Heart_INteranl_Structure_and_Surface_Anatomy.pdf

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The Heart: Internal and
surface anatomy

Fraser Chisholm
[email protected]

Learning Outcomes
After this lecture, time spent in the dissecting room, and further private study you
should be able to:
1. Describe the margins and surfaces of the heart
2. Describe the morphological features of the cardiac valves
3. Describe the surface anatomy of the heart and its valves in relation to patient
examination and the interpretation of radiographs
4. Explain why points of auscultation of heart sounds are different from the surface
projection of the heart valves
5. Describe the functional anatomy of the chambers of the heart
6. Explain the functional importance and position of the fibrous skeleton of the
heart
7. Explain the clinical significance of papillary muscles and chorda tendinea
8. Identify cardiac borders on chest x-ray and other anatomical structures on
medical images
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Circulation
• Pulmonary circulation
– Right heart pumps deoxygenated blood
to the lungs
– Low pressure: 12 – 16 mmHg

• Systemic circulation
– Left heart pumps oxygenated blood
throughout the body
– High pressure: 70 – 120 mmHg

• Therefore, require two separate
sides, each with a chamber to
receive and one to pump
3

Heart Surfaces

4

Heart Surfaces

Sternocostal (anterior) Diaphragmatic (inferior)

• Right ventricle • Left ventricle
• Right atrium
• Left ventricle

• Right ventricle

• Separated from the base
of heart by the coronary
sinus

R Pulmonary
• Right Atrium
L Pulmonary
• Left Ventricle
•Cardiac
impression
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Heart surfaces

Base (posterior)
• Left Atrium and
pulmonary veins

Apex
• Left 5th intercostal
Mid-clavicular line

• Right atrium

• Fixed posteriorly to the
pericardium, at the level of
T6(5)-T9(8) vertebrae

• More superior and
lateral in children
6

Heart Margins – important for imaging
• Right margin:
– Right atrium

• Left margin:
– Left ventricle and left auricle

• Inferior margin
– Right ventricle + left ventricle

7

Septa and Chambers
•
•

Interatrial (IA) septum
Interventricular (IV) septum

•

Atrioventricular (AV) septum

•
•

Right (RA) and left (LA) atria
Right (RV) and left (LV)
ventricles

➢ Right Atrium + Right Ventricle = Right heart
➢ Left Atrium + Left Ventricle = Left Heart

8

Atria
Right

•
•
•

Forms most of the right margin of the heart
Atrium proper (w/smooth surface) + auricle
(w/ridges)
Superior v. cava (SVC), inferior v. cava (IVC),
coronary sinus (CS) and anterior cardiac vv.

Left

• Forms most of the base of the heart
• Atrium proper (w/smooth surface) +
auricle (w/ridges)
• 4x pulmonary veins

9

Atrial Tributaries
• Opening of SVC
– Deep to the joint between right 3rd costal
cartilage and sternum
– No valve inside SVC
– Intervenous tubercle (foetus)

• Opening of IVC
– Valve of inferior vena cava

• Opening of coronary sinus
– Valve of coronary sinus prevent
regurgitation of blood

• Openings of anterior cardiac
veins
Left Atrium
• Pulmonary veins
– No valves
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Atrial walls
Right

• Crista terminalis separates right atrium
from right auricle

• Fossa ovalis
− On the right side of IA septum
− Site of foramen ovale of the foetal heart

Left

Falx septi
− Depressed area on the left side of IA
septum
− Caused by the fusion of valve of
foramen ovale
− Not at the same level as foramen ovale
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Auricles

• Ridged inner surface, formed by pectinate muscles
• Provide some power of contraction without significantly thickening the
cardiac wall
12

Ventricles
Right

•
•
•
•

Behind sternum
Sits on central tendon of diaphragm
Wall thickness 3-4 mm.
Max. systolic pressure of 30mmHg

Left

• Left border and Apex
• Wall thickness 8-12mm
• Max. (normal) systolic pressure of
120mmHg
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Septa and Chambers

Parasternal long axis view
Taken from Robert Humphries’ “Basic Echo Cardiography”
teaching
14

Septa and Chambers

Parasternal short axis view
Taken from Robert Humphries’ “Basic Echo Cardiography”
teaching
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Septa and Chambers

Apical 4 chamber view
Taken from Robert Humphries’ “Basic Echo Cardiography”
teaching
16

