Neointimal hyperplasia (NIH) plays a pivotal role in vascular restenosis after revascularization. We previously identified that chemokine‐like factor 1 (CKLF1) could aggravate NIH by arresting smooth muscle cells in G2/M phase and preventing apoptosis via phosphoinositide 3‐kinase/AKT/nuclear factor‐kappa B signaling. Here, we demonstrate that CKLF1 promotes monocyte adhesion and smooth muscle cell migration via VCAM‐1. Our work furthers our understanding of how CKLF1 contributes to NIH causality.
Intra-arterial perfusion with elastase is a common method used to create abdominal aortic aneurysms (AAA) models. The present study aimed to explore the impact of porcine pancreatic elastase (PPE) perfusion pressure on the morphology of abdominal aortic aneurysms. A total of 40 male Sprague Dawley rats were randomized into four groups. The elastase was perfused at pressures in the aortic lumen of 300, 100 and 0 mmHg in three groups, respectively. Rats perfused with saline at 300 mmHg were used as controls. The maximum diameters of the AAA were monitored with ultrasound at 7, 14 and 28 days after the operation. Elastin degradation and inflammatory cell counts were determined using histochemical staining. All rats were successfully perfused at the scheduled pressure. After 7 days, the AAA formation ratio of PPE-300, PPE-100 and PPE-0 was 100, 50 and 0%, respectively. After 14 days, the AAA formation ratio in PPE-100 and PPE-0 reached 90 and 20%, respectively. After 28 days, the diameters of the isolated aorta in PPE-300, PPE-100, PPE-0 and NaCl-300 were (mean ± standard deviation) 7.34±1.81, 4.02±0.40, 2.92±0.32 and 2.49±0.07 mm, respectively, and the difference between groups was statistically significant (P<0.05). The formation ratio in PPE-300, PPE-100, PPE-0 and NaCl-300 was 100, 100, 20 and 0%, respectively. Elastase perfusion pressure could impact the AAA formation ratio at an early stage and the maximum diameter of the aneurysm without increasing animal mortality. Elastase perfusion with high pressure could accelerate aneurysm formation and represents a potential method for building large-size abdominal aortic aneurysms. However, the underlying mechanisms need further investigation.
Purpose: Magnesium-based alloy scaffold is a promising biodegradable stent due to its intrinsic mechanical performance and biocompatibility. Based on our preliminary experiments, we designed a novel sirolimus-eluting magnesium-based alloy scaffold. This work aimed to assess its safety and degradation performance in vivo.
Methods: The scaffolds were implanted in the lower limb arteries of Bama mini-pigs. Safety was defined as no immediate thrombosis or >30% residual stenosis, which was assessed with optical coherence tomography and digital subtraction angiography. Blood biochemical analyses were performed to evaluate hepatorenal toxicity. The degradation process of the scaffolds, the endothelialization, and lumen loss of the stented-vessels were detected with scanning electron microscopy, immunohistochemical, hematoxylin-eosin staining and optical coherence tomography.
Results: Twenty-four scaffolds were successfully implanted in six pigs with no signs of immediate thrombosis or >30% residual stenosis. The scaffolds were covered by endothelium at one month and absolutely resorbed at six months post implantation. Blood analysis showed that the hepatorenal function except for alanine aminotransferase and γ-glutamyl transpeptidase was normal. Obvious intimal hyperplasia and lumen loss were found in the stented vessels at three months, while the diameters and inner lumen areas of stented segments had increased significantly at six months (p
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