Abstract
Standard imaging in acute stroke enables the exclusion of non-stroke structural CNS lesions and cerebral haemorrhage from clinical and pre-clinical ischaemic stroke trials. In this review, the potential benefit of imaging (e.g., angiography and penumbral imaging) as a translational tool for trial recruitment and the use of imaging endpoints are discussed for both clinical and pre-clinical stroke research. The addition of advanced imaging to identify a “responder” population leads to reduced sample size for any given effect size in phase 2 trials and is a potentially cost-efficient means of testing interventions. In pre-clinical studies, technical failures (failed or incomplete vessel occlusion, cerebral haemorrhage) can be excluded early and continuous multimodal imaging of the animal from stroke onset is feasible. Pre- and post-intervention repeat scans provide real time assessment of the intervention over the first 4–6 h. Negative aspects of advanced imaging in animal studies include increased time under general anaesthesia, and, as in clinical studies, a delay in starting the intervention. In clinical phase 3 trial designs, the negative aspects of advanced imaging in patient selection include higher exclusion rates, slower recruitment, overestimated effect size and longer acquisition times. Imaging may identify biological effects with smaller sample size and at earlier time points, compared to standard clinical assessments, and can be adjusted for baseline parameters. Mechanistic insights can be obtained. Pre-clinically, multimodal imaging can non-invasively generate data on a range of parameters, allowing the animal to be recovered for subsequent behavioural testing and/or the brain taken for further molecular or histological analysis.
Highlights
Stroke is a clinical syndrome that has diverse causes, and imaging is an essential component of diagnosis
The third Interventional Management of Stroke (IMS-3) trial [14] tested the value of additional mechanical thrombectomy (MT) amongst patients treated with IV thrombolysis with recombinant tissue plasminogen activator, but did not identify any significant benefit of MT compared to IV rtPA alone
The number of subjects included in these observational studies, is small; in DEFUSE-2, only 21 patients contributed to the Bno target mismatch^ group [17]
Summary
Stroke is a clinical syndrome that has diverse causes, and imaging is an essential component of diagnosis. Subsequent human PET studies translated these concepts into the relationship between cerebral blood flow and the metabolic rate for oxygen [3]. The distinction between functionally impaired penumbra and regions of Bbenign oligaemia^—tissue that exhibits reduced perfusion but will survive regardless of whether or not reperfusion occurs—is generally based upon thresholds of prolonged mean transit time (MTT) or delayed time to peak (TTP) in contrast-based perfusion studies using either MRP or CTP. Definitions of these tissue compartments—core, penumbra and benign oligaemia—depend upon the imaging technique and the selection of threshold values. Vascular imaging with CT or MR angiography (CTA or MRA) can identify the presence of extracranial stenosis, the presence of intracranial thrombotic occlusion in large vessels (typically out to the third order branches of the middle cerebral artery [MCA]) and the extent of primary and leptomeningeal collaterals
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