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Case Notes
History
50 year old female presenting with acute-onset, left sided, weakness.Exam
2 minute delayed post contrast head CTA with: analysis of pial collateralization, plus a comparative analysis of the CT density within the venocapillary pool (using the initial and delayed post contrast CTA’s), plus an analysis of venous egress. This part of the CTA is referred to as either the delayed post contrast CTA or the 2nd pass CTA, since it is performed after the 2nd contrast bolus. It has the benefit of recirculation effects, and twice the contrast load, as the initial post contrast head CTA. The delayed post contrast CTA is used to detect distal pial collateralization and to assess the CT-density within the parenchymal venocapillary pool, which provides the best CTA evidence of ischemic injury.
Purposes
1. To identify any, and all, sites of intracranial afferent block (either occlusion or combination of tandem stenosis and an incomplete circle of Willis);
2. To determine whether the observed pial collateral gap observed on the CTA head finally reaches the proximal thrombus on the delayed post contrast CTA head (considered fair collateral). However, this tissue may still be at risk for ischemic injury;
3. If the a pial collateral gap remains on the delayed post contrast head CTA, then tissue within the gap will likely be in the dense ischemic core and become a completed stroke (ischemic cascade plus glutamate cascade leading to liquefactive necrosis or sequestered infarct or both).
4. Given there is observably reasonable pial collateral, it does NOT ensure that there is perfusion of the underlying tissue. To assess whether the existing pial collateral actually perfuses the underlying brain parenchyma, a comparative analysis is made between the CT contrast density within the venocapillary pool in the affected region on the initial post contrast CTA with the CT density on the delayed post contrast CTA, and that is compared to unaffected comparable region on the contra lateral side. At-risk tissue (ischemic penumbra) will exhibit a partial rise in CT density between the 1st and the 2nd post contrast CTA, but it will not reach normal range compared to unaffected brain. Tissue that shows little or no rise in CT density in the venocapillary pool will be within the dense ischemic core. The areas of significantly reduced & absent parenchymal contrast CT density are at higher risk of hemorrhagic conversion upon reperfusion (spontaneous or therapeutic). Note: analysis of the CT density in the venocapillary pool and CT perfusion are both approximations of tissue actual perfusion based on changes in concentration of the contrast media in tissue over time. Thus, an initial short-term high depth-duration oligemic event can occur, initiating the ischemic cascade. But the afferent block can quickly clear, which means tissue injury can be initiated, but the antegrade blood flow is restored. In this circumstance, tissue injury will have occurred, but the restroration of pial blood flow will appear as normal or near normal on both the CT perfusion and the CT density within the venocapillary pool. Thus, both the CTA and CT perfusion may underestimate tissue injury, which is why the stroke protocol MR is of value, since actual tissue injury will always show up, in some fashion, on MR diffusion sequences.
5. Given there is an ICA stenosis/occlusion, is there effective EC-IC collateral;
6. In the context of restricted intradural afferent arterial blood flow obstruction (in the absence of a primary stem occlusion), has regional hypoperfusion produced oligemia in the expected anastomotic border zones producing a watershed stroke pattern;
7. In the context of an ICA thrombosis, tandem stenoses, incomplete portions of circle of Willis, or a combination of these, is there a shift in the location of the anastomotic border zones such that oligemia produces an end-of the-line watershed stroke pattern. Low flow ischemia within the end-of the-line portion of a shifted watershed can account strokes that involve tissue not primarily affected by the thrombus.
8. To evaluate the state of venous egress, at least for the major veins (note: SWI is the most effective of assessing flow in the deep parenchymal medullary veins).
Purposes
1. To identify any, and all, sites of intracranial afferent block (either occlusion or combination of tandem stenosis and an incomplete circle of Willis);
2. To determine whether the observed pial collateral gap observed on the CTA head finally reaches the proximal thrombus on the delayed post contrast CTA head (considered fair collateral). However, this tissue may still be at risk for ischemic injury;
3. If the a pial collateral gap remains on the delayed post contrast head CTA, then tissue within the gap will likely be in the dense ischemic core and become a completed stroke (ischemic cascade plus glutamate cascade leading to liquefactive necrosis or sequestered infarct or both).
