cardio & vessels

Question 1

nodes

Answer 1

specialized regions where pacemaker cells are grouped together ➔ control rate & coordination of cardiac contractions

• sinoatrial (SA) node exhibits autorhythmicity of 70 AP/min = fastest
  
  • located in wall of R atrium near opening of superior vena cava
• atrioventricular (AV) node exhibits autorhythmicity of 50 AP/min
  * follows SA node
  * can take over if SA is damaged
  
  • located near base of R atrium
• bundle of His = tract of pacemaker cells
  
  • starts at AV node & divides into p L & R ventricles
  • L & R ventricle need own conduction system: necessary for tuning
• purkinje fibers = specialized transmission cells ➔ have pacemaker cells but not as strong
  
  • small terminal fibers from bundle of His & spread through ventricular myocardium
  • exhibit autorhythmicity of 30 AP/min
  • follow SA node (& AV node)
• interatrial pathway conducts pacemaker activity from R ➔ L atrium
  
  • L atrium ≠ nodes
  • both atria have pacemaker cels, only R has nodes
• internodal pathway conducts from SA ➔ AV
• AV nodal delay = slowed conduction of pacemaker activity through AV node
  
  • delay ensures ventricles contract AFTER atrial depolarization & contraction
  • critical for allowing proper feeling
• node pathway: SA node ➔ internodal pathway ➔ AV node ➔ AV bundle of His ➔ R & L bundle branches ➔ purjinke fibers

Question 2

arteries

Answer 2

large vessels that carry blood from heart to systemic circulation

• a lot of elastin fibers to stretch to hold pressure from heart
• little resistance to blood flow b/c of large radius
• conduit for low resistance flow & acts as a pressure reservoir b/c elasticity ➔ driving force during ventricular diastole (relaxing & filling)
• can expand & store pressure from contraction
• energy from stretch used to continue propulsion
• arterial walls recoil & maintain pressure during relaxation

Question 3

capillaries

Answer 3

smallest diameter vessels that branch from arterioles

• most SA:V ratio
• majority of gas exchange ➔ “action”
• no elastin, SM, or collagen, only thin layer of endothelium
• ↓ thickness = ↑ ROD

Question 4

veins

Answer 4

= blood reservoir & channel for oxygen-poor blood flow back to heart

• large diameter vessels when venules merge
• large veins have less elastin because does not have pressure from heart

Question 5

microcirculation

Answer 5

collection of arterioles, capillaries, & venules

Question 6

blood flow is determined by

Answer 6

1. pressure gradient in vessels
2. resistance caused by friction & viscosity

Question 7

blood flow

Answer 7

F = ∆P/R

• F = flow rate: V of blood passing through vessel per unit of time
• ∆P = pressure gradient: diff in pressure between beginning & end of vessel
• R = resistance to flow

Question 8

resistance to flow depends on:

Answer 8

1. blood viscosity = friction in blood based on concentration of plasma proteins & # of circulating RBC
2. vessel length: ↑ inner vessel SA in contact w/ blood = ↑ resistance to flow
3. vessel radius: resistance is inversely proportional to the fourth power of the radius (multiplying the radius by itself four times)

• R ∝ 1/r⁴
• F ∝ r⁴

Question 9

pulse pressure

Answer 9

diff between systolic & diastolic pressure

Question 10

mean arterial pressure

Answer 10

MAP = diastolic pressure + 1/3 pulse pressure

• monitored & regulated by BP reflexes
• systolic = highest arterial pressure
• diastolic = lowest arterial pressure

Question 11

R valves

Answer 11

1. R atrioventricular (AV) (tricuspid) valve
2. R pulmonary semilunar valve

Question 12

valve btwn L atrium & L ventricle

Answer 12

L atrioventricular (AV) (bicuspid or mitral) valve

Question 13

electrical activity general overview

Answer 13

• heart is self-excitable: initiiates own rhythmic contractions
• contractile cells = 99% of cardiac muscle ➔ do all mechanical pumping work
• autorhythmic cells initiate & conduct own AP that promote muscle contraction
  
  • display pacemaker activity: membrane potential slowly depolarizes btwn AP, drifting to threshold
  • cyclically initiate AP tbat spread throughout heart to trigger rhythmic contractions

Question 14

cardiac muscle AP

Answer 14

• -90 mV = too negative ∴ cannot initiate own AP
• long refractory period during plateau phase prevents muscle summation & tetanus

1. rapid depolarization: fast Na channels open ➔ Na in fast
2. plateau phase:
   
