Cardiac physiology, Topnotch

Question 1

Blood flow velocty in the aorta

Answer 1

11cm/sec

Question 2

Blood flow velocity in the capillaries

Answer 2

0.03cm/sec

Question 3

Control conduits for blood flow

Answer 3

Arterioles

Question 4

Receptor for venous and arteriolar vasoconstriction in the skin, splanchnic, and renal circulation

Answer 4

a1

Question 5

Receptor for arteriolar vasodilation in the skeletal muscles

Answer 5

b2

Question 6

T/F: Capillaries undergo vasoconstriction and vasodilation

Answer 6

F

Question 7

Law: Blood flow is proportional to pressure difference and inversely proportional to resistance

Answer 7

Ohm’s law

Question 8

Law: Resistance is proportional to blood viscosity and length of vessel and inversely proportional to radius of vessel raised to the fourth power

Answer 8

Poiseuille’s law

Question 9

Factors that affect Reynold’s number

Answer 9

1) Blood density
2) Blood viscosity
3) Blood flow velocity
4) Blood vessel diameter

Question 10

Laminar vs turbulent: High Reynold’s number

Answer 10

Turbulent

Question 11

Highest arterial BP

Answer 11

SBP

Question 12

Lowest arterial BP

Answer 12

DBP

Question 13

Systolic pressure-diastolic pressure

Answer 13

Pulse pressure

Question 14

Central venous pressure is synonymous to ___ atrial pressure

Answer 14

Right

Question 15

Pulmonary capillary wedge pressure estimates ___ atrial pressure

Answer 15

Left

Question 16

Mean aortic pressure

Answer 16

100mmHg

Question 17

Mean arteriolar pressure

Answer 17

50mmHg

Question 18

Mean capillary pressure

Answer 18

20mmHg

Question 19

Pressure in vena cava

Answer 19

4mmHg

Question 20

Glomerular hydrostatic pressure

Answer 20

60mmHg

Question 21

ECG: AV node conduction

Answer 21

PR segment

Question 22

ECG: Conduction time through AV node

Answer 22

PR interval

Question 23

ECG: Ventricular repolarization

Answer 23

T wave

Question 24

ECG: Depolarization + repolarization of ventricles

Answer 24

QT interval

Question 25

ECG: Plateau of ventricular action potential

Answer 25

ST segment

Question 26

Effect on ECG: Flat/inverted T wave

Answer 26

Hypokalemia

Question 27

Effect on ECG: Low P wave, tall T wave

Answer 27

Hyperkalemia

Question 28

Effect on ECG: Prolonged QT interval

Answer 28

Hypocalcemia

Question 29

Effect on ECG: Shortened QT interval

Answer 29

Hypercalcemia

Question 30

PR segment

Answer 30

End of P wave, start of QRS complex

Question 31

PR interval

Answer 31

Start of P wave, start of QRS complex

Question 32

QT interval

Answer 32

Start of QRS complex, end of T wave

Question 33

ST segment

Answer 33

End of QRS complex, start of T wave

Question 34

Ventricular action potential: Phases

Answer 34

0-4

Question 35

Ventricular action potential: Phase 0

Answer 35

Na influx (depolarization)

Question 36

Ventricular action potential: Phase 1

Answer 36

K efflux (partial repolarization)

Question 37

Ventricular action potential: Phase 2

Answer 37

Ca influx (plateau)

Question 38

Ventricular action potential: Phase 3

Answer 38

K efflux (complete repolarization)

Question 39

Ventricular action potential: Phase 4

Answer 39

RMP

Question 40

SA node action potential: Phases

Answer 40

0,3,4

Question 41

SA node action potential: Phase 0

Answer 41

Ca influx (depolarization)

Question 42

SA node action potential: Phase 3

Answer 42

K efflux

Question 43

SA node action potential: Phase 4

Answer 43

Slow Na influx towards threshold

Question 44

Rate of phase 4 depolarization (fastest to slowest)

