants. I have  published 53 peer reviewed full journal papers, two book chapters, eight  full conference papers and over 130 conference abstracts.

报告简介:

Elevation of oxygen extraction fraction (OEF) in brain tissue  portends a 6-7 fold increased risk of subsequent stroke in patients with  chronic atherosclerotic carotid artery occlusion.  In this talk,  Dr.  An will introduce MR methods that we have used to obtain cerebral OEF  and MR oxygen metabolic index (MROMI),  and will also talk about how we  use MROMI to identify ischemic penumbra in  stroke patients.   Simultaneous PET/MR imaging offers exciting opportunities. Registration  of PET and MRI is a natural consequence of the PET/MR scanner. The  simultaneity of PET and MR on these devices is the key to realizing  their potential.  However, one major challenge of simultaneous PET/MR  imaging is attenuation correction (AC).  Dr. An will talk about some  novel methods that we have developed to do MR based AC for PET and will  introduce a novel MR method to obtain motion information.