Septa and Chambers

Subcostal view
Taken from Robert Humphries’ “Basic Echo Cardiography”
teaching
17

Atrio-Ventricular valves

•
•
•
•

Right

Left

Tricuspid valve
3 Cusps, attached to anulus fibrosus
Blood flows anteriorly and medially
Deep to inferior right Sternum

• Mitral valve (bicuspid)
• 2 Cusps, attached to anulus fibrosis
• Blood flows towards the apex of the
heart
• Deep to left inferior strerum
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Chordae tendinea
• Fibrous chords that extend between papillary muscles and AV valve cusps
• Prevent eversion of cusps and therefore: prevent regurgitation of blood
into the atria during ventricular systole
• Chorda tendinea from one papillary muscle attach to more than one cusp

19

Ventricular outflow tracts
Left

Right

• Infundibulum (conus arteriosus)
• Leads to pulmonary trunk
• Blood flows upwards, backwards
and to the left side through this
valve

•
•
•
•

Aortic Vestibule
Posterior to infundibulum
Leads to the aorta
Blood flows upwards, backwards
and to the right side through this
valve
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Semilunar valves
Left

Right

• Pulmonary Valve
• 3 cusps
• Ant, Left, Right
• Nodule at each apex

• Aortic valve
• 3 cusps
• Post, Left, Right
• Nodule at each apex

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Pulmonary and Aortic Sinuses
Right

• 3 pulmonary sinuses behind the
cusps
• Fill during diastole to close the
valve

Left

• 3 aortic sinuses (of Valsalva)
• Left, Right and non-coronary
• Origins of Left and Right Coronary
arteries
• Fill during diastole
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Fibrous skeleton of the heart
• Heart has a structural support frame
formed by a complex set of fibrous
rings with connecting areas

• Provides a great amount of structural
and functional support
• 4 fibrous rings (anulus fibrosus) around
AV, aortic and pulmonary valves
• Between the four rings are two
trigones (right and left) and the
membranous portions of the IA, IV,
and AV septa

23

Fibrous skeleton of the heart
• Serves as origin/ insertion for atrial and ventricular
muscles
• Points of attachment for the cusps
• Maintains the patency and integrity of AV and
semilunar orifices
• Serves as origin/insertion for atrial and ventricular
muscles

• Insulates the atria from the ventricles
• Allows independent atrial and ventricular
contraction
• Atrioventricular bundle of His should be the
only conduction between them (otherwise
arrhythmias)

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Cardiac wall

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Cardiac wall

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Muscles of the Ventricles
• Morphologically there are 2 or 3 types
of muscles on ventricle walls
1. Trabecula carnea: Numerous irregular
muscular ridges

2. Papillary muscles
- Three (usually!) in the right; 2 in the
left ventricle
- Named relative to their position
- Contract before ventricular
contraction

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Muscles of the Ventricles
3. Septomarginal trabecula
(moderator band)
− Only in RV
− Bridge between
interventricular septum and
anterior papillary muscle
− Carries right bundle branch of
AV bundle of cardiac
conduction system

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Cardiac Auscultation
• The valves open and close due to
changes in blood pressure and cause
“sounds” when they close
• Closure of AV valves causes 1st heart
sound (S1): Start of systole
• Closure of semilunar valves causes 2nd
heart sound (S2): Start of diastole

• Sitting or recumbent position,
inspiration, expiration, Valsalva
manoeuvre, exercise can cause changes
in heart sounds

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Surface anatomy
1: Right 3rd costal cartilage
2 cm right of the midline
2: Right 6th costal cartilage
2 cm right of the midline

4
1

2

3

3: Left 5th interspace–
7-9 cm left of the midline
4: Left 2nd costal cartilage
(interspace) –
3 cm left of the midline
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Surface anatomy: Valves

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Cardiac auscultation
1st Heart Sound
• Tricuspid valve (S1): Best heard just to the left
of the lower part of the sternum near the 4th/
5th intercostal space
• Mitral valve (S1): Best heard over the apex of
the heart in the left 5th intercostal space at the
midclavicular line

• 2nd Heart Sound
• Aortic valve (S2): Best heard over the
medial end of the right 2nd intercostal space

• Pulmonary valve (S2): Best heard over the
medial end of the left 2nd intercostal space

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Chest X-ray

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Chest X-ray

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Chest Imaging

Kelley Fig. 6.4

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