   1. early, brief repolarization: T-K+ channels open & Na+ channels close ➔ K+ out fast
   2. slow repolarization: K channels close & slow L-type Ca channels open ➔ Ca in slow
3. rapid repolarization: L-type Ca channels close & ordinary K-channels open ➔ K out fast
4. RMP maintained by open leaky K+ channels

Question 15

end-diastolic volume (EDV)

Answer 15

V of blood in ventricle when relaxation & filling is complete

• = max blood capacity

Question 16

end-systolic volume (ESV)

Answer 16

V of blood remaining in ventricle after contraction/emptying

Question 17

stroke volume

Answer 17

amount of blood pumped every contraction

• by each ventricle per beat
• EDV − ESV

Question 18

systole

Answer 18

ventricular contraction & emptying

• ST segment of ECG wave
• rapid emptying due to pressure

Question 19

diastole

Answer 19

ventricular relaxation & filling

• takes longer to fill than empty
• TP segment of ECG wave

Question 20

heart sounds

Answer 20

normal sounds from valve closings

• first heart sound (S₁) = “lub” ➔ closing of AV valves
• second heart sound (S₂) = “dub” ➔ closing of aortic & pulmonary valves

defective valves produce turbulent flow

• heart murmur
• stenotic = not open completely ➔ whistle
• insufficient = not close completely ➔ swish

Question 21

cardiac output (CO)

Answer 21

• CO = HR x SV
• ↑ venous return = ↑ ventricular filling (↑ EDV)
  
  • more blood pumped back to heart ➔ more blood fills ventricles ➔ more blood remaining in ventricles after diastole
• ↑ EDV = ↑ stroke volume

Question 22

frank-starling law

Answer 22

• describes length-tension relationship btwn EDV & SV
• more blood returned to the heart = more blood pumped out
• intrinsic control of CO
• main determinant of cardiac muscle fiber length = degree of diastolic filling
  
  • more heart is stretched = longer fibers before contraction
  • ↑ length ➔ ↑ force of contraction ∴ ↑ SV

Question 23

heart walls

Answer 23

• cells
  
  • fibroblasts protect heart from foreign substances → immune system
  • monocytes
  • endothelial cells
• endocardium = thin layer of endothelial tissue lining interior of each chamber ➔ exchanges O2 & gases quickly
• myocardium = middle layer of heart wall composed of CM
  
  • CM cells are connected end-to-end by intercalated discs
  • 2 types of contact:
    
    1. desmosomes mechanically hold CC together → strength for beating
    2. gap junctions provide paths of low resistance for transmitting info: small mol & electrical signals ➔ enables functional syncytium
• epicardium = thin external membrane covering heart filled w/ small volume of pericardial fluid ➔ lubrication ↓ friction

Question 24

endocardium

Answer 24

thin layer of endothelial tissue lining interior of each heart chamber ➔ exchanges O2 & gases quickly

Question 25

myocardium

Answer 25

middle layer of heart wall composed of CM

• CM cells are connected end-to-end by intercalated discs
• 2 types of contact:
  
  1. desmosomes mechanically hold CC together → strength for beating
  2. gap junctions provide paths of low resistance for transmitting info: small mol & electrical signals ➔ enables functional syncytium

Question 26

pacemaker potential

Answer 26

1. slow depolarization until threshold
   
   1. K+ channels close = no K+ out & I channels (funny = Na channels) open = **Na+ in ** (critical driver)
   2. Na channels close & T-type Ca channels open ➔ Ca in = main driver (T = transient)
2. depolarization at threshold: rising phase
   
   1. L-type Ca channels open ➔ Ca in (L = long-lasting)
   2. T-type Ca channels close
3. repolarization: K+ channels open ➔ K+ out

Question 27

difference btwn pacemaker potential & CM contractile AP

Answer 27

1. RMP
2. plateau phase in contractile: fisrt fast K channels (K out fast) then T-Ca chanels (Ca in slow)
3. slow depolarization in PMC vs rapid in contractile
4. maximum depolarization
5. 1st funny (Na) channels then T-Ca channels vs fast Na channels

Question 28

excitation-contraction coupling in contractile CM

Answer 28

• dihydropyridine receptors = voltage-gated Ca channels that allow entry in cardiac cell (does not trigger foot proteins like in skeletal muscle)
• Ca from both SR & ECF
  
  1. dihydropyridine receptors in T-tubules act as voltage-gated Ca channels ➔ open to let Ca into cytosol
  2. Ca entry triggers more Ca released by SR
• # of activated cross-bridges proportional to cytosolic Ca
• long refractory period prevents tentanus of CM

