PET/CTA detection of muscle inflammation related to cholesterol crystal emboli without arterial obstruction.

BACKGROUND: PET/CTA was used to evaluate the effect of cholesterol crystal emboli (CCE) on muscle injury. Cholesterol crystals (CCs) released during plaque rupture travel downstream and lodge in muscle triggering inflammation and tissue injury. METHODS: Thigh muscles in three groups of rabbits (n = 22) were studied after intra-arterial injection of CCs, Group I (n = 10); polystyrene microspheres, Group II (n = 5); or normal saline, Group III (n = 7). After 48 hours, muscle inflammation and injury were measured by fluorodeoxy-glucose uptake using PET/CTA, serum tissue factor (TF), and creatinine phosphokinase (CPK). Macrophages were stained with RAM11 and CCs with Bodipy. RESULTS: SUVmax of thigh muscles was greater for Group I vs Group II and III (0.40 ± 0.16 vs 0.21 ± 0.11, P = .038 and 0.23 ± 0.06, P = .036). CPK levels rose significantly in Group I vs Group II and III (6.7 ± 6.0 vs 0.6 ± 0.4, P = .007 and 0.9 ± 0.4 mg·dL-1, P = .023). No arterial thrombosis was detected by CTA or histology of embolized arteries and TF did not rise significantly. There were extensive macrophage infiltrates surrounding muscle necrosis in Group I only. CONCLUSIONS: Cholesterol crystal emboli triggered muscle inflammation and necrosis with an intact circulation. PET/CTA may help in the early detection of inflammation caused by CCs.

Cholesterol crystal embolization following plaque rupture: a systemic disease with unusual features.

Cholesterol crystal embolic (CCE) syndrome is often a clinically challenging condition that has a poor prognostic implication. It is a result of plaque rupture with release of cholesterol crystals into the circulation that embolize into various tissue organs. Plaque rupture seems to be triggered by an expanding necrotic core during cholesterol crystallization forming sharp tipped crystals that perforate and tear the fibrous cap. Embolizing cholesterol crystals then initiate both local and systemic inflammation that eventually lead to vascular fibrosis and obstruction causing symptoms that can mimic other vasculitic conditions. In fact, animal studies have demonstrated that cholesterol crystals can trigger an inflammatory response via NLRP3 inflammasome similar to that seen with gout. The diagnosis of CCE syndrome often requires a high suspicion of the condition. Serum inflammation biomarkers including elevated sedimentation rate, abnormal renal function tests and eosinophilia are useful but non-specific. Common target organ involvement includes the skin, kidney, and brain. Various testing including fundoscopic eye examination and other non-invasive procedures such as trans-esophageal echocardiography and magnetic resonance imaging may be helpful in identifying the embolic source. Treatment includes aspirin and clopidogrel, high dose statin and possibly steroids. In rare cases, mechanical intervention using covered stents may help isolate the ruptured plaque. Anticoagulation with warfarin is not recommended and might even be harmful. Overall, CCE syndrome is usually a harbinger of extensive and unstable atherosclerotic disease that is often associated with acute cardiovascular events.

Lower Extremity Fibromuscular Dysplasia: Clinical Manifestations, Diagnostic Testing, and Approach to Management.

Fibromuscular dysplasia (FMD), a disease well described in the renal and cerebrovascular circulations, also manifests in the lower extremity (LE) arteries. This study reports on the clinical presentation, imaging findings, and treatment of patients with LE FMD seen at a single center. Over a 7-year span, 100 of 449 patients with FMD had imaging of the LE arteries, of which 62 were found to have LE FMD (13.8% of the entire FMD cohort including patients with and without LE imaging). The majority of patients were women (96.8%), with an average age of 52 ± 11.3 years at the time of diagnosis. All patients had FMD present in another vascular bed, most commonly in the renal (80.6%) and extracranial carotid arteries (79.0%). Most patients had multifocal FMD (95.2%) and bilateral LE disease (69.4%), with the external (87.1%), common (19.4%), and internal (11.3%) iliac arteries most commonly affected. Presenting symptoms of LE involvement included claudication (22.6%), atypical leg symptoms (14.5%), and dissection (6.5%), but most patients were asymptomatic (71.0%). Nearly all patients were managed conservatively (98.4%) and only 1 patient required intervention.

Effect of statins on cholesterol crystallization and atherosclerotic plaque stabilization.

Pleiotropic effects of statins have not been fully elucidated. Recently we demonstrated that cholesterol expands when crystallizing and may trigger plaque rupture. The present study evaluated the potential direct effects of statins in altering cholesterol crystallization as a possible mechanism for plaque stabilization independent of cholesterol lowering. Cholesterol powder was dissolved in oil with and without pravastatin, simvastatin, or atorvastatin (10 to 90 mg) and then allowed to crystallize to measure peak volume expansion (ΔVE) in graduated cylinders. Effect of ΔVE on fibrous membrane damage was also evaluated. Human coronary, carotid, and peripheral arterial plaques (65 plaques from 55 patients) were incubated with statin or saline solution using matched plaque segments to evaluate direct effects of statins on preformed crystals. Also, the effect of in vivo use of oral statins on crystal structure was examined by scanning electron microscopy and crystal content in plaques scored from 0 to +3. For all statins, ΔVE decreased significantly in a dose-dependent fashion (0.76 ± 0.1 vs 0 ml at 60 mg, p <0.001). By scanning electron microscopy crystal structure with statins had loss of pointed tip geometries, averting fibrous membrane damage. Cholesterol crystal density was markedly decreased and appeared dissolved in human plaques incubated with statins (+2.1 ± 1.1 vs +1.3 ± 1.0, p = 0.0001). Also, plaques from patients taking oral statins compared to controls had significantly more dissolving crystals (p = 0.03). In conclusion, statins decreased ΔVE by altering cholesterol crystallization and blunting sharp-tipped crystal structure and dissolving cholesterol crystals in human arteries in vivo and in vitro, providing plaque stabilization.