Cardiovascular System Design

Question 1

Cardiovascular disease stats

Answer 1

• cardiovascular disease represents 30%

- how amount of it is low and middle income, where less proportion is high income

Question 2

Risk factors for cardiovascular disease

Answer 2

Behavioral:

• tobacco
• diet
• physical inactivity

Metabolic:

• lipid
• hypertension
• obesity
• diabetes

Question 3

Cardiovascular two circulations in series

Answer 3

• functionally the cardiovascular system has two circulations in series, termed the pulmonary and systemic circulations
• systemic blood flows entirely into and out of the pulmonary circulation driven by the right heart pump
• blood is driven into the systemic circulation by the left heart pump. Flow in the systemic circulation is divided between different tissues in parallel
• distributions of body fluids between blood, intracellular compartments and interstitial compartment (=internal environment)

Question 4

General scheme in circulation

Answer 4

• distribution of blood volume
• different flow rates through tissue
• comparison of flow and oxygen usage-not always matching. Concept of excess capacity
• resistance
• capacitance
• high pressure/ low pressure system
• supply and reservoir
• concept of capillary bed, but still closed

Question 5

Distribution of blood in the circulatory system

Answer 5

• blood is pumped into the aorta and consectively passes though many different vessels before it returns to the right heart
• at any on time, 84% of blood is in the systemic circulation with the remainder in the heart (7%) and pulmonary vessels (9%)
• the venous vessels contain >50% of total blood
• vessels are distinguished by physical dimensions, morphological characteristics and function
• all are lined with a contiguous sheet of endothelial cells, including heart chambers and valve leaflets

Question 6

Concept of heart as a pump

Answer 6

• 4 chambered pump with valves, names/anatomy
• no direct connection normally between right and left heart pumps
• myogenic
• central control of BP and contractility
• systole/diastole concepts
• Starling’s law of the heart
• beating depends upon external calcium
• electrophysiology

Question 7

Blood flow through the heart

Answer 7

• deoxygenated blood returns to the right atrium through the systemic circulation
• right ventricle pumps this blood into the pulmonary circulation
• reoxygenated blood returns to the left atrium through the pulmonary veins
• oxygenated blood is pumped by the left ventricle into the systemic arterial circulation
• tricuspid and pulmonary valves regulate entry into pulmonary circulation
• mitral and aortic valves regulate entry into the systemic circulation

Question 8

Requirements for effective cardiac function

Answer 8

• contractions of individual cardiac cells must occur at regular intervals and be synchronized (not arrhythmic)
• valves must open fully (not stenotic)
• valves must not leak (not insufficient or regurgitant)
• muscle contractions must be forceful (not failing)
• ventricles must fill adequately during diastole

Question 9

Cardiac Output Overview

Answer 9

• defined as the quantity of blood per unit time pumped into the aorta by the heart
• since the heart pump is in series with the systemic circulation, the cardiac output also equals the quantity of blood per unit time that flows through the circulation
• the amount of blood pumped per minute from the heart depends on the volume of blood ejected out of each ventricle (stroke volume) and the number of heart beats per min (heart rate)
• typical cardiac output values for resting individual with normal heart function 5 L/min
• major determinants of stroke volume: ventricular preload (length of muscle at onset of contraction), ventricular afterload (tension of muscle during contraction), mycocardial contractility

Question 10

Effects of conditions of cardiac output

Answer 10

No change: sleep, moderate changes in environmental temperature

Increase: anxiety and excitement (50-100), eating (30%), exercise (up to 700%), high environmental temp, pregnancy, epinephrine

Decrease: sitting or standing from lying position (20-30%), rapid arrhythmias, heart disease

Question 11

Changes in cardiac output with exercise

Answer 11

• CO (mL/min) = SV (mL) x HR (beats/min)
• resting cardiac output: 6,400 ml/min = 100 ml/beat x 64 beats/min
• strenuous exercise cardiac output: 20,760 = 120 mL x 173 beats/min

Question 12

Starling’s Law and Cardiac Output

Answer 12

• cardiac output is determined almost entirely by the rate of blood flow into the heart from the veins, the so-called venous return
• peripheral tissue controls local blood flow, and all blood return by the way of the veins to the right atrium. The heart automatically pumps this incoming blood into the arteries to continue the flow
• the heart stretches from increased volume of inflowing blood and contracts with a greater force of contraction and thus a greater quantity of blood is pumped out
• the larger the ventricular end-diastolic volume, the larger the stroke volume
• ventricular pumping= change in volume
• contraction creates a tension increasing pressure within the chamber, leading to an opening of the outlet valve

Question 13

Blood circulation through arteries and veins

Answer 13

• artery >50 um
• arteriole 20-50 um
• metarteriole 10-15 um
• arterial end of capillary 5 um
• venous end of capillary 9 um
• collecting venule
• small venule 20 um
• veins 0.5-3 cm
• arteriolar vasocontriction via smooth muscles leads to increase in peripheral resistance
• venous vasoconstriction via smooth muscle leads to reduced venous volume and increase in cardiac output via Starling’s law

