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Deck 9: B--Cardiac Physiology

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Question
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Which structures are open during isovolumetric relaxation?
Use this figure to answer the corresponding questions. Which structures are open during isovolumetric relaxation? <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Which structures are open during isovolumetric relaxation? <div style=padding-top: 35px>
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Question
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Identify the location(s) where slow calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where slow calcium channels are open. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) where slow calcium channels are open. <div style=padding-top: 35px>
Question
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Identify the location(s) where the cell's permeability to Na+ is the greatest.
Use this figure to answer the corresponding questions. Identify the location(s) where the cell's permeability to Na<sup>+</sup> is the greatest. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) where the cell's permeability to Na<sup>+</sup> is the greatest. <div style=padding-top: 35px>
Question
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Which structures have oxygenated blood flowing through them?
Use this figure to answer the corresponding questions. Which structures have oxygenated blood flowing through them? <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Which structures have oxygenated blood flowing through them? <div style=padding-top: 35px>
Question
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The structure labeled B
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Question
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Identify the location(s) that indicates when fast calcium channels open within the cell.
Use this figure to answer the corresponding questions. Identify the location(s) that indicates when fast calcium channels open within the cell. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) that indicates when fast calcium channels open within the cell. <div style=padding-top: 35px>
Question
Describe the generation of pacemaker action potentials and then track the resulting impulse through the cardiac conduction system. Include the names of specific types of channels in the first part of your answer.
Question
Describe the mechanisms involved by which the parasympathetic and sympathetic nervous systems affect cardiac output. Include ACh, NE, regulated K+ channels, If channels and T-type Ca2+ channels, vagus nerve, cardiac nerves, contractility, stroke volume, and heart rate in your answer.
Question
Use this figure to answer the corresponding questions.
Identify the location(s) where voltage-gated potassium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where voltage-gated potassium channels are open. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) where voltage-gated potassium channels are open. <div style=padding-top: 35px>
Question
List the following in the correct order of their occurrence within the ST segment on the ECG: ventricular ejection begins, lub sound, opening of semilunar valves, period of isovolumetric contraction, closing of AV valves, ventricular systole begins.
Question
Use the answer code below to complete the following statements.
Use the answer code below to complete the following statements. <div style=padding-top: 35px>
Question
Describe how contractile cells are able to contract rapidly but are not likely to experience tetanus. Include the following terms in your
Question
Use this figure to answer the corresponding questions.
This graph shows the electrical activity for one of the heart's
Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's <div style=padding-top: 35px> Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's <div style=padding-top: 35px>
Question
Use this figure to answer the corresponding questions.
Identify the location(s) where fast calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. <div style=padding-top: 35px>
Question
Use this figure to answer the corresponding questions.
This graph shows the electrical activity for one of the heart's
Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's <div style=padding-top: 35px> Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's <div style=padding-top: 35px>
Question
Use this figure to answer the corresponding questions.
Identify the location(s) where fast calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. <div style=padding-top: 35px>
Question
Use this figure to answer the corresponding questions.
Which structures are closed during ventricular ejection?
Use this figure to answer the corresponding questions. Which structures are closed during ventricular ejection? <div style=padding-top: 35px> Use this figure to answer the corresponding questions. Which structures are closed during ventricular ejection? <div style=padding-top: 35px>
Question
Describe the way in which high blood pressure and a defective semilunar valve can make it more difficult for the heart to pump blood into the systemic circulation and how these factors can decrease cardiac output. Include the following in your
Question
Match between columns
Premises:
Responses:
valve
Prevents backflow of blood into the left ventricle
valve
Type of blood in a pulmonary vein
valve
Prevents valves from opening into the atria
valve
Type of blood flowing through the right AV valve
valve
Surrounds and supports the heart valves
valve
Closes when the right ventricle begins systole
valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
chordae tendineae
Prevents backflow of blood into the left ventricle
chordae tendineae
Type of blood in a pulmonary vein
chordae tendineae
Prevents valves from opening into the atria
chordae tendineae
Type of blood flowing through the right AV valve
chordae tendineae
Surrounds and supports the heart valves
chordae tendineae
Closes when the right ventricle begins systole
chordae tendineae
Prevents blood from leaving the left ventricle during isovolumetric contraction
bicuspid valve and mitral valve
Prevents backflow of blood into the left ventricle
bicuspid valve and mitral valve
Type of blood in a pulmonary vein
bicuspid valve and mitral valve
Prevents valves from opening into the atria
bicuspid valve and mitral valve
Type of blood flowing through the right AV valve
bicuspid valve and mitral valve
Surrounds and supports the heart valves
bicuspid valve and mitral valve
Closes when the right ventricle begins systole
bicuspid valve and mitral valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
fibrous skeleton
Prevents backflow of blood into the left ventricle
fibrous skeleton
Type of blood in a pulmonary vein
fibrous skeleton
Prevents valves from opening into the atria
fibrous skeleton
Type of blood flowing through the right AV valve
