Physiology 1.03 PDF

Summary

This document provides an overview of human heart physiology and anatomy. It covers the cardiac exam, heart chambers, and their associated structures, along with an explanation of the functions and processes of heart valves. The layout appears to be that of a presentation or course material, complete with diagrams and illustrative figures.

Full Transcript

Physiology 1.03

Clinical Physiology =
Fundamental Physiologic Basis
of the Vital Signs

BMS 100
The Cardiac Exam
Heart Anatomy
Surface Anatomy
Chambers
Valves And Great Vessels
Basic Cardiac Physiology
The Cardiac Cycle
Valvular Movements
The Cardiac Physical Exam
Surface Anatomy And Auscultation
Phases Of The Cardiac Cycle And Heart Sounds
Murmurs and Valvular Abnormalities
Locations Of The Major Pulses
The Heart Chambers – Anatomy review
Note the location of:
The chambers:
 The left and right atrium
 The left and right ventricle
 The interventricular septum  the thick
muscular wall that separates the left
and right ventricle
The great vessels:
 The pulmonary trunk + left & right
pulmonary arteries
 The aorta
 The superior and inferior vena cavae
 The pulmonary veins
Basic Heart Anatomy

Anatomy & Physiology, 2e. p. 755, fig 19.4
https://openstax.org/books/anatomy-and-
physiology-2e
The Heart Chambers – Anatomy review
Note the location of:
The chambers:
 The left and right atrium
 The left and right ventricle
 The interventricular septum  the thick
muscular wall that separates the left
and right ventricle
The great vessels:
 The pulmonary trunk + left & right What
pulmonary arteries chamber is
 The aorta each great
 The superior and inferior vena cavae vessel
 The pulmonary veins directly
connected
to?
The Heart - Valves
There are two major types of valves that ensure one-way
flow through the heart
Atrioventricular valves
 Between the atria and the ventricles – prevent
backflow
So when the left ventricle contracts, blood
moves into the aorta, not the left atrium
So when the right ventricle contracts, blood
moves into the ______________, not the right
atrium
Semilunar (“half-moon”) valves
 Between the ventricles and the great arteries
So when the ventricle relaxes during diastole,
blood isn’t “sucked back” into that ventricle
Why does that arterial blood still move
forwards?
The Heart - Valves
There are two major types of valves that ensure
one-way flow through the heart
Atrioventricular valves
 Larger, and more “floppy” in nature
 Anchored by the chordae tendinae
Keeps them from “flopping back” (prolapse)
into the atria during ventricular contraction
Semilunar (“half-moon”) valves
 Smaller and “tighter”
Therefore do not require chordae tendinae to
anchor them
Basic Heart Anatomy

Anatomy & Physiology, 2e. p. 755, fig 19.4
https://openstax.org/books/anatomy-and-
physiology-2e
 Basic Heart Anatomy – More
details
Note:
Papillary
muscles
Chordae
tendinae
The general
shape of the
semilunar and
atrioventricular
(AV) valves
What
structures
would be
located
anteriorly, and
which would be Anatomy & Physiology, 2e. p. 761, fig 19.9
https://openstax.org/books/anatomy-and-
located physiology-2e
Anterior And Posterior
Views Of The Heart

Anatomy & Physiology, 2e. p. 758, fig 19.6
https://openstax.org/books/anatomy-and-
physiology-2e
Anterior And Posterior
Views Of The Heart

Anatomy & Physiology, 2e. p. 758, fig 19.6
https://openstax.org/books/anatomy-and-
physiology-2e
Anterior vs. Posterior
Surfaces
The anterior surface of the heart is obviously
easier to auscultate and palpate than the
posterior surface
Anterior surface – major structures
 Part of the right atrium (auricle)
 Right ventricle
 The “tip” of the left ventricle
It’s the easiest place to palpate the cardiac
impulse in most people
Point of Maximal Impulse (PMI)
 The superior – lateral side of the left ventricle
 Both semi-lunar valves are somewhat anterior to
the AV valves  see next slides
Valves – the superior
aspect

