Chapter 12 (Midterm 2)

Question 1

Why does the left side of the heart have more myocardium tissue than the right side?

Answer 1

it needs more pressure to move blood throughout the body and maintains the same flow rate as the right side

Question 2

What differentiates the arterioles from the other microcirculation vessels?

Answer 2

covered in smooth muscle cells = regulates pressure and controls where blood flows

Question 3

What differentiates the venules from the other microcirculation vessels?

Answer 3

covered in of connective tissue = can stretch more

Question 4

What differentiates the capillaries from the other microcirculation vessels?

Answer 4

purely consists of endothelial cells = site of exchange

Question 5

What are the two advantages of parallel blood flow?

Answer 5

allows the control of blood flow to each organ, deO2 blood/waste are not traveling from one organ to another

Question 6

What is the importance of parallel blood flow?

Answer 6

to make sure that each of the peripheral organs and tissues receives only a fraction of the blood pumped by the left ventricle

Question 7

What drives blood flow?

Answer 7

resistance from the vessels and the pressure from the heart

Question 8

What is hydrostatic pressure?

Answer 8

pressure exerted by any fluid

Question 9

What is resistance (R) to flow?

Answer 9

how hard it is for blood to flow between two points at any given pressure difference

Question 10

What is resistance controlled by?

Answer 10

the vessels

Question 11

What is pressure controlled by?

Answer 11

the heart

Question 12

What is the equation for blood flow?

Answer 12

the difference in high and low pressure (from the heart) divided by the resistance (from the vessels)

Question 13

What is the myocardium?

Answer 13

middle layer of the heart muscle

Question 14

What is the myocardium composed of?

Answer 14

cardiac muscle and forms the bulk of the heart mass

Question 15

What is the function of myocardium?

Answer 15

the layer of the heart that contracts = generates force to pump blood out of the heart

Question 16

What are the important features of cardiac muscles that are unique?

Answer 16

many large mitochondria, high resistance to fatigue, few wide T-tubules, no triads

Question 17

What is the advantage of having a high resistance to fatigue for cardiac muscles?

Answer 17

no relaxation stage = constant beating

Question 18

What are intercalated discs?

Answer 18

connecting junctions between cardiac cells

Question 19

What do intercalated discs contain?

Answer 19

desmosomes and gap junctions

Question 20

What is an advantage of having an increased number of desmosomes?

Answer 20

heart increases in surface area

Question 21

What is the function of desmosomes?

Answer 21

holds the cardiac cells together and prevents them from separating during contraction = allows for a unison beating

Question 22

What is the function of gap junctions?

Answer 22

allows ions to pass from electrically coupled adjacent cells

Question 23

What does functional syncytium mean?

Answer 23

to be a single coordinated unit

Question 24

What allows the heart to be a functional syncytium?

Answer 24

gap junctions

Question 25

What is the purpose of functional syncytium for a heart?

Answer 25

allows for even blood flow

Question 26

What is the sinoatrial (SA) node?

Answer 26

a small group of conducting cells

Question 27

What is the pacemaker for the entire heart?

Answer 27

the SA node

Question 28

What determines heart rate?

Answer 28

the discharge rate of action potentials released from the SA node

Question 29

What is the atrioventricular (AV) node?

Answer 29

the link between the atrial and ventricular depolarization

Question 30

What does laminar flow mean?

Answer 30

normal blood flow through the valves and vessels, makes no sound

Question 31

What does a stenotic valve mean?

Answer 31

a narrowed valve, doesn’t fully open

Question 32

What is an insufficient valve?

Answer 32

a leaky valve that can cause backflow

Question 33

What does a stenotic or insufficient valve indicate?

Answer 33

turbulent flow

Question 34

How can a doctor diagnose a patient whose blood flow is turbulent?

Answer 34

listen for a heart murmur

Question 35

What is the internodal pathway?

Answer 35

low resistance conducting-cell pathway connecting the sinoatrial and atrioventricular nodes of the heart

Question 36

Where in the heart does the action potential must pass through for contraction to begin?

Answer 36

the apex (apex means bottom)

Question 37

What are the bundle of His?

Answer 37

conducting system fibers, also known as AV bundle

Question 38

What are the left and right bundle fibers?