Answer 44

SA node > AV node > His-Purkinje system

Question 45

Master pacemaker of the heart

Answer 45

SA node

Question 46

Cardiac pacemaker with the slowest conduction velocity of 0.01-0.05m/sec

Answer 46

AV node

Question 47

Cardiac pacemaker with the fastest conduction velocity of 2-4m/sec

Answer 47

His-Purkinje system

Question 48

Intrinsic firing rate: SA node

Answer 48

70-80bpm

Question 49

Intrinsic firing rate: AV node

Answer 49

40-60bpm

Question 50

Intrinsic firing rate: Bundle of His

Answer 50

40bpm

Question 51

Intrinsic firing rate: Purkinje fibers

Answer 51

15-20bpm

Question 52

Stable vs unstable: RMP of SA node

Answer 52

Unstable

Question 53

Stable vs unstable: RMP of latent pacemakers

Answer 53

Stable

Question 54

RMP of latent pacemakers

Answer 54

-90mV

Question 55

Time required for excitation to spread throughout cardiac tissue

Answer 55

Conduction velocity

Question 56

Conduction velocity is proportional to

Answer 56

Inward current during upstroke

Question 57

RMP of cardiac muscle is determined by

Answer 57

Conductance to K

Question 58

Accounts for SA node automaticity

Answer 58

If/slow funny Na channels

Question 59

Phase of cardiac AP responsible for setting the heart rate

Answer 59

Phase 4

Question 60

Propagation of AP around the ventricles wherein the sign never reaches an area with ARP

Answer 60

Circus movements

Question 61

Circus movements are the basis for

Answer 61

Vfib

Question 62

Causes for circus movements (3)

Answer 62

1) Long conduction pathway
2) Decreased conduction velocity
3) Short refractory period

Question 63

Condition wherein there is a long conduction pathway

Answer 63

Dilated cardiomyopathy

Question 64

Conditions wherein there is decreased conduction velocity (3)

Answer 64

1) Ischemic heart
2) Hyperkalemia
3) Blocked Purkinje

Question 65

Condition wherein there is a short refractory period

Answer 65

1) Epinephrine

2) Electrical stimulation

Question 66

All Na inactivation gates closed

Answer 66

Absolute refractory period

Question 67

Some Na inactivation gates start to open

Answer 67

Effective refractory period

Question 68

T/F: AP can be conducted during ERP

Answer 68

F

Question 69

AP can be conducted with a higher than normal stimulus

Answer 69

RRP

Question 70

All Na inactivation gates open; membrane potential is higher than RMP

Answer 70

Supranormal period, cell is more excitable than normal

Question 71

Drugs that change heart rate

Answer 71

Chronotropic

Question 72

Drugs that change conduction velocity

Answer 72

Dromotropic

Question 73

Drugs that change contractility

Answer 73

Inotropic

Question 74

Drugs that change rate of relaxation

Answer 74

Lusitropic

Question 75

Affected by chronotropes

Answer 75

SA node

Question 76

Affected by dromotropes

Answer 76

AV node

Question 77

Affected by inotropes

Answer 77

Stroke volume

Question 78

Preload of the heart

Answer 78

Left ventricular end-diastolic volume

Question 79

Afterload of the heart

Answer 79

Aortic pressure

Question 80

Increase in preload will increase stroke volume within certain PHYSIOLOGIC LIMITS

Answer 80

Frank-Starling mechanism

Question 81

Frank-Starling mechanism is due to (2)

Answer 81

1) Maximum degree of overlap between actin and myosin

2) Reduction of space between thick and thin filaments

Question 82

Proportional vs inverse: LVEDV and venous return

Answer 82

Proportional

Question 83

Proportional vs inverse: LVEDV and right atrial pressure

Answer 83

Proportional

Question 84

Blood ejected by the ventricle per heart beat

Answer 84

Stroke volume

Question 85

Percentage of EDV ejected by the ventricle per heart beat

Answer 85

EF

Question 86

Total blood volume ejected per unit time

Answer 86

Cardiac output

Question 87

Formula: Stroke volume

Answer 87

EDV-ESV

Question 88

Formula: EF

Answer 88

SV/EDV

Question 89

Formula: CO

Answer 89

HR x SV

Question 90

Normal stroke volume

Answer 90

70mL

Question 91

Normal EF

Answer 91

55%

Question 92

Normal CO

Answer 92

5L/min

Question 93

Work the heart performs with each beat

Answer 93

Stroke work

Question 94

Work per unit time

Answer 94

Cardiac minute work

Question 95

Ratio of work output to total chemical energy expenditure

Answer 95

Maximum efficiency of cardiac contraction

Question 96

Stroke work is equal to

Answer 96

SV x aortic pressure

Question 97

Primary source of energy for stroke work

Answer 97

Fatty acids

Question 98

Cardiac minute work is equal to

Answer 98

CO x aortic pressure

Question 99

Myocardial O2 consumption is increased by (4)

Answer 99

1) Afterload
2) Size of heart
3) Contractility
4) Heart rate

Question 100

Normal maximum efficiency of cardiac contraction

Answer 100

20-25%

Question 101

Phases of the cardiac cycle

Answer 101

1) Atrial contraction/systole
2) Isovolumetric contraction
3) Rapid ventricular ejection
4) Slow ventricular ejection
5) Isovolumetric relaxation
6) Rapid ventricular filling
7) Slow ventricular filling

