Unit 2: Circulation Pt1

Question 1

What is the main function of the systemic circulation?

Answer 1

to deliver adequate oxygen nutrients to systemic tissues and remove CO2 and other waste products form the systemic tissue

Question 2

T/F. Systemic circulation can act as a conduit for transport of hormones, and other substances and allows these substances to potentially act at a distant site from their production.

Answer 2

True

Question 3

What are systemic arteries designed to do?

Answer 3

to carry oxygenated blood under high pressure out to tissue beds

Question 4

What are the 5 functional parts of the circulation system?

Answer 4

1. systemic arteries
2. arterioles and pre capillary sphincters
3. capillaries
4. venules
5. systemic veins

Question 5

What collects blood from capillaries?

Answer 5

venules

Question 6

What is the functional unit of circulation and is one cell layer thick and is where exchange b/w tissues (cells) and blood occurs?

Answer 6

capilaries

Question 7

What act as control valves to regulate local flow?

Answer 7

arterioles and pre capillary sphincters

Question 8

What are the three things included in micro-circulation?

Answer 8

• arterioles and pre capillary sphincters
• capillaries
• venules

Question 9

What percentage of blood is on the venous sides at any give time?

Answer 9

65%

Question 10

What returns the blood to heart/dynamic storage?

Answer 10

systemic veins

superior vena cava, inf. vena cava, coronary sinus

Question 11

What is blood flow proportional to?

Answer 11

metabolic flow

Question 12

What controls cardiac output?

Answer 12

local systemic tissue flow (venous return)

Question 13

T/F. Arterial pressure fluctuates drastically.

Answer 13

False– it is kept relatively CONSTANT

Question 14

What is arterial pressure independent of? What is arterial pressure control based on?

Answer 14

local flow or cardiac output

Based on:

• neural control (brain)
• volume control (kidney)

Question 15

Characteristically wise, what does the wall of a capillary consist of?

Answer 15

only endothelium

Question 16

Characteristically wise, what does the wall of the aorta consist of?

Answer 16

Elastic tissue > Fibrous tissue > smooth muscle

Question 17

What is the one layers in vessel walls that exists in ALL vessels?

Answer 17

endothelium

Question 18

Characteristically wise, what does the wall of a typical artery consist of?

Answer 18

Smooth muscle > elastic tissue > fibrous tissue

Question 19

Characteristically wise, what does the wall of a vein consist of?

Answer 19

elastic tissue = smooth muscle = fibrous tissue

–equal amounts of all

Question 20

What is Ohm’s Law?

Answer 20

V = IR

analogous to change in P = FR —–or—– F = (change in P)/R

Question 21

What is the volume of blood that passes a certain point per unit of time?

Answer 21

Flow (F); eg. ml/min

“Q” – can also = Flow

Question 22

What are two equations for Flow?

Answer 22

F = velocity X cross sectional area

F = Pressure gradient/ R

Question 23

At a given Flow, the velocity is ______ proportional to the total cross sectional area.

Answer 23

inversely

Question 24

Flow is directly proportional to ____ and inversely proportional to _____.

Answer 24

Directly–> to pressure gradient (change in P)

Inversely–> (R) resistance

Question 25

What is the driving force of blood and is the difference in pressure b/w two points?

Answer 25

Pressure gradient

Question 26

What is the pressure gradient proportional to?

Answer 26

Flow (F)

Question 27

Where does the greatest resistance to flow occur?*

Answer 27

in the pre-capillary resistance vessels:

• arterioles
• metarterioles
• precapillary sphincters

Question 28

At a give F (flow rate) the greater the drop in P in a segment or compartment will cause what?*

Answer 28

greater the resistance to flow

Question 29

In a parallel circuit how do you get the Total Resistance?

Answer 29

find lowest number in resistance and go below it

Total resistance < smallest ind. R

Question 30

In a series circuit, how do you find the Total Resistance?

Answer 30

= sum of ind. R’s

Question 31

What type of circuit is the systemic circulation, predominantly?*

Answer 31

parallel circuit

Question 32

What are some advantages to parallel circuitry?

Answer 32

• independence of local flow control
• minimizes TPR (total peripheral resistance)
• oxygen rich blood supply to every tissue

Question 33

In parallel circuitry, how is local flow controlled?

Answer 33

independently–> increase/decrease flow to tissues independently

Question 34

What type of circuit is the pulmonic and systemic circulations in? How would one calculate the Total Vascular Resistance (TVR)?

Answer 34

series; TVR = sum of total pulmonic resistance + the total peripheral resistance (TPR)

Question 35

What is the internal friction of a fluid associated with the intermolecular attraction?

Answer 35

viscosity

Question 36

What is the viscosity of blood? Plasma? Water?

