MODULE-8-THORAX-2-CARDIOVASCULAR-STRUCTURES-Transcript_docx.pdf

Transcript

Module 8: THORAX 2: CARDIOVASCULAR STRUCTURES
Alarde, Aritrangco, Escalante, Gampong, Jarumahom, Patacsil, Silagan

1
EMBRYOLOGY On day 23, the primitive heart tube elongates,
Cardiac Loop. Because the bulbus cordis and primitive
The heart begins its development from mesoderm on ventricle grow more rapidly than other parts of the tube
day 18 or 19 following fertilization. and because the atrial and venous ends of the tube are
confined by the pericardium, the tube begins to loop
Progenitor heart cells lie in the and fold.
epiblast, immediately adjacent to
the cranial end of the primitive
streak.

From there, they migrate through the streak and into the
visceral layer of lateral plate mesoderm where some form a
horseshoe-shaped cluster of cells called the primary heart On about day 28, thickenings of mesoderm of the
field (PHF) inner lining of the heart wall, called Endocardial cushions,
These cells form portions of the atria and the entire left appear. They grow toward each other, fuse, and divide
ventricle. the single atrioventricular canal (region between atria
and ventricles) into smaller, separate left and right
The right ventricle and atrioventricular canals.
outflow tract (conus cordis
and truncus arteriosus) are Also, the interatrial septum begins its growth
derived from the secondary toward the fused endocardial cushions. Ultimately, the
heart field (SHF), which also interatrial septum and endocardial cushions unite and an
contributes cells to formation opening in the septum, the foramen ovale
of the atria at the caudal end
of the heart

On the 22nd day, the Primitive heart tube develops into
five distinct regions and begins to pump blood. From tail
end to head end (and in the same direction as blood flow
(1) sinus venosus,
(2) primitive atrium,
(3) primitive ventricle,
(4) bulbus cordis,
(5) truncus arteriosus.

MOLECULAR REGULATION OF CARDIAC DEVELOPMENT
Signals from anterior endoderm induce a
heart-forming region in overlying visceral mesoderm
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by inducing the transcription factor NKX2.5.
The signals require secretion of bone morphogenetic
proteins (BMPs) 2 and 4 secreted by the endoderm and
lateral plate mesoderm.
The activity of WNT proteins (3a and 8), secreted by the
neural tube, must be blocked because they normally
inhibit heart development. 2. Atrial Septal Defect
The combination of BMP activity and WNT inhibition by ASD is a congenital heart abnormality with an incidence
CRESCENT and CERBERUS causes expression of NKX2.5, the of 6.4/10,000 births and with a 2:1 prevalence in female
master gene for heart development. to male infants.
BMP expression also upregulates expression of fibroblast
growth factor 8 (FGF8) that is important for the expression One of the most significant defects is the ostium

of cardiac-specific proteins. secundum defect, characterized by a large opening

The combination of BMP activity and WNT inhibition by between the left and right atria. It may be caused by
Crescent and Cerberus causes expression of NKX2.5, the excessive cell death and resorption of the septum
master gene for heart development. primum or by inadequate development of the septum
BMP expression also upregulates expression of fibroblast secundum
growth factor 8 (FGF8) that is important for the expression
of cardiac-specific proteins.

Congenital Heart Defects 3. Ebstein Anomaly is a condition where the tricuspid
1. Hypoplastic right heart syndrome [HRHS] and valve is displaced toward the apex of the right ventricle,
Hypoplastic left heart syndrome are rare defects that and as a result, there is an expanded right atrium and a
cause an underdevelopment of the right or left sides of
small right ventricle.
the heart, respectively.
The valve leaflets are abnormally positioned, and the
anterior one is usually enlarged.
 3
is an example of the 22q11 deletion syndrome
characterized by a pattern of malformations that have
4. Tetralogy of Fallot their origin in abnormal neural crest development.
the most frequently occurring abnormality of the
conotruncal region, is due to an unequal division of the These children have facial defects, thymic hypoplasia,
conus resulting from anterior displacement of the parathyroid dysfunction, and cardiac abnormalities
conotruncal septum. involving the outflow tract, such as persistent truncus
arteriosus and tetralogy of Fallot. Craniofacial
malformations.

HISTOLOGY

LAYERS OF THE HEART WALL

5. A patent ductus arteriosus [PDA]

one of the most
frequently occurring Endocardium
abnormalities of the Consists of:
great vessels [8/I0,000 - a very thin layer of endothelium and supporting
births], especially in connective tissue
- middle myoelastic layer of smooth muscle fibers and
premature infants,
connective tissue
either may be an
- deep layer of connective tissue called the
isolated abnormality or subendocardial layer
may accompany other *small blood vessels and Purkinje fibers found in
heart defects. subendocardial layer
- lines the chambers of the heart and extends over
In particular, defects that cause large differences projecting structures such as the valves, chordae
between aortic and pulmonary pressures may cause tendineae, and papillary muscles
increased blood flow through the ductus, preventing its
Myocardium
normal closure.
- consists mainly of cardiac muscle with its fibers arranged
spirally around each heart chamber
6.DiGeorge sequence

- thickness: ventricle walls (particularly left) > atrial walls
reason: strong force is needed to pump blood
through the systemic and pulmonary circulations
- facilitate the contraction and relaxation of the heart
walls in order to receive and pump the blood into the
systemic circulation
*myocardial cells provide a scaffold for heart
chambers and conduct electrical stimuli
 4
Epicardium Tunica media
- covered by the simple squamous mesothelium that also - intermediate predominantly muscular layer
lines the pericardial space - consists primarily of concentric sheets of smooth muscle
*mesothelial cells secrete a lubricant fluid that which during:
prevents friction as the beating heart contacts the 1) contraction - vessel diameter decreased:
parietal pericardium on the other side of the vasoconstriction
pericardial cavity- consists of loose connective tissue 2) relaxation - vessel diameter increased: vasodilation
containing autonomic nerves and variable amounts - particularly broad and extremely elastic
of fat - at high magnification, it consists of the following:
- consists of an underlying subepicardial layer of a) concentric fenestrated sheets of elastin,
connective tissue separated by collagenous tissue;
*subepicardial layer contains coronary blood vessels, b) and smooth muscle fibres
nerves, and adipose tissue - typically thickest in artery
Tunica adventitia/externa
LAYERS OF BLOOD VESSELS - intermediate pr
- outer connective tissue layer
- consists of elastic and collagen fibers
- contains numerous nerves and, especially in larger
vessels, tiny blood vessels that supply the tissue of the
vessel walls
*vasa vasorum - small blood vessels which supply
blood to the vessel tissues (vessels to vessels)
- easily seen on large vessels such as the aorta
- supplies the vessel wall with nerves and self-vessels
Tunica intima/interna - helps anchor the vessels to surrounding tissues
- forms the inner lining of a blood vessel, and is in direct
contact with the blood as it flows through the lumen LAYERS OF ELASTIC ARTERIES, MUSCULAR ARTERIES, AND
- single layer of flattened endothelial cells supported by a ARTERIOLES BASED ON THEIR DIAMETER, TUNICS AND ROLE
layer of collagenous tissue rich in elastin disposed in the IN THE CIRCULATORY SYSTEM
form of both fibres and discontinuous sheets
- two components:
1) endothelium - innermost layer, continuous with the
endocardial lining of the heart, thin layer of flattened
cells that lines the inner surface of the entire
cardiovascular
system
2) basement membrane - deep to the endothelium,
provides a physical support base for the epithelial
layer
- internal elastic lamina, its outermost part forms its
boundary with the tunica media
 5
VEINS postcapillary venules and cause
extravasation(leaking from vessel to surrounding
tissue/area) of white blood cells during
inflammation and allergic reactions.
High endothelial venules are specialized
postcapillary venules in lymphoid tissue, they are
lined by cuboidal endothelial cells. Locations:
Lymph nodes, tonsils, lymph nodules. High
endothelial venules are not present in the spleen.
Small veins (0.1–1 mm diameter) drain blood from
Veins carry blood toward the heart.
muscular venules. They are lined by endothelium,
Based on diameter, veins are classified as:
2– 3 layers of smooth muscle cells, and
connective tissue adventitia.