Question 29

electrocardiogram

Answer 29

graphic record of electrical activity that reaches surface as result of depolarization/repolarization

• AP of heart generates electrical currents ➔ can reach body surface & be detected as voltage differences between 2 points
• P wave = atrial depolarization
  
  • SA node fires to AV & internodal pathway
• PR segment = AV nodal delay: slower conduction through AV nodea
  
  • ensures ventricles contract AFTER atrial depolarization & contraction
• QRS wave = ventricular depolarization
  
  • simultaneous atrial repolarization, but cannot be detected because masked by ventricles)
• ST segment = systole = ventricular contracting & emptying
• T wave = ventricular repolarization
• TP segment = diastole = ventricular relaxation & filling

Question 30

HR & rhythms

Answer 30

normal ≈ 60-100 bpm

• > 100 = tachycardia
• ventricular fibrillation = no conduction of purkinje fibers
• heart attack caused by blockages

Question 31

mechanical events of the heart

Answer 31

cycle = alternating periods of systole & diastole

• end-diastolic volume = V of blood after relaxation (max blood capacity)
• isovolumetric ventricular contraction = closed valves ↑ pressure ➔ ventricular volume stays the same before systole while pressure builds
• end-systolic volume = blood left over after contraction/emptying
• stroke volume = amount of blood pumped each contraction
• isovolumetric ventricular relaxation = closed valves ↓ pressure ➔ volume in ventricles remains the same before diastole during atrial filling
• pressure from A carries on to B

Question 32

stenotic valves

Answer 32

won’t open completely ➔ whistle

Question 33

insufficient valves

Answer 33

not close completely ➔ swish

Question 34

1. lub-whistle-dub
2. lub-dub-whistle
3. lub-swish-dub
4. lub-dub-swish

Answer 34

1. stenotic + systolic
2. stenotic + diastolic
3. insufficient + systolic
4. insufficient + diastolic

Question 35

parasympathetic regulation of HR

Answer 35

• ACh through muscarinic receptors
• vagus nerve to SA & AV nodes & atrial contractile cells
• little ventricular innervation
• SA node: ACh delays closing K+ channels ➔ ↑ K+ permeability ➔ more K+ out ➔ greater hyperpolarization = stronger depolarization required (longer time) ➔ slowing contractions
• AV node: ACh ↑ K+ permeability ➔ ↓ excitability ➔ delays response
• atrial contractile cells: ACh ↓ Ca permeability during plateau phase ➔ less Ca enters cell ➔ ↓ contraction strength

Question 36

sympathetic regulation of HR

Answer 36

• NE through beta-adrenergic receptors
• nerves innervate atria & ventricles
• SA node: NE ↓ K+ permeability: closes K+ channels faster after AP ➔ less hyperpolarization = faster depolarization
• AV node: NE ↑ Ca permeability ➔ shorter AV nodal delay
• bundle of His & Purkinje fibers = similar to AV node
• atrial & ventricular contractile cells: NE ↑ Ca permeability during plateau phase ➔ more Ca enters = ↑ contraction & stronger

Question 37

regulation of stroke volume

Answer 37

intrinsically by venous blood return

• Frank-Starling law: heart normally pumps out during systole same V of blood returned to it during diastole
  
  • increased venous return results in increased SV
  • more blood returned = more blood pumped out
  • main determinant of cardiac muscle fiber length = degree of diastolic filling
  • more heart is stretched = longer fibers before contraction
  • ↑ length ➔ ↑ force of contraction ∴ ↑ SV
  • dependent on lengt-tension relationship

extrinsically by SNS

• shifts Frank-Starling curve L: ↑ Ca ➔ ↑ contractile force & SV of the heart
• extrinsic control enhances heart’s contractility ➔ contracts more forcefully and squeezes out a greater percentage of the blood it contains, leading to more complete ejection

Question 38

heart failure

Answer 38

• ↑ BP ➔ ↑ heart workload
• CO cannot meet demands of body
• can happen in 1 or both ventricles ➔ congestion of blood in veins back to heart
• ventricle must generate more pressure to eject blood
  
  1. ↑ BP
  2. exit valve is stenotic
• ↓ in CO that shifts frank-starling curve ↓ & right
  
  • SNS stimulation shifts curve ↑ & L
• heart compensates with:
  
  • hypertrophy: ↑ thickness of cardiac muscle fibers (enlarged heart)
  • ↑ sympathetic activity
  • ↑ blood volume from retention of salt & water by kidneys

