Oscar A. Chiesa

Hypercholesterolemia Induces Side-Specific Phenotypic Changes and Peroxisome Proliferator–Activated Receptor-γ Pathway Activation in Swine Aortic Valve Endothelium

Background—The endothelium of healthy aortic valves expresses different phenotypes on the aortic and ventricular sides. On the aortic side, which is susceptible to aortic valve sclerosis, there is a balanced coexpression of both propathological and protective pathways. Side-specific global gene expression can address endothelial phenotype balance in early aortic valve sclerosis. Methods and Results—Adult male swine were fed a hypercholesterolemic or an isocaloric normal diet for 2-week and 6-month periods. Hypercholesterolemia induced localized lipid insudation confined to the aortic side of the leaflet. Transcript profiling of valve endothelial populations showed that the susceptible aortic side was more sensitive to 2-week hypercholesterolemia than the ventricular side (1,325 vs 87 genes were differentially expressed). However, greater sensitivity was not evidence of a dysfunctional phenotype. Instead, pathway analyses identified differential expression of caspase 3–, peroxisome proliferator–activated receptor &ggr;–, TNF-&agr;–, and nuclear factor-&kgr;B–related pathways that were consistent with a protective endothelial phenotype. This was confirmed at the protein level at 2 weeks and persisted at 6 months. Conclusions—In a large animal model at high spatial resolution, endothelium on the pathosusceptible side of the aortic valve leaflet is responsive to hypercholesterolemia. Transcript profiles indicative of a protective phenotype were induced and persisted on the side prone to aortic valve sclerosis.

Prelesional arterial endothelial phenotypes in hypercholesterolemia: universal ABCA1 upregulation contrasts with region-specific gene expression in vivo

Atherosclerosis originates as focal arterial lesions having a predictable distribution to regions of bifurcations, branches, and inner curvatures where blood flow characteristics are complex. Distinct endothelial phenotypes correlate with regional hemodynamics. We propose that systemic risk factors modify regional endothelial phenotype to influence focal susceptibility to atherosclerosis. Transcript profiles of freshly isolated endothelial cells from three atherosusceptible and three atheroprotected arterial regions in adult swine were analyzed to determine the initial prelesional effects of hypercholesterolemia on endothelial phenotypes in vivo. Cholesterol efflux transporter ATP-binding cassette transporter A1 (ABCA1) was upregulated at all sites in response to short-term high-fat diet. Proinflammatory and antioxidative endothelial gene expression profiles were induced in atherosusceptible and atheroprotected regions, respectively. However, markers for endoplasmic reticulum stress, a signature of susceptible endothelial phenotype, were not further enhanced by brief hypercholesterolemia. Both region-specific and ubiquitous (ABCA1) phenotype changes were identified as early prelesional responses of the endothelium to hypercholesterolemia.

Pulsed High–Intensity-focused US and Tissue Plasminogen Activator (TPA) Versus TPA Alone for Thrombolysis of Occluded Bypass Graft in Swine

PURPOSE Prosthetic arteriovenous or arterial-arterial bypass grafts can thrombose and be resistant to revascularization. A thrombosed bypass graft model was created to evaluate the potential therapeutic enhancement and safety profile of pulsed high-intensity-focused ultrasound (pHIFU) on pharmaceutical thrombolysis. MATERIALS AND METHODS In swine, a right carotid-carotid expanded polytetrafluoroethylene bypass graft was surgically constructed, containing a 40% stenosis at its distal end to induce graft thrombosis. The revascularization procedure was performed 7 days after surgery. After model development and dose response experiments (n = 11), two cohorts were studied: pHIFU with tissue plasminogen activator (TPA; n = 4) and sham pHIFU with TPA (n = 3). The experiments were identical in both groups except no energy was delivered in the sham pHIFU group. Serial angiograms were obtained in all cases. The area of graft opacified by contrast medium on angiograms was quantified with digital image processing software. A blinded reviewer calculated the change in the graft area opacified by contrast medium and expressed it as a percentage, representing percentage of thrombolysis. RESULTS Combining pHIFU with 0.5 mg of TPA resulted in a 52% ± 4% increase in thrombolysis on angiograms obtained at 30 minutes, compared with a 9% ± 14% increase with sham pHIFU and 0.5 mg TPA (P = .003). Histopathologic examination demonstrated no differences between the groups. CONCLUSIONS Thrombolysis of occluded bypass grafts was significantly increased when combining pHIFU and TPA versus sham pHIFU and TPA. These results suggest that application of pHIFU may augment thrombolysis with a reduced time and dose.

Quantitative Mapping of Vascular Geometry for Implant Sites

In vivo characterization of the complex dynamic forces and repetitive deformations experienced by pelvic and leg vasculature is important to improve the evaluation of safety and effectiveness of implantable interventional devices such as stents [1]. The goal of this study was to use image based geometric modeling and analytical techniques to characterize the vascular deformations that occur with pelvic-hind limb motion in swine.

The Role of Imaging Tools in Biomedical Research: Preclinical Stent Implant Study

Imaging tools are used at the bedside for diagnostic and interventional procedures. The use of more than one modality (including fused modalities) can provide information from diverse sources during different stages of imageguided interventional procedures such as diagnosis, delivery of a stent to treat vascular disease and subsequent evaluation. Multi-modality interventions use an array of tools including ultrasound, fluoroscopy, angiography, endoscopy, electromagnetic tracking, robotics and computed tomographic (CT) imaging, alone or in combination, together with analytical tools during preclinical vascular and therapeutic procedures. Explant analysis includes specimen radiography (Faxitron) and scanning electron microscopy (SEM)).