Medium-Sized Veins
Venules, small veins, medium-sized veins, and
large veins. 1-10 mm
Has Tunica intima,Tunica media, and Tunica
Venules and Small Veins
adventitia

Smallest veins are called venules.They collect ○ Tunica intima(consists)

blood from capillaries. Endothelium

Diameter are two types: Basal lamina

○ Post-capillary venules (10-50 µm) Thin subendothelial connective

Receive blood from capillaries tissue

Lined by endothelium and Discontinuous internal elastic

pericytes lamina

○ Muscular venules (50-100 µm) ○ Tunica media

Lined by endothelium, 1-2 layers Thin

of smooth muscles and Consists of few layers of smooth

surrounded by thick layer of muscle cells

connective tissue ○ Tunica adventitia

Histamine and serotonin act mainly on Thick layer of connective tissue
 6
containing collagen and elastic contains few smooth muscle cells
fibers ○ Tunica media
Accompany medium-sized arteries (e.g. radial Consists of concentrically
vein, tibial vein, popliteal vein, etc.) arranged smooth muscle cells,
Presence of valves in lumen to prevent collagen fibers, and fibroblasts
retrograde flow of blood Boundary between tunica media
Venous valves are more in veins of lower limb to and tunica intima is difficult to
counteract effect of gravity decide
○ Tunica adventitia
Thickest layer of large vein
Consists of longitudinally arranged
smooth muscle cells
Also contains collagen fibers,
elastic fibers, and fibroblast (e.g.
Superior vena cava, inferior vena
cava)

Larger Veins

>10 mm
CAPILLARIES
Presence of three layer vessels:
○ Tunica intima The smallest blood vessels
Consists of vascular endothelium, Form a network that connects arterioles with
basal lamina, and thin venule and nourishes tissue
subendothelial connective tissue Average diameter of 8 µm (4-10 µm)
Subendothelial connective tissue Human body has ~50,000 miles of capillaries
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(80467.2 km) (>10 kDa)
Lumen at some place is narrower than the Locations: found in connective tissue, muscles,
diameter of RBCs (7.2 µm). RBCs need to get skin, lungs, and central nervous system
folded on themselves for passage through such
capillaries
Consists of endothelium and its basal lamina
NO Tunica media and Tunica adventitia
In some capillaries, pericytes are present
Pericyte lie embedded in basal lamina of
endothelium
Pericyte has long oval euchromatic nuclei and
several cytoplasmic processes that clasp
capillary
Pericyte can get differentiated into smooth
muscle cell or fibroblast

TYPES

Fenestrated Capillaries (Visceral)

endothelial cells have numerous circular
openings called fenestrations (fenestrations =
aperture or pores)
Size of fenestrations: 50–80 nm
Basal lamina is continuous and covers entire
capillary
Fenestrations are developed because of pinched
off process of pinocytosis. Thin endothelium loses
its portion on pinocytosis leaving behind a
fenestration (gap)
Fenestrations are closed by a nonmembranous
Continuous Capillaries (Somatic)
diaphragm that consists of thin layer of cytoplasm

Edges of endothelial cells fuse completely with and basal lamina. Diaphragm closes filtration

adjoining cells by tight junctions (uninterrupted pores or fenestrations

vascular endothelium) Locations: renal glomeruli, pancreas, endocrine

Basement membrane completely surrounds the glands, intestinal villi, choroid plexus, ciliary

endothelium (continuous basal lamina) process of eye, and gallbladder

exchange of nutrients takes place through
cytoplasm of endothelial cells
Transcytosis: Endothelial cells of continuous
capillaries show pinocytic vesicles in the
cytoplasm (mode of transepithelial transport)
Tight junction restricts passage of large molecules
 8
LYMPHATIC VESSEL
carry large molecules and excess extracellular fluid
to main bloodstream (lymph)
Lymph is a fluid that flows through lymphatic vessels
and lymph nodes
It is a pale fluid that is generated from transudate
(extravascular fluid) and contains plasma proteins.
Lymph also contains white blood cells,
predominantly lymphocytes
also contains large fat molecules called
chylomicrons that are absorbed from intestine.
Such lymph containing large amount of fat
molecules looks similar to milk; hence, it is also
called chyle
Discontinuous Capillaries (Sinusoids) Lymph may also contains cancerous cells, viruses,
large, irregular gaps are present in the wall bacteria, and foreign material (dyes)
Endothelial cells have large pores or slits. Most of Lymphatic vessels include: lymph capillaries, large
these pores are not closed by basal lamina lymphatic vessels, and thoracic duct
(discontinuous basal lamina)
Because of sluggish blood flow, sinusoids provide
a chance of exchanging of bigger molecules
easily
Locations:Liver, spleen, lymph nodes, bone
marrow, endocrine glands (adrenal cortex,
hypophysis cerebri, parathyroid gland), and
carotid bodies
In liver, sinusoidal wall shows two special cells:
○ Kupffer cells - Phagocytic (macrophage)
cells
○ Ito cells - Vitamin A storing cells
In spleen, endothelial cells have unique Lymph Capillaries
elongated shape and have gaps between
adjacent cells begin in tissue as blind-ended sacs
lined by lymphatic endothelium
are more permeable than blood capillaries, thus
they permit entry to absorbed larger lipid
molecules in intestine
Most of the tissues have lymph capillaries
absent in: Epidermis, cornea, cartilage, hair, nails,
splenic pulp, bone marrow, choroid, internal ear,
meninges, and nervous tissue
Most of the lymph capillaries carry lymph toward
lymph nodes through afferent lymph vessels
Lymph leave the lymph nodes through efferent
lymph vessels
 9

