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Transcript 
1. Cardiac Physiology
2. Circulatory System Review
Components
Heart
Blood vessels
Blood
3. Fig. 9-1, p. 242
4. Fig. 9-2b, p. 243
5. Right and Left Ventricles
Both pump same volumes at same time
Pulmonary
Low pressure
Low resistance
Systemic
High pressure
High resistance
6. Heart Wall
Inner layer
Endothelium
Middle layer
Myocardium
Cardiac muscle
Interlacing bundles spiraling around heart
Outer layer
Visceral pericardium
7.
http://www.dkimages.com/discover/previews/740/76722.
JPG
8. Cardiac Muscle Tissue
Striated
Sarcomeres
Thick and thin filaments like skeletal muscle
T-tubules
No lateral sacs/triads
Mitochondria
Myoglobin
Intercalcalated discs
Desmosome
Gap junction
9. Fig. 9-5, p. 246
10. Functional Syncytia
Atria – functional syncytium
Ventricles – functional synctium
Atrial cells do no connect with ventricular cells
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Atria and ventricles separated by
nonconducting layer of fibrous connective
tissue
Atrial depolarization and contraction separate
from ventricular depolarization and
contraction
Conduction system provides synchronization
11. Electrical Activity
Contractile cells
Autorhythmic cells
Initiate and conduct AP
Don’t “rest”
Pacemaker potential
12. Fig. 9-6, p. 247
13. Locations
Sinoatrial node
Atrioventricular node
Bundle of His (atrioventricular bundle)
Left and right bundle branches
Purkinje fibers
14. Fig. 9-7, p. 247
15. Fig. 9-8ab, p. 248
16. Fig. 9-8cd, p. 248
17. Coordination
Atrial excitation/contraction needs to be
finished before ventricular contraction takes
place
Each chamber must contract as a unit
Each pair of atria and each pair of ventricles
should contract simultaneously
18. Fig. 9-9, p. 250
19. Action Potential of Cardiac Cells
Resting potential = -90mV
Threshold = -70mV
20. Fig. 9-10, p. 251
21. Fig. 9-11, p. 251
22. Refractory Period
250msec
Prevents tetanus
23. Electrocardiography
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Composite of all APs generated by nodal and
contractile cells
24. Fig. 9-13a, p. 253
25. Fig. 9-13b, p. 253
26. Fig. 9-14, p. 254
27. EKG - Intervals
PQ interval (PR)
Start of atrial excitation to
start of ventricular excitation
ST segment
Depolarization of entire ventricular
myocardium
QT interval
Start of ventricular depolarization through
repolarization
28.
29.
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articleid=100685
30.
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31.
32.
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es/ECG/ECGresource27.jpg
http://www.anaesthesiauk.com/article.aspx?
articleid=100685
33.
http://library.med.utah.edu/kw/ecg/mml/ec
g_v_fib.html
34. Mechanical Physiology
Systole
Period of contraction
Diastole
Period of relaxation
Cardiac cycle
Atrial systole + atrial diastole +
ventricular systole + ventricular diastole
Heart beat
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35. Summary
Blood flows from region of higher pressure
to region of lower pressure
Pressure changes due to alternating
contraction and relaxation of myocardium
Pressure changes control opening and
closing of valves
36. Early Ventricular Diastole - Fig. 9-16, pg. 256
EKG –
Atria
AV valves
SL valves
Ventricular volume
Ventricular pressure
37. Late Ventricular Diastole - Fig. 9-16, pg. 256
EKG –
Atria
AV valves
SL valves
Ventricular volume
Ventricular pressure
38. End of Ventricular Diastole
Ventricle at maximum volume
End-diastolic volume (EDV)
~135ml
39. Ventricular Excitation
EKG – QRS complex
Onset of ventricular systole
Increased ventricular contraction
of AV valves
closing
40. Isovolumetric Contraction - Fig. 9-16, pg. 256
EKG –
Atria in
AV valves
SL valves
Ventricular volume
Ventricular pressure
41. Ventricular Ejection - Fig. 9-16, pg. 256
EKG –
Atria in
AV valves
SL valves
Ventricular volume
Ventricular pressure
42. End of Ventricular Systole
End-systolic volume
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Amount of blood remaining in ventricle
at end of systole (ESV)
~65ml
Stroke volume
Amount of blood pumped out of each
ventricle during each contraction (SV)
