hemodynamics

Question 1

Ohm’s Law

Answer 1

. Driving force for flow results from the difference in total fluid energy btw ant 2 points
. Total energy of fluid measured as pressure
. Blow flow directly proportional to pressure
. Blood flow is inversely proportional to resistance
. Resistance directly proportional to vessel length
. Resistance inversely proportional to radius
. F = deltaP/R

Question 2

Types of pressure

Answer 2

. Force applied to surface area
. Pascal
. MmHg (133.3 Pa/1.36 cm H2O)
. CmH2O (98 Pa)

Question 3

Gravitational pressure

Answer 3

. Form of potential energy due to gravity
. Pressure that results from gravity is hydrostatic pressure
. Pressure anywhere along column depends on product of its density, height, and gravitational acceleration

Question 4

Hydrostatic pressure

Answer 4

. Exerted by a stationary (static, not moving) column of fluid in a container
. Change in pressure between 2 different heights

Question 5

Dynamic or kinetic pressure

Answer 5

. Pressure generated by blood movement

. Generated by heart and elastic recoil of large aa.

Question 6

Driving pressure

Answer 6

. Sum of dynamic and hydrostatic pressures

Question 7

Transmural pressure

Answer 7

. Change in pressure between inside (hydrostatic) and outside of the vessel

Question 8

Vascular resistance in series

Answer 8

. Circuit of resistors arranged in chain
. Corresponds to progressive circulation through different vessels in circulatory tree
. LV -> aorta -> small artery
. Total resistance = sum of individual resistances

Question 9

Parallel vascular resistance

Answer 9

. Resistors arranged w/ heads and tails connected together
. Corresponds to circulation through different organs/regions of body
. Aorta to head, intestines, kidneys, and pelvis
. Total conductance = sum of individual conductance (1/R)
. Total resistance less than any individual resistance
. Flow is directly proportional to conductance

Question 10

Poiseuille’s Law

Answer 10

. Blood flow is directly proportional to axial pressure gradient
. Blood flow directly proportional to vessel radius raised to the 4th power
. Blood flow inversely proportional to the vessel resistance
. Blood flow inversely proportional to vessel length and blood viscosity

Question 11

Shear rate

Answer 11

. Velocity gradient between the moving sheets

. Relative velocities btw laminae (velocity of blood flow)

Question 12

Shear stress

Answer 12

. Force that must be applied to 2nd sheet to make it move faster
. Resistance to movement btw laminae (pressure)

Question 13

Viscosity

Answer 13

. Shear stress required to produce a particular shear rate
. Measure of internal friction
. Units: Poise
. Viscosity = shear stress/shear rate

Question 14

Laminar flow

Answer 14

. Shearing laminae are in concentric cylinders that move w/ different velocities
. Inner layer moves w/ highest velocity
. Outermost cylinder moves at slowest velocity
. Resulting velocity profile is a parabola w/ max velocity at central axis
. The lower the viscosity the sharper the parabolic distribution

Question 15

Effect of hematocrit on viscosity

Answer 15

. Relative viscosity inc. as hematocrit inc.
. Anemia: dec. hematocrit, dec. viscosity
. Polycythemia: inc. hematocrit, inc. viscosity

Question 16

Axial streaming

Answer 16

. Tendency of RBCs to accumulate in the center of the lumen of small vessels as flow velocity inc.
. Reduces viscosity and therefore resistance to flow
. Not important in larger vessels so it is assumed blood viscosity is independent of velocity

Question 17

Turbulent flow

Answer 17

. Disorderly pattern of fluid movement
. Non-laminar
. Occurs as driving pressure inc. and flow reaches critical velocity
. Streams mix radially and axial producing eddies and vortices
. Dissipates energy which causes resistance to flow
. Underlies heart murmurs, bp, damage to endothelial lining, and thrombi

Question 18

Reynold’s number

Answer 18

. Indicates propensity for turbulent blood flow
. The higher the reynold’s number (>3000) the greater chance for turbulent blood flow to develop
. Determinants: diameter, velocity, density, viscosity

