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Flashcards in cardio-physio-Cardiac electrophysiology Deck (149)
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1
Q

The conduction system of the heart is mainly made up of nerves/ specialized cardiac myocytes.

A

specialized cardiac myocytes

(SA node, AV node, Bundle of His, right and left branch bundles, left aortic fascicle, left posterior fascicle, Purkinje fibers

2
Q

Which specialized cardiomyocytes are associated with the right atrium?

A

The SA node and AV node

3
Q

Which specialized cardiomyocytes are associated with the left atrium?

A

Bachmann bundle

4
Q

What is the intrinsic firing rate of the SA node?

A

70-80 BPM

5
Q

What is the intrinsic firing rate of AV node?

A

40-60 BPM

6
Q

What is the heart’s natural pacemaker?

A

SA node, I f (funny) Na+ channels

7
Q

What is the intrinsic firing rate of the Bundle of His?

A

40

8
Q

What is the intrinsic firing rate of Purkinje fibers?

A

15-20

9
Q

Which 2 phases of the action potential do not exist in the SA node?

A

1 and 2

10
Q

Explain how the SA node membrane potential works in phase 4?

A

Phase 4 contains a drift in depolarizing membrane potential (Na+ and K+)

-the Na+ channels are funny in that they open up during phase 3, as the cells are repolarizing

11
Q

What happens at the threshold point and Phase 0 of the SA node action potential?

A

Mainly the Ca2+ channels are opened up

12
Q

What happens at the threshold point and Phase 3 of the SA node action potential?

A

K+ is the driving force of the repolarization phase (phase 3).

13
Q

There are/are not fast Na+ channels in the SA node?

A

are not

14
Q

What are the 2 types of calcium channels in the SA node cells?

A

T-type (transient- Ca2+ slowly trickles in during phase 4)

and L-type (Ca2+ drives membrane potential to depolarize)

15
Q

What is the name of the Na+ “funny” channels?

A

HCN channels - cause slight depolarizing drift in phase 4 of SA node

16
Q

Does the parasympathetic system have any effect on the contractility of the heart?

A

No, the vagus nerve does not reach branches that go down to the ventricles

17
Q

Which specialized cardiomyocytes are innervated by the sympathetic as well as parasympathetic nervous system?

A

The SA and AV nodes

18
Q

What three things are needed to determine stroke volume?

A
19
Q

What does ionotropic mean?

A

any effect on the contractility of the heart

positive ionotropic = increase contractility

negative ionotropic = decreased contractililty

20
Q

What is a dromotropic effect?

A

Affecting the conduction velocity of the heart, positive or negative

21
Q

What are chronotropic effects?

A

Affects the HR

positive = speed up HR

negative = slow down HR

22
Q

What effect does the sympathetic system have on the chronotropic, dromotropic, and ionotropic effects on the heart?

A

increase action of all three, acts on the B1 receptor, activates Ca2+ current channels, and phosphorylates phospholamban

23
Q

What effec does the parasympathetic system have on HR, what receptor does it act upon, and what ions are invovled?

A

Decreased HR, M2 receptor, and decrease or close Na+ funny channels (current), enhance Ach-K+ current, and decrease movement of Ca2+ into cells

24
Q

What effect does the parasympathetic system have on conduction velocity (dromotropic effect), what receptor does it act upon, and what ions are invovled?

A

Decrease conduction velocity, M2 receptor, decrease action of Ca2+ current and increase K+ current

25
Q

What effec does the parasympathetic system have on heart contractility, what receptor does it act upon, and what ions are invovled?

A

Decrease contractility (in atria only), M2 receptor, decrease Ca2+ current and increase K+ current

26
Q

What are the effects of Ach, adenosine, and B-blockers on the HR?

A

Decrease HR

27
Q

What effect do catecholomines have on HR?

A

increases it

28
Q

Which ANS component causes the following effects on the SA node:

steeper phase 4 - reach membrane potential faster

A

sympathetic ANS

29
Q

What happens to the phase 4 curve of the SA node action potential when stimulated parasympathetically?

A

the slope becomes less steep

30
Q

What happens to the membrane potential during parasympathetic stimulation?

A

becomes more negative, hyperpolarization

31
Q

What causes the hyperpolarazation of the action potential during parasympathetic stimulation (by Ach)?

