Cardiovascular Regulation

Download Report

Transcript Cardiovascular Regulation

Cardiovascular Regulation
Exercise Physiology
McArdle, Katch, and Katch, 4th ed.
Regulation of the
Cardiovascular System
Heart Rate Regulation
Blood Flow Regulation
Heart Rate Regulation
• The heart has both intrinsic (situated within
the heart) and extrinsic (originating outside
the heart) regulation.
• Many myocardial cells have unique
potential for spontaneous electrical activity
(intrinsic rhythm).
• In normal heart, spontaneous electrical
activity is limited to special region.
• Sinoatrial node serves as pacemaker.
Intrinsic Regulation of HR
• Sino atrial node: pacemaker
Intrinsic Regulation
• Depolarization muscle membrane creates an
action potential or electrical impulse
• Impulse travels through the heart in an
established pathway
– SA node →across atria →AV node →AV
bundle →left & right bundle branches →
Purkinjie fibers → Ventricles
Normal Route of Depolarization
S-A Node

Atria

A-V Node

Bundle of His

Purkinje Fibers

Ventricles
Intrinsic Heart Rate
• SA node rate approximately 90 bpm
• Parasympathetic innervation slows rate
– referred to as parasympathetic tone
– training increases parasympathetic tone
Electrocardiogram
• The ECG is recorded by placing electrodes
on the surface of the body that are
connected to an amplifier and recorder.
• Each wave in the shape of the ECG is
related to specific electrical change in heart.
• Purposes of ECG to monitor heart rate and
diagnose rhythm.
Electrocardiogram
Each wave of ECG related to specific
electrical change in the heart
• P wave - atrial depolarization
• QRS complex - ventricular depolarization
– masks atrial repolarization
• T wave - ventricular repolarization
ECG Arrhythmias
• PACs- premature
atrial contraction
• PVCs- premature
ventricular
contraction
• Ventricular
fibrillation- cardiovert
Extrinsic Regulation of HR
• Neural Influences override intrinsic rhythm
– Sympathetic: catecholamines
• Epinephrine
• Norepinephrine
– Parasympathetic
• Acetylcholine
• Cortical Input
• Peripheral Input
Neural Regulation of HR
• Sympathetic influence
– Epinephrine  ↑HR
(tachycardia) and ↑
contractility
– Norepinephrine  general
vasoconstrictor
• Parasympathetic influence
– Acetylcholine→↓HR
(bradycardia)
– Endurance (aerobic) trg.
increases vagal dominance
Cardiac Accelerator Nerves
Sympathetic Fibers
•
•
•
•
Innervate SA node & ventricles
Increase heart rate
Increase contractility
Increase pressure
Vagus Nerve
Parasympathetic Nerve
• Innervates SA node & AV node
• Releases acetylcholine
• Slows heart rate
• Lowers pressure
Cortical Influences on Heart Rate
• Cerebral cortex impulses pass through
cardiovascular control center in medulla oblongata.
– Emotional state affects cardiovascular response
– Cause heart rate to increase in anticipation of exercise
Peripheral Influences on HR
Peripheral receptors monitor state of active
muscle; modify vagal or sympathetic
• Chemoreceptors
– Monitor pCO2, H+, pO2
• Mechanoreceptors
– Heart and skeletal muscle mechanical receptors
• Baroreceptors
Peripheral Influence on HR
• Baroreceptors in
carotid sinus and
aortic arch.
– ↑ pressure → ? HR
& contractility
– ↓ pressure → ? HR
& contractility
Blood Flow Regulation
• During exercise, local
arterioles dilate and
venous capacitance
vessels constrict.
• Blood flow is regulated
according to Poiseuille’s
Law: Flow = pressure 
resistance.
Blood Flow Regulation
• Flow = pressure gradient x vessel radius4
vessel length x viscosity
• Blood flow Resistance Factors
1. Viscosity or blood thickness
2. Length of conducting tube
3. Radius of blood vessel
Blood Flow Regulation
• 1 of every 30 or 40 capillaries is open in
muscle at rest
• Opening “dormant” capillaries during
exercise
– Increases blood flow to muscle
– Reduces speed of blood flow
– Increases surface area for gas exchange
Local Factors Resulting in
Dilation
• ↓ tissue O2 produces
potent vasodilation in
skeletal and cardiac
muscle
•
•
•
•
•
•
•
Increased temperature
Elevated CO2
Lowered pH
Increased ADP
Nitric Oxide (NO)
Ions of Mg+2 and K+
Acetylcholine
Blood Flow Neural Factors
• Sympathetic nerves (adrenergic):
norepinephrine general vasoconstrictor
• Sympathetic nerves (cholingergic):
acetylcholine vasodilation in skeletal and
cardiac muscle.
Blood Flow Humoral Factors
• Sympathetic nerves
to adrenal medulla
causes release of
epinephrine &
norepinephrine into
blood (humor).
Blood Flow Humoral Factors
Sympathetic Nerves
to
Adrenal Medulla

epi & norepi in blood

vasoconstriction
except in skeletal muscle
Neural Factors of Flow Control
Neural
Factors
Sympathetic:
norepinephrine
(adrenergic)
vasoconstrictor
Sympathetic
acetylcholine
(cholinergic)
vasodilation in muscle
Local Metabolites
more powerful than
sympathetic
vasoconstrictors
Integrated Response
Regulation from Rest to Exercise
• Rapid increase in heart rate, SV, cardiac output
– due to withdrawal of parasympathetic stimuli
– increased input from sympathetic nerves
• Continued increase in heart rate
– temperature increases
– feedback from proprioceptors
– accumulation of metabolites
Integrated Response in Exercise
Conditions
Preexercise
“anticipatory”
response
Exercise
Activator
Response
Activation of motor  HR, myocardial
cortex & higher
contractility; vasobrain.
dilation in muscle
Continued sympathetic cholinergic
outflow; alterations
in local metabolic
conditions
Continued sympathetic adrenergic
outflow
Further dilations of
muscle vasculature
Concomitant constriction of vasculature in inactive
tissues