CV

Question 1

Pump

Answer 1

heart is one component

vascular system - stores E and promotes return to heart

skeletal muscles - promote return of blood to the heart

Question 2

exchanger

Answer 2

vascular system - distributes and collects blood

lungs - exchange CO2 and O2, receive blood from R heart and share thorax w the heart

Question 3

Extracellular v intracellular water

Answer 3

30/45 L intracellular

15/45 extracellular (12 interstitial, 3 in plasma)

Question 4

which organ receives the most bloodflow from the heart?

Answer 4

lung

receives 100% from right heart

Question 5

how do substances move within an organ?

Answer 5

diffusion - moving subsances across a cell membrane

Question 6

convection

Answer 6

moving substances alog w the bloodflow

how to move substances from one organ to another

Question 7

exchange vessels

Answer 7

“Exchange vessels” with slow velocity for diffusion

Question 8

conduit vessels

Answer 8

“Conduit vessels” with rapid velocity for efficient transit time

Question 9

ventricular systole

Answer 9

chamber is max contracted

blood out of outlet valve

Question 10

ventricular diastole

Answer 10

chamber is max relaxed

blood in through inlet valve

Question 11

P-R interval

Answer 11

time between delay

give ventricle and atrim time to fill with blood

atrial contraction and

“AV node” - delay to allow ventricule to fill

Question 12

Q-T interval

Answer 12

contains ventricular contraction

Question 13

heart pump

Answer 13

2 pumps in series - R and L

R - 100% to lungs (pulmonary = low pressure)

L - to body through arteries - most to kidney

flow to each can be independently regulated and shunted - filters (kidney, liver, GI, skin) get most blood

Question 14

Forward Flow

Answer 14

promoted by valves

if dysfunctional - turbulence and E is lost (friction, heat)

Question 15

Stroke Volume

Answer 15

Filled Volume (End Diastole) - Contracted Volume (End Systole)

vol of blood that leaves the heart

forward - how much goes through aortic valve

SV - forward or back through LA - valve disease

Question 16

cardiac output

Answer 16

heart rate x stroke volume

volume/time

Question 17

Flow

Answer 17

= Cardiac output!

change in pressure/resistance

I = V/R

V = pressure gradient, R = resistance

I = volume/time

V=IR

Question 18

series v parallel resistance

Answer 18

series - add resistances (high)

parallel - add inverses of resistance - low

Question 19

flow in the periphery

Answer 19

fixed throughout the system (as a result of changes inr esistance)

vasoconstricion or vasodilation to maintain relatively const flow

Question 20

pressure in the periphery

Answer 20

plummets from aorta to R atrium - result of changing resistance

Question 21

vascular stiffness

Answer 21

aorta stoes energy during systole and releases it during diastole (Windkessel effect)

PE converted into KE

if too stiff - E is dampened (aging, diabetes)

want it to be like a slinky

Question 22

arteries

Answer 22

elastin and collagen

thick walls

conduit vessels

Question 23

arterioles

Answer 23

thick walls

“resistance vessels” - regulated

more smooth muscle, less elastin

Question 24

capillaries

Answer 24

smallest vessels, largest SA

“exchange vessels”

no smooth muscle

Question 25

venules

Answer 25

thin walls

“capacitance vessels”

regulated

smooth muscle

Question 26

veins

Answer 26

“capacitance vessels” - regulated

smooth muscle, valves

Question 27

flow velocity changes across vascular tree

Answer 27

highest in arteries

lowest in capillaries

Question 28

blood volume in vacular tree

Answer 28

highest in venules and veins , lowest in arterioles/cap

Question 29

vascular resistance

Answer 29

highest in arterioles - shunting blood from one system to another

most regulated

Question 30

poiseuille’s law

Answer 30

resistance = 8xlengthxviscosity/radius^4

flow is dep on radius ^4 (most imp!!)

flows toward lowest P and least R

Question 31

MAP

Answer 31

= (2xdiastolic + systolic)/3

diastolic is 2x as important as systolic

(what organs see)

also = Cardiac output x SVR (which is resistance to blood flow by all vessels except pulmonary)

Question 32

diastolic BP

Answer 32

pressure in the artery at rest

Question 33

systolic BP

Answer 33

pressure in the artery during contraction

Question 34

pulse pressure

Answer 34

systolic - distolic pressure

Question 35

sympathetic stimulation

Answer 35

all portions of heart

norepinephrine

increase heart rate, speed of conductance, force of contraction

Question 36

parasympathetic stimulation

Answer 36

SA node, AV node, atrial muscle

mainly Ach

decfease HR, speed of conductance, force of contraction

Question 37

chronotropy

Answer 37

heart rate

Question 38

dromotropy

Answer 38

speed of conductance

Question 39

inotropy

Answer 39

force of contraction

Question 40

arterial baroreceptors

Answer 40

in carotid sinus

increase in MAP stretches carotid sinus and leads to increased firing of baroreceptors

increase Parasym and decrease sym to bring BP down if BP is up

pressure sensor

via medulla

Question 41

carotid massage

Answer 41

slows heart rate by vagal stimulation

main BP sensor

Question 42

atrial stretch receptors

Answer 42

volume! (carotid is pressure)

in RA (near SVC) and LA (near pulmonary veins)

increased atrial volume - singal pituitary gland - decreas ADH and urination increases

increased atrial vol –> increase HR –> increas CO to unload heart

Question 43

decrease intrathoracic P

Answer 43

breathe in –> increased venous return –> atrial stretch –> increased atrial baroreceptor activity –> medulla –> decreasd vagul outflow –> increase HR

Question 44

increase intrathoracic pressure

Answer 44

breathe out –> diaphragm out –> increased P in throax –> more blood to L heart and less to R heart (bc lungs are like sponge of blood) –> less atrial stretch –> decrease HR

Question 45

valsalva maneuver

Answer 45

expiration against a closed glottis

carotid baroreptirs

1. increased thoracic P forces blood into LA
2. strain (pathological!) - increased P prefects blood from returning - fall in CO and less distention of all baroreceptors (carotid and aortic)
3. P release - sudden distention of aorta and pulmonary artery - shift in blood vol to great vessels decreases venous return
4. equilibration - rapid increase in venous return and increased CO with stretch of baroreceotrs and fall in HR

Question 46

Bezold-Jarisch Reflex

Answer 46

low blood volume!

sympathetic followed by parasympathetic

rigorous contraction–> stim L ventricular receptors – decrease R and vasodilation

starts w sym response (increase HR) - ventricular over stim 0 compensatory decreased HR/vascular tone

dehydration - dancing

fasting blood test and fright

Question 47

conduit vessels

Answer 47

arteriies

Question 48

resistance vessels

Answer 48

arterioles

Question 49

exchange vessels

Answer 49

capillaries

Question 50

capacitance vessels

Answer 50

venules and veins

Question 51

pulse wave velocity

Answer 51

distance/time (measure of vascular stiffness)