Question 19

Bernoulli principle

Answer 19

. 2 forms of energy (potential and kinetic) are interconvertible
. Hemodynamic and hydrostatic pressure can be converted into kinetic energy to cause a liquid to flow

Question 20

Total energy, potential energy, and kinetic energy in vascular system

Answer 20

. Total: constant flow system, total energy remains constant
. Potential: hydrostatic pressure
. Kinetic: velocity of a fluid equals the distance the fluid has traveled per unit time, velocity varies inversely w/ cross sectional area

Question 21

T/F velocity will vary inversely w/ cross-sectional area

Answer 21

T

Question 22

Blood for in aortic stenosis

Answer 22

. Abrupt dec. in vessel cross sectional areacauses potential energy to convert to kinetic
. As results the transmural pressure dec. and velocity of flow inc.

Question 23

Blood flow in capillaries

Answer 23

. Small radius = low wall tension

. Reason why capillaries in feet don’t burst

Question 24

Arteriolar vasoconstriction

Answer 24

. Greater wall thickness/ lumen diameter ratio = low wall tension
. Provides greater control of vessel diameter and blood flow

Question 25

Aneurysm blood flow

Answer 25

. Large radius = high wall tension

. Can’t withstand transmural pressures and therefor can eventually rupture

Question 26

Blood flow in ciliated hearts

Answer 26

. Large radius= high wall tension

. Causes more work (higher oxygen consumption) required during systole to overcome the higher wall tension

Question 27

Elasticity in blood vessels

Answer 27

. Elastic properties of blood vessels are major cause of nonlinear pressure-flow relationship in vascular beds

Question 28

Type of tissues that make up vascular wall of blood vessels

Answer 28

. Endothelial cells: form single continuous layer in direct contact w/ blood
. Elastic tissue: cant stretch more than 100%
. Vascular smooth muscle cells: in all segments but capillaries, exert tension through active contraction, as smooth muscle contraction inc., elasticity dec.
. Fibrous tissue: collagen w/ high tensile strength but low elasticity

Question 29

The higher the wall thickness/diameter, the greater the control of ___

Answer 29

Vessel diameter and blood flow

Question 30

LaPlace relationship

Answer 30

. Precapillary sphincter has highest ratio and of thickness/lumen diameter and therefore the greatest control
. Veins have small wall thickness/lumen diameter ratio (thin wall, large diameter) and therefore regulate volume more than flow or pressure

Question 31

Non-linear pressure-flow relationship

Answer 31

. As driving pressure inc., the transmural pressure also inc. causing vessel to distend lowering the resistance
. As results blood flow inc. at higher pressures more than it would in rigid tube
. At low pressure the resistance inc.

Question 32

Resistance vessels

Answer 32

. Arteries
. Large aa. Have smaller esistance
. Small aa. Moderate resistance
. Arterioles have max resistance, pressure drop is greatest there, change from pulsatile flow to steady flow

Question 33

Why is pulsatile flow damped out at capillary level?

Answer 33

Distensibility of large aa.

. Frictional resistance in small aa. And arterioles

Question 34

Compliance

Answer 34

. Distensibility of elastic surface
. Defined as change in volume caused by given change in pressure
. Ability of a blood vessel to undergo deformation ad a result of a change in pressure
. Higher compliance the more easily the vessel can be stretched

Question 35

What determines the compliance properties of a vessel wall?

Answer 35

Physical arrangement of the vascular components
. Load on vascular wall is borne by elastin and smooth muscle and lastly by collagen
. Elastic properties on vessel wall, vascular smooth muscle tone, and vessel geometry are determinants

Question 36

Age-related changes in aortic compliance

Answer 36

. Distensibility of aa. Dec. w/ age
. Slope of curve at physiological pressures dec. (lowers compliance) in older groups
. Aa. Have less elastin and more collagen
. As compliance dec. a given inc. in volume elicits a larger inc. in pressure
. Results in wider pulse pressure ad more cardiac work, independent risk factor of developing heart disease
. Regular exercise slows and reverse age-related decreases in aortic compliance