Acute stroke

CT scanners are now nearly ubiquitous in or near the emergency departments of most North American hospitals. With multislice scanners, a noncontrast CT (NCCT) examination of the brain can be performed in well under 1 minute, with the newest scanners able to scan the head in 10 seconds or less. In most centers, the first (and sometimes only) imaging study undertaken for patients with suspected acute stroke is NCCT. 

At the other extreme are those acute stroke patients who have no visible arterial occlusion whatsoever, presumably because their infarcts were due to lesions in small arteries that cannot be imaged, or because an embolus in a large proximal artery has broken up spontaneously. Several smdies (again using catheter angiography rather than CTA) have shown that such patients generally enjoy relatively favorable outcomes. 

By far, the most widely used and most empirically studied tissue viability imaging techniques are those that study tissue perfusion, and discussion of perfusion imaging techniques will dominate this section. We will also mention a few emerging techniques that currently are not as widely used in the acute stroke setting, but show promise for the future. 

FIGURE 2.6 Dynamic susceptibility contrast imaging. Axial images of the brain are acquired repeatedly, in this case every 1.5 seconds. As a bolus of intravenously injected contrast material enters the brain, first arteries, then brain parenchyma, and finally veins demonstrate a transient loss of signal intensity. In this acute stroke patient, hypoperfusion of the left middle cerebral artery territory results in delayed arrival of the contrast bolus and prolonged stasis of contrast within the tissue. 

However, several important studies have shown that intravenous thrombolysis may be beneficial more than 3 hours after stroke onset, provided that only patients with a significant diffusion-perfusion mismatch are treated. In one such smdy, Ribo et al. found that patients with a significant diffusion-perfusion mismatch could be treated safely and effectively in the 3-6-hour time period. In phase II of the desmo-teplase in acute stroke (DIAS) trial, patients with diffusion-perfusion mismatch were treated with desmoteplase up to 9 hours after stroke onset, and showed better outcomes than patients given placebo, with only a minimal incidence of symptomatic hemorrhage. Similar success was achieved in the same time window by the dose escalation study of desmoteplase in acute ischemic stroke (DEDAS). ... 

These studies raise the possibility that, one day, imaging-based treatment protocols may allow for intravenous thrombolysis in patients well outside of the now-accepted 3-hour window, provided they demonstrate substantial diffusion-perfusion mismatch. Such protocols could allow for treatment of a vastly larger number of patients than are currently treated. It has been estimated that only 1-7% of acute stroke patients currently receive thrombolytic medication, and that, in up to 95% of cases, they are ineligible because they present outside of the 3-hour time window. As many as 80% of patients who present 6 hours after stroke onset may demonstrate a significant diffusion-perfusion mismatch. "... 

CTP is a relatively recent development in acute stroke imaging that is already in routine clinical use in many centers. CTP and MRP are similar in that both techniques are based on rapid serial image acquisition during intravenous injection of a bolus of contrast material. In both techniques, measurements of density over time (for CTP) or signal intensity over time (for MRP) are converted to contrast agent-versus-time curves, and these are processed in similar ways to yield the same perfusion measurements (most often CBV, CBF, and MTT). Example CTP images are shown in Figure 2.12. 

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