Vasodilatation

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Vasodilation refers to the widening of blood vessels resulting from relaxation of smooth muscle cells within the vessel walls, particularly in the large arteries, arterioles and veins. The process is essentially the opposite of vasoconstriction, or the narrowing of blood vessels. When vessels dilate, the flow of blood is increased due to a decrease in vascular resistance. Therefore, dilation of arterial blood vessels (mainly arterioles) leads to a decrease in blood pressure. The response may be intrinsic (due to local processes) or extrinsic (due to hormones or the nervous system), as well organ specific or systemic. Factors that result in vasodilation are simply termed vasodilators.

Contents

Function

Vasodilation directly affects the relationship between mean arterial pressure and cardiac output and total peripheral resistance (TPR). Mathematically, cardiac output is computed by multiplying the heart rate (in beats/minute) and the stroke volume (the volume of blood ejected during systole). TPR depends on several factors including the length of the vessel, the viscosity of blood (determined by hematocrit), and the diameter of the blood vessel. The latter is the most important variable in determining resistance. An increase in either of these physiological components (cardiac output or TPR) cause a rise in the mean arterial pressure. Vasodilators work to decrease TPR and blood pressure through relaxation of smooth muscle cells in the tunica media layer of large arteries and smaller arterioles.[1]

Vasodilation occurs in superficial blood vessels of warm-blooded animals when their ambient environment is hot; this process diverts the flow of heated blood to the skin of the animal, where heat can be more easily released into the atmosphere. The opposite physiological process is vasoconstriction. These processes are naturally modulated by local paracrine agents from endothelial cells (e.g nitric oxide, bradykinin, potassium ions and adenosine), as well as an organism's Autonomic Nervous System and adrenal glands, both of which secrete catecholamines such as norepinephrine and epinephrine, respectively.

Examples and individual mechanisms

Vasodilation is a result of relaxation in smooth muscle surrounding the blood vessels. This relaxation, in turn, relies on removing the stimulus for contraction, which depends predominately on intracellular calcium ion concentrations and phosphorylation of myosin light chain (MLC). Thus, vasodilation mainly works either by lowering intracellular calcium concentration or dephosphorylation of MLC. This includes stimulation of myosin light chain phosphatase and induction of calcium symporters and antiporters that pump calcium ions out of the intracellular compartment. This is accomplished through reuptake of ions into the sarcoplasmic reticulum via exchangers and expulsion across the plasma membrane. [2] There are three main stimuli that can result in the vasodilation of blood vessels, the specific mechanisms to accomplish these effects varying from vasodilator to vasodilator.

  1. Hyperpolarization-Mediated: Changes in the resting membrane potential of the cell affects the level of intracellular calcium through modulation of voltage sensitive calcium channels in the plasma membrane.
  2. cAMP-Mediated: Adrenergic stimulation results in elevated levels of cAMP and protein kinase A, which results in elevating calcium removal from the cytoplasm
  3. cGMP-Mediated: Endothelium-derived relaxing factor (also known as nitric oxide), a potent vasodilator, operates through this mechanism through stimulation of protein kinase G.

Compounds that mediate the above mechanisms may be grouped as endogenous and exogenous.

Endogenous

Vasodilators [3] Receptor
(↑ = opens. ↓ = closes) [3]		 Transduction
(↑ = increases. ↓ = decreases) [3]
EDHF  ? hyperpolarization --> ↓VDCC --> ↓intracellular Ca2+
depolarization Voltage-gated K+ channel
interstitial K+ directly
nitric oxide NO receptor cGMP --> ↑PKG activity -->
  • phosphorylation of MLCK --> ↓MLCK activity --> dephosphorylation of MLC
  • SERCA --> ↓intracellular Ca2+
β2 adrenergic agonists β-2 adrenergic receptor Gs activity --> ↑AC activity --> ↑cAMP --> ↑PKA activity --> phosphorylation of MLCK --> ↓MLCK activity --> dephosphorylation of MLC
histamine Histamine H1 receptor
prostacyclin IP receptor
Prostaglandin D2 DP receptor
Prostaglandin E2 EP receptor
VIP VIP receptor Gs activity --> ↑AC activity --> ↑cAMP --> ↑PKA activity -->
(extracellular) adenosine A1, A2a and A2b adenosine receptors ATP-sensitive K+ channel --> hyperpolarization --> close VDCC --> ↓intracellular Ca2+
  • (extracellular) ATP
  • (extracellular) ADP
 P2Y receptor activate Gq --> ↑PLC activity --> ↑intracellular Ca2+ --> ↑NOS activity --> ↑NO --> (see nitric oxide)
L-Arginine imidazoline and α-2 receptor? Gi --> ↓cAMP --> activation of Na+/K+-ATPase[4] --> ↓intracellular Na2+ --> ↑Na+/Ca2+ exchanger activity --> ↓intracellular Ca2+
Bradykinin Bradykinin receptor
Substance P
Niacin (nicotinic acid)
Platelet activating factor (PAF)
CO2 - interstitial pH --> ?[5]
(probably) interstitial lactic acid -
muscle work -

Exogenous vasodilators

Therapeutic uses

Vasodilators are used to treat conditions such as hypertension, where the patient has an abnormally high blood pressure, as well as angina and congestive heart failure, where maintaining a lower blood pressure reduces the patient's risk of developing other cardiac problems.[6] Flushing may be a physiological response to vasodilators.

References

  1. ^ CVPharmacology
  2. ^ American Physiological Society
  3. ^ a b c Unless else specified in box, then ref is: Walter F., PhD. Boron. Medical Physiology: A Cellular And Molecular Approaoch. Elsevier/Saunders. ISBN 1-4160-2328-3.  Page 479
  4. ^ Regulation of Na+-K+-ATPase by cAMP-dependent protein kinase anchored on membrane via its anchoring protein Kinji Kurihara, Nobuo Nakanishi, and Takao Ueha. Departments of 1 Oral Physiology and 2 Biochemistry, School of Dentistry, Meikai University, Sakado, Saitama 350-0283, Japan
  5. ^ Modin A, Björne H, Herulf M, Alving K, Weitzberg E, Lundberg JO (2001). "Nitrite-derived nitric oxide: a possible mediator of 'acidic-metabolic' vasodilation". Acta Physiol. Scand. 171 (1): 9–16. doi:10.1046/j.1365-201x.2001.171001009.x. PMID 11350258. 
  6. ^ CVPharmacology
v  d  e
Major drug groups
Gastrointestinal tract/metabolism (A)
Blood and blood forming organs (B)
Cardiovascular system (C)
Skin (D)
Reproductive system (G)
Endocrine system (H)
Infections and infestations (J, P)
Malignant disease (L01-L02)
Immune disease (L03-L04)
Muscles, bones, and joints (M)
Brain and nervous system (N)
Respiratory system (R)
Other ATC (V)
v  d  e
Vasodilators used in cardiac diseases (C01D)
Nitrates/nitrovasodilators
Quinolone vasodilators
Others
v  d  e
Peripheral vasodilators (C04)
Imidazoline derivatives/
Alpha blockers
Niacin and derivatives
Purine derivatives
Ergot alkaloids
Other peripheral vasodilators
v  d  e
Cardiovascular system, physiology: cardiovascular physiology
Volumes
Interactions
Tropism
Hemodynamics
Other

Wikipedia content modification information:

  • This page was last modified on 12 October 2008, at 01:27.

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