Imaging Selection in Ischemic Stroke: Feasibility of Automated CT-Perfusion Analysis

Background Advanced imaging may refine patient selection for ischemic stroke treatment but delays to acquire and process the imaging have limited implementation. Aims We examined the feasibility of imaging selection in clinical practice using fully automated software in the EXTEND trial program. Met...

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Bibliographic Details
Published in:International journal of stroke 2015-01, Vol.10 (1), p.51-54
Main Authors: Campbell, Bruce C.V., Yassi, Nawaf, Ma, Henry, Sharma, Gagan, Salinas, Simon, Churilov, Leonid, Meretoja, Atte, Parsons, Mark W., Desmond, Patricia M., Lansberg, Maarten G., Donnan, Geoffrey A., Davis, Stephen M.
Format: Article
Language:English
Subjects:
acute ischemic stroke
Diffusion Magnetic Resonance Imaging - methods
Feasibility Studies
Humans
Image Processing, Computer-Assisted - methods
Multimodal Imaging - methods
penumbra imaging
Perfusion CT
Perfusion MRI
PWI
Software
Stroke - diagnosis
Stroke - therapy
thrombolysis
Thrombolytic Therapy - methods
Time-to-Treatment
Tomography, X-Ray Computed - methods
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Summary:Background Advanced imaging may refine patient selection for ischemic stroke treatment but delays to acquire and process the imaging have limited implementation. Aims We examined the feasibility of imaging selection in clinical practice using fully automated software in the EXTEND trial program. Methods CTP and perfusion-diffusion MRI data were processed using fully-automated software to generate a yes/no ‘mismatch’ classification that determined eligibility for trial therapies. The technical failure/mismatch classification error rate and time to image and treat with CT vs. MR-based selection were examined. Results In a consecutive series of 776 patients from five sites over six-months the technical failure rate of CTP acquisition/processing (uninterpretable maps) was 3·4% (26/776, 95%CI 2·2–4·9%). Mismatch classification was overruled by expert review in an additional 9·0% (70/776, 95%CI 7·1–11·3%) due to artifactual ‘perfusion lesion’. In 154 consecutive patients at one site, median additional time to acquire CTP after noncontrast CT was 6·5 min. Subsequent RAPID processing time varied from 3–10 min across 20 trial centers (median 5 min 20 s). In the EXTEND trial, door-to-needle times in patients randomized on the basis of CTP (n = 47) were median 78 min shorter than MRI-selected (n = 16) patients (P < 0·001). Conclusions Automated CTP-based mismatch selection is rapid, robust in clinical practice, and associated with faster treatment decisions than MRI. This technological advance has the potential to improve the standardization and reproducibility of interpretation of advanced imaging and extend use to practice settings beyond highly specialized academic centers.
ISSN:1747-4930
1747-4949
DOI:10.1111/ijs.12381