A

The stimulation of K-Ach channels on the cell membrane (enhance efflux of K+ from cell)

32
Q

What is a dipole?

A

separation of charge, it is also a vector- with direction and magnitude

33
Q

The ECG shows the electrical activity of what?

A

the atria and ventricles (mainly the ventricles)

34
Q

What corresponds to the time it takes for the electrical impulse to travel from SA node, through AV node, to the start of ventricular depolarizaton?

A

The PR interval

35
Q

What is the normal range for the PR interval?

A

0.12-0.20 seconds (3 to 5 small boxes)

36
Q

What is an example of a pathology with abnormal PR intervals (

A

First-degree AV block

37
Q

Which part of the ECG corresponds with venticular depolarization and what is the normal range?

A

The QRS complex, < or equal to 0.10 sec (around 2.5 sec)

38
Q

A QRS complex longer than 0.10 sec could indicate what?

A

Delayed condcution within bundle branches or later branches or delayed conductin outside conduction pathways - ventricular tachycardia

39
Q

What part of the ECG corresponds to the mechanical contracton of the ventricles?

A

The QT interval

40
Q

What pathology is associated with an abnormal QT interval?

A

Long QT syndrome -inherited or acquired

41
Q

Which type of pathology is indicated in the following:

progressive prolongation of the PR interval and eventual failure of P wave to conduct to ventricle

A
42
Q

What is the pathology? Several P waves for every QRS

A
43
Q

What is the pathology? QRS complexes unrelated to P waves

A
44
Q
A
45
Q

Which ECG leads are bipolar?

A

I,II,III

46
Q

Which leads are precordial unipolar?

A

V1-V6

47
Q

Which bipolar lead is described below?

• left arm (+) to right arm (−) = (angle of view 0°);

A

Lead I

48
Q

Which bipolar lead is described below?

left leg (+) to right arm (−) = (angle of view +60°);

A

Lead II

49
Q

Which lead is described below?

• left leg (+) to left arm (−) = angle of view +120°

A

lead III

50
Q

What are the uniploar limb leads?

A

aVL, aVF, aVR

51
Q

Study the diagram

A
52
Q

What is the direction of the QRS complex in lead I?

A

Up

53
Q

What does the T wave represent on the ECG?

A

ventricular repolarization

54
Q

Study this diagram

A
55
Q

What are the heart rate intervals with the 300 rule?

A
56
Q

3 types of capillaries?

A
  1. Continuous
  2. Fenestrated
  3. Discontinuos
57
Q

This is the most common form of capillary, with interendothelial junctions 10 to 15 nm wide (e.g., skeletal muscle). However, these clefts are absent in the bloodbrain barrier, whose capillaries have narrow tight junctions

A

Continuous capillary

58
Q

In these capillaries, the endothelial cells are thin and perforated with fenestrations. These capillaries most often surround epithelia (e.g., small intestine, exocrine glands).

A

Fenestrated

59
Q

In addition to fenestrae, these capillaries have large gaps. Discontinuous capillaries are found in sinusoids (e.g., liver)

A

. Discontinuous capillary.

60
Q

Which type of flow tends to fluctuate: increase and decrease every ~ 15 sec (vasomotion)?

A

Capillary

61
Q

Vasomotion (fluctuating capillary flow), can for a while in “closed” capillaries.

A

stop

62
Q

Which 3 criteria allow for sufficient surface area and enough time for efficient exchange of gases, water, nutrients, and waste products.

A
  1. Decreased blood pressure
  2. Increased exchange surface area
  3. Decreased blood velocity
63
Q

Although diastolic and mean arterial pressures are relatively constant, systolic pressure may be up to mmHg higher in the brachial artery than in the aorta

A

40 mmHg

64
Q

What phenomonen arises principally because of an increase in arterial stiffness moving away from the heart?

A

Systolic pressure amplification

65
Q

The peripheral resistance is increased by vasodilation/vasoconstriction?

A

vasoconstriction

66
Q

What are the mechanisms promoting an increase in peripheral resistance?

A

Endocrine and neuronal

67
Q

What endocrine system hormones are released to increase peripheral resistance?

A

epinephrine

norepinephrine

angiotensin-II

renin

68
Q

What endocrine system process occurs to decrease peripheral resistance?