Lymph Node

Large Lymph Vessels is a small kidney-shaped structure that filters the
lymph
Lymph capillaries join to form lymph vessels
has convex surface and concave area (hilum)
include: thoracic duct, right lymphatic duct,
Each lymph node receives lymph through many
jugular lymph trunk, subclavian trunk,
afferent lymphatic vessels
broncho-mediastinal trunk, intestinal lymph trunks,
Each lymph node has efferent lymphatic vessels
and lumbar lymph trunks
through which filtered lymph leave through hilum.
show tunica intima, media, and adventitia (similar
Lymph node receives blood vessels through
to veins)
hilum
Differences of lymphatic vessels from veins are as
Shows capsule, subscapular sinus, outer cortex,
follows:
paracortex, and medulla

Elastic fibers are present in all layers of
lymphatic vessel

Circular smooth muscles are present in both
tunica media and adventitia of lymphatic
vessels

In thoracic duct, smooth muscles are
arranged longitudinally
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Capsule
thymus-dependent cortex
○ Lymph node is covered by connective
tissue capsule. It is made up of dense Sinuses of Lymph Node
connective tissue ○ three types of sinuses in lymph node:
○ Trabeculae extend from capsule in the Subcapsular sinus/cortical sinus
substance of lymph node Just beneath the
○ Reticular meshwork capsule, a zone called
Reticular tissue forms subcapsular sinus is
supporting meshwork present
consists of reticular cells, It receives lymph from
follicular dendritic cells, afferent lymphatic
macrophages, and reticular vessels
fibers Intermediate/trabecular
cells synthesize type III sinuses
collagen/ reticular fibers Trabecular sinuses are
cells are elongated cells with present adjacent to
fine cytoplasmic processes trabeculae
Dendritic cells are Trabecular sinuses
antigen-presenting cells that connect subcapsular
present antigens to T-cells sinus with medullary
Parenchyma sinuses
○ Outer darkly stained cortex Medullary sinuses
○ Inner lightly stain medulla Medullary sinuses lie
Cortex among the
It is darkly stained outer anastomosing
part of parenchyma medullary cords. They
It consists of: receive lymph from
○ Superficial trabecular sinus and
nodular cortex: drain it into efferent
It shows lymph vessels
presence of ○ Sinuses are filled with reticular
numerous meshwork that helps in filtration of
lymphatic lymph, trapping of cellular debris and
follicles microorganisms, and antigen
○ Deep cortex or presentation to immune cells
paracortex: It Medulla
lies between ○ Medulla is an inner part of the lymph
nodular cortex node. It consists of:
and medulla Medullary cords: These are
Nodular cortex contains mainly anastomosing cords of lymphocytes,
B lymphocytes macrophages, and plasma cells
Lymphatic nodules have Medullary sinuses: These are spaces
central lightly stained germinal that separate adjacent medullary
center and outer darkly cords. They converge at hilum and
stained corona or mantle form efferent lymphatic vessels
zone. Germinal center is the Medullary cords mainly consist of B
zone of B cell proliferation cells, in addition to plasma cells and
Paracortex mainly consists of T macrophages
cells; hence, it is also called
 11

GROSS ANATOMY:
PERICARDIUM
DEFINITION
A PERICARDIUM IS A FIBROSEROUS SAC THAT
ENCLOSES THE HEART AND THE ROOTS OF THE GREAT
VESSELS AND OCCUPIES THE MIDDLE MEDIASTINUM.

POSTERIOR TO THE BODY OF THE STERNUM AND THE
SECOND TO THE SIXTH COSTAL CARTILAGES AND FUNCTION:
ANTERIOR TO THE FIFTH TO THE EIGHT THORACIC TO RESTRICT EXCESSIVE MOVEMENT OF THE HEART AS A
VERTEBRAE WHOLE AND TO SERVE AS A LUBRICATED CONTAINER IN
WHICH THE DIFFERENT PARTS OF THE HEART CAN
RECEIVES BLOOD FROM THE PERICARDIOPHRENIC, CONTRACT FREE FROM THE SURROUNDING STRUCTURES
BRONCHIAL AND ESOPHAGEAL ARTERIES
LAYERS:
IS INNERVATED BY VASOMOTOR AND SENSORY FIBERS
FROM THE PHRENIC AND VAGUS NERVE AND THE FIBROUS PERICARDIUM
SYMPATHETIC TRUNK. IS THE STRONG, FIBROUS OUTER LAYER OF THE
SAC.
The pericardium lies within the middle mediastinum,
posterior to the body of the sternum and the second ATTACHES FIRMLY BELOW TO THE CENTRAL
to the sixth costal cartilages and anterior to the fifth to TENDON OF THE DIAPHRAGM
the eight thoracic vertebrae.
IT FUSES WITH THE OUTER COATS OF THE GREAT
BLOOD VESSELS PASSING THROUGH IT-
NAMELY, THE AORTA, PULMONARY TRUNK,
SUPERIOR AND INFERIOR VENA CAVA, AND THE
PULMONARY VEINS. (SNELL)

ATTACHES IN FROM OF THE STERNUM BY
FIBROUS BANDS CALLED THE
STERNOPERICARDIAL

LIGAMENT (MOORE)
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A CONTINUOUS SUPERIORLY WITH THE TUNICA epicardium. The slit-like space between the
ADVENTITIA OF THE GREAT VESSELS ENTERING AND parietal and visceral layers is referred to as the
LEAVING THE HEART AND FUSING WITH
pericardial cavity. Normally, the cavity contains
PRETRACHEAL LAYER OF DEEP CERVICAL FASCIA
(MOORE) a small amount of tissue fluid (about 50 mL), the
pericardial fluid, which acts as a lubricant to
THE INFERIOR WALL(FLOOR) OF THE FIBROUS facilitate movements of the heart. (SNELL)
PERICARDIAL SAC IS FIRMLY ATTACHED AND
CONFLUENT (PARTIALLY BLENDED) CENTRALLY
PERICARDIAL SINUSES
WITH THE CENTRAL TENDON OF THE DIAPHRAGM.
(reference:https://slideplayer.com/slide/7887489
/)

THE SITE OF CONTINUITY HAS BEEN REFERRED TO
AS THE PERICARDIACOPHRENIC LIGAMENT
HOWEVER, THE FIBROUS PERICARDIUM AND
CENTRAL TENDON ARE NOT TWO SEPARATE
STRUCTURES THAT FUSED TOGETHER
SECONDARILY, NOR ARE THEY SEPARABLE BY
DISSECTION
(reference:https://slideplayer.com/slide/7887489
/)

SEROUS PERICARDIUM
The pericardial sinuses are spaces posterior to the heart
formed by the reflections of the serous pericardium
around the great vessels.
TRANSVERSE SINUS
- relatively short horizontal space between the
reflection of the serous pericardium around the
aorta and pulmonary trunk and the reflection
around the large veins
OBLIQUE SINUS
- The reflection around the large veins forms an
inverted U-shaped cup-de-sac.

