1. Control �of �Cardiac Output
2. Reading Klabunde, Cardiovascular Physiology Concepts
Chapter 4 (Cardiac Function)
3. Basic Theory of �Circulatory Function The blood flow to each tissue of the body is almost always precisely controlled in relation to the tissue needs
The cardiac output is controlled mainly by the sum of all the local tissue flows
Frank-Starling Relationship is the predominant factor in matching venous return and cardiac output
In general, the arterial pressure is controlled independently of either local blood flow or cardiac output control
4. Definitions Cardiac Output
The quantity of blood pumped into the aorta each minute
Venous Return
The quantity of blood flowing from the veins into the right atrium each minute
5. Cardiac Output CO = HR x SV
SV = EDV – ESV
7. Determinants of Cardiac Output
9. Heart Rate
10. Heart Rate Changes in heart rate are generally more important quantitatively in producing changes in cardiac output than are changes in stroke volume
Changes in heart rate alone inversely affect stroke volume
11. Heart Rate At low HR
Increase in HR is greater than decrement in SV
At high HR
The decrease in SV is greater than the increase in HR (decreased filling time)
12. Effects of Heart Rate �on Cardiac Output
13. Bowditch (Treppe) Effect An increase in heart rate will also cause positive inotropy (Bowditch effect, Treppe or “staircase” phenomenon).
This is due to an increase in intracellular Ca++ with a higher heart rate:
More depolarizations per minute
Inability of Na+/K+-ATPase to keep up with influx of Na+, thus, the Na+-Ca++ exchange pump doesn’t function as well
14. Factors Affecting �Stroke Volume
16. Preload
17. Preload Preload can be defined as the initial stretching of the cardiac myocytes prior to contraction. It is related to the sarcomere length at the end of diastole.
Because we cannot measure sarcomere length directly, we must use indirect indices of preload.
LVEDV (left ventricular end-diastolic volume)
LVEDP (left ventricular end-diastolic pressure)
PCWP (pulmonary capillary wedge pressure)
CVP (central venous pressure)
18. Determinants of Preload Venous Blood Pressure
Venomotor tone (Venous compliance)
Venous volume
Venous Return
Total Blood Volume
Respiration
Exercise/Muscle contraction
Gravity
Filling time (Heart rate)
Ventricular compliance
Atrial contraction
Inflow or outflow resistance
Ventricular systolic failure
19. Frank-Starling Mechanism
20. Frank-Starling Mechanism When venous return to the heart is increased, ventricular filling increases, as does preload. This stretching of the myocytes causes an increase in force generation, which enables the heart to eject the additional venous return and thereby increase stroke volume.
Simply stated: The heart pumps the blood that is returned to it
21. Frank-Starling Mechanism Allows the heart to readily adapt to changes in venous return.
The Frank-Starling Mechanism plays an important role in balancing the output of the 2 ventricles.
In summary: Increasing venous return and ventricular preload leads to an increase in stroke volume.
22. Frank-Starling Mechanism
23. Frank-Starling Relationship
24. Frank-Starling Mechanism There is no single Frank-Starling Curve for the ventricle. Instead, there is a family of curves with each curve defined by the existing conditions of afterload and inotropy.
25. Frank-Starling Curves
26. Afterload
27. Afterload Afterload can be viewed as the "load" that the heart must eject blood against.
In simple terms, the afterload is closely related to the aortic pressure.
28. Afterload More precisely defined in terms of ventricular wall stress:
LaPlace’s Law: Wall stress = Pr/h
P = ventricular pressure
R = ventricular radius
h = wall thickness
29. Afterload is better defined �in relation to ventricular wall stress LaPlace’s Law
30. Afterload Afterload is increased by:
Increased aortic pressure
Increased systemic vascular resistance
Aortic valve stenosis
Ventricular dilation
31. Effects of Afterload
32. Anrep Effect An abrupt increase in afterload can cause a modest increase in inotropy.
The mechanism of the Anrep Effect is not fully understood.
33. Contractility
34. Contractility The inherent capacity of the myocardium to contract independently of changes in afterload or preload.
Changes in contractility are caused by intrinsic cellular mechanisms that regulate the interaction between actin and myosin independent of sarcomere length.
Alternate name is inotropy.
35. Contractility Force of contraction
Increased rate and/or quantity of Calcium delivered to myofilaments during contraction
Heart functions at lower end-systolic volume and lower end-diastolic volume
37. Factors Regulating Inotropy
38. Ancillary Factors
39. Ancillary Factors Affect the Venous System and Cardiac Output Gravity
Venous pooling may significantly reduce CO
Muscular Activity and Venous Valves
Respiratory Activity
40. Effects of Gravity on the �Venous System and Cardiac Output Gravity
Venous pooling may significantly reduce CO
41. Muscular Activity and Venous Valves
42. Effects of Respiration Spontaneous respiration
Decreased intra-thoracic pressure results in a decreased right atrial pressure which enhances venous return
Mechanical ventilation
Increased intra-thoracic pressure during positive-pressure lung inflation causes increased right atrial pressure which decreases venous return
Valsalva Maneuver
Causes a large increase in intra-thoracic pressure which impedes venous return to the right atrium
43. Summary of Factors �That Influence �Cardiac Output �and �Mean Arterial Pressure
45. Myocardial Oxygen Consumption
46. Myocardial Oxygen Consumption Oxygen consumption is defined as the volume of oxygen consumed per minute (usually expressed per 100 grams of tissue weight)
47. Myocardial Oxygen Demand �is Related to Wall Stress LaPlace’s Law
48. Factors Increasing �Myocardial Oxygen Consumption
Increased Heart Rate
Increased Inotropy (Contractility)
Increased Afterload
Increased Preload
Changes in preload affect myocardial oxygen consumption less than do changes in the other factors
49. The End