A

decreased renin secretion

69
Q

Describe neural controlled differences that occur during vasoconstricion and vasodilation to increase or decrease peripheral resistance?

A
  1. Increased sympathetic activity for increased peripheral resistance
  2. increased parasympathetic and decreased sympathetic activity to promote vasodilation to decrease peripheral resistance
70
Q

What are the two main families of receptors of the sympathetic nervous system?

A

α and β

71
Q

Two main families of receptors of the sympathetic nervous system, designated α and β, are classified based on response to the adrenergic agonists epinephrine, norepinephrine, and .

A

isoproterenol

72
Q

Alterations in the structure of the receptors influence their affinity for various agents.

A

primary

73
Q

What are the major effects mediated by a1 adrenoreceptors?

A
74
Q

What are the major effects mediated by a2 adrenoreceptors?

A
75
Q

What are the major effects mediated by B1 adrenoreceptors?

A
76
Q

What are the major effects mediated by B2 adrenoreceptors?

A
77
Q

is a medication used for the treatment of bradycardia (slow heart rate), heart block, and rarely for asthma.

A

isoproterenol

78
Q

Isoproterenol is a β adrenoreceptor agonist that is the isopropylamine analog of epinephrine (adrenaline).

A

non-selective

79
Q

Vasoconstriction evoked by the sympathetic nerve activity is caused by the local release of .

A

Norepinephrine

80
Q

Intra-arterially injected elicits only vasoconstriction (α1-adrenergic receptor).

A

norepinephrine

81
Q

Low doses of epinephrine produce (β2- adrenergic receptor), whereas large doses cause .

A

vasodilation; vasoconstriction

82
Q

What is the distending force that tends to increase the circumference of the vessel?

A

The transmural pressure (ΔP)

83
Q

Which law describes how tension in the vessel wall increases with transmural pressure?

A

Laplace’s law

84
Q

According to LaPlace’s law, for a given internal fluid pressure, the wall tension will be to the radius of the vessel.

A

proportional

85
Q

It is convenient to express this wall tension (T) as the force that must be applied to bring together the two edges of an imaginary , of unit length L, cut in the wall along the longitudinal axis of the vessel.

A

slit

86
Q

Larger/smaller arteries must have stronger walls since an artery of twice the radius must be able to withstand twice the wall tension

A

Larger

87
Q

The tiny capillaries rely on their size to protect them from wall tension.

A

small

88
Q

vesicles form when the plasma membrane invaginates and pinches off to capture and internalize an extracellular fluid sample. The vesicles then migrate across the vessel wall and release their contents on the opposite side.

A

Pinocytosis

89
Q

Which transportation mechanism is not a major pathway for exchange, but it does provide for transit of large, charged molecules such as antibodies?

A

Pinocytosis

90
Q

Blood entering capillaries is pressurized, so pathways allow water and anything dissolved in it (e.g. electrolytes) to be driven out of the vasculature and into the interstitium. This of fluid is not completely unregulated, however. Intercellular junctions typically contain a proteinaceous barrier that both cements cells together and filters fluid as it leaves the blood. Proteins are too large to escape via junctions or pores and remain trapped within the vasculature.

A

bulk flow

91
Q

What type of transportation mechanism is from the capillary via junctions and fenestrations and is driven by blood pressure (P)?

A

Bulk flow

92
Q

The same pathways that allow for bulk flow also provide pathways for of water and other small molecules via fenestrations and pores.

A

simple diffusion - Movement is driven by chemical concentration gradients between blood, interstitium, and cells.

93
Q

Lipid-soluble materials cross between blood and interstitium by simple diffusion across cells and their plasma membranes. This is the primary means by which O2 and CO2 are exchanged.

A

endothelial

94
Q

Which of the following mechanisms is most important quantitatively for the exchange of electrolytes across capillaries?

A) Bulk flow B) Diffusion C) Osmosis D) Vesicular transport

A

The correct answer is “a” because this is the mechanism by which fluid and accompanying electrolytes move through capillary intercellular junctions. Choice “b” is incorrect because diffusion, although an important mechanism of exchange, is quantitatively less important than bulk flow. Furthermore, electrolytes are charged ions and therefore do not diffuse through membrane lipid bilayers. Choice “c” is incorrect because osmosis concerns the movement of water. Choice “d” is incorrect because vesicular transport is primarily for the transport of large macromolecules.

