Vascular pt 1

Question 0

Tunica media consists of?

Answer 0

• Smooth muscle

- External elastic lamina

Question 1

Tunica intima consists of ?

Answer 1

• Endothelium
• Subendothelial layer of loose CT
• Internal elastic membrane

Question 2

Tunica externa (adventitia) contains?

Answer 2

• Loose CT with collagen and elastin

- Contains vasa vasorum & nervi vascularis (autonomics) in larger arteries and veins

Question 3

Large (elastic) artery contains?

– Eg. aorta, subclavian, common carotid

Answer 3

• Tunica intima
• Internal elastic membrane
• Tunica media
• Tunica adventitia

Question 4

Medium (Muscular) contains ?

– Eg. ulnar, coronary a.

Answer 4

• Tunica intima
• internal elastic membrane
• Tunica media – more SM, less elastic
• Tunica adventitia (thick layer of collagen, with less elastin)

Question 5

List Small arteries and arterioles functions and characteristics?

Answer 5

Both maintain an endothelium surrounded by basement membrane

arterioles are the primary site of smooth muscle control over blood pressure and flow regulation

Question 6

capillaries contain?

Answer 6

• Endothelium
• Basement membrane
• Pericytes (primitive smooth muscle cells)

Question 7

Venules and veins contain?

Answer 7

-Small elastic fibers
-smooth muscle and CT
Pressures are low so walls are thin

Question 8

Medium Veins contain?

Answer 8

• T. media
• T. adventitia (externa)
veins up to 10 mm diameter, many with valves, especially lower limb

Question 9

Large Veins contain?

-eg. SVC, IVC portal vein, over 10 mm diameter

Answer 9

• T. media: few smooth muscle layers

* T. adventitia: thick with CT (collagen & elastin) plus longitudinal smooth muscle

Question 10

Blood distribution in the circulatory system

Answer 10

•  Veins 64%
•  Arterial side 20%
	–  Arteries 13%
	– Arterioles and capillaries 7%
•  Heart/pulmonary 16%
Where the blood is depends on Blood Flow and Vascular Resistance

Question 11

Q (flow) is the Cardiac Output, how is this determined?

Answer 11

– Determined by stroke volume and heart rate: Q = SV ∙ HR

– Regulated by neural and hormonal systems

Question 12

R (resistance) is the Total Peripheral (Vascular) Resistance is regulated by?

Answer 12

Regulated by metabolic and neurohumoral mechanisms

Question 13

ΔP (pressure gradient) is the Blood Pressure, how is this determined.

Answer 13

– derived from the interactions of the cardiac output (flow) and resistance.
– ΔP is estimated by various measures of blood pressure: systolic/diastolic, mean arterial pressure (MAP), pulse pressure, etc.

Question 14

TOTAL PERIPHERAL (VASCULAR) RESISTANCE

Answer 14

R = ΔP/Q
• Pressure gradient is ΔP = (P aorta – P vena cava)
– Since P vena cava is negligibly small, it can be eliminated so that ΔP = P aorta

Question 15

VELOCITY is similar to FLOW, but is a very different measure.

Answer 15

• Flow is the amount of blood that passes a given point in a period of time (volume/sec)
• Velocity is the rate of linear displacement of fluid (cm/sec).

Question 16

For a given cardiac output (Q), velocity varies inversely with diameter of blood vessel

Answer 16

• The more dilated the blood vessel, the slower the blood flow.
• Fluid slows at it enters wider vessels and accelerates as it enters smaller vessels.

Question 17

Highest velocity of blood flow is in __

Lowest Velocity is in __

Answer 17

• Highest velocity of blood flow is in the aorta

* Lowest velocity in capillaries.

Question 18

explain Laminar streaming

Answer 18

• Fluid particles travel in concentric layers (lamina): from slowest near walls to fastest in the center, creating a velocity gradient
• Velocity gradient is generated by viscosity

Question 19

what is viscosity?

Answer 19

• Viscosity is the inner friction in the fluid: it is generated by the interaction between molecules and particles in the blood and resists any relative motion among them
• Increase in viscosity (η) reduces flow Q ~1/η

Question 20

Velocity gradient is created by blood viscosity and friction from walls, what does a higher viscosity do to the velocity gradient?

