Cardiac conduction velocity
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Cardiac conduction velocity
Physiology
Anatomy and physiology
Cardiovascular system anatomy and physiology
Lymphatic system anatomy and physiology
Coronary circulation
Hemodynamics
Blood pressure, blood flow, and resistance
Pressures in the cardiovascular system
Laminar flow and Reynolds number
Resistance to blood flow
Compliance of blood vessels
Control of blood flow circulation
Microcirculation and Starling forces
Cardiac output
Measuring cardiac output (Fick principle)
Stroke volume, ejection fraction, and cardiac output
Cardiac contractility
Frank-Starling relationship
Cardiac preload
Cardiac afterload
Law of Laplace
Cardiac and vascular function curves
Altering cardiac and vascular function curves
Cardiac cycle and pressure-volume loops
Cardiac work
Cardiac cycle
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Changes in pressure-volume loops
Cardiovascular physiological responses
Physiological changes during exercise
Cardiovascular changes during hemorrhage
Cardiovascular changes during postural change
Auscultation of the heart
Normal heart sounds
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Myocyte electrophysiology
Action potentials in myocytes
Action potentials in pacemaker cells
Excitability and refractory periods
Cardiac excitation-contraction coupling
Electrocardiography
Electrical conduction in the heart
Cardiac conduction velocity
ECG basics
ECG normal sinus rhythm
ECG intervals
ECG QRS transition
ECG axis
ECG rate and rhythm
ECG cardiac infarction and ischemia
ECG cardiac hypertrophy and enlargement
Blood pressure regulation
Baroreceptors
Chemoreceptors
Renin-angiotensin-aldosterone system
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Atrioventricular node
conduction pathway p. 314
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Transcript
Contributors
Tanner Marshall, MS
Cardiac conduction velocity is the velocity at which a depolarization wave moves through the myocardium, the muscular middle layer of the heart, and it’s measured in meters per second.
The depolarization wave travels through the sinoatrial node, or SA node, through both atria, down the atrioventricular or AV node, through the Bundle of His and the Purkinje fibers, and finally to all of the parts of the ventricles, all in about 220 milliseconds, which is less than a quarter of a second!
If we zoom in on the myocardium, the depolarization waves move across neighboring cells. It moves from one cell to the next when ions like calcium and sodium slip through gap junctions and trigger voltage-gated sodium channels in that cell over to open up, allowing a rush of more sodium into the cell and causing an action potential to occur.
That then results in more sodium and calcium leaking through to the next cell, triggering an action potential, which goes on to the next, and so on.
Ultimately these cellular processes determine how fast or slow a depolarization wave will move across different types of tissues.
More sodium channels and gap junctions speed up the depolarization wave, Fewer gap junctions and fewer sodium channels slow down the depolarization wave.
Alright so let’s break down the conduction velocities in the different parts of the heart, starting at the SA node,i the depolarization wave moves through the myocytes in the atria at about 1 meter per second, then goes through the AV node really slowly, roughly between 0.01 and 0.05 meters per second.
Summary
The cardiac conduction velocity is the speed at which the electrical signal travels through the heart muscle. This electrical signal is generated by the sinoatrial (SA) node, which is located in the right atrium. After getting propagated through booth atria, the signal travels down the atrioventricular (AV) node in the Bundle of His and the Purkinje fibers, and later to all of the parts of the heart ventricles. Cardiac conduction velocity is measured in meters per second (m/s).
The cardiac conduction velocity can be affected by several factors, including age, medications, electrolyte levels, and disease states. Older individuals generally have a slower cardiac conduction velocity, as do those taking certain medications (such as beta blockers). Electrolyte imbalances (such as low potassium levels) can also decrease cardiac conduction velocity. Finally, heart diseases (such as cardiomyopathies) can also result in a slower cardiac conduction velocity.
There are several ways to measure cardiac conduction velocity. The most common method is an electrocardiogram (ECG), which measures the electrical activity of the heart and can be used to determine the cardiac conduction velocity.
Sources
- "Physiology" Elsevier (2017)
- "Medical Physiology" Elsevier (2016)
- "Human Anatomy & Physiology" Pearson (2017)
- "Principles of Anatomy and Physiology" Wiley (2014)
- "Impact of Sarcoplasmic Reticulum Calcium Release on Calcium Dynamics and Action Potential Morphology in Human Atrial Myocytes: A Computational Study" PLoS Computational Biology (2011)
- "The Role of the Funny Current in Pacemaker Activity" Circulation Research (2010)
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