The serous pericardium lines the fibrous - Runs along the axis of the heart, from apex to the
pericardium and coats the heart. It is divided into ascending aorta
parietal and visceral layers. (SNELL)

Parietal layer lines the inner surface of the fibrous
pericardium and reflects around the roots of the
great vessels to become continuous with the
visceral layer of serous pericardium that closely
covers the heart. (SNELL)
Visceral layer is closely applied to the superficial
surface of the heart and is often called the
 13
serous pericardium. (SNELL)

HEART

OVERVIEW:
THE RIGHT SIDE RECEIVES OXYGEN-POOR BLOOD FROM
THE BODY AND TISSUES AND THEN PUMPS IT TO THE LUNGS
TO PICK UP OXYGEN AND DISPEL CARBON DIOXIDE

ITS LEFT SIDE RECEIVES OXYGENATED BLOOD RETURNING
FROM THE LUNGS AND PUMPS THIS BLOOD THROUGHOUT
THE BODY TO SUPPLY OXYGEN AND NUTRIENTS TO THE
BLOOD SUPPLY OF THE PERICARDIUM (NOTE: INFOS BELOW
BODY TISSUES
CAN BE FOUND IN KENHUB AND MOORE)

The arterial supply of the pericardium comes -MOORE-
predominantly from the pericardiacophrenic -SLIGHTLY LARGER THAN ONE’S LOOSELY CLENCHED FIST
artery (a branch of the internal thoracic artery). - A DOUBLE, SELF-ADJUSTING SUCTION AND PRESSURE
This artery is located within the fibrous PUMP
pericardium on its passage through the thoracic - CONSISTS OF FOUR CHAMBERS:
cavity. 1. RIGHT ATRIUM
2. LEFT ATRIUM
Additionally, the musculophrenic artery (a 3. RIGHT VENTRICLE
terminal branch of the internal thoracic), 4. LEFT VENTRICLE
bronchial, esophageal, and superior phrenic
arteries (branches of the thoracic aorta) LAYERS OF THE HEART (DEEP TO SUPERFICIAL)
contribute to vascularisation of the pericardium. ENDOCARDIUM- A THIN LAYER (ENDOTHELIUM AND
SUBENDOTHELIAL CONNECTIVE TISSUE) OR LINING
Note that coronary arteries also take part in MEMBRANE OF THE HEART THAT ALSO COVERS ITS VALVES
arterial supply, but only to the visceral layer of the
serous pericardium. MYOCARDIUM- A THICK, HELICAL MIDDLE LAYER
COMPOSED OF CARDIAC MUSCLE
NERVE SUPPLY OF THE PERICARDIUM
-MOORE- EPICARDIUM- A THIN EXTERNAL LAYER (MESOTHELIUM)
PHRENIC NERVE (C3-C5): FORMED BY THE VISCERAL LAYER OF SEROUS
- PRIMARY SOURCE OF SENSORY FIBERS; PAIN PERICARDIUM.
SENSATIONS CONVEYED BY THESE NERVES ARE
COMMONLY REFERRED TO THE SKIN (C3-C5 STRUCTURE
DERMATOMES) OF THE IPSILATERAL -SNELL-
SUPRACLAVICULAR REGION (TOP OF THE
SHOULDER OF THE SAME SIDE. TWO INTERNAL SEPTA (DIVIDES THE HEART INTO 4
VAGUS NERVES CHAMBERS)
- FUNCTION UNCERTAIN 1. ATRIAL (INTERATRIAL)SEPTUM- SEPARATES THE
SYMPATHETIC TRUNKS RIGHT AND LEFT ATRIA
- VASOMOTOR 2. VENTRICULAR (INTERVENTRICULAR) SEPTUM
- SEPARATES THE RIGHT AND LEFT
Phrenic nerves carry sensory fibers from the pericardium VENTRICLES
and the parietal layer of the serous pericardium. Visceral - LIES OBLIQUELY, WITH THE RIGHT SURFACE
afferent fibers travel with branches of the sympathetic FACING FORWARD AND TO THE RIGHT
trunks and the vagus nerve from the visceral layer of the
 14
AND LEFT SURFACE FACING BACKWARD
AND TO THE LEFT
- HAS A LOWER, THICKER AND MUSCULAR
PART AND A SMALLER UPPER, THINNER
MEMBRANOUS PART.

BORDERS
-SNELL AND MOORE-

RIGHT BORDER (SLIGHTLY CONVEX) -COMPOSE OF THE
RIGHT ATRIUM AND EXTENDING BETWEEN THE SVC AND THE APEX OF THE HEART
THE IVC IS FORMED BY THE INFEROLATERAL PART OF THE
LEFT VENTRICLE (MOORE)
LEFT BORDER (OBLIQUE, NEARLY VERTICAL)- COMPOSE LIES AT THE LEVEL OF THE 5TH LEFT INTERCOSTAL
OF THE LEFT AURICLE AND LEFT VENTRICLE SPACE, 3.5 in. (9cm) FROM THE MIDLINE (SNELL)
NORMALLY REMAINS MOTIONLESS THROUGHOUT
INFERIOR (LOWER) BORDER (NEARLY HORIZONTAL)- THE CARDIAC CYCLE (MOORE)
MAINLY FORMED BY THE RIGHT VENTRICLE IS WHERE THE SOUNDS OF MITRAL VALVE CLOSURE
ARE MAXIMAL (APEX BEAT); THE APEX UNDERLIES
SUPERIOR BORDER- FORMED BY THE RIGHT AND LEFT ATRIA THE SITE WHERE THE HEARTBEAT MAY BE
AND AURICLES IN AN ANTERIOR VIEW; THE ASCENDING AUSCULTATED ON THE THORACIC WALL. (MOORE)
AORTA AND PULMONARY TRUNK EMERGE FROM THIS
BORDER AND THE SVC ENTERS ITS RIGHT SIDE. POSTERIOR THE BASE OF THE HEART (MOORE)
TO THE AORTA AND PULMONARY TRUNK AND ANTERIOR IS THE HEART’S POSTERIOR ASPECT (OPPOSITE THE
TO THE SVC, THIS BORDER FORMS THE INFERIOR APEX)
BOUNDARY OF THE TRANSVERSE PERICARDIAL SINUS. IS FORMED MAINLY BY THE LEFT ATRIUM, WITH A
LESSER CONTRIBUTION BY THE RIGHT ATRIUM
FACE POSTERIORLY TOWARD THE BODIES OF
VERTEBRAE T6-T9 AND IS SEPARATED FROM THEM
BY THE PERICARDIUM, OBLIQUE PERICARDIAL
SINUS, ESOPHAGUS, AND AORTA
EXTENDS TO THE BIFURCATION OF THE
PULMONARY TRUNK SUPERIORLY, AND INFERIORLY
TO THE CORONARY SULCUS
RECEIVES PULMONARY VEINS ON THE RIGHT AND
LEFT SIDES OF ITS LEFT ATRIAL PORTION AND THE
SUPERIOR AND INFERIOR VENAE CAVAE AT THE
SUPERIOR AND INFERIOR ENDS OF ITS RIGHT
ATRIAL PORTION

THE BASE OF THE HEART IS CALLED THE BASE OF BECAUSE
THE HEART IS PYRAMID SHAPED AND THE BASE LIES
OPPOSITE THE APEX. (SNELL)

