Atherosclerosis: Difference between revisions

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''Ronak Delewi, MD; Hayang Yang, MsC; John Kastelein, MD, PhD''<br /><br />  
''Ronak Delewi, MD; Hayang Yang, MsC; John Kastelein, MD, PhD''<br /><br />  
{{DevelopmentPhase}}
{{case|
{{case|
A 53 years old man, without medical history or  medication visits the family physician and makes an anxious impression. His friend has recently suffered from a myocardial infarction (MI) and he is worried that he might also soon face the same situation. As for family medical history, he has a father with hypertension and an uncle with diabetes mellitus. He does not seem to have any symptoms or complaints at this moment, but he has been smoking for 25 years and is overweight. Because of these characteristics he is worried that he will suffer from a MI. Upon physical examination, his BMI was 29 kg/m<sup>2</sup>, RR was 152/90 mmHg and heart rate was 75 bpm. The family physician orders a blood test for lipid profile and glucose. Both turn out to be in the normal range. <br />
A 53 years old man, without medical history or  medication visits the family physician and makes an anxious impression. His friend has recently suffered from a myocardial infarction (MI) and he is worried that he might also soon face the same situation. As for family medical history, he has a father with hypertension and an uncle with diabetes mellitus. He does not seem to have any symptoms or complaints at this moment, but he has been smoking for 25 years and is overweight. Because of these characteristics he is worried that he will suffer from a MI. Upon physical examination, his BMI was 29 kg/m<sup>2</sup>, RR was 152/90 mmHg and heart rate was 75 bpm. The family physician orders a blood test for lipid profile and glucose. Both turn out to be in the normal range. <br />
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== 1.2 Arterial vessel with atherosclerosis ==
== 1.2 Arterial vessel with atherosclerosis ==
[[File:RCA_atherosclerosis.jpg|thumb|Atheroclerotic plaque in a coronary artery]]
=== Three pathologic stages of atherogenesis ===
=== Three pathologic stages of atherogenesis ===
Atherogenesis can be divided into five key steps, which are 1) endothelial dysfunction, 2) formation of lipid layer or fatty streak within the intima, 3) migration of leukocytes and smooth muscle cells into the vessel wall, 4) foam cell formation and 5) degradation of extracellular matrix. Via these consecutive steps, an atherosclerotic plaque is formed. 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.<br />
Atherogenesis can be divided into five key steps, which are 1) endothelial dysfunction, 2) formation of lipid layer or fatty streak within the intima, 3) migration of leukocytes and smooth muscle cells into the vessel wall, 4) foam cell formation and 5) degradation of extracellular matrix. Via these consecutive steps, an atherosclerotic plaque is formed. 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.<br />
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The concept of ‘vulnerable plaque’ has developed into a new concept of ‘vulnerable patient’ as the concept of pathogenesis of atherosclerosis was linked to a person’s susceptibility to coagulation and thus vascular events, which can be influenced by many personal factors such as genetics (e.g. procoagulant prothombin gene mutation), coexisting condition (e.g. diabetes), and lifestyle factors (e.g. smoking, obesity).<br />
The concept of ‘vulnerable plaque’ has developed into a new concept of ‘vulnerable patient’ as the concept of pathogenesis of atherosclerosis was linked to a person’s susceptibility to coagulation and thus vascular events, which can be influenced by many personal factors such as genetics (e.g. procoagulant prothombin gene mutation), coexisting condition (e.g. diabetes), and lifestyle factors (e.g. smoking, obesity).<br />
{|
|-
| rowspan="2" | [[File:plaque_rupture_A.svg|100px]]
| rowspan="2" | [[File:plaque_rupture_B.svg|100px]]
| rowspan="2" | [[File:split_arrow.svg|50px]]
| [[File:plaque_rupture_C.svg|100px]] || [[File:plaque_rupture_clot.svg|100px]]
|-
| [[File:plaque_rupture_D.svg|100px]]
|-
| colspan="4" width="450px" | Progression of coronary atherosclerosis can be gradual (bottom) or can lead to plaque rupture with acute occlusion of a coronary vessel due to clot formation
|}