Question 14

Vasculature morphology

Answer 14

• aorta- 2.5 cm diameter, 2mm wall thick, 1 only, 4.5 area
• arteries- 0.4 cm diameter, 1mm wall thick, 160 total, 20 area
• arterioles- 30um diameter, 20 um wall thick, 5 x 10^7 total, 200 area
• capillaries- 5um diameter, 1 um wall thick, 10^10 total, 4500 area
• venules- 70um diameter, 7 um wall thick, 10^8 total, 4000 area
• veins- 0.5 cm diameter, 0.5 mm wall thick, 200 total, 40 area
• venae cavea- 3 cm diameter, 1.5 mm thickness, 2 total, 18 area

Question 15

Properties of flow throughout the circulation

Answer 15

• equal flow through each stage (level of arborization) of the system
• heart acts a generator of a constant pressure head rather than as a generator of constant flow
• four man variables: flow (or flow velocity), pressure, resistance and volume
• Flow velocity- highest in arteries, then arterioles, capillaries, and then increases again for venules and veins
• blood volume: 12% arteries, 2% arterioles, 5% capillaries, 60% venules and veins
• vascular resistance highest in arterioles

Question 16

Introduction to Blood Pressure

Answer 16

• units of blood pressure
• systolic, diastolic and mean arterial pressures
• estimate mean arterial pressure given values for systolic and distolic pressure
• the origin of the dichrotic notch
• describe the change in blood pressure around the circulation

Question 17

Air vs blood pressure

Answer 17

• P = density x gravity x height
• medical pressures are measured relative to atmospheric pressure
• substract from 760 mmHG

Question 18

Mean arterial pressure

Answer 18

• defined as the average pressure over the entire cardiac cycle
• mean arterial pressure estimated from diastolic pressure and pulse pressure
• MAP= DP + 1/3(SP-DP) = DP +1/3PP

Question 19

Pulse pressure

Answer 19

• defined as the difference between the systolic and diastolic pressures
• pP = SP - DP

Question 20

Systolic pressure

Answer 20

-systolic arterial pressure is the peak arterial pressure reached during ejection of blood by the heart

Question 21

Diastolic pressure

Answer 21

-diastolic arterial pressure is the lowest arterial pressure reached during diastole, when the heart is relaxed and filling with blood

Question 22

Dichrotic notch

Answer 22

• incisura

- a small dip caused by backfilling of the aortic valve as it closes

Question 23

Changes in blood pressure with age

Answer 23

-there is a steep rise during early growth and then a subsequent rise after age 45

Question 24

Blood pressures throughout the circulatory system

Answer 24

• the arterial portion of the circulation is characterized by high, pulsatile pressure and high flow velocity
• the profile changes to one of low pressure and velocity without pulsatile character in veins
• the largest drop in mean arterial pressure occurs across the arteriolar segment of the circulation, indicating that this is the site of highest vascular resistance in the cardiovascular system

Question 25

Blood pressure using the auscultatory method

Answer 25

• external pressure of cuff is higher than systolic pressure leads to no blood flow
• as cuff pressure is lowered, flow is restored
• however, the pulsatile pressure changes causes turbulence and thus generates sounds that the clinician can detect
• as cuff pressure is further reduced, the velocity fluctuations increase generating higher turbulence and louder sounds
• finally when cuff pressure is below diastolic, the flow has returned to laminar and is silent

Question 26

Direct method to measure BP

Answer 26

• arterial pressure is measured directly via arterial catheter passed in a retrograde (against flow) for pressures in arteries, aorta, and left ventricle
• venous catheter is passed antegrade (with flow) for pressures in veins, right atrium and right ventricle
• not possible to measure pulmonary venous and left atrial pressures directly, need to use pulmonary capillary wedge pressure

Question 27

Pulmonary artery catheterization

Answer 27

• catheter is passed from systemic vein, through the right heart into the pulmonary artery
• Lumen is open at distal end (Swan=Ganz)
• balloon is inflated and pressure falls downstream of the balloon
• vascular pressure equilibrates beyond the balloon and the wedge pressure at the catheter tip is a measure of pulmonary venous and left atrium
• approximates left ventricular end-diastolic pressure

Question 28

Determinants of mean arterial pressure

Answer 28

• critically important variable because it is the average effective pressure driving blood through systemic organs
• mean arterial pressure is directly related to cardiac output and TPR = CO x TPR = Heart rate x stroke volume x TPR. All changes in MAP results from changes in either CO or TPR
• MAP falls between systolic and diastolic pressures. Can be estimated by relationship: MAP = DP + 1/3(SP-DP)
• pulse pressure = stroke volume/ compliance, or SP-PP
• in resting young adult, PP = 40 mmHg since stroke volume is ~80 mL and compliance is ~2 mL/mm Hg

Question 29

Controlling mean arterial blood pressure

Answer 29

• MAP must be high enough to drive blood flow, but not damage organs
• short term MAP control is primarily by altering cardiac output (CO) and peripheral resistance. This is accomplished both neurally and hormonally
• short term control of MAP: altering peripheral resistance counteracts most moment to moment fluctuations of MAP
• vasomotor activity regulates vasomotor tone and thus peripheral resistance
• most short term alterations in MAP are countered via the baroreceptor reflex
• long -term control of MAP: achieved primarily by altering blood volume via the kidneys