Answer 36

Blood –> 3
Plasma –> 1.5
Water–> 1

Question 37

T/F. Water has 3x viscosity than blood. (is thicker)

Answer 37

False– blood is 3x more thicker than water

Blood –> 3
Water–> 1

Question 38

What is the relationship b/w viscosity and velocity in blood?

Answer 38

viscosity is inversely proportional to velocity (speed)

• -blood moving slower = thicker
• • blood moving fast = thinner

Question 39

At micro-circulation, as velocity decreases what happens to viscosity? Why?

Answer 39

viscosity increases; due to elements in blood sticking together

Question 40

What effect does fibrinogen have on RBC’s? How does age correlate?

Answer 40

increase flexibility of RBC’s

–increase age may decrease flexibility of RBC’s and therefore may be why older inds have decreased circulation

Question 41

T/F. In small vessels cells line up which decreases viscosity and offsets the fact that velocity decrease will increases viscosity.

Answer 41

True (thank you Fahaeus-Lindquist)

Question 42

What is the percent of packed cell volume? What is the normal range? What if it is below normal range?

Answer 42

Hematocrit (primarily is RBCs)

Normal Range = 38%-45%

Below–> means decrease in RBCs– maybe they are anemic

Question 43

What type of flow pattern is considered normal?

Answer 43

Laminar

Question 44

What type of flow pattern is most efficient?

Answer 44

laminar

Question 45

What type of flow patterns is silent and streamline?

Answer 45

laminar

Question 46

What type of flow pattern has cross mixing and vibrational noise?

Answer 46

turbulent flow (least efficient)

Question 47

What type of flow pattern is frequently ass. with vessel disease (bruit)?

Answer 47

turbulent flow

Question 48

What is the probability statement for turbulent flow? If this number is higher, what does that mean for turbulence?

Answer 48

Reynold’s number; greater the R number, the greater the probability for turbulence

Question 49

If Reynold’s Number < 2000 flow is usually _______.

If Reynold’s Number > 3000 flow is usually ____.

Answer 49

laminar

turbulent

**notice it says USUALLY—> it is NOT definitely

Question 50

What is the equation for Reynold’s number?

Answer 50

Reynold’s number = (velocity x tube diameter x density) / viscosity

Question 51

What is the ultrasound used to determine velocity of flow? How does it work?

Answer 51

Doppler Ultrasonic Flow-meter

RBC’s moving toward transmitter, compress sound waves, increase frequency of returning waves

Question 52

A broad band Doppler reading is indicative of what type of flow?

Answer 52

turbulent flow

Question 53

A narrow band Doppler reading is indicative of what type of flow?

Answer 53

laminar flow

Question 54

What two things can be used to determine Cardiac Output?

Answer 54

1. Fick Principal

2. Indicator dilution

Question 55

What two tings can be used for Determination or Flow?

Answer 55

1. Determination of Cardiac Output

2. Determination of Vessel flow

Question 56

What does the Fick Principal measure?

Answer 56

blood flow to a tissue/organ

Question 57

What are the three necessary components to calculate the Fick Principal and measure the blood flow to a tissue/organ? Ex: measuring oxygen

Answer 57

1. input blood conc. of oxygen
2. output blood conc. of oxygen
3. addition/removal of oxygen from tissue (uptake of O2)

Question 58

What it comes to the Fick Principal, what is Flow equal to?

Answer 58

= amount of substance per min / Artery-Vein difference

Question 59

(Fick Principal)

What does the Pulmonary Blood Flow (PBF) equal?

Answer 59

= O2 uptake / AV O2 difference

PBF = CO

Question 60

What is the relationship b/w Pulmonary Blood Flow (PBF) and Cardiac Output (CO)?

Answer 60

they are equal

PBF = CO

Question 61

(Fick Principal) Ex:

if VO2 = 160 ml/L and AO2 = 200 ml/L and the O2 uptake is 200 ml/min. What is the Pulmonary Blood Flow (PBF)?

Answer 61

PBF = = O2 uptake / AV O2 difference

PBF = 200 ml/min // (200ml/L - 160ml/L)

PBF = 200 ml/min // 40ml/L

PBF = 5 L/min

Question 62

What is the gold standard of flow determination? What is it based on?

Answer 62

Indicator Dilution; based on conservation of mass

CO is inversely proportional to average duration of the curve (dye concentration)

Question 63

If the Indicator dilution curve average duration increased, what happens to CO?

Answer 63

CO will decrease

(they are inversely proportional)–

Question 64

What is the ability of a vessel to stretch?

Answer 64

distensibility

Question 65

What is the ability of a vessel to stretch and hold volume?

Answer 65

conpliance

Question 66

What is the equation for distensibility?

Answer 66

= change in volume / (change in pressure x initial vol.)

Question 67

What is the equation for compliance?

Answer 67

= change in volume / change in pressure

= Distensibility x initial vol.

Question 68

What is the relationship b/w volume and pressure?

When volume increases what happens to pressure?