Question 39

sphygmomanometer

Answer 39

measures BP (systolic & diastolic arterial pressure) (i.e. 120/80)

• BP expressed as systolic over diastolic
• cuff pressure > BP: no blood flows = no sound
• cuff pressure between systolic & diastolic pressure
  
  1. artery transiently opens a bit when BP reaches peak
  2. blood escapes through partially occluded artery for brief interval before arterial pressure < cuff pressure & artery collapses again
• cuff pressure < systolic & diastolic: blood flows smoothly ➔ no sound

Question 40

pressure graph from ventricle ➔ venules & veins

Answer 40

• L ventricular pressure swings between 0 during diastole & 120 during systole
• arterial pressure fluctuates between systolic & diastolic
• arteriolar pressure drops dramatically across length of arteriole

Question 41

arteriolar radius factors

Answer 41

arterioles = major resistance vessels b/c of small radius regulated by:

• excercise
• temp
• stretch

intrinsic (local) control

1. local metabolic changes cause dilation: SM tone is controlled by release of mediators (NO) from endothelial cells lining interior walls of arterioles
   
   • ↓ O2 during demand
   • ↑ CO2 during demand
   • ↑CO2 &/or lactic acid = ↓ blood pH
   • ↑neuronal activity outpaces Na/K ATPases ➔ ↑ extracellular K
   • ↑[solute] = ↑ osmolarity
   • ↑ adenosine from cardiac muscles
   • ↑ histamine release from damaged tissues ➔ vasodilation during inflammatory response
2. local physical control:
   
   • ateriolar SM tone = inversely proportional to temp
   • myogenic response: arteriolar SM responds to stretch by contracting

extrinsically:

• vasopressin & angiotensin II
• EP/NE influence on SNS
• vasoconstriction from sympathetic activity

Question 42

capillary exchange

Answer 42

• exchange occurs btwn blood & interstitial fluid
• occurs by diffusion & bulk flow
  
  • pores in capillary walls allow plasma to pass by not proteins or RBC
  • ultrafiltration = bulk flow out of capillaries (+ net pressure)
    
    1. capillary BP (P_c) = forces fluid out of capillaries into IF
    2. interstitial fluid-colloid osmotic pressure (πIF) forces capillary water to IF
  • reabsorption = bulk flow into capillaries ( − net pressure)
    
    2. plasma-colloid pressure (πp) forces IF to capillaries controlled by [plasma proteins]
    3. interstitial fluid hydrostatic pressure (P_IF) forces IF to capillaries
• net pressure = (Pc + πIF) - (PIF + πP) (out-in)
• inward pressure stays same throughout length
• outward pressure slowly declines

Question 43

ultrafiltration

Answer 43

bulk flow out of capillaries (+ net pressure)

Question 44

reabsorption

Answer 44

bulk flow into capillaries (− net pressure)

Question 45

capillary BP (P_c)

Answer 45

forces fluid out of capillaries into IF

Question 46

plasma-colloid pressure (πp)

Answer 46

forces IF to capillaries

• controlled by [plasma proteins]

Question 47

interstitial fluid hydrostatic pressure (P_IF)

Answer 47

forces IF to capillaries

Question 48

interstitial fluid-colloid osmotic pressure (πIF)

Answer 48

forces capillary water to IF

Question 49

net pressure =

Answer 49

(Pc + πIF) - (PIF + πP) (out-in)

Question 50

venous capacity

Answer 50

V of blood veins can hold

Question 51

venous return

Answer 51

V of blood entering each atrium per minute

• influenced by:
  
  • sympathetic activity produces vasoconstriction to ↑ venous pressure & ↑ venous return
  • skeletal muscle activity: contraction compresses veins & ↑ venous pressure ➔ counteracts effects of gravity
  • venous valves prevent backflow (located w/in lumen of large veins)
  • respiratory activity: brief ↓ in pressure w/in chest cavity ↑ pressure gradient between veins & lower extremities ↑ chest
  • cardiac suction: arterial pressure briefly falls below 0 mmHg during ventricular contraction ➔ ↑ venous pressure gradient & sucks venous blood into atria

Question 52

sympathetic activity’s influence on venous return

Answer 52

produces vasoconstriction to ↑ venous pressure & ↑ venous return

Question 53

skeletal muscle’s influence on venous return

Answer 53

contraction compresses veins & ↑ venous pressure ➔ counteracts effects of gravity

Question 54

venous valves’ influence on venous return

Answer 54

prevent backflow (located w/in lumen of large veins)

