Ni Mei, Wang Yan, Zhang Mei, Zhang Peng Fei, Ding Shi Fang, Liu Chun Xi, Liu Xiao Ling, Zhao Yu Xia, Zhang Yun
Shandong Univ. Qilu Hospital, No. 107, Wen Hua Xi Road, Jinan, Shandong 250012, P. R. China.
Am J Physiol Heart Circ Physiol. 2009 May;296(5):H1598-606. doi: 10.1152/ajpheart.01202.2008. Epub 2009 Mar 13.
To establish an animal model with disruptions of atherosclerotic plaques, 96 male apolipoprotein E knockout (apoE(-/-)) mice were randomly divided into stress, lipopolysaccharide (LPS), stress+LPS, and control groups (n = 24 each). All mice were fed a high-fat diet throughout the experiment, and carotid atherosclerotic lesions were induced by placement of a constrictive perivascular collar. Four weeks after surgery, mice in the LPS and stress+LPS groups were intraperitoneally injected with LPS (1 mg/kg twice per week for 8 wk). Eight weeks after surgery, mice in the stress and stress+LPS groups were treated with intermittent physical stress (electric foot shock and noise stimulation) for 4 wk. Morphological analysis revealed a plaque disruption rate of 16.7% in control, 34.8% in LPS, 54.2% in stress, and 60.9% in stress+LPS groups. The disruption rates in stress and stress+LPS groups were both significantly higher than those of controls (P = 0.007 and P = 0.002, respectively). Luminal thrombosis secondary to plaque disruption was observed only in the stress+LPS group. Both stress and LPS stimulation significantly decreased fibrous cap thickness and increased macrophage and lipid contents in plaques. Moreover, the combination of stress and LPS stimulation further lowered cap thickness and enhanced accumulation of macrophages and expression of inflammatory cytokines and matrix metalloproteinases. Stress activated the sympathetic nervous system, as manifested by increased blood pressure and flow velocity. Plasma fibrinogen levels were remarkably elevated in the stress and stress+LPS groups. In conclusion, stress- and LPS-costimulated apoE(-/-) mice provide a useful model for studies of plaque vulnerability and interventions.
为建立动脉粥样硬化斑块破裂的动物模型,将96只雄性载脂蛋白E基因敲除(apoE(-/-))小鼠随机分为应激组、脂多糖(LPS)组、应激+LPS组和对照组(每组n = 24)。在整个实验过程中,所有小鼠均喂食高脂饮食,并通过放置血管周围缩窄套环诱导颈动脉粥样硬化病变。手术后4周,LPS组和应激+LPS组的小鼠腹腔注射LPS(1 mg/kg,每周两次,共8周)。手术后8周,应激组和应激+LPS组的小鼠接受间歇性身体应激(电足电击和噪音刺激)4周。形态学分析显示,对照组的斑块破裂率为16.7%,LPS组为34.8%,应激组为54.2%,应激+LPS组为60.9%。应激组和应激+LPS组的破裂率均显著高于对照组(分别为P = 0.007和P = 0.002)。仅在应激+LPS组观察到斑块破裂继发的管腔内血栓形成。应激和LPS刺激均显著降低纤维帽厚度,并增加斑块中的巨噬细胞和脂质含量。此外,应激和LPS刺激的联合作用进一步降低了帽厚度,并增强了巨噬细胞的积聚以及炎性细胞因子和基质金属蛋白酶的表达。应激激活了交感神经系统,表现为血压和血流速度增加。应激组和应激+LPS组的血浆纤维蛋白原水平显著升高。总之,应激和LPS共同刺激的apoE(-/-)小鼠为研究斑块易损性和干预措施提供了一个有用的模型。
