Properties of Cardiac Muscle Discussion 2022
Added on 2022-09-16
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HEALTHCARE1
Properties of Cardiac Muscle
Name of the Student
Name of the University
Author Note
Properties of Cardiac Muscle
Name of the Student
Name of the University
Author Note
HEALTHCARE2
Properties of the Cardiac Muscle
Cardiac muscle, also known as the heart muscle is an involuntary muscle present in
the vertebrates. It is present around the heart and makes up the myocardium. It is a striped
muscle and the cells may contain a single or rarely, two nuclei. They are branched and are
often linked to each other via the presence if intercalated disc. The major function of the
cardiac muscles includes pumping blood into the circulatory vessels via rhythmic
contractions (Opentextbc.ca., 2020). This essay aims to shed light on the different properties
of the cardiac muscles, namely excitability, automaticity, conductivity, as well as
contractility.
Discussion
Cardiac excitability is a very important property of the said muscles. Excitability can
be described as the event of the cardiac muscles easily undergoing a set of phenomenon
related to depolarization and repolarization, conduction of electrical activity and
communication between the cells. It is the ability of a cell of the cardiac muscle to carry out
the successful generation of the action potential. This action potential is produced due to the
depolarization event on the membrane, following which the impulse is transmitted along the
membrane of the cardiac muscle (Aggarwal & Makielski, 2013). In a simpler language,
cardiac excitability may refer to as the muscle cell’s ability to successfully respond to an
electrical stimulus (Learningcentral.health.unm.edu., 2020). The cardiac cells are capable of
contracting and relaxing due to the influence of this depolarization and repolarization. The
excitation occurs through an organized flow of charged ions through the ion channels of the
cardiac membrane. Hence, this is also responsible for the concentration of the ions around the
membrane. The resting membrane potential of an adult human being is around -90mV
(Aggarwal & Makielski, 2013). The factors which affect the excitability of the heart are
Properties of the Cardiac Muscle
Cardiac muscle, also known as the heart muscle is an involuntary muscle present in
the vertebrates. It is present around the heart and makes up the myocardium. It is a striped
muscle and the cells may contain a single or rarely, two nuclei. They are branched and are
often linked to each other via the presence if intercalated disc. The major function of the
cardiac muscles includes pumping blood into the circulatory vessels via rhythmic
contractions (Opentextbc.ca., 2020). This essay aims to shed light on the different properties
of the cardiac muscles, namely excitability, automaticity, conductivity, as well as
contractility.
Discussion
Cardiac excitability is a very important property of the said muscles. Excitability can
be described as the event of the cardiac muscles easily undergoing a set of phenomenon
related to depolarization and repolarization, conduction of electrical activity and
communication between the cells. It is the ability of a cell of the cardiac muscle to carry out
the successful generation of the action potential. This action potential is produced due to the
depolarization event on the membrane, following which the impulse is transmitted along the
membrane of the cardiac muscle (Aggarwal & Makielski, 2013). In a simpler language,
cardiac excitability may refer to as the muscle cell’s ability to successfully respond to an
electrical stimulus (Learningcentral.health.unm.edu., 2020). The cardiac cells are capable of
contracting and relaxing due to the influence of this depolarization and repolarization. The
excitation occurs through an organized flow of charged ions through the ion channels of the
cardiac membrane. Hence, this is also responsible for the concentration of the ions around the
membrane. The resting membrane potential of an adult human being is around -90mV
(Aggarwal & Makielski, 2013). The factors which affect the excitability of the heart are
HEALTHCARE3
referred to as bathmotrophic factors; where the positive bathmotrophic factors increase the
excitability and the negative bathmotrophic factors decrease the excitability (HALL, 2020).
The excitability of the cardiac muscle is often coupled with contractility. Therefore, a
properly timed cardiac excitation is essential to properly conduct the excitation-contraction
process (Aggarwal & Makielski, 2013). The force that causes the contractibility can be is
referred to as inotropy. The positive inotropic factors increase the force of the contraction,
while the negative inotropic factor does the opposite (HALL, 2020). The excitation and
contraction occur by the use of a unique mechanism which may be referred to as calcium-
induced calcium release. The modification of the intracellular concentration of calcium ions
(Ca2+) controls cardiac contractility. During the normal functioning of the heart muscles, the
concentration must be high during the systole and low during the diastole (Eisner et al.,
2017). Cardiac muscle requires Ca2+ ions in the extracellular fluid to contract. When the
action potential passes over the membrane, it spreads to the interior following the transverse
tubules. This action potential works on the longitudinal sarcoplasmic tubules causing the
release of calcium ions from the sarcoplasmic reticulum. These calcium ions diffuse into the
myofibrils and in turn, acts as a catalyst for the chemical reactions that stimulate sliding of
actin and myosin. In the second phase, along with the release of the calcium from the
sarcoplasmic reticulum, the calcium from T tubules also enter the sarcoplasm. The calcium
entering the cells activate the calcium release channels. The calcium released from the T
tubules increases the power of contraction. This whole process is responsible for the
excitation-contraction coupling of the cardiac muscle (HALL, 2020).
Automaticity is another vital property of the cardiac cells. This refers to the ability of
the cells to spontaneously depolarize and repolarize, that is, to generate an action potential
(Tmedweb.tulane.edu., 2020). This is also called autorhythmicity, as the cells are self-
excitatory. These characteristics are majorly due to the pacemaker cells present in the heart
referred to as bathmotrophic factors; where the positive bathmotrophic factors increase the
excitability and the negative bathmotrophic factors decrease the excitability (HALL, 2020).
The excitability of the cardiac muscle is often coupled with contractility. Therefore, a
properly timed cardiac excitation is essential to properly conduct the excitation-contraction
process (Aggarwal & Makielski, 2013). The force that causes the contractibility can be is
referred to as inotropy. The positive inotropic factors increase the force of the contraction,
while the negative inotropic factor does the opposite (HALL, 2020). The excitation and
contraction occur by the use of a unique mechanism which may be referred to as calcium-
induced calcium release. The modification of the intracellular concentration of calcium ions
(Ca2+) controls cardiac contractility. During the normal functioning of the heart muscles, the
concentration must be high during the systole and low during the diastole (Eisner et al.,
2017). Cardiac muscle requires Ca2+ ions in the extracellular fluid to contract. When the
action potential passes over the membrane, it spreads to the interior following the transverse
tubules. This action potential works on the longitudinal sarcoplasmic tubules causing the
release of calcium ions from the sarcoplasmic reticulum. These calcium ions diffuse into the
myofibrils and in turn, acts as a catalyst for the chemical reactions that stimulate sliding of
actin and myosin. In the second phase, along with the release of the calcium from the
sarcoplasmic reticulum, the calcium from T tubules also enter the sarcoplasm. The calcium
entering the cells activate the calcium release channels. The calcium released from the T
tubules increases the power of contraction. This whole process is responsible for the
excitation-contraction coupling of the cardiac muscle (HALL, 2020).
Automaticity is another vital property of the cardiac cells. This refers to the ability of
the cells to spontaneously depolarize and repolarize, that is, to generate an action potential
(Tmedweb.tulane.edu., 2020). This is also called autorhythmicity, as the cells are self-
excitatory. These characteristics are majorly due to the pacemaker cells present in the heart
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