NOTE!
THE HEART DOES NOT REST ON ITS BASE: IT RESTS ON ITS
DIAPHRAGMATIC (INFERIOR) SURFACE

ADDITIONAL LEARNING:
 15
The fibrous skeleton of the heart, also called the cardiac
skeleton, consists of four fibrous rings (anuli fibrosi, singular:
annulus fibrosis) and the membranous portions of the septa
of the heart. This skeleton is located at the base of the
ventricles, between the atria and the ventricles.
The rings of the fibrous skeleton are composed of dense,
fibrous connective tissue that encircle the orifices of the
heart valves. These fibrous rings are interconnected by
connective tissue called the right and left trigones and form
the structural support for the heart on which the valvular
leaflets and cardiac muscle fibers are anchored. (KENHUB)

A. RIGHT ATRIUM

FORMS THE RIGHT BORDER OF THE HEART AND
RECEIVES VENOUS BLOOD FROM THE SVC, IVC,
AND CORONARY SINUS.(MOORE)

CONSISTS OF TWO PARTS: (SNELL)
- MAIN CAVITY (ATRIUM PROPER) - smooth
walled and forms from the embryonic
sinus venosus
- AURICLE- A SMALL EARLIKE
OUTPOUCHING; roughened or
(PHOTO FROM MOORE)

SURFACES: (MOORE)
1. STERNOCOSTAL (ANTERIOR) - FORMED MAINLY BY
THE RIGHT VENTRICLE

2. DIAPHRAGMATIC (INFERIOR)- FORMED MAINLY BY
THE LEFT VENTRICLE AND PARTLY BY THE RIGHT
VENTRICLE; IT IS RELATED MAINLY TO THE CENTRAL
TENDON OF THE DIAPHRAGM

3. BASE(POSTERIOR)
RIGHT PULMONARY SURFACE- FORMED MAINLY BY
THE RIGHT ATRIUM
LEFT PULMONARY SURFACE- FORMED MAINLY BY trabeculated by bundles of muscle fibers,
THE LEFT VENTRICLE; IT FORMS THE CARDIAC the musculi pectinati (pectinate muscle
IMPRESSION IN THE LEFT LUNG.
THE INTERIOR OF THE RIGHT ATRIUM (MOORE)

CHAMBERS OF THE HEART
 16
SMOOTH, THIN-WALLED, POSTERIOR PART (THE
SINUS VENARUM)ON WHICH THE VENA CAVA
AND CORONARY SINUS OPEN, BRINGING POORLY
OXYGENATED BLOOD INTO THE HEART

ROUGH, MUSCULAR ANTERIOR WALL COMPOSED
OF PECTINATE MUSCLES (L. MUSCULI PECTINATI)

RIGHT AV ORIFICE THROUGH WHICH THE RIGHT
ATRIUM DISCHARGES THE POORLY OXYGENATED
BLOOD IT HAS RECEIVED INTO THE RIGHT
VENTRICLE
RIGHT ATRIOVENTRICULAR VALVE (TRICUSPID VALVE)
REGULATES THE RIGHT ATRIOVENTRICULAR ORIFICE,
SULCUS TERMINALIS(TERMINAL GROOVE)- EXTERNALLY
WHICH LIES ANTERIOR TO THE INFERIOR VENA CAVA
SEPARATES THE SMOOTH AND ROUGH PARTS OF THE
OPENING.
ATRIAL WALL.

B. LEFT ATRIUM
CRISTA TERMINALIS- A VERTICAL RIDGE THAT INTERNALLY
SEPARATES THE SMOOTH AND ROUGH PARTS OF THE
ATRIAL WALL.
FORMS MOST OF THE BASE OF THE HEART
ADDITIONAL: (MOORE)

THE OPENING OF THE CORONARY SINUS-A SHORT THE VALVELESS PAIRS OF RIGHT AND PULMONARY
VENOUS TRUNK RECEIVING MOST OF THE VEINS ENTER THE SMOOTH- WALLED ATRIUM
CARDIAC VEINS; BETWEEN THE RIGHT AV ORIFICE (MOORE)
AND THE IVC ORIFICE.
TWO PARTS: (SNELL)
THE INTERATRIAL SEPTUM- HAS AN OVAL, - ATRIUM PROPER (MAIN CAVITY)
THUMBPRINT-SIZED DEPRESSION, THE OVAL FOSSA - AURICLE
AND SEPARATES THE ATRIA. SITUATED BEHIND THE RIGHT ATRIUM AND FORMS
THE GREATER PART OF THE BASE OF THE HEART.
THE SVC OPENS INTO THE SUPERIOR PART OF THE RECEIVES OXYGENATED BLOOD FROM THE LUNGS
RIGHT ATRIUM AT THE LEVEL OF THE RIGHT 3RD VIA THE PULMONARY VEINS (4 OSTIA)
COSTAL CARTILAGE. THICKER WALLS
ITS LEFT AURICLE CONTAINS PECTINATE MUSCLE
THE IVC OPENS INTO THE INFERIOR PART OF THE LANDMARKS: T5-58 (SUPINE), T6-T9(ERECT)
RIGHT ATRIUM ALMOST IN LINE WITH THE SVC AT
APPROXIMATELY THE LEVEL OF THE 5TH COSTAL THE INTERIOR OF THE LEFT ATRIUM
CARTILAGE ❖ A LARGER SMOOTH-WALLED PART AND A
SMALLER MUSCULAR AURICLE CONTAINING
PECTINATE MUSCLE
❖ FOUR PULMONARY VEINS (TWO SUPERIOR AND
INFERIOR) ENTERING ITS SMOOTH POSTERIOR WALL
❖ A SLIGHTLY THICKER WALL THAN THAT OF THE
RIGHT ATRIUM
❖ AN INTERATRIAL SEPTUM THAT SLOPES
POSTERIORLY AND TO THE RIGHT
 17
RECEIVES BLOOD FROM THE RIGHT ATRIUM AND
PUMPS IT VIA PULMONARY TRUNK INTO THE LUNGS
FOR BLOOD OXYGENATION

THE WALLS ARE MUCH THICKER THAN THOSE RIGHT
ATRIUM AND SHOW MANY INTERNAL PROJECTING
RIDGES FORMED OF MUSCLE FIBERS

THE INTERIOR OF THE RIGHT VENTRICLE HAS
IRREGULAR MUSCULAR ELEVATIONS (TRABECULAE
CARNEA).