95
Q

Since virtually the entire capillary surface is available for diffusion, the permeability is extremely high/low.

A

high

96
Q

Respiratory gases, general anaesthetics and the blood flow tracer xenon are examples of what type of solute?

A

lipophlic

97
Q

Describe simple diffusion as it relates to lipid soluble molecules and gases, water soluble molecules, and proteins:

A
98
Q

Fluid movement between the blood vessels and tissues depends on two driving forces:

A
  • Hydrostatic (blood) pressure
  • Osmotic (oncotic) pressure
99
Q

The Starling forces (hydrostatic and oncotic pressures) allow for of fluid and nutrients across the capillary wall.

A

bulk flow

100
Q

Hydrostatic vs osmotic pressures

A

Hydrostatic “pushes” fluid across boundary while osmotic pressure “pulls” fluid across boundary

101
Q

Fluid transfer across capillaries is convective and depends on hydrostatic and osmotic forces (i.e., Starling forces).

A

net

102
Q

The net driving force formula?

A
103
Q

Blood enters capillaries at a pressure of ~35 mm Hg. Blood exits capillaries and enters veins at a pressure of ~15 mm Hg. Mean capillary hydrostatic pressure (Pc) is typically closer/farther to venous pressure than it is to arteriolar pressure but still is usually a positive pressure that drives fluid out of the capillary and into the interstitium.

Also, what type of force is being described here?

A

closer; Capillary hydrostatic pressure

104
Q

The main force opposing capillary hydrostatic pressure (Pc) is the ?

A

osmotic pressure created by plasma proteins. Values for πc typically average ~25 mm Hg.

105
Q

What happens if fluid filters from the vasculature faster than it can be removed?

A

Tissue swells

106
Q

Tissues that are enclosed within skin, bone, or another physical boundary have limited opportunity for expansion, so interstitial (Pi) climbs and can become a significant force driving fluid back into the .

A

capillary

107
Q

As part of an immune response to foreign pathogens, is produced by basophils and by mast cells found in nearby connective tissues.

A

histamine

108
Q

Histamine increases/decreases the permeability of the capillaries to white blood cells and some proteins.

A

increases

109
Q

What is the principle that water permeability of the capillary wall – depends on capillary type.

A

Kf - hydraulic conductance

110
Q

Kf - hydraulic conductance is not influenced by such factors as changes in arteriolar resistance, hypoxia, or buildup of metabolites but can be influenced by .

A

Histamine

111
Q

What is the formula for fluid movement (Jv) acros the capillary wall?

A
112
Q

Maintaining a balance between the forces governing fluid and from the vasculature is vital for continued health.

A

filtration; reabsorption

113
Q

Excess fluid filtration causes ?

A

edema

114
Q

What happens if there is an inability to recover filtered fluid?

A

Compromise LV preload and MAP

115
Q

Review diagram

A
116
Q

What arises in the interstitium as small, thin-walled channels of endothelial cells that then join together to form increasingly larger vessels?

A

Lymphatics

117
Q

What are similar to capillaries but with many interendothelial junctions that behave like one-way microvalves?

A

The initial lymphatics

118
Q

What tethers the initial lymphatics to surrounding connective tissue?

A

Anchoring filaments

119
Q

The walls of the larger/smaller collecting lymphatics are similar to those of small veins, consisting of endothelium and sparse smooth muscle.

A

larger

120
Q

The large lymphatic vessels, like the veins, have lymph valves that restrict retrograde movement of lymph.

A

secondary

121
Q

The large lymphatics ultimately drain into the left and right veins.

A

subclavian

122
Q

Although initial lymphatics may appear collapsed and show no contractile activity, a pressure gradient from the interstitial fluid to the lymphatic lumen deforms the endothelial cells so that the microvalves open and fluid enters the initial lymphatic during the phase.

A

expansion

123
Q

During this time of initial lymphatics called expansion phase, the secondary lymph valves are open/closed?

A

closed

124
Q

Movement of fluid from the interstitium into the lymphatic capillaries is driven by the pressure gradient between the interstitial space and the lymph.

