Review

. 2014 Aug;35(8):1515-9.

doi: 10.3174/ajnr.A3892. Epub 2014 Mar 20.

Calcified cerebral emboli, a "do not miss" imaging diagnosis: 22 new cases and review of the literature

B S Walker¹, L M Shah², A G Osborn²

Affiliations

¹ From the Department of Radiology, University of Utah School of Medicine, Salt Lake City, Utah. brett.walker@imail.org.
² From the Department of Radiology, University of Utah School of Medicine, Salt Lake City, Utah.

PMID: 24651819
PMCID: PMC7964438
DOI: 10.3174/ajnr.A3892

Review

Calcified cerebral emboli, a "do not miss" imaging diagnosis: 22 new cases and review of the literature

B S Walker et al. AJNR Am J Neuroradiol. 2014 Aug.

. 2014 Aug;35(8):1515-9.

doi: 10.3174/ajnr.A3892. Epub 2014 Mar 20.

Authors

B S Walker¹, L M Shah², A G Osborn²

Affiliations

¹ From the Department of Radiology, University of Utah School of Medicine, Salt Lake City, Utah. brett.walker@imail.org.
² From the Department of Radiology, University of Utah School of Medicine, Salt Lake City, Utah.

PMID: 24651819
PMCID: PMC7964438
DOI: 10.3174/ajnr.A3892

Abstract

Background and purpose: Calcified cerebral emboli are a rarely reported but devastating cause of stroke and may be the first manifestation of vascular or cardiac disease. Our aim was to evaluate the diagnosis, prevalence, imaging appearance, presumed embolic source, treatment, and outcome of patients with calcified cerebral emboli.

Materials and methods: Our radiology information system was searched for all CT scans by using keywords "calcified," "emboli," and their permutations. The radiology information system was also searched to identify all "stroke" CT reports to calculate the prevalence of calcified cerebral emboli. We also performed a MEDLINE search to identify all published case reports.

Results: Twenty-two cases were identified from our database, and 48 were cases reported from the literature. The middle cerebral artery was the site of 83% of calcified emboli. Presumed sources were calcific aortic stenosis (36%), carotid atherosclerotic plaque (30%), and mitral annular calcification (11%). Spontaneous embolism occurred in 86%. Surgical treatment was performed in 34% of patients. Sixty-four percent of the patients with calcified aortic stenosis underwent aortic valve replacement. Among those with identifiable arterial disease, 53% underwent endarterectomy. Forty-one percent of patients experienced at least 1 recurrent stroke. The prevalence of calcified cerebral emboli identified on stroke CT scans at our institution was 2.7%. Seventy-three percent of cases were correctly identified. Twenty-seven percent were misdiagnosed on initial interpretation, while 9% were overlooked on preliminary interpretation.

Conclusions: Calcified cerebral emboli are more common than previously assumed, are frequently overlooked or misinterpreted, affect clinical course when diagnosed, and carry substantial risk for recurrent stroke.

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Figures

**Fig 1.**
Case 1. An 84-year-old man with a known remote right MCA infarct had sudden onset of new strokelike symptoms. The noncontrast CT scan (A) shows calcified emboli (*straight arrows*) in the horizontal MCA segment and posterior division of the MCA with adjacent encephalomalacia (*curved arrows*). Subtle hypoattenuation of the adjacent gyrus is also present (*black arrow*). CT perfusion (B) shows the old infarction (*white arrows*) as a focal area of decreased cerebral blood volume (left). The new ischemic injury (*curved arrow, right*) is shown just posterior to the old infarction. Coronal MIP image (C) shows the calcific distal common proximal internal carotid artery plaque (*arrow*), which was identified as the probable source of emboli. NCCT (D) with initial scan (left) and follow-up scan (right) 1 day later shows interval migration of calcified embolus (*arrows*) within the right MCA. The patient underwent right carotid endarterectomy. Pathologic examination of the endarterectomy specimen revealed intimal proliferative material consisting of thrombotic debris, cholesterol clefts, dystrophic calcifications, and myxoid degeneration.

**Fig 2.**
Case 2. Axial nonenhanced CT of the head (A, left) in a 59-year-old woman with acute-onset right hemiparesis shows a small hyperattenuated focus (*arrow*) that measured 101 HU, consistent with a calcific embolus within the posterior left frontal lobe. Axial CTA (A, right) confirms the intravascular location of the embolus. Coronal MIP CT angiogram of the neck (B) shows irregular calcified atherosclerotic plaque (*arrow*) within a dilated left carotid bulb and proximal internal carotid artery. The patient had surgical resection of the left carotid fusiform aneurysm and repair with a graft. Pathologic examination of the specimen disclosed a calcified and thickened wall with approximately 30% narrowing.

**Fig 3.**
Case 3. Axial nonenhanced CT of the head (A) in an 89-year-old man presenting with acute onset of left hemiparesis. A hyperattenuated focus (*straight arrow*) measuring 345 HU, consistent with calcified embolus, is seen within the posterior distribution of the right MCA. A second embolus is seen more superiorly (*curved arrow*). Axial diffusion tensor imaging (B) of the same patient reveals diffusion restriction within multiple areas (*arrows*) in the right MCA distribution, including both the anterior and posterior divisions, indicating multiple cortical infarctions. These infarctions are likely the result of noncalcified emboli dislodged from the same location as the calcified embolus. FLAIR (C) reveals multiple areas of FLAIR hyperintensity (*straight arrows*) in the same areas as the restricted diffusion, consistent with late acute-to-subacute infarction. There is also intravascular hyperintense signal showing slow flow (*curved arrow*) distal to the calcified embolus. Sonography (D) shows stenosis of the right internal carotid artery (*arrow*) as the likely source of emboli. Initially, the large calcified embolus (A, left) was diagnosed as a calcified vessel wall. A smaller second embolus (A, right) was overlooked as was a third calcified embolus (not shown).

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Calcified cerebral emboli, a "do not miss" imaging diagnosis: 22 new cases and review of the literature

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Calcified cerebral emboli, a "do not miss" imaging diagnosis: 22 new cases and review of the literature

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