SUPRAVENTRICULAR CREST, A THICK MUSCULAR
RIDGE (FOUND IN RIGHT VENTRICLE) SEPARATES
THE RIDGED MUSCULAR WALL OF THE INFLOW
PART OT THE CHAMBER FROM THE SMOOTH WALL
OPENINGS INTO THE LEFT ATRIUM OF THE CONUS ARTERIOSUS OR OUTFLOW PART.
THE FOUR PULMONARY VEINS, TWO FROM EACH LUNG, THE INFLOW PART OF THE VENTRICLE RECEIVES
OPEN THROUGH THE POSTERIOR WALL AND HAVE NO BLOOD FROM THE RIGHT ATRIUM THROUGH THE
VALVES. THE LEFT ATRIOVENTRICULAR ORIFICE IS RIGHT AV (TRICUSPID) ORIFICE
GUARDED BY THE MITRAL VALVE.
VALVES SNELL)
C. RIGHT VENTRICLE (MOORE AND SNELL) RIGHT ATRIOVENTRICULAR (TRICUSPID) VALVE
GUARDS THE RIGHT ATRIOVENTRICULAR ORIFICE
CONSISTS OF THREE CUSPS FORMED BY A FOLD OF
ENDOCARDIUM WITH SOME CONNECTIVE TISSUE
ENCLOSED:
1. ANTERIOR
2. SEPTAL
3. INFERIOR (POSTERIOR) CUSPS

VENTRICULAR VALVE
GUARDS THE PULMONARY ORIFICE AND CONSISTS
OF THREE SEMILUNAR CUSPS THAT FORMED OF
ENDOCARDIUM WITH SOME CONNECTIVE TISSUE
ENCLOSED:
1. ANTERIOR
2. RIGHT
3. LEFT CUSPS
TAKES UP THE MAJORITY OF THE ANTERIOR
SURFACE OF THE HEART, A SMALL PART OF THE
DIAPHRAGMATIC SURFACE, AND MOST THE ENTIRE THREE PAPILLARY MUSCLES (CORRESPOND TO THE CUSPS
INFERIOR BORDER OF THE HEART OF THE TRICUSPID VALVE)

SUPERIORLY, IT TAPERS INTO AN ARTERIAL CONE, 1. ANTERIOR PAPILLARY MUSCLE
THE CONUS ARTERIOSUS (INFUNDIBULUM), WHICH LARGEST AND MOST PROMINENT
LEADS INTO THE PULMONARY TRUNK. ARISES FROM THE ANTERIOR WALL OF THE
RIGHT VENTRICLE
 18
ITS TENDINOUS CORDS ATTACH TO THE INTERVENTRICULAR SEPTUM (IVS)- (MOORE)
ANTERIOR AND POSTERIOR CUSPS OF THE COMPOSED OF MUSCULAR AND MEMBRANOUS
TRICUSPID VALVE PARTS
2. POSTERIOR PAPILLARY MUSCLE
SMALLER THAN THE ANTERIOR MUSCLE A STRONG, OBLIQUELY PLACED PARTITION
CONSIST OF SEVERAL PARTS BETWEEN THE RIGHT AND LEFT VENTRICLES
ARISES FROM THE INFERIOR WALL OF THE FORMING PART OF THE WALLS OF EACH OTHER.
RIGHT VENTRICLE
ITS TENDINOUS CORDS ATTACH TO THE MUSCULAR PART OF (IVS)- FORMS THE MAJORITY
POSTERIOR AND SEPTAL CUSPS OF THE OF THE SEPTUM ; HAS THE THICKNESS OF THE
TRICUSPID VALVE REMAINDERS OF THE WALL OF THE LEFT VENTRICLE
3. SEPTAL PAPILLARY MUSCLE AND BULGES INTO THE CAVITY OF THE RIGHT
ARISES FROM THE INTERVENTRICULAR VENTRICLE
ITS TENDINOUS CORDS ATTACH TO THE MEMBRANOUS PART OF THE (IVS)- FOUND
ANTERIOR AND SEPTAL CUSPS OF THE SUPERIORLY AND INFERIORLY; A THIN MEMBRANE
TRICUSPID VALVE. AND A PART OF THE FIBROUS SKELETON OF THE
HEART
SEPTOMARGINAL TRABECULA (MODERATOR BAND)
A CURVED MUSCULAR BUNDLE THAT TRANSVERSES
THE RIGHT VENTRICULAR CHAMBER FROM THE
INFERIOR PART OF THE IVS TO THE BASE OF THE
ANTERIOR PAPILLARY MUSCLE

D.LEFT VENTRICLE

FORMS THE APEX OF THE HEART, NEARLY ALL ITS
LEFT (PULMONARY) SURFACE AND BORDER AND
MOST OF THE DIAPHRAGMATIC SURFACE.
ITS WALLS ARE SUBSTANTIALLY THICKER THAN
THOSE OF THE RIGHT VENTRICLE
MORE POWERFUL PUMP THAN THE LEFT VENTRICLE
THE LARGEST OF ALL THE CHAMBERS, MAINLY DUE
TO THE THICKNESS OF ITS MUSCULAR WALL
OCCUPIES MOST OF THE PULMONARY AND
INFERIOR SURFACES OF THE HEART, INCLUDING ITS
APEX
ADDITIONAL INFO ABOUT RV
PERFORM MORE WORK THAN THE RIGHT
VENTRICLE DUE TO ITS ARTERIAL HIGH PRESSURE.
TRICUSPID VALVE- GUARDS THE RIGHT AV ORIFICE.

THE INTERIOR OF THE LEFT VENTRICLE HAS: MOORE
TENDINOUS CORDS- ATTACH TO THE FREE EDGES AND
VENTRICULAR SURFACES OF THE ANTERIOR, POSTERIOR
AND SEPTAL CUSPS.

VENTRICULAR DIASTOLE- BLOOD FLOW BACK TOWARD
THE HEART AND ENTERS THE SINUSES;THE VALVE CUSPS FILL,
COME INTO APPOSITION IN THE CENTER OF THE LUMEN,
AND CLOSE THE PULMONARY ORIFICE. (SNELL)
 19
WALLS THAT ARE TWO TO THREE TIMES AS THICK AS REVERSAL OF FLOW TAKES PLACE AROUND THE ANTERIOR
THOSE OF THE RIGHT VENTRICLE CUSP OF THE MITRAL VALVE.

WALLS ARE MOSTLY COVERED WITH A MESH OF AORTIC VALVE- OBLIQUELY PLACED BETWEEN THE LEFT
TRABECULAE CARNEAE THAT ARE FINER AND VENTRICLE AND THE ASCENDING AORTA; LOCATED
MORE NUMEROUS THAN THOSE OF THE RIGHT POSTERIOR TO THE LEFT SIDE OF THE STERNUM AT THE LEVEL
VENTRICLE OF THE 3RD RIB. (SNELL)
3 CUSPS:
A CONICAL CAVITY THAT IS LONGER THAN THAT 1. RIGHT CORONARY
OF THE RIGHT VENTRICLE 2. LEFT CORONARY
3. POSTERIOR (NONCORONARY)
ANTERIOR AND POSTERIOR PAPILLARY MUSCLES
THAT ARE LARGER THAN THOSE IN THE RIGHT
VENTRICLE

A SMOOTH-WALLED, NONMUSCULAR,
SUPERO-ANTERIOR OUTFLOW PART, THE AORTIC
VESTIBULE , LEADING FROM THE VENTRICULAR
CAVITY TO THE AORTIC ORIFICE AND AORTIC
VALVE

A DOUBLE-LEAFLET MITRAL VALVE THAT GUARDS
THE LEFT AV ORIFICE

AN AORTIC ORIFICE THAT LIES IN ITS RIGHT
POSTEROSUPERIOR PARTS AND IS SURROUNDED BY
(KEY POINTS OF LEFT VENTRICLE: TABLE FROM KENHUB)
A FIBROUS RING TO WHICH THE RIGHT POSTERIOR
AND LEFT CUSPS OF THE AORTIC VALVE ARE
GREAT VESSELS
ATTACHED; THE ASCENDING AORTA BEGINS AT
1. Ascending Aorta
THE AORTIC ORIFICE.