4. Given there is observably reasonable pial collateral, it does NOT ensure that there is perfusion of the underlying tissue. To assess whether the existing pial collateral actually perfuses the underlying brain parenchyma, a comparative analysis is made between the CT contrast density within the venocapillary pool in the affected region on the initial post contrast CTA with the CT density on the delayed post contrast CTA, and that is compared to unaffected comparable region on the contra lateral side. At-risk tissue (ischemic penumbra) will exhibit a partial rise in CT density between the 1st and the 2nd post contrast CTA, but it will not reach normal range compared to unaffected brain. Tissue that shows little or no rise in CT density in the venocapillary pool will be within the dense ischemic core. The areas of significantly reduced & absent parenchymal contrast CT density are at higher risk of hemorrhagic conversion upon reperfusion (spontaneous or therapeutic). Note: analysis of the CT density in the venocapillary pool and CT perfusion are both approximations of tissue actual perfusion based on changes in concentration of the contrast media in tissue over time. Thus, an initial short-term high depth-duration oligemic event can occur, initiating the ischemic cascade. But the afferent block can quickly clear, which means tissue injury can be initiated, but the antegrade blood flow is restored. In this circumstance, tissue injury will have occurred, but the restroration of pial blood flow will appear as normal or near normal on both the CT perfusion and the CT density within the venocapillary pool. Thus, both the CTA and CT perfusion may underestimate tissue injury, which is why the stroke protocol MR is of value, since actual tissue injury will always show up, in some fashion, on MR diffusion sequences.
5. Given there is an ICA stenosis/occlusion, is there effective EC-IC collateral;
6. In the context of restricted intradural afferent arterial blood flow obstruction (in the absence of a primary stem occlusion), has regional hypoperfusion produced oligemia in the expected anastomotic border zones producing a watershed stroke pattern;
7. In the context of an ICA thrombosis, tandem stenoses, incomplete portions of circle of Willis, or a combination of these, is there a shift in the location of the anastomotic border zones such that oligemia produces an end-of the-line watershed stroke pattern. Low flow ischemia within the end-of the-line portion of a shifted watershed can account strokes that involve tissue not primarily affected by the thrombus.
8. To evaluate the state of venous egress, at least for the major veins (note: SWI is the most effective of assessing flow in the deep parenchymal medullary veins).
Prior Study
Noncontrast Head CTDense mural calcification in Rt. ICA which projects over the arterial lumen; this could represent a site of high cervical Rt ICA flow-limiting stenosis.
No clear evidence of a hyperacute stroke is evident.
CT Perfusion
Reduced perfusion rate in the Rt. cerebral watershed territory, but the area appears physiologically compensated by collateral blood flow.
CTA of the Neck
Rt. carotid bifurcation has moderate focal stenosis affecting both the EAC & IAC origins in the 50% range.
Rt. proximal ICA is occluded just after carotid sinus with apparent intraluminal soft clot consistent with hyperacute thrombus formation.
Rt. ICA reopacifies at mid-cavernous segment from ascending pharyngeal artery to infra-lateral trunk EC-IC connection. However, the reopacified ICA has less contrast density and is smaller in size than expected indicating less the fully functional EC-IC collateralization which puts the Rt. hemisphere at risk for hypoperfusion.
CTA of the Head
1. Acutely thrombosed Rt. cervical ICA with partial flow restoration at the cavernous level from functional EC-IC connections.
2. Intracranial arteries appear patent, although the filling rate is delayed and the arterial opacification in the Rt. ICA circuit is less than the left. Additionally, the left A1 segment is hypoplastic. Thus, this combination raises the possibility of a oligemic hypoperfusion in the Rt. carotid watershed areas, which matches the findings on the CT perfusion.