• w/out: contracted skeletal muscle would squeeze blood both towards & away from heart

Question 55

respiratory’s influence on venous return

Answer 55

inhaling ↓ pressure in chest ➔ blood flows fown pressure

Question 56

cardiac suction’s influence on venous return

Answer 56

arterial pressure briefly falls below 0 mmHg during ventricular contraction ➔ ↑ venous pressure gradient & sucks venous blood into atria

Question 57

extrinsic

Answer 57

attached partly to an organ or limb and partly to some other part said of certain groups of muscles

Question 58

intrinsic

Answer 58

coming from within, from the inside

Question 59

intrinsic

Answer 59

coming from within, from the inside

Question 60

regulation of MAP

Answer 60

CO

• HR
  
  • parasympathetic:: ACh via muscarinic receptors
    
    • SA & AV: ↑K permeability = more K out = greater hyperpolarization = stronger depolarization required = delayed response = slower contractions
    • contractile cells: ACh ↓ Ca permeability during plateau phase = less Ca in = ↓contraction strength
  • sympathetic: NE via beta-adrenergic receptors
    
    • SA: ↓ K permeability closes K channels faster = less hyperpolarization = faster depolarization
    • AV: ↑ Ca permeability = shorter AV nodal delay
    • bundle of His & purkinje fibers = similar to AV node
    • contractile cells: ↑ Ca permeability during plateau phase
• SV
  
  • NE/EP ↑ Ca = stronger contractions
  • venous return:
    
    • blood volume:
      
      • passive bulk flow shifts btwn capillary & IF
      • salt & water balance influenced by vasopressin & angiotensin II that affect vassopressin, renin-aldosterone system
    • respiratory activity: inhalation ↓ chest pressure ➔ concentration gradient
    • skeletal muscle activity counteracts gravity when contractions force blood through veins
    • cardiac suction from pressure gradient when arterial pressure falls below 0 during ventricular contraction

total peripheral resistance

• blood viscocity: hydration & RBC
• arteriolar radius:
  
  • local metabolic control: skeletal muscle activity
    
    • ↓ O2 during demand
    • ↑ CO2 during demand
    • ↑CO2 &/or lactic acid = ↓ blood pH
    • ↑neuronal activity outpaces Na/K ATPases ➔ ↑ extracellular K
    • ↑[solute] = ↑ osmolarity
    • ↑ adenosine from cardiac muscles
    • ↑ histamine release from damaged tissues ➔ vasodilation during inflammatory response
  • extrinsic vasoconstrictor control:
    
    • vasopressin & angiotensin II
    • sympathetic activity & EP/NE

blood volume

Question 61

baroreceptor reflex

Answer 61

automatically regulates CO & total peripheral resistance

• responds to changes in arterial BP by ↑ or ↓ rate of firing via parasymp & symp neurons of cardiovascular control centers
  
  1. carotid sinus baroreceptor
  2. aortic arch baroreceptor
     * baroreceptors = mechanoreceptors sensitive to changes in MAP & pulse pressure

Question 62

BP anormalilties

Answer 62

• hypertension = BP above 140/90 mm Hg
  
  • 1° = unknown cause (90%)
  • 2° to others (10%)
• orthostatic hypotension: when a person moves from lying down to standing up, pooling of blood in the leg veins from gravity reduces venous return, decreasing stroke volume and thus lowering CO and blood pressure

Question 63

compared to the resting state, the cardiac cycle during exercise:

Answer 63

both systole & diastole decrease, but greater decrease in diastole because the arterioles dilate due to local control

Question 64

response to exercise

Answer 64

diastole decreases

intrinsic (local) control

1. local metabolic changes cause dilation: SM tone is controlled by release of mediators (NO) from endothelial cells lining interior walls of arterioles
   
   • ↓ O2 during demand
   • ↑ CO2 during demand
   • ↑CO2 &/or lactic acid = ↓ blood pH
   • ↑neuronal activity outpaces Na/K ATPases ➔ ↑ extracellular K
   • ↑[solute] = ↑ osmolarity
   • ↑ adenosine from cardiac muscles
   • ↑ histamine release from damaged tissues ➔ vasodilation during inflammatory response
2. local physical control:
   
   • ateriolar SM tone = inversely proportional to temp
   • myogenic response: arteriolar SM responds to stretch by contracting

extrinsically:

• vasopressin & angiotensin II
• EP/NE influence on SNS
• vasoconstriction from sympathetic activity

Question 65

3 phases of the cardiac cycle

Answer 65

1. mid-to-late diastole
2. ventricular systole
3. early diastole