LEFT ATRIOVENTRICULAR (MITRAL) VALVE (MOORE)
LOCATED POSTERIOR TO THE STERNUM AT THE
LEVEL OF THE 4TH COSTAL CARTILAGE
GUARDS THE ATRIOVENTRICULAR ORIFICE AND
HAS TWO CUSPS:
1. ONE ANTERIOR- LARGER AND INTERVENES
begins at the base of the left ventricle and runs
BETWEEN THE ATRIOVENTRICULAR AND AORTIC
upward and forward to come to lie behin
ORIFICE
d the right half of the sternum at the level of the
2. ONE POSTERIOR
sternal angle
it becomes continuous with the arch of the aorta
(EACH CUSPS RECEIVES TENDINOUS CORDS FROM MORE
THAN ONE PAPILLARY MUSCLE. THE CORDS BECOME TAUT Aortic Sinuses
JUST BEFORE AND DURING SYSTOLE, PREVENTING THE at the root of ascending aorta possess 3 bulges
CUSPS FROM BEING FORCED INTO THE LEFT ATRIUM.AS IT called Aortic Sinuses
TRANSVERSES THE LEFT VENTRICLE, THE BLOODSTREAM One aortic sinus is located behind each aortic
UNDERGOES TWO RIGHT ANGLE TURNS, WHICH TOGETHER valve cusp
RESULTS IN 180 DEGREES CHANGE IN DIRECTION.THIS
 20
Arteries originate from these Aortic Sinus into the iliac arteries just above the pelvis.
3. Ligamentum Arteriosum

Right coronary artery arises from the right aortic sinus
runs forward between the right side of the - is a fibrous band that connects the bifurcation of
pulmonary trunk and the right auricle, and the pulmonary trunk to the lower concave
descends almost vertically in the right surface of the aortic arch
atrioventricular groove (coronary sulcus) - The ligamentum arteriosum is the remnant of the
At the inferior border of the heart, it continues ductus arteriosus, which in the fetus conducts
posteriorly along the atrioventricular groove to blood from the pulmonary trunk to the aorta, thus
anastomose with the left coronary artery in the bypassing the lungs.
posterior interventricular groove. - The left recurrent laryngeal nerve hooks around

Left coronary artery arises from the left aortic sinus the lower border of the ductus which closes after

usually larger than the right coronary artery birth.

supplies the major part of the heart - Should it remain patent, aortic blood will enter
the pulmonary circulation.Surgical ligation of the
passes forward between the left side of the
ductus is then necessary, and the surgeon must
pulmonary trunk and the left auricle, enters the
take care to preserve the left recurrent laryngeal
atrioventricular groove (coronary sulcus), and nerve.
divides into an anterior interventricular branch
and a circumflex branch
2. Course of Aorta
4. Flow of Blood

The aorta is the largest blood vessel in the body
and is responsible for transporting oxygen rich
blood from your heart to the rest of your body.
It begins at the left ventricle of the heart,
extending upward (Ascending Aorta) into the
chest to form an Aortic Arch. It then continues
1. Oxygen-poor blood returns from the body to the
downward (Descending Aorta) into the
heart through the superior vena cava (SVC) and
abdomen (Abdominal Aorta), where it branches
 21
inferior vena cava (IVC), the two main veins that Brachiocephalic artery- passes upward and to
bring blood back to the heart. the right of the trachea and divides into the right
2. The oxygen-poor blood enters the right atrium subclavian and right common carotid arteries
(RA), or the right upper chamber of the heart. behind the right sternoclavicular joint.
3. From there, the blood flows through the tricuspid
valve (TV) into the right ventricle (RV), or the right Left common carotid artery - arises on the left
lower chamber of the heart side of the brachiocephalic artery. It runs upward
4. The right ventricle (RV) pumps oxygen-poor and to the left of the trachea and enters the
blood through the pulmonary valve (PV) into the neck behind the left sternoclavicular joint.
main pulmonary artery (MPA).
5. From there, the blood flows through the right and Left subclavian artery - arises from the aortic
left pulmonary arteries into the lungs. arch behind the left common carotid artery. It
6. In the lungs, oxygen is put into the blood and runs upward along the left side of the trachea
carbon dioxide is taken out of the blood during and the esophagus to enter the root of the neck.
the process of breathing. After the blood gets It arches over the apex of the left lung and
oxygen in the lungs, it is called oxygen-rich continues toward the left upper limb.
blood.
7. Oxygen-rich blood flows from the lungs back into
the left atrium (LA), or the left upper chamber of Descending Thoracic Aorta- lies in the posterior

the heart, through four pulmonary veins. mediastinum. It begins as the continuation of the arch of

8. Oxygen-rich blood then flows through the mitral the aorta on the left side of the lower border of the body

valve (MV) into the left ventricle (LV), or the left of the fourth thoracic vertebra.

lower chamber.
9. The left ventricle (LV) pumps the oxygen-rich
blood through the aortic valve (AoV) into the
aorta (Ao), the main artery that takes
oxygen-rich blood out to the rest of the body.

AORTIC ARCH/ DESCENDING THORACIC AORTA

Aortic Arch- is the continuation of the ascending aorta.

Branches:
Bronchial arteries- supply the lungs
Pericardial arteries- supply dorsal portion of
pericardium
Superior phrenic arteries- support the diaphragm
Esophageal arteries- supply the esophagus
Posterior intercostal arteries- supply the
intercostal spaces
Subcostal arteries- supply the flat abdominal wall
Branches:
muscles

Subclavian artery
 22
-Is a paired arterial vessel of the thorax. -is a long, paired vessel that originates from the proximal
-Main function of the subclavian artery is to supply blood part of the subclavian artery.
to the upper limbs, thorax, neck, and brain.
Origin Subclavian artery

Branches Anterior collaterals:
-Anterior intercostal branches
-Perforating branches
-Medial mammary arteries

Posterior collaterals:
-Mediastinal branches
-Thymic branches
Branches:
-Pericardiacophrenic artery