Question 102

Occurs during distal 3rd of systole

Answer 102

Atrial contraction

Question 103

T/F: Atrial contraction is essential for ventricular filling

Answer 103

F

Question 104

Atrial pressure wave seen with atrial contraction

Answer 104

a wave

Question 105

Abnormal heart sound heard with atrial contraction against a stiff ventricle

Answer 105

S4

Question 106

Atrial wave seen in isovolumetric contraction

Answer 106

c wave

Question 107

Heart sound heard during isovolumetric contraction

Answer 107

S1 (AV valves close)

Question 108

Atrial filling begins at this phase

Answer 108

Rapid ventricular ejection

Question 109

ECG wave seen in reduced ventricular ejection

Answer 109

T wave

Question 110

Phase of cardiac cycle where incisura of aortic pressure is seen

Answer 110

Isovolumetric relaxation

Question 111

Atrial pressure wave seen in isovolumetric relaxation

Answer 111

v wave

Question 112

Heart sound heard with isovolumetric relaxation

Answer 112

S2

Question 113

Heart sound heard during rapid ventricular filling

Answer 113

S3

Question 114

Rapid ventricular filling takes place in which part of diastole

Answer 114

First 1/3

Question 115

Longest phase of the cardiac cycle

Answer 115

Reduced ventricular filling

Question 116

Reduced ventricular filling is aka

Answer 116

Diastasis

Question 117

Length of reduced ventricular filling is dependent on

Answer 117

Heart rate

Question 118

Reduced ventricular filling occurs during

Answer 118

Middle 3rd of diastole

Question 119

Increase vs decrease in aortic pressure: Incisura

Answer 119

Increase

Question 120

BP control (3)

Answer 120

1) Central
2) Acute
3) Long-term

Question 121

Central control of heart rate and BP

Answer 121

Vasomotor area of medulla

Question 122

Portion of medulla: Excitatory to the CV system

Answer 122

Lateral

Question 123

Portion of medulla: Inhibitory to the CV system

Answer 123

Medial

Question 124

Acute controllers of BP

Answer 124

1) ANS
2) CNS ischemic response
3) Baroreceptors
4) Chemoreceptors
5) Lower pressure receptors

Question 125

Long-term control of BP

Answer 125

RAAS

Question 126

SY vs PSY: Greater control of the BP

Answer 126

SY

Question 127

Buffers minute-to-minute changes in BP

Answer 127

Baroreceptors

Question 128

Location of baroreceptors (2)

Answer 128

1) Carotid sinus

2) Aortic arch

Question 129

Carotid baroreceptors respond to increase/decrease in pressures from

Answer 129

50-180mmHg

Question 130

Aortic baroreceptors respond to pressure ___mmHg

Answer 130

> 80

Question 131

Chemoreceptors respond to (2)

Answer 131

1) Low O2
2) High CO2
3) GIVEN BP less than 80mmHg

Question 132

Location of low pressure receptors (2)

Answer 132

1) Atria

2) Pulmonary arteries

Question 133

Low pressure receptors respond to

Answer 133

Increased intravascular volume

Question 134

Responses of low pressure receptors

Answer 134

1) Increase ANP
2) Decrease ADH
3) Renal vasodilation
4) Increase heart rate

Question 135

Increase in heart rate to match vascular resistance with cardiac output

Answer 135

Brainbridge reflex

Question 136

CNS ischemic response starts at ___mmHg

Answer 136

Less than 60

Question 137

CNS ischemic response is optimal at ___mmHg

Answer 137

15-20

Question 138

In CNS ischemic response, all systemic arterioles vasoconstrict EXCEPT (2)