Answer 20

• Higher viscosity increases the velocity gradient .
• A greater velocity gradient increases shear stress which alter vascular properties
• Excess rbc synthesis in response to hypoxia (polycythemia) increase viscosity, impairing blood flow

Question 21

in capillaries rbc’s travel in single file and adhere less to the vessel wall. what does this do for viscosity?

Answer 21

there is less viscosity; in fact there is a water space between cells and the capillary wall (Fåhræus‐Lindquist effect).

Question 22

according to Bernoulli’s principle:
Constricting a blood vessel?
Expanding a blood vessel?

Answer 22

• increases blood velocity and shear stress

* decreases blood velocity by increasing lateral (transmural) pressure

Question 23

explain Shear Stress

Answer 23

• Excess velocity of laminar flow produces shear stress (viscous drag) on endothelial cells
• Temporary shear stress can be compensated by autoregulation that vasodilates the vessel and slows the flow
• Shear stress (τ)
– increases with viscosity, flow and velocity
– decreases with radius

Question 24

what are the problems with prolonged shear stress

Answer 24

* Excess shear stress associated with occlusion can alter gene expression via cytoskeletal signaling * can lead to inflammation, remodeling, atherosclerosis involving the extracellular matrix (ECM), smooth muscle and endothelium.

Question 25

Turbulence develops under the conditions of:

Answer 25

``` high velocity (V), large vessel diameter (D), high fluid density (ρ) and low viscosity (η). – Combined into the Reynold’s number which determines the threshold of turbulence. ```

Question 26

Turbulence can occur in __ | Turbulence produces sounds called __

Answer 26

narrow, atherosclerotic vessels (high velocity), aortic arch (large diameter), bifurcations, eg aorta called bruits (blood vessels) and murmurs (heart)

Question 27

Turbulence produces greater levels of transmural pressures that increase the chance of endothelial injury & subsequent plaque formation. this manifests as?

Answer 27

an Aortic aneurism: involves rupture of endothelium and infusion of blood into the tunica media creating a false lumen • Because it separates the aortic wall layers, it is called a “dissecting aortic aneurism”

Question 28

Differences in resistances affect blood flow in the vascular system how?

Answer 28

* Blood flow through individual organs depends on the resistance of organ’s vessels * Blood flow through the entire system depends on the TPR

Question 29

generalize how TPR and MAP are caclulated

Answer 29

Organ vascular systems are arranged in parallel and the sum of the individual resistances determine not just local pressures, but also the resistance and pressure of the entire system.

Question 30

Blood flow through individual organs is determined mostly by regulation of

Answer 30

arteriolar resistance

Question 31

Generalize central control of vascular system

Answer 31

-mostly vasoconstrictive | Autonomic neurons and endocrines regulate total vascular system maintain overall blood pressure and flow

Question 32

Generalize local control ( autoregulation )

Answer 32

mostly vasodilatory - maintaining constant blood flow to an organ with a steady metabolic rate in the face of changing blood pressure - adjusting blood flow to an organ according to local changes in its metabolic activity

Question 33

explain ANS regulation of organ blood blow (i.e. arteriolar resistance)

Answer 33

Mainly sympathetic nervous system (NE & EPI) - Alternating increased or decreased sympathetic activity produces constriction and dilation respectively via alpha‐1 receptors

Question 34

explain alpha 1 receptors

Answer 34

most common vascular adrenergic receptors; found in all arterioles . – binding with norepinephrine or epinephrine leads to vasoconstriction via IP3

Question 35

Explain β2 receptors

Answer 35

found in arterioles of skeletal and cardiac muscle (non‐innervated; hormonal only) – binding of mostly epinephrine leads to vasodilation via cAMP

Question 36

During sympathetic response (eg. exercise) blood is directed to?

Answer 36

skeletal muscle and heart (β2 vasodilation) and away from the internal organs (α1 vasoconstriction) – However, most vasodilation in continuing muscle activity is due to build up of metabolites

Question 37

Mechanisms for autoregulation include:

Answer 37

Metabolic Myogenic Endothelial

Question 38

Explain Active Hyperemia

Answer 38

the increase in organ blood flow (hyperemia) associated with increased activity of an organ or tissue. • consumes O2 , generating local hypoxia, this vasodilates arterioles by inducing formation of vasodilator metabolites. • Increased blood flow washes out metabolites and vessels constrict back to normal

Question 39

Metabolic vasodilators are specific to organs and include:

Answer 39

* Adenosine (Ado) inhibits contraction via cAMP in coronary and possibly muscle arterioles * K+ & PO4 dilate skeletal muscle vasculature * CO2, H+ dilate cerebral vasculature

Question 40

Major vasodilator in most blood vessels

Answer 40

Nitric oxide (NO)

Question 41

how is NO synthesized?

Answer 41

Synthesized from arginine via nitric oxide synthase, NOS.

Question 42

How is NO released?

Answer 42

• NO is released from endothelial cell & enters smooth muscles cells • Released from endothelium by: – Shear forces of blood flow (flow mediated vasodilation) – Chemical means: ACh, ATP, hypoxia, histamine, bradykinin

Question 43

what does NO generate?

Answer 43

* NO generates cGMP which inhibits Ca++ actions on myosin light chain kinase, leading to its relaxation * NO also regulates proliferation of SM cells

Question 44

Prostaglandins (prostacyclin), PG does what?

Answer 44

uses cAMP to inhibit Ca++ mediated smooth muscle contraction

Question 45

how is endothelin ET-1 released?

Answer 45

Released in response to vasoconstrictors

Question 46

NO and PG are counterbalanced by ?

Answer 46

• NO and PG counterbalanced by ET‐1 which contracts smooth muscle (vasoconstriction)

Question 47

What is ET function?

Answer 47

• ET both constricts and induces proliferation of smooth muscle cells

Question 48

ET-1 and NO roll in hypertesion?

Answer 48

• In hypertension, ET‐1 is up regulated, while NO is down regulated. Endothelial cells hypertrophy and smooth muscles proliferate

Question 49

Smooth muscle cells secrete ?

Answer 49

collagen, elastin and proteoglycan

Question 50

Even though blood pressure derives from direct interaction of CO and R, it can also be affected by?

Answer 50

renal regulation of fluid volume and salt concentration

Question 51

Parasympathetic vasodilation is localized to a few structures:

Answer 51

eg. cerebral and genital vessels

Question 52

Blood flow (Q) is related to

Answer 52