== Complications of atherosclerosis ==
== Complications of atherosclerosis ==
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==== ''Tobacco smoking'' ====
==== ''Tobacco smoking'' ====


Tobacco use is known to increase the risk of atherosclerosis and ischemic heart disease based on numerous studies. For example, INTERHEART study shows that smoking is responsible for 36% of the population-attributable risk of a first MI. Other studies showed that smoking is an independent major risk factor for coronary heart disease, cerebrovascular disease and total atherosclerotic cardiovascular disease.  The Atherosclerosis Risk in Communities Study measured the direct effect of smoking on the development of atherosclerosis. They measured intima-medial thickness of the carotid artery of 10,914 patients for three years with ultrasound. Their result showed that current smokers had a 50% increased progression of atherosclerosis in comparison to nonsmokers during the study period. Also patients with environmental tobacco smoke exposure (passive smokers) had 20% higher rate of atherosclerotic progress versus patients without environmental smoke exposure.<br />
Tobacco use, including environmental smoking exposure, is known to increase the risk of atherosclerosis and ischemic heart disease based on numerous studies. For example, INTERHEART study shows that smoking is responsible for 36% of the population-attributable risk of a first MI. Other studies showed that smoking is an independent major risk factor for coronary heart disease, cerebrovascular disease and total atherosclerotic cardiovascular disease.  The Atherosclerosis Risk in Communities Study measured the direct effect of smoking on the development of atherosclerosis. They measured intima-medial thickness of the carotid artery of 10,914 patients for three years with ultrasound. Their result showed that current smokers had a 50% increased progression of atherosclerosis in comparison to nonsmokers during the study period. Also patients with environmental tobacco smoke exposure (passive smokers) had 20% higher rate of atherosclerotic progress versus patients without environmental smoke exposure.<br />
   
   
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. <br />
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. <br />
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==== ''Diet'' ====
==== ''Diet'' ====


Several studies suggest that diet, more specifically intake of fruit and vegetable can reduce the risk of coronary heart disease and stroke. In the INTERHEART study, lack of daily consumption of fruits and vegetables was responsible for 14% of the population-attributable risk of a first MI. Another meta-analysis study showed that additional daily portion of fruit reduced the risk of stroke by 11%, but no such effect was found with vegetable consumptionAnother form of diet such as high fiber consumption can also relatively reduce the risk of coronary heart disease and stroke compared to low fiber consumption. In addition, the Hale project has shown that Mediterranean-styled diet as primary prevention for CVD among elderly aged 70-90 without CVD significantly reduces all-cause, coronary heart disease and CVD mortality.<br />
A healthy diet reduces CVD risk. In general, when following the rules for a healthy diet, no dietary supplements are neededN-3 polyunsaturated fatty acid (PUFA) consumption mainly from oily fish, is potentially associated with beneficial effects on cardiac risk factors, notably reduction in triglycerides but not all randomized, controlled trials have shown reductions in CV events Thus current recommendations are to increase PUFA intake through fish consumption, rather than from supplements. Recently, the largest study ever conducted with a so-called ‘Mediterranean’ diet, supplemented with extra-virgin olive oil or nuts, reduced the incidence of major cardiovascular events in patients at high risk of CV events but without prior CV disease.<cite>Estruch</cite>


==== ''Alcohol consumption'' ====
==== ''Alcohol consumption'' ====
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#Theorell Theorell, T., Lind, E., Floderus, B. “The relationship of disturbing life-changes and emotions to the development of myocardial infarction and other serious diseases.” Int J Epidemiol 1975; 4:281.
#Theorell Theorell, T., Lind, E., Floderus, B. “The relationship of disturbing life-changes and emotions to the development of myocardial infarction and other serious diseases.” Int J Epidemiol 1975; 4:281.
#Vita Vita J.A., Keaney J.F. Jr. “Endothelial function: a barometer for cardiovascular risk? Circulation” 2002; 106:640.
#Vita Vita J.A., Keaney J.F. Jr. “Endothelial function: a barometer for cardiovascular risk? Circulation” 2002; 106:640.
#Estruch pmid=23944307
</biblio>
</biblio>

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