Answer 38

conducting fibers that separate at the bottom (apex) of the heart and enter through the walls of both ventricles

Question 39

What are the Purkinje fibers?

Answer 39

large-diameter conducting cells that rapidly transmits the impulse through the ventricles

Question 40

What ions are permeable to the plasma membrane of myocardial cells?

Answer 40

K, Na, and Ca(21)

Question 41

What is different between skeletal and cardiac muscles cells in terms of calcium permeability?

Answer 41

cardiac muscle is more permeable to calcium than skeletal muscle is

Question 42

What type of calcium channels does cardiac muscle use?

Answer 42

L-type Ca2+ channels

Question 43

What is the unique about the specialized calcium channel?

Answer 43

opens slower than Na+ channels do but remain open for a prolonged period

Question 44

What is the purpose of the specialized calcium channel?

Answer 44

maintains the depolarization of the membrane and creating a balance between the potassium going out and calcium flowing in

Question 45

What are the four ion channels that contribute to the pacemaker potential?

Answer 45

potassium, F-Type (Na+) channels and T-type Ca2+, and L-type Ca2+ channel

Question 46

What are F-type channels?

Answer 46

“funny” sodium conducting channel mainly responsible for the inward flow of positive current in autorhythmic cardiac cells

Question 47

What are T-type Ca2+ channels?

Answer 47

open temporarily (T) but contributes to the inward movement of Ca2+ ions and acts as a final depolarizing boost to the pacemaker potential

Question 48

What are the only electrical connections between the atria and ventricles?

Answer 48

AV node and Bundle of His

Question 49

How do the Purkinje fibers help prevent backflow?

Answer 49

must transmit action potentials to the papillary muscles in order to contract before the rest of the ventricle contracts

Question 50

What is stroke volume?

Answer 50

amount of blood heart fills per contraction

Question 51

Are there any electrical events during the period of isovolumic relaxation?

Answer 51

No, this phase is in between heartbeats

Question 52

What are arrhythmias?

Answer 52

uncoordinated atrial and ventricular contractions

Question 53

What is fibrillation?

Answer 53

a rapid irregular heartbeat where the SA node no longer controls the heart rate

Question 54

What is defibrillation?

Answer 54

the procedure in which an electrical current passes through the heart to try to stop the fibrillation

Question 55

Why do we have a plateau phase in some action potentials? (between cardiomyocytes and skeletal muscle cells)

Answer 55

cardiomyocytes need that plateau phase in its APs to maintain depolarization

Question 56

What role does calcium play?

Answer 56

maintains depolarization and increases frequency of action potentials

Question 57

What is the electrocardiogram (EKG)?

Answer 57

tool for evaluating the electrical events that happen within the heart

Question 58

What causes a P wave on an EKG?

Answer 58

atrial depolarization

Question 59

What causes the QRS complex in an EKG?

Answer 59

ventricular depolarization

Question 60

What causes a T wave in an EKG?

Answer 60

ventricular repolarization

Question 61

Why isn’t there a wave for atrial repolarization?

Answer 61

it occurs at the same time as the QRS complex

Question 62

What is an ectopic pacemaker?

Answer 62

controls ventricular contraction at a different rhythm

Question 63

What is cardiac output?

Answer 63

amount of blood pumped out of each ventricle in one minute

Question 64

What are the Frank-starling forces?

Answer 64

relationship between the end-of-diastole volume and stroke volume

Question 65

What is end-diastole volume?

Answer 65

the blood returned from the venous vessels || also called venous return

Question 66

What is end-of diastole pressure?

Answer 66

the preload

Question 67

How can venous return increase?

Answer 67

when there is an increase in the blood flow through peripheral organs to veins

Question 68

What is arterial pressure?

Answer 68

the afterload that affects stroke volume

Question 69

What is hypertension?

Answer 69

a high pressure in the arteries decreases stroke volume

Question 70

What causes high blood pressure?

Answer 70

capillary damage due to clotting at the capillaries

Question 71

What is blood pressure?

Answer 71

force exerted by the blood against the vessel wall

Question 72

What is mean arterial pressure (MAP)?

Answer 72

average pressure during the cardiac cycle

Question 73

How is blood returned to the heart?

Answer 73

increase in arterial pressure = increase pressure gradient throughout vasculature = increase blood flow (venous return)

Question 74

How does an increase in resistance affect blood flow?