``` blood pressure (ΔP) and vascular resistance (R) Q = ΔP/R ```

Question 53

Define Total peripheral resistance

Answer 53

TPR = ΔP/Q = P aorta/CO P (aorta) is estimated by the Mean Arterial Pressure TPR = MAP/CO

Question 54

Explain how resistance is inversely proportional to 4th power of vessel radius

Answer 54

– small decreases in arteriolar radius (vasoconstriction) causes significant increases in resistance, reducing flow or increasing pressure differences. – Tube with twice the radius yields 16 times the flow.

Question 55

Velocity is a function of

Answer 55

flow and cross‐sectional area

Question 56

what does local control (autoregulation) use to optimizes blood flow and O2 delivery ?

Answer 56

uses metabolites, myogenic and endothelial mechanisms

Question 57

Alpha & beta receptors both bind NE & EPI, but

Answer 57

produce opposite responses α1 receptors: Vasoconstriction via IP3 β2 receptors: Vasodilation via cAMP

Question 58

During exercise blood is shunted away from the GI tract to the skeletal muscles and the heart by ?

Answer 58

epinephrine

Question 59

Autoregulation maintains constant blood flow to the organ/tissue by constricting or dilating arterioles via ?

Answer 59

metabolites, NO, or myogenic actions

Question 60

Without autoregulation, blood flow would

Answer 60

increase with rise in perfusion pressure

Question 61

* If pressure drops __ | * If pressure increases__

Answer 61

blood vessels dilate to maintain flow blood vessels constrict to reduce blood flow

Question 62

Pressure enhances smooth muscle contraction by activating cell pathways that increase

Answer 62

both Ca++ influx and Ca++ binding to myosin light chains

Question 63

___ minimize arterial pressure build up in legs and feet during standing

Answer 63

Myogenic responses

Question 64

Smooth muscle contains?

Answer 64

- elastic & reticular fibers | - proteoglycans between SM cells

Question 65

what does collagen do in arteries

Answer 65

limits expansion

Question 66

what does elastin do in arteries ?

Answer 66

creates recoil pressure during diastole