Cardiovascular control

Question 1

What is ANP?

Answer 1

Atrial natriuretic peptide. Released from atrial myocytes in response to  increased blood volume and atrial pressure. Acts via cGMP.

Question 2

What does ANP cause?

Answer 2

Causes vasodilation and  decreased Na
+ reabsorption at the renal collecting tubule. Dilates afferent renal arterioles (in) and constricts efferent arterioles (out), promoting diuresis and contributing to “aldosterone escape” mechanism.

Question 3

What is BNP?

Answer 3

Released from ventriculate myocytes in response to increased tension. Similar physiologic mech to ANP. Longer half life.

Question 4

What can BNP be used to diagnose?

Answer 4

HF.

Question 5

What three kinds of sensors in the cardiovascular system are involved in short term responses?

Answer 5

Arterial baroeceptors, atrial baroreceptors, ventricular baroreceptors.

Question 6

Where are arterial baroreceptors located?

Answer 6

At carotid sinus and aortic arch.

Question 7

What causes arterial baroreceptors to fire?

Answer 7

Cationic channels that response to stretch; open and firing more when stretched ie when pressure is increased.

Question 8

Are arterial baroreceptors more responsive to pulsatile changes or static changes?

Answer 8

Pulsatile changes. If pressure increases slowly and is maintained at a new high, firing rate of baroreceptors decline back towards baseline causing resetting.

Question 9

What is the afferent pathway of aortic arch baroreceptors?

Answer 9

Afferent = out = via vagus nerve to solitary nucleus of medulla.

Question 10

What is the afferent pathway of carotid sinus baroreceptors?

Answer 10

Afferent = out = via glossopharyngeal (IX) nerve to solitary nucleus of the medulla.

Question 11

What is the efferent pathway of the baroreceptor reflexes?

Answer 11

Efferents modulate sympathetic/parasympathetic firing at heart and blood vessels.

Question 12

How does hypotension elicit baroreceptor response?

Answer 12

Decr arterial pressure, decreased stretch, decreased afferent baroreceptor firing. This leads to increased efferent SYMPATHETIC firing and decreased PARASympathetic stimulation. Result is vasoconstriction, incr HR, Incr contractility, Incr BP.

Question 13

How does carotid massage elicit baroreceptor response?

Answer 13

Incr pressure on carotid sinus, increase stretch, increased afferent baroreceptor firing, Increased parasympathetic activity, increased AV node refractory period, decrease HR.

Question 14

Quick review, why would carotid massage lead to increased AV node refractory period?

Answer 14

Increased vagal tone = increased Ach. Ach binds to G-coupled protein on pacemaker cell membrane, alpha subunit interacts w/ K+ channel, allowing greater K+ efflux from pacemaker cell, thus making cell more negative and farther from threshold. Slower to reach activation = HR goes down.

Question 15

Where are chemoreceptors located?

Answer 15

Peripherally in the carotid sinus and aortic arch. Central ones as well.

Question 16

What do peripheral chemoreceptors respond to?

Answer 16

Stimulated by drop in pO2 (<60), rise in pCO2, and decrease in pH of blood.

Question 17

What do peripheral chemoreceptors do when stimulated?

Answer 17

Primarily concerned with respiration, but increased firing also leads to communication with medulla that leads to increased adrenergic output –> increased BP.

Question 18

What do central chemoreceptors respond to?

Answer 18

Just changes in pH and pCO2 of brain interstitial fluid, which are influenced by arterial pCO2. Do not directly response to pO2.

Question 19

What is the cushing reaction?

Answer 19

Triad of hypertension, bradycardia, and respiratory depression.

Question 20

What is the sequence of events causing the cushing reaction?

Answer 20

Increased intracranial pressure constricts arterioles, leading to cerebral ischemia. This increases pCO2 and decreases pH. Central chemoreceptors increase sympathetic output, leading to HTN. The stretch effect on the baroreceptors causes peripheral baroreceptor-induced bradycardia.

Question 21

What is normal right atrial pressure?

Answer 21

<5

Question 22

What is normal right ventricular pressure?

Answer 22

25/5

Question 23

What is normal pulmonary artery pressure?

Answer 23

25/10

Question 24

What is normal pulmonary capillary wedge pressure? What is it a good approximation of?

Answer 24

<12. Good approximation of left atrial pressure.

Question 25

What is normal left atrial pressure?

Answer 25

<12

Question 26

What is normal left ventricular pressure?

Answer 26

130/10

Question 27

What is normal aortic pressure?

Answer 27

130/90

Question 28

In what context would you see PCWP > LV diastolic pressure

Answer 28

Mitral stenosis

Question 29

What local metabolites have a vasodilatory effect on the blood vessels supplying the heart?

Answer 29

adenosine, NO, CO2, Decr O2.

Question 30

What local metabolites have a vasodilatory effect on the vessels supplying the brain?

Answer 30

CO2 (pH)

Question 31

What regulates blood supply to the kidney?

Answer 31

Myogenic and tubuloglomerular feedback

Question 32

What regulates blood supply to the lungs?

Answer 32

Hypoxia causes vasoconstriction; this is unique. IT happens so that only well-ventilated areas are perfused. In other organs, hypoxia causes vasodilation.

Question 33

What regulates blood flow to skeletal muscle?

Answer 33

At rest: sympathetic tone.

During exercise: Local metabolites lactate, adenosine, K+, H+, CO2.

Question 34

What regulates blood flow to the skin?

Answer 34

Sympathetic stimulation is the most important mechanism: temperature control.

Question 35

What pressures do Pi and Pc refer to?

Answer 35

Pi = interstitial fluid pressure = pushing fluid into capillary.
Pc = capillary pressure = pushing fluid out of capillary

Question 36

What pressures to (Pi)c and (Pi)i refer to?

Answer 36

(Pi)i = interstitial fluid colloid osmotic pressure, pulls fluid out of capillary. 
(Pi)c = plasma colloid osmotic pressure, pulls fluid into capillary

Question 37

If Kf = permeability of capillary to fluid and Z = permeability of capillary to protein, what is net fluid flow?

Answer 37

Jv = net fluid flow = Kf(Pc-Pi) - Z(Pic - Pii). 
Eg = net fluid flow = Pressure pushing out minus pressure pulling in.

Question 38

Edema caused by heart failure is an example of what kind of pressure change?

Answer 38

Increased capillary pressure – more fluid pushed out.

Question 39

Edema caused by nephrotic syndrome is an example of what kind of pressure change?

Answer 39

Decreased (pi)c, decreased plasma proteins - less fluid pulled in.

Question 40

Edema caused by liver failure is an example of what kind of pressure change?

Answer 40

Decreased (pi)c, decreased plasma proteins - less fluid pulled in.

Question 41

Edema caused by toxins, infections, burns is an example of what kind of pressure change?

Answer 41

Increased Kf, increased capillary permeability, more fluid pushed out.

Question 42

Edema caused by lymphatic blockage is an example of what kind of pressure change?

Answer 42

Increased Pii (increased interstitial fluid colloid osmotic pressure).