fibrous skeleton
Surrounds and supports the heart valves
fibrous skeleton
Closes when the right ventricle begins systole
fibrous skeleton
Prevents blood from leaving the left ventricle during isovolumetric contraction
oxygenated blood
Prevents backflow of blood into the left ventricle
oxygenated blood
Type of blood in a pulmonary vein
oxygenated blood
Prevents valves from opening into the atria
oxygenated blood
Type of blood flowing through the right AV valve
oxygenated blood
Surrounds and supports the heart valves
oxygenated blood
Closes when the right ventricle begins systole
oxygenated blood
Prevents blood from leaving the left ventricle during isovolumetric contraction
deoxygenated blood
Prevents backflow of blood into the left ventricle
deoxygenated blood
Type of blood in a pulmonary vein
deoxygenated blood
Prevents valves from opening into the atria
deoxygenated blood
Type of blood flowing through the right AV valve
deoxygenated blood
Surrounds and supports the heart valves
deoxygenated blood
Closes when the right ventricle begins systole
deoxygenated blood
Prevents blood from leaving the left ventricle during isovolumetric contraction
bicuspid valve, mitral valve, and aortic valve
Prevents backflow of blood into the left ventricle
bicuspid valve, mitral valve, and aortic valve
Type of blood in a pulmonary vein
bicuspid valve, mitral valve, and aortic valve
Prevents valves from opening into the atria
bicuspid valve, mitral valve, and aortic valve
Type of blood flowing through the right AV valve
bicuspid valve, mitral valve, and aortic valve
Surrounds and supports the heart valves
bicuspid valve, mitral valve, and aortic valve
Closes when the right ventricle begins systole
bicuspid valve, mitral valve, and aortic valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
Question
Match between columns
Premises:
Responses:
embolus
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
embolus
Referred cardiac pain
embolus
Freely floating clot
embolus
Abnormal clot attached to a vessel wall
angina pectoris
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
angina pectoris
Referred cardiac pain
angina pectoris
Freely floating clot
angina pectoris
Abnormal clot attached to a vessel wall
thrombus
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
thrombus
Referred cardiac pain
thrombus
Freely floating clot
thrombus
Abnormal clot attached to a vessel wall
atherosclerosis
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
atherosclerosis
Referred cardiac pain
atherosclerosis
Freely floating clot
atherosclerosis
Abnormal clot attached to a vessel wall
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Deck 9: B--Cardiac Physiology
1
Use this figure to answer the corresponding questions.
Which structures are open during isovolumetric relaxation?
Use this figure to answer the corresponding questions. Which structures are open during isovolumetric relaxation? Use this figure to answer the corresponding questions. Which structures are open during isovolumetric relaxation?
E
2
Use this figure to answer the corresponding questions.
Identify the location(s) where slow calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where slow calcium channels are open. Use this figure to answer the corresponding questions. Identify the location(s) where slow calcium channels are open.
C
3
Use this figure to answer the corresponding questions.
Identify the location(s) where the cell's permeability to Na+ is the greatest.
Use this figure to answer the corresponding questions. Identify the location(s) where the cell's permeability to Na<sup>+</sup> is the greatest. Use this figure to answer the corresponding questions. Identify the location(s) where the cell's permeability to Na<sup>+</sup> is the greatest.
A
4
Use this figure to answer the corresponding questions.
Which structures have oxygenated blood flowing through them?
Use this figure to answer the corresponding questions. Which structures have oxygenated blood flowing through them? Use this figure to answer the corresponding questions. Which structures have oxygenated blood flowing through them?
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5
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The structure labeled B
Use this figure to answer the corresponding questions. The structure labeled B Use this figure to answer the corresponding questions. The structure labeled B
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6
Use this figure to answer the corresponding questions.
Identify the location(s) that indicates when fast calcium channels open within the cell.
Use this figure to answer the corresponding questions. Identify the location(s) that indicates when fast calcium channels open within the cell. Use this figure to answer the corresponding questions. Identify the location(s) that indicates when fast calcium channels open within the cell.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
7
Describe the generation of pacemaker action potentials and then track the resulting impulse through the cardiac conduction system. Include the names of specific types of channels in the first part of your answer.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
8
Describe the mechanisms involved by which the parasympathetic and sympathetic nervous systems affect cardiac output. Include ACh, NE, regulated K+ channels, If channels and T-type Ca2+ channels, vagus nerve, cardiac nerves, contractility, stroke volume, and heart rate in your answer.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
9
Use this figure to answer the corresponding questions.
Identify the location(s) where voltage-gated potassium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where voltage-gated potassium channels are open. Use this figure to answer the corresponding questions. Identify the location(s) where voltage-gated potassium channels are open.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
10
List the following in the correct order of their occurrence within the ST segment on the ECG: ventricular ejection begins, lub sound, opening of semilunar valves, period of isovolumetric contraction, closing of AV valves, ventricular systole begins.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
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11
Use the answer code below to complete the following statements.
Use the answer code below to complete the following statements.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
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k this deck
12
Describe how contractile cells are able to contract rapidly but are not likely to experience tetanus. Include the following terms in your
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
13
Use this figure to answer the corresponding questions.
This graph shows the electrical activity for one of the heart's
Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
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14
Use this figure to answer the corresponding questions.