SV = EDV - ESV
43. Isovolumetric Relaxation - Fig. 9-16, pg. 256
EKG –
Atria in
AV valves
SL valves
Ventricular volume
Ventricular pressure
44. Fig. 9-16, pg. 256
45. Fig. 9-16, pg. 256
46. Fig. 9-16, pg. 256
47. Fig. 9-16, pg. 256
48. Fig. 9-16, pg. 256
49. Cardiac Output
Cardiac output (CO)
CO = HR x SV
~5 liters/minute
Cardiac reserve
50. Regulation of Cardiac Output
Heart rate (HR)
Stroke volume (SV)
51. Regulation of Stroke Volume
Stroke volume is difference between EDV
and end systolic volume (ESV)
SV = EDV -ESV
Typically ~60% of blood in ventricle is
pumped out when ventricle contracts
Factors affecting SV
Preload
Contractility
Afterload
52. Preload
Degree of stretch of heart muscle
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Resting cardiac muscles cells are less than
optimum length
Increased venous return
Increased ED
Increased SV
53. Frank-Starling Law - Fig. 9-20, pg. 262
54. Contractility - Fig. 9-22, pg. 263
Strength of contraction given any EDV
Increased contractility leads to increased
ejection fraction
Due to increased Ca2+
55. Afterload
Back pressure exerted by arterial blood
80mmHg/8mmHg
Not usually a major determinant of stroke
volume
56. Control of Stroke Volume
Intrinsic control
Venous return
Increased return results in increased SV
Extrinsic control
Degree of sympathetic stimulation
Increased epinephrine and
norepinephrine results in increased
calcium influx and greater cross-bridge
cycling
Shifts Starling curve to left
Also enhances venous return
57. Fig. 9-22, pg. 263
58. http://www.thiemeconnect.com/bilder/srccm/200103/srm00083.01
59. Heart Rate
Intrinsic rate set by SA node
Autonomic influences
Parasympathetic
Atrium
SA node
AV node
Sparse in ventricles
Sympathetic
All of the above + rich innervation of
the ventricles
60. ANS Influence on Heart Rate
Parasympathetic
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Decrease rate of depolarization of SA
Increases AV delay
Little effect of ventricular contraction
Sympathetic
Increase rate of depolarization of SA
Decrease AV delay
Speed transmission of AP through
conduction pathway
Increased contractile strength
61. Fig. 9-18, pg. 260
62. Fig. 9-19, pg. 261
63. Table 9-3, pg. 260
64. Heart Failure
Inability of cardiac output to meet demands
for oxygen/nutrient delivery and removal of
wastes
Decrease in contractility
65. Fig. 9-24, pg. 264
66. Compensatory Mechanisms
Sympathetic stimulation
Increased salt and water retention by the
kidneys
Decompensated heart failure
Cardiac muscle cells stretched
Congestive heart failure
Backup of blood in venous system
67. Fig. 9-24, pg. 264
68. Heart Failure
Causes
Damage to heart muscle
Prolonged pumping against elevated BP
69. Coronary Artery Disease (CAD)
Coronary Circulation
Endothelium impermeable
Myocardium too thick for diffusion
Receives blood during diastole
Blood flow adjusted to match heart’s
requirements
CAD
Pathology in coronary arteries
Insufficient flow in times of need
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Myocardium too thick for diffusion
Receives blood during diastole
Blood flow adjusted to match heart’s
requirements
CAD
Pathology in coronary arteries
Insufficient flow in times of need
70. CAD
Myocardial ischemia/myocardial infarction
Vascular spasm
Cold, exertion, anxiety
Atherosclerotic plaques
Thromoboembolism
71. Atherosclerosis
Plaque
Under vessel lining
Lipid core
Smooth muscle
Connective tissue
Formation
Injury
Inflammatory resonse
Cholesterol, free radicals, high blood
pressure, homocysteine, bacteria,
viruses
72. Atherosclerosis
Accumulation of low-density lipoprotein
(LDL)
Endothelial cells release chemicals that
attract monocytes
Macrophages phagocytize LDL
Smooth muscle forms atheromas
73. Atherosclerosis
Plaque bulges into lumen of vessel
Damaged vessels unable to dilate normally
Plaque inhibits diffusion – fibroblasts
Ca2+ deposited into plaque
74. Fig. 9-25a, p. 266
75. Complications
Angina pectoris
Myocardial infarction
Thromboembolism
Thrombus
Embolus
76. Fig. 9-26ab, p. 267
77.
Fig. 9-27, p. 268
78. Table 9-4, p. 269
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