A

hydrostatic

125
Q

The edges of lymphatic capillary cells overlap, acting as one-way valves; one-way flow of lymph is also maintained in lymphatic vessels.

A

endothelial; larger

126
Q

Flow is augmented by smooth muscle filaments of the lymphatics that contract when stretched.

A

collecting

127
Q

Intermittent compression and relaxation of lymphatics occur during what three processes?

A

espiration, walking, and intestinal peristalsis

128
Q

Explain lymphatic flow during the compression phase?

A
129
Q

Extracellular fluid moves in three convective loops:

A
  1. cardiovascular loop
  2. transvascular loop
  3. lymphatic loop
130
Q

What is the transvascular loop?

A

fluid moves out of the capillaries at their arteriolar end and into the capillaries at their venular end.

131
Q

Each segment of the lymph vessel between successive valves functions as a separate automatic .

A

pump- . That is, even slight filling of a segment causes it to contract, and the fluid is pumped through the next valve into the next lymphatic segment.

132
Q

What refers to the presence of excess fluid in the body tissues?

A

Edema

133
Q

In most instances, edema occurs mainly in the extracellular/intracellular fluid compartment.

A

extracellular

134
Q

What three conditions are especially prone to cause intracellular swelling:

A

1) hyponatremia (Hyponatremia is decrease in serum sodium concentration < 136 mEq/L caused by an excess of water relative to solute);
2) depression of the metabolic systems of the tissues;
3) lack of adequate nutrition to the cells.

135
Q

Extracellular fluid edema occurs when excess fluid accumulates in the extracellular spaces. There are two general causes of extracellular edema:

A

1) abnormal leakage of fluid from the plasma to the interstitial spaces across the capillaries,
2) failure of the lymphatics to return fluid from the interstitium back into the blood, often called lymphedema.

136
Q

What is the most common clinical cause of interstitial fluid accumulation?

A

excessive capillary fluid filtration.

137
Q

Fluid buildup in the body cavities is called?

A

Effusions

138
Q

What pathology describes one or both of his heart’s lower chambers lose their ability to pump blood effectively. As a result, blood can back up in their legs, ankles and feet, causing edema. Can also cause swelling in abdomen area. Sometimes, this condition can cause fluid to accumulate in lungs (pulmonary edema), which can lead to shortness of breath.

A

CHF

139
Q

Severe disease (such as cirrhosis) causes you to retain fluid. Cirrhosis also leads to high/low levels of albumin and other proteins in your blood. Fluid leaks into the abdomen and can also cause leg edema.

A

liver; low

140
Q

When you have disease, extra fluid and sodium in your circulation may cause edema.

A

kidney;

141
Q

The edema associated with kidney disease usually occurs where?

A

In your legs and around your eyes.

142
Q

Protein malnutrition called is mostly found in people living in geographical areas that have limited food resources. It’s most commonly seen in children whose diets are low in and . Delayed growth in children, a swollen belly, and frequent infections are symptoms.

A

kwashiorkor; protein; calories

143
Q

Edema can also be caused by and increase/decrease in hydraulic conductance or capillary permeability

A

increase

From possible burns, infection, toxins, that result from release of histamine and cytokines

144
Q

Which drugs work on lowering insulin resistance, which is the underlying problem for many people with type 2 diabetes?

A

Thiazolidinediones—sometimes shortened to TZDs or glitazones

145
Q

What is a potent diuretic which, if given in excessive amounts, can lead to a profound diuresis with water and electrolyte depletion. Therefore, careful medical supervision is required and dose and dose schedule must be adjusted to the individual patient’s needs.

A

LASIX® (furosemide)

146
Q

What do these drugs have in common:

A

Drugs that may cause edema

147
Q

What is a common type of drug used to treat edema?

A

Diuretics

148
Q
A

The correct answer is “c” because increased postcapillary/precapillary resistance ratio caused by arterial (precapillary) vasodilation increases capillary hydrostatic pressure and fluid filtration. Choice “a” is incorrect because a decreased capillary hydrostatic pressure decreases fluid filtration. Choice “b” is incorrect because a decreased capillary filtration constant decreases net filtration. Choice “d” is incorrect because a reduced venous pressure decreases capillary pressure and filtration.

149
Q
A