Answer 68

change in Vol and change in pressure are proportional

pressure increases too

Question 69

A small change in volume that is associated with a large change in pressure is characteristic of what vascular compartment?

Answer 69

systemic arteries

Question 70

A large change in volume that is associated with a small change in pressure is characteristic of what vascular component?

Answer 70

systemic veins

Question 71

Wall tone is _______ related to compliance and distensibility.

Answer 71

inversely related to

Question 72

Veins are about _____ times more distensible and _____ times more compliant than systemic arteries.

Answer 72

8x

24x

Question 73

T/F. Systemic arteries hold less blood under higher pressure, while systemic veins hold more blood under lower pressure.

Answer 73

True (therefore why veins are more compliant)

Question 74

How is local blood flow regulated?

Answer 74

in proportion to metabolic demand in most tissues

Question 75

What is involved in short term control of blood flow to a tissue?

Answer 75

vasodilation, vasoconstriction of pre-capillary resistant vessels (aterioles, metarterioles, pre-capillary sphincters)

Question 76

What is involved in long term control of blood flow to tissues?

Answer 76

involves changes in tissue vascularity

• formation (angiogenesis) or dissolution of vessels
• vascular endothelial growth factor and angiogenin peptides

Question 77

What will vasoconstrict an arteriole vessel?

Answer 77

SNS releasing NE onto an alpha- receptor that is on vessel wall

Question 78

Vasodilation will do what to Resistance and Flow?

Vasoconstriction will do what to Resistance and Flow?

Answer 78

Vasodilation–> decrease R; and increase F

Vasoconstriction –> increase R; and decrease F

Question 79

What is the Local vasodilatior theory?

Answer 79

active tissue release local vasodilator (metabolites) which relax vascular smooth muscle

(**newer theory)

Question 80

What is the Oxygen demand theory?

Answer 80

as tissue uses up oxygen, vascular smooth muscle cannot maintain constriction

(older theory)

Question 81

What are some local vasodilators?

Answer 81

• Adenosine
• CO2
• adenosine phosphate compounds
• histamine
• K+ and H+
• PGE and PGI series prostaglandins
• CO and NO

Question 82

Why is autoregulation important for blood vessels?

Answer 82

• ability to keep blood flow (F) constant in face of changing arterial BP
• most tissues show some degree of autoregulation (RoA = Range of Autoregulation)
• flow is proportional to metabolic demand

Question 83

What is autoregulated in the kidney?

Answer 83

renal flow and glomerular filtration rate (GFR)

Question 84

What is production of new micro-vessels called?

Answer 84

angiogenesis

Question 85

What is the shear stress caused by enhanced blood flow velocity associated with partial occlusion?

Answer 85

arteriogenesis

Question 86

What are small peptides that stimulate growth of new vessels? What is an example?

Answer 86

Angiogenic factors

Ex: VEGF (vascular endothelial growth factor) –> first isolated from tumors

Question 87

What does stress activated endothelium up-regulate expression of?

Answer 87

MCP-1 (moncyte chemo attractant protein-1)

• monocytes invade arterioles–> inflam. occurs

Question 88

What does Hypoxia causes release of? Which stimulates what?

Answer 88

VEGF–> stimulates capillary proliferation and maybe collateral arterial vessels
- partial mediated by adenosine

Question 89

T/F. NPY from SNS is angiogenic.

Answer 89

True

Question 90

What are three mechanisms for Neovascularization (= new vessels)?

Answer 90

1. Vasculogenesis
2. Angiogenesis
3. Arteriogenesis

Question 91

What type of neovascularization is mesenchymal cell differentiate into endothelial cells (de novo development of new blood vessels)?

Answer 91

Vasculogenesis

Question 92

What type of neovascularization is formation of new blood vessels by sprouting from pre existing small vessels (usually lacking developed tunica media)?

Answer 92

angiogenesis

Question 93

What type of neovascularization is rapid proliferation of pre-existing collateral vessels with fully developed tunica media?

Answer 93

arteriogenesis

Question 94

What are three angiogenesis triggers?

Answer 94

1. Mechanical (hemodynamic and shear stress)
2. Chemical (hypoxia and NO)
3. Molecular (decrease glucoise leads to increase VEGF); inflam.; angiogenic growth factors

Question 95

What are four Angiogenic growth factors?

Answer 95

• fibroblast growth factor
• VEGF (VEGF receptors)
• placenta growth factor (PLGF)
• angiopoietin

Question 96

What are three methods of Therapeutic angiogenesis?

Answer 96

1. Protein therapy (use of GF proteins)
2. gene therapy (manipulate gene expression for angiogenic peptides)
3. cellular therapy (cells that produce angiogenic factors are introduced into ischemic tissues)

Question 97

What is clinical enhancement/promotion of collateral blood vessels/flow in ischemic tissues?

Answer 97

Therapeutic angiogenesis