EXPH 386 Leary Notes 7-8 PDF

Summary

These notes cover the cardiovascular system, including electrocardiogram (ECG) analysis, pressure changes, and the intrinsic and extrinsic regulation of heart rate. Sympathetic and parasympathetic influences on the heart are discussed, along with exercise and blood flow.

Full Transcript

○ 0.06 seconds time till ventricles contract upon stimulation
Electrocardiogram (ECG/EKG)
○ Records the electrical activity of the heart
○ P wave
Atrial depolarization
○ QRS complex
Ventricular depolarization and atrial repolarization simultaneously
○ T wave
Ventricular repolarization
○ ECG abnormalities may indicate coronary heart disease
ST segment depression can indicate MI
Relationship between Pressure Changes and ECG
○ We have atrial depolarization which signals atrial contraction which has a small
increase in blood volume which acts on the ventricular walls increasing pressure
ever so slightly
○ Polarization passes AV node and into ventricles which causes contraction and
generates maximal pressure which signals ventricular repolarization
Areas of the Heart That Can Initiate a Rhythm and Intrinsic Rate
○ The slower the lower
○ Sinus node: 60-100 BPM
○ Atrial Tissue: 60-100 BPM
○ AV node: 40-60 BPM
○ Ventricular Tissue: 20-40 BPM
Extrinsic Heart Rate Regulation
○ Neural influences superimpose on the inherent rhythm of the myocardium
To accelerate HR in anticipation of exercise and adjust HR as exercise
intensity increases or decreases
○ Range 20-200 BPM (dependent upon physical fitness)
Sympathetic and Parasympathetic Control
○ Sympathetic stimulation
Catecholamine (NE/Epinephrine)
Results in tachycardia
Increases SA node depolarization, increases HR
Increases contractility
○ Parasympathetic influence
Acetylcholine- vagal influence
Results in bradycardia
Slow SA node depolarization, slows HR
Exercise and Blood Flow
 Parasympathetic Neural Control
○ Periphery
Excitation of iris, gallbladder, coronary arteries
Inhibits gut sphincters, intestines, and skin vasculature
During the onset of exercise, HR increases by inhibition of PNS
Sympathetic Control on Blood Flow
○ Mechanism is NE via adrenergic fibers that lie within smooth muscle of small
arteries, arterioles, and precapillary sphincters
○ Inactive Tissue (vasoconstriction)
Renal, splanchnic, and inactive skeletal muscle
Produces systemic vasoconstriction of inactive muscle
○ Active Tissue (vasodilation)
Active muscle
Decreases SNS activity
Neural Response During Exercise
○ Anticipatory response
Decrease parasympathetic
Increase sympathetic
○ Exercise
Parasympathetic inhibition (early)
Sympathetic stimulation (more intense)
○ What happens?
Increased HR and contractility
Increase in arterial blood pressure
Vasodilation of active skeletal muscles
Vasoconstriction of skin gut spleen etc.
Vasoconstriction increases venous return
Functional Sympatholysis
○ Sympathetic neural activity on blood vessels = vasoconstriction
○ So how do we get increased blood flow to active tissues?
Local changes in muscle metabolites and other substances reduce vascular
responsiveness to alpha adrenergic receptor activation
Peripheral Input Control of CV response
○ Initial signal to “drive” cardiovascular system comes from higher brain centers
○ Fine-tuned by feedback from
Chemoreceptor
Sensitive to blood, O2, CO2, and pH levels
Baroreceptors
Sensitive to changes in arterial blood pressure
Muscle mechanoreceptors (heart, skin, joints)