1. Local Control of Blood Flow
2. Reading Klabunde, Cardiovascular Physiology Concepts
Chapter 7 (Organ Blood Flow) pages 141-151.
3. Regulation of Peripheral Blood Flow Dual Control
Extrinsic
Primarily by the nervous system
Humorally also
Intrinsic (Locally in the tissues)
Controlled by the conditions in the immediate vicinity of the blood vessels
4. Regulation of Peripheral Blood Flow
5. Pharmacologic Stimuli that Cause Contraction or Relaxation of Vascular Smooth Muscle Catecholamines
Epinephrine
Norepinephrine
Dopamine
Endothelin
Serotonin
Angiotensin II
Vasopressin Histamine
Adenosine
Nitric Oxide (NO)
Carbon Dioxide
Potassium
Hydrogen Ion
Prostaglandins
Acetylcholine
Bradykinin
6. Intrinsic Control of �Local Blood Flow:��Metabolic Factors
7. Tissue Metabolic Activity Is the Main Factor in Acute Control of Local Blood Flow One of the most fundamental principles of circulatory function is the ability of each tissue to control its own local blood flow in proportion to its metabolic needs
Metabolic Mechanism
Any intervention that results in an inadequate oxygen (nutrient) supply for the metabolic requirements of the tissues results in the formation of vasodilator substances which increase blood flow to the tissues.
8. Acute Local Feedback Control �of Blood Flow
9. Metabolic Mechanisms Hypoxia
Tissue metabolites and ions
Adenosine
Potassium ions
Carbon dioxide
Hydrogen ion
Lactic acid
Inorganic phosphate
10. Examples of Metabolic Control �of Local Bloodflow Active Hyperemia
Reactive Hyperemia
11. Active Hyperemia
12. Reactive Hyperemia
13. Reactive Hyperemia Within limits the peak blood flow and the duration of the of the reactive hyperemia are proportional to the duration of the occlusion
14. Intrinsic Control of �Local Blood Flow:��Autoregulation
15. Autoregulation Intrinsic ability of an organ to maintain a constant blood flow despite changes in perfusion pressure
Possible explanations for Autoregulation:
Myogenic Mechanism
Metabolic Mechanism
16. Ohm’s Law
17. Cerebral Autoregulation
18. Autoregulation
19. Theories to Explain Autoregulation:�Myogenic Mechanism
When the lumen of a blood vessel is suddenly expanded, the smooth muscles respond by contracting in order to restore the vessel diameter and resistance. The converse is also true.
Vascular smooth muscle cells depolarize when stretched.
Proposed mechanism is stretch of vascular smooth muscle causes activation of membrane calcium channels.
20. Theories to Explain Autoregulation:�Myogenic Mechanism
21. Theories to Explain Autoregulation:�Metabolic Mechanism
When the pressure increases to a tissue, the flow increases, and excess oxygen and nutrients are provided to the tissues. These excess nutrients cause the blood vessels to constrict and the flow to return nearly to normal despite the increased pressure.
22. Intrinsic Control of �Local Blood Flow:��Endothelial Factors
23. The endothelium plays an active role in regulating the microcirculation Endothelium is a source of substances that elicit contraction or relaxation of the vascular smooth muscle
Vasoactive substances released from endothelium:
Nitric Oxide (NO)
Endothelium-derived relaxing factor
Prostacyclin
Endothelin
Endothelial-derived hyperpolarizing factor (EDHF)
25. Nitric Oxide
26. Nitric Oxide Generated from amino acid L-arginine
Generated from NO synthase
Increases GMP concentration which produces relaxation by decreasing cytosolic free calcium
Very short half-life (6 seconds)
Due to rapid oxidation to nitrite and nitrate
Also due to binding by substances such as hemoglobin
NO is a gas and must be delivered by an inhaled delivery system
27. Nitric Oxide NO production is stimulated by:
Shearing forces acting on the endothelium
Acetylcholine
Bradykinin
Histamine
Insulin
Substance P
28. Nitric Oxide Important functions in cardiovascular system:
Vasodilation
Inhibition of vasoconstrictor influences
Inhibition of platelet adhesion to the vascular endothelium
Inhibition of leukocyte adhesion to the vascular endothelium
Antiproliferative
Free radical scavenger
29. Nitric Oxide Systemic Effects:
Pulmonary vasodilation
Decreased pulmonary vascular resistance
Decreased pulmonary artery pressure
Pulmonary vasodilation decreases right ventricular afterload and improves right ventricular performance
Increased arterial oxygen tension
Inhaled nitric oxide is delivered only to ventilated alveoli.
This improves V/Q relations by vasodilating capillaries and improving blood flow to areas participating in gas exchange.
30. Nitric Oxide
31. Prostacyclin
32. Prostacyclin Prostacyclin synthase in endothelial cells acts on cyclo-endoperoxide products to form Prostacyclin (PGI2)
Prostacyclin (PGI2)
Strong vasodilator
Inhibits platelet adhesion to the vascular endothelium
33. Endothelin
34. Endothelin Synthesized by endothelium
Potent vasoconstrictor
Other actions:
Increased aldosterone secretion
Increased cardiac inotropy and chronotropy
Decreased renal blood flow and GFR
Releases atrial natriuretic peptide
In failing heart, contributes to calcium overload and hypertrophy
35. Endothelin Implicated in the pathogenesis of:
Hypertension
Vasospasm
Heart failure
Pulmonary hypertension
36. When Damage to Endothelium Occurs Damage to endothelial cells will lead to:
Decreased Nitric Oxide and Prostacyclin production
Increased Endothelin production
This will lead to:
Vasoconstriction
Vasospasm
Thrombosis
37. THE END