Which phase
of the cycle??
Anatomy & Physiology, 2e. p. 765, fig 19.13 and p.
784, fig. 19.27
Valves – the superior
aspect

Which phase
of the cycle??
Anatomy & Physiology, 2e. p. 764, fig 19.12 and p.
784, fig. 19.27
The Heart – Surface
Anatomy
Surface Anatomy?
 Using superficial (usually palpable)
anatomical landmarks during the physical
exam to localize structures that lie deeper in
the body
 Used for a variety of physical exam
maneuvers
Correlating a sound with a deep
anatomical structure
Correlating a palpation finding (mass,
pain) with a likely deep anatomical
structure
Bones Of The Thoracic Cage

Palpation tips for the
thoracic cage:
Find the “bump”
between the
manubrium and
body of the sternum
Angle of Louis
Right below this is
the 2nd intercostal
space
This makes
landmarking and
rib-counting
much easier
Anatomy & Physiology, 2e. p. 259, fig. 7.32
Locate these on
https://openstax.org/books/anatomy-and-physiology-
The Heart – Surface Anatomy

Anatomy & Physiology, 2e. p. 753, fig 19.2 and p.
259, fig. 7.32
The Heart – Surface Anatomy

Where is:
The right border of
the heart - and
what cardiac
structures form it?
The inferior
surface of the
heart – what
structures form it?
The left border of
the heart – what
structures form it?

The base of the heart
= where the great
arteries emerge from
Anatomy & Physiology, 2e. p. 753, fig 19.2 and p. the superior aspect
259, fig. 7.32
The Heart – Surface
Anatomy

Key locations for
auscultation and
palpation:
2nd intercostal
space, left sternal
border
Corresponds to
the pulmonic
valve
2nd intercostal
space, right sternal
border
Corresponds to
the aortic valve
Anatomy & Physiology, 2e. p. 753, fig 19.2 and p.
259, fig. 7.32
The Heart – Surface
Anatomy
4th/5th intercostal
space, right sternal
border
Best place to hear
sounds from the left
ventricle and right
AV valve
5th intercostal space,
mid-clavicular line
**Best place to:
hear left AV valve
and left
ventricular
sounds
Palpate the PMI
Anatomy & Physiology, 2e. p. 753, fig 19.2 and p.
259, fig. 7.32 ** In a person with a
Another View – Surface
Anatomy The highlighted,
coloured spots are
where the sounds
are “carried” for
each valve
This picture is
not very
anatomically
correct – the
heart is very
small
The apex (PMI)
should be
approximately at
the 5th ICS, MCL
The right heart
Anatomy & Physiology, 2e. p. 788, fig 19.30
border (right
https://openstax.org/books/anatomy-and-physiology- atrium and vena
The Systemic Pressures
And The Cardiac Cycle
The following pressure tracing shows:
 The aortic pressures – red
 The left ventricular pressures – green
 The left atrial pressures – yellow

These pressures are shown at the same time
as the heart sounds that are caused by the:
 Closing of the atrioventricular valves (mitral
valve on the left side)
 Closing of the semilunar valves (aortic valve on
the left side)
Systemic Pressures

Anatomy & Physiology, 2e. p. 787, fig 19.29
https://openstax.org/books/anatomy-and-physiology-
Systemic Pressures – the Left
Atrium
A – the left atrium (LA)
contracts, helping fill
the left ventricle (LV)

B – the LV contracts 
pressure increase
causes the left AV
valve to close  the
first heart sound (Lub)

C – The LA fills while
the pressure in the LV
is high
A B C D E
D – The pressure in the
LV drops, resulting in
opening of the left AV
valve
Anatomy & Physiology, 2e. p. 787, fig 19.29
E – the LA fills
https://openstax.org/books/anatomy-and-physiolo
Systemic Pressures – The Left
Ventricle
A – the relaxed LV
experiences a “bump”
in pressure as the LA
fills it

B – the LV contracts 
pressure increase
causes the left AV
valve to close  the
first heart sound (Lub)

