LEC 9+10 Physiology/2nd stage PDF

Summary

These lecture notes cover topics related to the heart, including Starling's law and the autonomic nervous system. They detail the physiological mechanisms involved in these systems, including diagrams and explanations. The document is from Dijlah University.

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Lecture 9 Physiology/2nd stage Dr. Farah Altaay

Starling's Law of the heart:
In the late19th century, Otto Frank found using isolated frog heart that
the strength of ventricular contraction was increased when the ventricle was
stretched prior to contraction. This observation was extended by the studies
of Ernest Starling in the early 20th century who found that
increasing venous return to the heart, will increase the filling pressure
(left ventricular end-diastolic pressure; LVEDP) of the ventricle caused the
stroke volume (SV) to increase. Conversely, decreasing venous return
decreased stroke volume. This cardiac response to changes in venous return
and ventricular filling pressure is intrinsic to the heart and does not depend
on extrinsic neurohumoral mechanisms.

So, the ability of the heart to change its force of contraction and
therefore stroke volume in response to changes in venous
return is called the Frank-Starling mechanism (or Starling's Law
of the heart). In other words, Frank–Starling law of the heart
indicates that the increased filling pressure of the heart results
in increased cardiac output

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Lecture 9 Physiology/2nd stage Dr. Farah Altaay

Frank-Starling curves:
Frank-Starling curves show how changes in ventricular preload lead
to changes in stroke volume.

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Lecture 9 Physiology/2nd stage Dr. Farah Altaay

When venous return is increased, there is increased filling of the ventricle,

leading to an increase in end-diastolic volume (see Figure above). This will
increase stroke volume, to match physiological increases in venous return.
This is not, however, the case for ventricles that are in failure.

What is the physiological significance of the Frank-Starling law
of the heart for blood circulation?

The Frank-Starling mechanism is a physiological principle that explains
how the heart responds to changes in venous return. Increases in venous
return cause the heart's chambers to fill with more blood, which then causes
the heart to stretch and contract more forcefully, and pump more blood out
to the rest of the body. So, he greater the preload, the greater will be the
volume of blood in the heart at the end of diastole.

Starlings' Law is therefore representing the relationship between the
contractility and the afterload.

thanx

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Lecture 10 Physiology/2nd stage Dr. Farah Altaay

The autonomic nervous system (ANS): is a component of the peripheral
nervous system that regulates involuntary physiologic processes including heart
rate, blood pressure, respiration, digestion, and glandular functions (secretions)
of the body.

The ANS has two interacting systems: the sympathetic and parasympathetic
systems. It is controlled by centers located in the spinal cord, brain stem, and
hypothalamus.

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Lecture 10 Physiology/2nd stage Dr. Farah Altaay

 Heartbeats originate from the rhythmic pacing discharge from the
sinoatrial (SA) node within the heart itself. In the absence of extrinsic
neural or hormonal influences, the SA node pacing rate would be about
100 beats per minute. Heart rate and cardiac output, however, must vary
in response to the needs of the body’s cells for oxygen and nutrients under
varying conditions.
 In order to respond rapidly to the changing requirements of the body’s
tissues, the heart rate and contractility are regulated by the autonomic
nervous system, hormones, and other factors.
 sympathetic and parasympathetic neurons exert antagonistic effects on the
heart. The sympathetic system prepares the body for energy expenditure,
emergency or stressful situations.
 Conversely, the parasympathetic system is most active under restful
conditions. The parasympathetic counteracts the sympathetic system after
a stressful event and restores the body to a restful state.
 The sympathetic nervous system releases norepinephrine (NE) while the
parasympathetic nervous system releases acetylcholine (ACh).

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Lecture 10 Physiology/2nd stage Dr. Farah Altaay

What is the effect of Sympathetic stimulation on cardiovascular
system?

During exercise, emotional excitement, or under various pathological
conditions (e.g., heart failure), the sympathetic nervous system is activated.

The stimulation of the sympathetic nervous system causes:

1. increase heart rate.
2. Increase myocardial contractility.
3. blood vessel constriction.
4. increases renin secretion by the kidneys, which leads to a series of actions
that rapidly leads to increased systemic blood pressure.

What is the effect of Parasympathetic stimulation on
cardiovascular system?

In contrast, the parasympathetic counteracts the sympathetic system after a
stressful event and restores the body to a restful state.

1. Parasympathetic stimulation decreases heart rate.
2. It decreases cardiac output.
3. The parasympathetic stimulation decreases blood pressure.
4. Parasympathetic stimulation does not cause vasodilatation because most
blood vessels lack parasympathetic innervations and their diameter is
regulated by sympathetic nervous system only, so that it is a decrease in
sympathetic stimulation or tone that allows vasodilatation.

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Lecture 10 Physiology/2nd stage Dr. Farah Altaay

Sympathetic neurotransmitters: Neurotransmitters are chemical substances
released into the synaptic cleft from nerve terminals. They transmit signals from
a neuron to a target cell across a synapse, e.g., acetylcholine for neuromuscular
junctions.

While the preganglionic neurons of both the sympathetic and parasympathetic
system secret acetylcholine (ACh) which is why they are referred to as
cholinergic, the majority of the postganglionic endings of the sympathetic
nervous system release NE, which resembles epinephrine (i.e., adrenalin).
Thus, these sympathetic postganglionic fibers are commonly called
adrenergic fibers.

Sympathetic receptors:

There are two types of adrenergic receptors: β and α. In the cardiovascular
system there are β1, β2, α1, and α2 adrenergic receptors.

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Lecture 10 Physiology/2nd stage Dr. Farah Altaay

Sympathetic and parasympathetic receptors and their functions in the heart and vessels
Heart Vessels

Function
Receptor Function
Receptor
Inotropy Chronotropy
α1 + + α1 Vasoconstriction
Norepinephrine β1 + + β1 Vasoconstriction
β2 + + β2 Vasodilation
Acetylcholine M2 - - M2 Vasodilation

Parasympathetic neurotransmitters: Acetylcholine is the predominant
neurotransmitter from the parasympathetic nervous system, in both the
preganglionic and postganglionic neurons. Acetylcholine inhibits the
contraction of cardiomyocytes by activating muscarinic receptors (M2).

These parasympathetic postganglionic fibers are commonly called cholinergic
fibers because they secrete acetylcholine at their nerve endings.

Parasympathetic Receptors: The parasympathetic postganglionic fibers
are cholinergic. Acetylcholine can bind to two types of cholinergic receptors
called nicotinic receptors and muscarinic receptors.

THANK YOU

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