Action potentials in myocytes

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Action potentials in myocytes

ETP Cardiovascular System

ETP Cardiovascular System

Introduction to the cardiovascular system
Anatomy of the heart
Anatomy of the coronary circulation
Anatomy clinical correlates: Heart
Anatomy of the superior mediastinum
Anatomy of the inferior mediastinum
Anatomy clinical correlates: Mediastinum
Development of the cardiovascular system
Fetal circulation
Cardiac muscle histology
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Arteriole, venule and capillary histology
Cardiovascular system anatomy and physiology
Lymphatic system anatomy and physiology
Coronary circulation
Blood pressure, blood flow, and resistance
Pressures in the cardiovascular system
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Resistance to blood flow
Compliance of blood vessels
Control of blood flow circulation
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Measuring cardiac output (Fick principle)
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Cardiac contractility
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Law of Laplace
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Physiological changes during exercise
Cardiovascular changes during hemorrhage
Cardiovascular changes during postural change
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Action potentials in myocytes
Action potentials in pacemaker cells
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Cardiac excitation-contraction coupling
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A study is done to record the action potentials of the different cells in the heart. During the study, a myocyte action potential is recorded and is shown below. During which of the following phases do calcium ions influx into the myocyte causing contraction?  

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Content Reviewers

Rishi Desai, MD, MPH

Action potentials are the really fast electrical changes that happen across the membrane of certain cells, and often propagate from one cell to an adjacent cell. And cells in the heart communicate this way. Now, that signal’s gotta start somewhere, so some of these cells, called pacemaker cells, have the responsibility of setting the rhythm and pace of the heartbeat. So they’ve got this really important job, but they’re a relatively tiny group, and make up only about 1% of the heart cells. But they’re able to continually generate new action potentials that get conducted to the rest of the heart, or the other 99%, and so these are what tell the heart to pump. The cells that receive that signal are called myocytes because they make up the myocardium, which is the muscular middle layer of the heart. Myocytes are also called contractile cells because they contract to allow the heart to pump blood. Myocytes are different from skeletal muscle cells though, which get their action potential signals directly from neurons. Cardiac myocytes receive signal from pacemaker cells causing them to contract.

Now let’s focus on a single myocyte cell going through a single action potential. The action potential of a myocyte is broken into five phases. Often they’re shown on a graph of membrane potential vs. time. We’re going to start with Phase 4, because why not.

In phase 4, or the resting phase, our little myocyte friend is at rest, hanging out with an overall charge or membrane potential of -90 mV. Now, the interesting thing is that it has gap junctions which are openings between two myocytes. So when the myocyte’s neighbour depolarizes, some ions - mainly calcium ions - start leaking through the gap junctions and that makes the membrane potential go up to about -70 mV. -70mV is called the threshold potential and it marks the start of phase 0.

Phase 0 is known as the depolarization phase. Basically, some voltage gated sodium channels open up when they sense that the membrane potential is -70mV, and they allow sodium to rush into the cell, creating an inward current. This rapid influx of sodium causes the myocyte’s membrane potential to go all the way up to +20mV. 

Now, if only a few ions leaked through from the neighboring cell, and the membrane potential didn’t get to the threshold potential of -70 mV, then those voltage-gated channels wouldn’t open and there’d be no depolarization. Essentially there’s nothing in-between, which is why we say that an action potential is an all-or-none process.

Summary

An action potential (AP) is a voltage change that propagates along the membrane of a myocyte (muscle cell) or other cells such as a nerve cell. The AP is generated by the movement of positively charged ions, mainly Na+ and K+, across the plasma membrane. This generates an electrical current that travels down the length of the myocyte.

The AP triggers the release of Ca2+ from intracellular stores, which in turn activates contractile proteins within the myocyte. This ultimately leads to muscle contraction.

Sources

  1. "Medical Physiology" Elsevier (2016)
  2. "Physiology" Elsevier (2017)
  3. "Human Anatomy & Physiology" Pearson (2017)
  4. "Principles of Anatomy and Physiology" Wiley (2014)
  5. "Sinoatrial node dysfunction induces cardiac arrhythmias in diabetic mice" Cardiovascular Diabetology (2014)
  6. "How does the shape of the cardiac action potential control calcium signaling and contraction in the heart?" Journal of Molecular and Cellular Cardiology (2010)
  7. "Ionic events responsible for the cardiac resting and action potential" The American Journal of Cardiology (1982)