Week 2

Question 1

What are the 3 basic principles of Circulatory Function

Answer 1

1. Blood flow to most tissues is controlled according to tissue needs
2. CO is the sum of all the local tissue blood flows
3. Arterial pressure regulation is generally independent of either local blood flow control or cardiac output control

Question 2

Def: Flow

Answer 2

The movement of substances or heat from one point to another, driven by energy gradients between those two points

Question 3

What directly impacts the rate of flow

Answer 3

Magnitude of energy gradient

Question 4

What energy gradient causes the flow of molecules

Answer 4

concentration

Question 5

What energy gradient causes the flow of heat

Answer 5

temperature

Question 6

what energy gradient causes the flow of gases

Answer 6

partial pressure

Question 7

What energy gradient causes the flow of fluids

Answer 7

oneiric pressure or hydrostatic pressure

Question 8

What energy gradients cause the flow of ions

Answer 8

Concentration and voltage (electrochemical)

Question 9

Def: Blood Pressure

Answer 9

a hydrostatic pressure, which reflects the force exerted by blood against a unit area of vessel wall

Question 10

Def: Resistance

Answer 10

the impediment to flow due to friction, both external (against vessel wall) and internal (due to viscosity)

Question 11

Def: Conductance

Answer 11

1/resistance

Question 12

Methods of measuring blood flow

Answer 12

Invasive: ultrasonic doppler flowmeter

Question 13

Methods for measuring blood pressure

Answer 13

invasive: intravascular pressure transducer
noninvasive: blood pressure sphygmomanometer

Question 14

Cardiac Output animal differences

Answer 14

Total blood flow through the aorta
Humans: 5 L/min
Giraffe: 60 L/min
Mouse: 0.02 L/min

Question 15

Def: Change in pressure

Answer 15

The difference in mean blood pressure between the aorta and the right atrium
- Little variation between species

Question 16

Def: total peripheral resistance

Answer 16

The resistance of the entire systemic circulation

Question 17

Sum of resistances in series

Answer 17

Sum individual resistances to get total resistance
- Total resistance is greater than any individual resistance

Question 18

Sum of resistances in parallel

Answer 18

Total resistance is equal to 1 over the sum of 1/rs
- total is less than any single resistance

Question 19

Def: Laminar Flow

Answer 19

Blood usually flows smoothly in ‘streamlines’ through vessels, with reactively little mixing in a radial direction

Question 20

Def: Turbulent Flow

Answer 20

Blood flow can become disorderly, whirling in a radial direction to form what are called ‘eddy currents’
- Usually occurs in largest vessels at highest flow rates, around obstacles or during vasodilation
-Increases the resistance to blood flow due to internal resistance

Question 21

Determinants of resistance in laminar flow

Answer 21

• Small changes in vessel diameter have large effect on blood flow
• in larger vessels, more streamlines of blood are far from the vessel wall where flow is much slower, blood flows at a higher velocity
  -Viscosity and vessel length also affect resistance but don’t change over short periods of time
• reduction in vessel diameter reduces blood flow at a given pressure gradient (arterioles)

Question 22

Poiseuille’s Law

Answer 22

F=(pi change in pressure r^4)/8nL
R= 8nL/pir^4

Question 23

Changes in blood viscosity

Answer 23

Changes in hematocrit can alter blood viscosity
-more red blood vessels increases friction between adjacent cells and vessel wall
Decrease: anemia - can occur during menstrual cycle and/or in response to blood loss
increase: polycythemia - occurs at high elevation, in response to sleep apnea, pulmonary disease etc.

Question 24

Pulmonary Circulation

Answer 24

• Picks up O2 at lungs
• Low pressure system (20mmHg)
• RV to Lungs to LA

Question 25

Systemic Circulation

Answer 25

• Delivers O2 to other organs and tissues
• High pressure system (100mmHg)
• LV to tissues to RA

Question 26

Layers of the Pericardium

Answer 26

• Epicardium
• Pericardial space
• Parietal Pericardium
• Fibrous Pericardium

Question 27

Layers of the heart walls

Answer 27

• Endocardium
• Myocardium
• Pericardium

Question 28

Heart muscle histology

Answer 28

Cardiomyocytes
- Striated
- Interconnected at intercalated disks

Question 29

Heart Fiber Structure

Answer 29

• Subendocardial fibers run oblique to subepicardial fibers
• aids in left ventricle ejection and relaxation
• Shortening of fibers during contraction cause wringing motion that pulls the base towards the apex and reduces lumen diameter
• At the end of systole, the left ventricle is similar to a loaded spring that recoils during diastole and rapidly expands lumen diameter

Question 30

How do heart valves help direct blood flow?

Answer 30

Open and closed passively in response to pressure gradients

Question 31

What is the relationship between flow and the volume of blood in the ventricle

Answer 31

Amount of time blood is flowing

Question 32

What causes blood flowrate to change?

Answer 32

change in pressure gradient

Question 33

Can anything cause blood flow to stop entirely?

Answer 33

Valves

Question 34

Ventricular Filling

Answer 34

• Begins when A-V valve opens
• Ends when A-V valve closes
• P atrium >P ventricle
• At end of stage atrial systole occurs resulting in a boast in pressure and volume

Question 35

Isovolumetric Contraction

Answer 35

• Begins when A-V valve closes
• Ends when P ventricle > P aorta causing aortic valve to open
• P atrium < P ventricle < P aorta
• Increase in pressure due to increase force with decrease ventricle space

Question 36

Ejection

Answer 36

• Begins when aortic valve opens
• P ventricle greater than P aorta
• Aortic valve takes time to close once pressure gradient shifts due to stiffness
• Ends when aortic valve closes

Question 37

Isovolumic Relaxation

Answer 37

• Begins when Aortic valve closes
• Ends when P ventricle < P atrium causing A-V valve to open
• P aorta > P ventricle > P atrium

Question 38

Atrioventricular Valves

Answer 38

• Very thin
• open/close very easily in response to forward/backward pressure gradients

Question 39

Semilunar Valves

Answer 39

• Stronger and heavier
• do not open and close as easily

Question 40

Pressure-Volume Loops

Answer 40

• Useful way of showing the changes in pressure and volume during the cardiac cycle
• The area of the loop represents the net external work of one cardiac cycle