Identify the location(s) where fast calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
15
Use this figure to answer the corresponding questions.
This graph shows the electrical activity for one of the heart's
Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's Use this figure to answer the corresponding questions. This graph shows the electrical activity for one of the heart's
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
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k this deck
16
Use this figure to answer the corresponding questions.
Identify the location(s) where fast calcium channels are open.
Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open. Use this figure to answer the corresponding questions. Identify the location(s) where fast calcium channels are open.
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
17
Use this figure to answer the corresponding questions.
Which structures are closed during ventricular ejection?
Use this figure to answer the corresponding questions. Which structures are closed during ventricular ejection? Use this figure to answer the corresponding questions. Which structures are closed during ventricular ejection?
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
18
Describe the way in which high blood pressure and a defective semilunar valve can make it more difficult for the heart to pump blood into the systemic circulation and how these factors can decrease cardiac output. Include the following in your
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
19
Match between columns
Premises:
Responses:
valve
Prevents backflow of blood into the left ventricle
valve
Type of blood in a pulmonary vein
valve
Prevents valves from opening into the atria
valve
Type of blood flowing through the right AV valve
valve
Surrounds and supports the heart valves
valve
Closes when the right ventricle begins systole
valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
chordae tendineae
Prevents backflow of blood into the left ventricle
chordae tendineae
Type of blood in a pulmonary vein
chordae tendineae
Prevents valves from opening into the atria
chordae tendineae
Type of blood flowing through the right AV valve
chordae tendineae
Surrounds and supports the heart valves
chordae tendineae
Closes when the right ventricle begins systole
chordae tendineae
Prevents blood from leaving the left ventricle during isovolumetric contraction
bicuspid valve and mitral valve
Prevents backflow of blood into the left ventricle
bicuspid valve and mitral valve
Type of blood in a pulmonary vein
bicuspid valve and mitral valve
Prevents valves from opening into the atria
bicuspid valve and mitral valve
Type of blood flowing through the right AV valve
bicuspid valve and mitral valve
Surrounds and supports the heart valves
bicuspid valve and mitral valve
Closes when the right ventricle begins systole
bicuspid valve and mitral valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
fibrous skeleton
Prevents backflow of blood into the left ventricle
fibrous skeleton
Type of blood in a pulmonary vein
fibrous skeleton
Prevents valves from opening into the atria
fibrous skeleton
Type of blood flowing through the right AV valve
fibrous skeleton
Surrounds and supports the heart valves
fibrous skeleton
Closes when the right ventricle begins systole
fibrous skeleton
Prevents blood from leaving the left ventricle during isovolumetric contraction
oxygenated blood
Prevents backflow of blood into the left ventricle
oxygenated blood
Type of blood in a pulmonary vein
oxygenated blood
Prevents valves from opening into the atria
oxygenated blood
Type of blood flowing through the right AV valve
oxygenated blood
Surrounds and supports the heart valves
oxygenated blood
Closes when the right ventricle begins systole
oxygenated blood
Prevents blood from leaving the left ventricle during isovolumetric contraction
deoxygenated blood
Prevents backflow of blood into the left ventricle
deoxygenated blood
Type of blood in a pulmonary vein
deoxygenated blood
Prevents valves from opening into the atria
deoxygenated blood
Type of blood flowing through the right AV valve
deoxygenated blood
Surrounds and supports the heart valves
deoxygenated blood
Closes when the right ventricle begins systole
deoxygenated blood
Prevents blood from leaving the left ventricle during isovolumetric contraction
bicuspid valve, mitral valve, and aortic valve
Prevents backflow of blood into the left ventricle
bicuspid valve, mitral valve, and aortic valve
Type of blood in a pulmonary vein
bicuspid valve, mitral valve, and aortic valve
Prevents valves from opening into the atria
bicuspid valve, mitral valve, and aortic valve
Type of blood flowing through the right AV valve
bicuspid valve, mitral valve, and aortic valve
Surrounds and supports the heart valves
bicuspid valve, mitral valve, and aortic valve
Closes when the right ventricle begins systole
bicuspid valve, mitral valve, and aortic valve
Prevents blood from leaving the left ventricle during isovolumetric contraction
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
20
Match between columns
Premises:
Responses:
embolus
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
embolus
Referred cardiac pain
embolus
Freely floating clot
embolus
Abnormal clot attached to a vessel wall
angina pectoris
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
angina pectoris
Referred cardiac pain
angina pectoris
Freely floating clot
angina pectoris
Abnormal clot attached to a vessel wall
thrombus
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
thrombus
Referred cardiac pain
thrombus
Freely floating clot
thrombus
Abnormal clot attached to a vessel wall
atherosclerosis
Consists of abnormal smooth muscle cells, cholesterol deposits, scar tissue, and possible calcium deposits plaque
atherosclerosis
Referred cardiac pain
atherosclerosis
Freely floating clot
atherosclerosis
Abnormal clot attached to a vessel wall
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
Unlock Deck
k this deck
locked card icon
Unlock Deck
Unlock for access to all 20 flashcards in this deck.
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