C – The LV relaxes, and
pressure starts to drop
A B C D E
D – When the LV
pressure is less than
the LA pressure, the
AV valve opens
Anatomy & Physiology, 2e. p. 787, fig 19.29
E – the LV fills
https://openstax.org/books/anatomy-and-
Systemic Pressures – The Aorta
A – diastolic pressure
C D just prior to ventricular
B
A contraction

B – the LV contracts 
pressure increase
overcomes aortic
diastolic pressure 
aortic valve opens

C – The LV applies
maximal (systolic)
pressure to the aorta

D – When the LV
pressure is less than
the aortic pressure,
the aortic valve closes
 second heart sound
Anatomy & Physiology, 2e. p. 787, fig 19.29 (Dub)
https://openstax.org/books/anatomy-and-physiology-
Types of Heart Sounds
It’s always normal to hear a valve closing
 AV valve  S1  “Lub”
This is a lower frequency sound, because the valve
itself is a bit bigger and more “floppy”
Think of the largest string on a guitar
 Semilunar valve  S2  “Dub”
This is a higher frequency sound, because the valve
itself is a bit smaller and “tigher”
Think of the smallest string on a guitar
It’s uncommon to hear a valve opening
 Some pathologies that affect the cardiac valves can
result in “opening” sounds – they’re usually called
opening snaps
Types of Heart Sounds
Blood flow can be smooth and orderly
 This is known as laminar flow, and this is normal in
the heart
Blood flow can be rapid, forming disorderly
eddies and vibrations
 This is known as turbulent flow
 It is often caused by valvular abnormalities, and can
cause a variety of sounds
Murmurs
Extra heart sounds (sometimes)
 It can be normal in some patients
Heart sounds are complex acoustical
phenomena – we’ll address them simply today
 Types Of Valvular
Abnormalities
Stenosis – the valve
doesn’t open widely
enough
 Higher pressures are
needed to push blood
through the narrow valve
 The higher pressures
cause “noisy” turbulent
flow  a murmur
 These murmurs are of
course heard while blood
is flowing across the
valve… when the valve
should be open.

Anatomy & Physiology, 2e. p. 764, fig 19.12
https://openstax.org/books/anatomy-and-physiology-
 Types Of Valvular
Abnormalities
Stenosis – the valve
doesn’t open widely
enough
 What would happen if
the aortic valve in this
picture “couldn’t” open
widely enough?
 When would you hear
the murmur?
Sometimes valves
“scar” over time due
to physical stresses 
narrowing
 Types Of Valvular
Abnormalities
Regurgitation – the valve
doesn’t close fully
 If the valve doesn’t
close, then backflow
occurs when the
chamber before it
relaxes
 This backflow causes a
“noisy” turbulent flow 
a murmur
 These murmurs are of
course heard while blood
is flowing across the
valve… when the valve
should be closed
 Types Of Valvular
Abnormalities
Regurgitation – the
valve doesn’t close
fully
 What would happen if
the mitral valve didn’t
close fully after the
left ventricle systole?
 When would you hear
the murmur?
Damage to heart
valves can make them
unable to close fully

Anatomy & Physiology, 2e. p. 766, fig 19.14
https://openstax.org/books/anatomy-and-physiology-
Fill in following chart on the
next

slide
You can hear heart murmurs during ventricular
systole or ventricular diastole
 If that murmur is due to a valve, it could be
because the valve is damaged and either:
Can’t close
Can’t open fully
The location where the murmur is heard loudest
and the phase of the cardiac cycle (ventricular
systole or diastole) should allow you to deduce
 Which valve is involved
 Whether the valve is stenotic or regurgitating
Try it on your own (example provided) – and then
error-check with a small group
Location Murmur heard Murmur heard
during ventricular during ventricular
diastole systole
2nd intercostal space,
right sternal border

2nd intercostal space, Pulmonic stenosis
left sternal border

5th intercostal space,
left sternal border

5th intercostal space,
mid-clavicular line