Describe how lipoprotein particles, the immune system and risk factors (such as smoking and hypertension) are...

The normal arterial vessel consists of 3 layers, namely intima, media and outer adventitia.

The intima is located closest to the arterial lumen and is therefore most ‘intimate’ with the blood. This layer is composed of a single layer of endothelial cells (endothelium), connective tissue, and several smooth muscle cells. The endothelium functions as an active metabolic barrier as well as a carrier between blood and the arterial wall. It plays a crucial role in atherosclerosis. Connective tissue consists of a matrix of collagen, proteoglycans and elastin. Lymphocytes, macrophages and other types of inflammatory cells may occasionally reside in the intima.

The media is the middle layer and its inner and outer boundaries are formed by the internal and external elastic laminae. The media consists of layers of smooth muscle cells with contractile and synthetic function. As for the contractile function, smooth muscle cells enable vasoconstriction and vasodilatation. As for the synthetic function, they are responsible for the growth of the vascular extracellular matrix.

The most external vessel wall layer is called the adventitia and contains fibroblasts, connective tissue, nerves, lymphatics and vasa vasorum. Inflammatory cells may also occasionally reside in the adventitia.

There is a constant dynamic interchange between the arterial wall and its cellular components and the surrounding extracellular matrix. By understanding the physiology of this dynamic interchange and the function of each cellular component, the dysfunction of these cellular components leading to atherogenesis can be better understood.

These risk factors will lead to The formation of the plaque can also be divided into three major stages namely 1) the fatty streak, which represents the initiation 2) plaque progression, which represents adaption and 3) plaque disruption, which represents the clinical complication of atherosclerosis

of the integrity of endothelial barrier due to endothelial dysfunction allows the passage of circulating lipoproteins (low-density lipoprotein, LDL) into the intima. By binding to proteoglycans, LDL particles start to accumulate. This accumulation is a critical process in atherogenesis since LDL may undergo chemical modifications while residing longer in the intima. It is needless to say that an elevated circulating LDL concentration strongly contributes to this accumulating process. Another major risk factor for this process is hypertension since it causes augmented vessel wall stress. Elevated vessel wall stress influences smooth muscle cells to synthesize proteoglycans in the intima, promoting LDL-binding with proteoglycans and therefore contributing to “trapping” of lipoproteins and lipid accumulation within the intima. At this point, macrophages adhere to dysfunctional endothelial cells and transmigrate into the intima. These macrophages are called ‘foam cells’ after they have taken up lipids.

As mentioned earlier, chemical modification occurs with LDL when chronic accumulation takes place inside the intima. There are several types of chemical modification that may occur. One is called oxidation and it results from the chemical reaction of reactive oxygen species and pro-oxidant enzymes produced by endothelial or smooth muscle cells, or macrophages penetrating the intima. This type of oxidative stress leads to cellular dysfunction and damage in endothelial cells and macrophages. Furthermore chronic hyperglycemia can stimulate glycation of LDL that may ultimately alter LDL into an antigenic and proinflammatory molecule. This explains why diabetes mellitus is a major risk factor for atherosclerosis. The biochemical modification of LDL into a proinflammatory molecule contributes to the inflammation process established by endothelial dysfunction. Furthermore, the oxidized LDL molecule induces tissue damage, which can initiate angiogenesis, forming new vasa vasorum in the plaque. It also induces leukocyte recruitment and foam cell formation in the fatty streak throughout the plaque development.

Leukocyte recruitment

Leukocyte recruitment to the arterial wall is another key step in atherogenesis, which is dependent on two important factors; expression of leukocyte adhesion molecules (LAM) on the endothelial wall and chemoattractant signals that direct diapedesis (intruding of molecules through the intact vessel wall). These two factors mainly direct monocytes to the atherosclerotic lesion. T lymphocytes that play a central role in the immune system reside within plaques at all stages of atherogenesis, mainly producing cytokines.

As mentioned earlier, modified LDL can maintain leukocyte recruitment by inducing LAM and chemokine expression. It can also stimulate endothelial and smooth muscle cells to produce proinflammatory cytokines. These proinflammatory cytokines can also induce LAM and chemoattractant cytokine expression, equivalent to the working of modified LDL. In conclusion, modified LDL can directly or indirectly promote leukocyte recruitment and atherogenesis.

Foam cell formation

When monocytes enter the intima, they differentiate into phagocytic macrophages. These phagocytic macrophages may become foam cells when they absorb lipoproteins. They don’t phagocyte LDL with a classic cell surface LDL-receptor, since it does not recognize modified LDL, but with a family of ‘scavenger’ receptors that do bind and internalize modified LDL. Uptake by scavenger receptors avoids negative feedback inhibition from the high cholesterol content unlike the classic LDL-receptors, and allows the macrophages to imbibe cholesterol-rich lipid that results into the formation of foam cells. This uptake seems to be beneficial at first sight, since it absorbs the inflammatory modified-LDL, however since these foam cells have impaired trafficking, they will be locally accumulated in the plaque and encourage the plaque progression by serving as a source of proinflammatory cytokines.

Tobacco smoking can lead to many mechanisms that contribute to atherosclerosis. Smoking also leads to increased LDL levels, decreased HDL levels in blood and elevated insulin resistance. In addition it enhances oxidative modification of LDL by releasing free radicals and reduces generation of nitric oxide. This can promote endothelial dysfunction and thus lead to impairment of vasodilatation of coronary arteries and reduction of coronary flow reserve even in passive smokers. Tobacco smoking inappropriately stimulates sympathetic nervous system, increasing heart rate, blood pressure and perhaps coronary vasoconstriction. Smoking promotes a prothrombotic environment through inhibition of endothelial release of tissue plasminogen activator, elevation of fibrinogen concentration in blood, enhancement of platelet activity (possibility related to sympathetic activation) and enhanced expression of tissue factor. Smoking can even damage the vessel wall and ultimately cause a decrease in the elasticity of the artery, enhancing the stiffness of vessel wall. Smoking has been associated with increased C-reactive protein and fibrinogen, suggesting a correlation with inflammatory response, which is an important part of atherogenesis. There have also been findings that show higher expression of leukocyte adhesion molecules among smokers than nonsmokers. Smoking may additionally induce tissue hypoxia through displacement of oxygen with carbon monoxide in hemoglobin.

Ultimately all these will lead to atherosclerosis and myocardial infarction