Pathophysiology of Arterial Vascular Disease

Question 1

atherosclerosis

Answer 1

• Characterized by intimal thickening caused by the accumulation of a plaque, which contains inflammatory cells, smooth muscle cells, connective tissue and lipids
• Dysregulation of efflux and influx of lipids; more lipids coming into the arteries
• Causes an imbalance in blood-oxygen supply and blood-oxygen demand
• Can be symptomatic or asymptomatic

Question 2

Arterial Vascular Disease

Answer 2

• Abnormality of the structure and/or function of arterial blood cells
• Caused by atherosclerosis plaque

Question 3

modifiable risk factors for atherosclerosis

Answer 3

• Diabetes Mellitus (DM)
• Hypertension (HTN)
• Obesity: (BMI >30 kg/m2)
• Cigarette Smoking
• Dyslipidemia: Especially atherogenic dyslipidemia (defined as low HDL and high LDL and TG)
• Physical Inactivity

Question 4

non-modifiable risk factors for atherosclerosis

Answer 4

• Sex: Male > Female (men have higher risk until women are post-menopausal)
• Age: > 45 years in males; > 55 years in females
• Family history of premature CVD: < 55 years for male relative; < 65 years for female relative; First degree relative that has had an MI or stroke

Question 5

How does cigarette smoking contribute to atherosclerosis?

Answer 5

• Cigarette smoking
• The stuffs in the cigarette sits on the arterial walls and causes a endothelial dysfunction
• Foreign substance -> inflammatory response
• Increase oxidative stress
• Alter lipid metabolism -> increase LDL, decrease HDL

Question 6

How does HTN contribute to atherosclerosis?

Answer 6

• Chronically vasoconstricted
• Enhanced calcium sensitivity
• Exacerbating the response to vasoconstrictors

Question 7

How does DM contribute to atherosclerosis?

Answer 7

Hyperglycemia causes tissue damage -> Contributes to endothelial dysfunction

Question 8

How does dyslipidemia contribute to atherosclerosis?

Answer 8

Provides more LDL-C to be oxidized, which potentiates an inflammatory response

Question 9

Identify patients who would benefit from aspirin for primary prevention of ASCVD-related events

Answer 9

• Aged 50 to 59 years
• ≥ 10% 10-year CVD risk
• Life expectancy of at least 10 years
• Willing to take low-dose aspirin daily for at least 10 years
• Should not have increased risk for bleeding

Question 10

initiation of atherosclerosis

Answer 10

• Endothelial dysfunction

- Development of Fatty Streak

Question 11

Endothelial dysfunction

Answer 11

• Imbalance between vaso-constriction and dilation
• Inflammation via LDL-C
• Ultimately leads to apoptosis of vascular smooth muscle

Question 12

Development of Fatty Streak

Answer 12

• Accumulation of LDL-C in the arterial intima -> Oxidized LDL-C potentiates cytokine release -> Cytokines induce expression of adhesion molecules for leukocytes -> Cytokines cause monocytes to differentiate to macrophages and express scavenger receptors -> Scavenger receptors allow macrophages to uptake of oxidized LDL-C, which cause macrophages to become foam cells
• Endothelial dysfunction -> artery becomes porous and allows for oxidized LDL to come into the arterial intima -> leukocytes in blood attaches to them
• Comprised mainly of macrophage foam cells
• Precursor to atheroma
• Accumulation of foam cells in intima produce the “fatty streak”

Question 13

progression of atherosclerosis

Answer 13

Cytokines cause smooth muscle cells to migrate from media of artery into intima (starting to get stenosis of that vessel) -> Smooth muscle cells divide and develop extracellular matrices, contributing to a growing, fibrotic plaque -> Calcification, fibrosis, and apoptosis, yielding a fibrotic capsule, surrounding a lipid-rich core (AKA – “the necrotic core”) -> more macrophages and monocytes are going to come to that area

Question 14

risk factors for plaque rupture

Answer 14

• High lipid content
• Higher concentration of macrophages
• Thin fibrous cap of plaque

Question 15

steps involved in atherothrombosis

Answer 15

• Plaque sits on top of endothelial tissues -> damaged endothelial tissues -> exposes tissue factor -> activates coagulation cascade -> potentiates thrombin production via extrinsic pathway
• Platelets roll along exposed collagen via surface glycoproteins and bind to vWF -> after adhesion, activated platelets release molecules that help promote more activation and vasoconstriction: serotonin, adenosine diphosphate (ADP), thromboxane A2 (TxA2)

Question 16

ADP and TXA2

Answer 16

• Provides further platelet activation
• Vasoconstrictors
• Recruitment of surrounding platelets
• Change in platelet conformation -> Conversion of GP IIb/IIIa receptor into active form -> allows fibrinogen to create a platelet meshwork
• Upregulation of pro-inflammatory cytokines

Question 17

Thrombin

Answer 17

• Most potent platelet activator

- Stimulates protease-activation receptor (PAR-1)

Question 18

Activated GP IIb/IIIa

Answer 18

• allow crosslinking of platelets
• potentiates platelet aggregation and spreading of platelets across extracellular matrix by fibrinogen bridges
• Facilitates fibrinogen forming bridges between activated platelets

Question 19

Thrombin

Answer 19

converts fibrinogen into fibrin

Question 20

Fibrin

Answer 20

stabilizes interlocking platelets, creating a fibrin mesh-work

Question 21

major players in atherothrombosis: Atherosclerotic Endothelium

Answer 21

• LDL-C; Oxidized
• Leukocytes; Macrophages
• Foam Cells
• TF
• vWF

Question 22

major players in atherothrombosis: Platelet

Answer 22

• ADP
• TXA2
• GP IIb/IIIa
• Thrombin
• PAR-1 Receptor
• Fibrin

Question 23

Atherosclerosis usually afflicts which arteries?

Answer 23

medium-large-sized arteries:

• Aorta
• Carotid arteries
• Coronary arteries
• Peripheral arteries

Question 24

Etiology of Atherosclerosis

Answer 24

• interplay between fatty streak, lipid accumulation, endothelial dysfunction, atherosclerotic risk factors
• shear stress