Answer 74

decreases blood flow

Question 75

What is the major factor in determining the resistance of a vessel?

Answer 75

the diameter of the vessel

Question 76

How does the structure of veins make blood being returned to the heart possible?

Answer 76

arteries are thick, muscular highly elastic = can change diameter and control pressure

Question 77

What are baroreceptors?

Answer 77

receptors that sense arterial pressure and use negative feedback to keep MAP at set point

Question 78

Where are baroreceptors located?

Answer 78

aorta and carotid arteries

Question 79

What controls the blood flow to the organs?

Answer 79

arteriolar resistance

Question 80

What is the driving force of venous return to the heart?

Answer 80

pressure gradient between peripherial veins and the right atrium

Question 81

How does the body control which organs will receive blood?

Answer 81

through arteriolar dilation or contraction

Question 82

What is the role of smooth muscle in the control of blood flow to organs?

Answer 82

responsible for contracting to make arterioles contract

Question 83

What are the two horomonal receptors on the smooth muscles of arterioles?

Answer 83

alpha and beta-2

Question 84

What effect does the beta-2 receptor have on blood flow to organ? Which organs does it work prevalently at?

Answer 84

increases flow to organ; skeletal muscles, brain, heart and lungs

Question 85

What effect does the alpha receptor have on blood flow to organ? Which organs does it work prevalently at?

Answer 85

decreases flow to organ; GI tract and kidneys

Question 86

What else contributes to the return of blood to the heart?

Answer 86

skeletal muscle pump and respiratory pump

Question 87

What is a skeletal muscle pump?

Answer 87

(during muscle contraction) venous diameter decreases = increase venous pressure = force flow of blood to heart

Question 88

In skeletal muscle pumps, why does the pressure only force the flow of blood to the heart? What prevents the backflow?

Answer 88

the decrease in venous pressure forces the valves in the veins to close = prevents backflow due to the veins’ one-way valves

Question 89

What makes venous return unique since it is a low pressure difference system?

Answer 89

one-way valves, the skeletal muscle and respiratory pumps

Question 90

What are one-way valves?

Answer 90

valves are curved in a way that when it opens, material only flows one way; what they look like: closed valve = (JL) | open valve = (J L)

Question 91

What is the respiratory pump?

Answer 91

venous return is enhanced via inspiration; increases the pressure differences between the peripheral veins and the heart

Question 92

What is the role of sodium channels in setting the heart rate?

Answer 92

helps depolarize the membrane potential as it only opens when membrane potential is negative

Question 93

What can change the heart rate in terms of the SA node?

Answer 93

PNS signalling of APs

Question 94

How does the SA node work as a pacemaker?

Answer 94

the one that initiates the APs for the heart to contract

Question 95

What role does the sympathetic/parasympathetic nervous system have in the changes of total peripheral resistance?

Answer 95

can adjust all arteriole resistance by affect changes to their diameter and size, etc.

Question 96

What is the autonomic nervous system?

Answer 96

all of the internal organs such as blood vessels, stomach, intestine, liver, kidneys, heart, etc.

Question 97

What are the two branches of the autonomic nervous system?

Answer 97

sympathetic and parasympathetic

Question 98

What is the sympathetic nervous system?

Answer 98

fight/flight response - prepares body for intense physical activity

Question 99

What is the parasympathetic nervous system?

Answer 99

relaxes body, inhibits/slows high energy functions

Question 100

In terms of the Frank-Starling Mechanism, how does it affect the quantity of blood the heart moves and the pressure generated?

Answer 100

an increase in amount of blood heart moves = increase in Frank-starling = increase contraction = increase in pressure generated

Question 101

In terms of the Frank-Starling Mechanism, what will the cardiac muscles do if the stroke volume and the end-diastole volume both increase?

Answer 101

muscle will contract

Question 102

In terms of the Frank-Starling Mechanism, what will the cardiac muscles do if the stroke volume and the end-diastole volume both decrease?

Answer 102

muscle will relax

Question 103

In terms of the Frank-Starling Mechanism, what is the affect if the sympathetic nervous system is activated?

Answer 103

heart rate will increase = increase heart contraction = increase in blood volume heart moves = increase in pressure