Answer 138

1) Cerebral vessels

2) Coronary vessels

Question 139

Cushing reflex/reaction is a response to

Answer 139

Increased ICP

Question 140

Cushing reflex/reaction: Triad

Answer 140

1) Htn
2) Bradycardia
3) Irregular respirations

Question 141

Responsible in maintaining normal BP despite wide variation in salt intake

Answer 141

RAAS

Question 142

RAAS takes ___ to take effect

Answer 142

20 minutes

Question 143

Normal capillary hydrostatic pressure

Answer 143

25mmHg

Question 144

Normal capillary oncotic pressure

Answer 144

28mmHg

Question 145

Normal interstitial hydrostatic pressure

Answer 145

-3mmHg

Question 146

Causes interstitial hydrostatic pressure to be negative

Answer 146

Lymphatic pump

Question 147

Normal interstitial oncotic pressure

Answer 147

8mmHg

Question 148

Hydraulic conductance of capillary wall

Answer 148

Filtration coefficient

Question 149

Normal net filtration in capillaries

Answer 149

2mL/min

Question 150

Net filtration pressure in kidneys

Answer 150

10mmHg

Question 151

Amount of lymph produced per day

Answer 151

2-3L

Question 152

T/F: Lymphatic vessels have valves

Answer 152

T

Question 153

Cause of edema in burns and inflammation

Answer 153

Increased filtration coefficient

Question 154

Mechanisms for control of local blood flow

Answer 154

1) Acute control

2) Long-term control

Question 155

Mechanisms for ACUTE control of LOCAL blood flow

Answer 155

1) Myogenic theory
2) Metabolic theory
3) Autoregulation

Question 156

Myogenic theory of BP control

Answer 156

Stretching of vascular smooth muscle causes a reflex contraction and vice verse

Question 157

Metabolic theory of BP control

Answer 157

Metabolic activity causes release of vasodilator substances

Question 158

Mechanisms under metabolic theory of BP control

Answer 158

1) O2/nutrient lack theory

2) Vasodilator theory

Question 159

O2 lack theory of BP control

Answer 159

O2 is needed for smooth muscle contraction and lack of O2 leads to vasodilation

Question 160

Nutrient lack theory of BP control

Answer 160

Thiamine, niacin, riboflavin, and glucose are needed for smooth muscle contraction and lack of these leads to vasodilation

Question 161

Vasodilator theory of BP control

Answer 161

Metabolism releases adenosine, CO2, K, and hydrogen, which are vasodilators

Question 162

Metabolic theory: Increase in blood flow in response to brief periods of decreased blood flow

Answer 162

Reactive hyperemia

Question 163

Metabolic theory: Increase in blood flow to meet increased metabolic demand

Answer 163

Active hyperemia

Question 164

Autoregulatory mechanism: Kidneys

Answer 164

Tubuloglomerular feedback

Question 165

Autoregulatory mechanism: Brain

Answer 165

Response to CO2 and H levels

Question 166

Autoregulatory mechanism: Heart

Answer 166

Response to perfusion pressure

Question 167

Mechanism for long-term control of LOCAL blood flow

Answer 167

Angiogenesis

Question 168

Susbtances that cause angiogenesis (3)

Answer 168

1) VEGF
2) FGF
3) Angiogenin

Question 169

Angiogenesis occurs in response to

Answer 169

Hypoxia

Question 170

Vascularity is determined by

Answer 170

MAXIMUM blood flow need

Question 171

Most potent vasoconstrictor

Answer 171

ET-1

Question 172

Vasodilator substance that counteracts TXA2

Answer 172

PGI2

Question 173

Vasodilator vs vasoconstrictor: NE

Answer 173

Vasoconstrictor

Question 174

Vasodilator vs vasoconstrictor: Epi

Answer 174

Vasoconstrictor

Question 175

Vasodilator vs vasoconstrictor: ANP

Answer 175

Vasodilator

Question 176

Vasodilator vs vasoconstrictor: H

Answer 176

Vasodilator

Question 177

Vasodilator vs vasoconstrictor: CO2

Answer 177

Vasodilator EXCEPT at pulmonary vascular bed

Question 178

Vasodilator vs vasoconstrictor: PGF

Answer 178

Vasoconstrictor

Question 179

Vasodilator vs vasoconstrictor: K

Answer 179

Vasodilator

Question 180

Vasodilator vs vasoconstrictor: TXA2

Answer 180

Vasoconstrictor

Question 181

Vasodilator vs vasoconstrictor: ATII

Answer 181

Vasoconstrictor

Question 182

Vasodilator vs vasoconstrictor: PGE

Answer 182

Vasodilator

Question 183

Vasodilator vs vasoconstrictor: Lactate

Answer 183

Vasodilator

Question 184

Vasodilator vs vasoconstrictor: Adenosine

Answer 184

Vasodilator

Question 185

Vasodilator vs vasoconstrictor: Bradykinin

Answer 185

Arteriolar vasodilator, venous vasoconstrictor

Question 186

Vasodilator vs vasoconstrictor: Histamine

Answer 186

Arteriolar vasodilator, venous vasoconstrictor

Question 187

Special circulation/s whose major metabolic control is local rather than central

Answer 187

1) Cerebral
2) Coronary
3) Pulmonary
4) Renal
5) Skeletal during exercise

Question 188

Special circulation/s whose major metabolic control is central (ANS) rather than local

Answer 188

Skin