Vertebral artery- is the first branch of the -Sternal branches

subclavian artery. It courses superiorly along -Bronchial branches

each side of the neck region and ultimately -Tracheal branches

merges with its counterpart at the Terminal branches:

pontomedullary junction to form the basilar
artery. The vertebral artery supplies the upper -Superior epigastric artery

spinal cord, brainstem, cerebellum and posterior -Musculophrenic artery

part of the brain.
Supply Skin and muscles of the anterior
Internal thoracic artery- in contrast to the
aspect of the thoracic cage and
vertebral artery, descends along the inner
superior aspect of the abdominal
surface of the anterior chest wall. It gives rise to
wall, typical ribs, breasts, parietal
several branches along its course to supply the
pleura, sternum, pericardium and
anterior thoracic wall and the breast.
thymus.
Thyrocervical trunk- is a short and wide branch
that arises close to the medial border of the
anterior scalene muscle. Its major branch, the
SUPERIOR VENA CAVA
inferior thyroid artery, supplies several important
structures in the neck including the larynx,
The two brachiocephalic
pharynx, trachea, platysma, esophagus, thyroid veins join to form the superior
and parathyroid glands). vena cava, which conveys all
Costocervical trunk- this short artery that supplies the venous blood from the
the posterior cervical muscles and upper thorax. head and neck and both
Dorsal scapular artery-this artery provides arterial upper limbs. It passes
downward to end in the right
supply for muscles of the upper back and
atrium of the heart.
shoulder including the trapezius muscle, levator
scapulae muscle and rhomboid muscle The azygos vein joins the
posterior aspect of the
The internal thoracic artery (internal mammary artery) superior vena cava just
before it enters the
 23
pericardium
Left brachiocephalic vein
It is a large vein, with a wide diameter of up to 2cm and The tributaries of the
a length of approximately 7cm. left brachiocephalic
vein are the left
After Circulating through the body systemically, vertebral, internal
Deoxygenated Blood returns to the Right Atrium of the thoracic, inferior
heart through either the SVC, which drains the upper thyroid and superior
Body, or the IVC that drains everything below the intercostal veins.
Diaphragm. In addition, it often
receives the thymic,
supreme intercostal,
pericardiacophrenic
and the left posterior
intercostal vein of the 1st intercostal space.

The SVC receives tributaries from several minor vein Right brachiocephalic
groups:
The tributaries of the right
Mediastinal veins brachiocephalic vein are the
Oesophageal veins right vertebral, internal
Pericardial veins thoracic and inferior thyroid
veins, and occasionally the
Brachiocephalic vein (Innominate vein) right posterior intercostal vein
of the 1st intercostal space.
The brachiocephalic vein, also known as the innominate
vein, is a paired vein of the superior mediastinum that
drains the venous blood from the head and neck, upper
limbs and the upper
part of the thorax.
Azygos Vein
The azygos venous system
It is formed by the
is located on either side of
confluence of the
the vertebral column and
internal jugular and
drains the viscera within
subclavian veins on
the mediastinum, as well
each side, just
as the back and
posterior to the
thoracoabdominal walls.
sternoclavicular joint.
This system consists of the azygos vein and its two
main tributaries: the hemiazygos vein and the
 24
accessory hemiazygos vein.

Tributaries
The azygos vein has two tributaries, which are referred to
as the hemiazygos vein and the accessory hemiazygos
vein.

The hemiazygos vein is
often connected to the left
renal vein. It is formed by
the oesophageal and
mediastinal tributaries, the Tributaries
common trunk of the left The subclavian vein receives venous blood from the
ascending lumbar vein and internal and external jugular veins of the lateral cervical
left subcostal vein, and by region, as well as the dorsal scapular vein which drains
the lower three posterior the region of the same name, as well as the anterior
intercostal veins. It ascends jugular vein, which lies on the front of the neck.
anterior to the vertebral
column before crossing the
column posterior to the aorta, esophagus and thoracic
duct at the level of T8.

The accessory hemiazygos vein is formed by veins from
the fourth to eighth intercostal spaces and sometimes by
the left bronchial veins.

It descends to the left of the vertebral column before
crossing T7, where it joins with the azygos vein. Sometimes
it joins the hemiazygos vein and, in this case, their
common trunk drains into the azygos vein.

Subclavian vein
The subclavian vein is the
major vein of the arm,
shoulder and neck. Its
name means ‘under the CORONARY CIRCULATION
clavicle’, due to the Arterial Supply
course it takes when The 2 main coronary arteries are the left main
entering the thorax. and right coronary arteries:
○ Left main coronary artery (LMCA). The left
main coronary artery supplies blood to
the left side of the heart muscle (the left
ventricle and left atrium). The left main
coronary divides into branches:
The left anterior descending
artery branches off the left
coronary artery and supplies
blood to the front of the left side
of the heart.
 25
The circumflex artery branches The venous drainage of the heart is mostly
off the left coronary artery and through the coronary sinus – a large venous
encircles the heart muscle. This structure located on the posterior aspect of the
artery supplies blood to the outer heart. The cardiac veins drain into the coronary
side and back of the heart. sinus, which in turn, empties into the right atrium.
○ Right coronary artery (RCA). The right There are also smaller cardiac veins which pass
coronary artery supplies blood to the directly into the right atrium.
right ventricle, the right atrium, and the Tributaries
SA (sinoatrial) and AV (atrioventricular) ○ Great cardiac vein (anterior
nodes, which regulate the heart rhythm. interventricular vein) – the largest
The right coronary artery divides into tributary of the coronary sinus. It
smaller branches, including the right originates at the apex of the heart and
posterior descending artery and the ascends in the anterior interventricular
acute marginal artery. Together with the groove. It then curves to the left and
left anterior descending artery, the right continues onto the posterior surface of
coronary artery helps supply blood to the the heart. Here, it gradually enlarges to
middle or septum of the heart. form the coronary sinus.
Smaller branches of the coronary arteries ○ Small cardiac vein – located on the
include: obtuse marginal (OM), septal perforator anterior surface of the heart, in a groove
(SP), and diagonals. between the right atrium and right
ventricle. It travels within this groove onto
the posterior surface of the heart, where
it empties into the coronary sinus.
○ Middle cardiac vein (posterior
interventricular vein) – begins at the apex
of the heart and ascends in the posterior
interventricular groove to empty into the
coronary sinus.
○ Posterior cardiac vein – located on the
posterior surface of the left ventricle. It lies
to the left of the middle cardiac vein and
empties into the coronary sinus.

Anterior View
PHYSIOLOGY: GUYTON

1. STATE THE PHASIC CHANGES IN CORONARY
BLOOD FLOW DURING SYSTOLE AND DIASTOLE IN
RELATION TO THE EFFECT OF CARDIAC MUSCLE
COMPRESSION.

Posterior View

Venous Supply
 26
FLOW IN RELATION TO THE EFFECT OF
INTRAMYOCARDIAL PRESSURE.

Figure demonstrates the special arrangement of
the coronary vessels at different depths in the
heart muscle, showing on the outer surface
Figure shows the changes in blood flow epicardial coronary arteries which supply most of
through the nutrient capillaries of the left the muscle.
ventricular coronary system in ml/min in Smaller intramuscular arteries derived from the
the heart during systole and diastole, as epicardial arteries penetrate the muscle,
extrapolated from studies in experimental supplying the needed nutrients.
animals.
Lying immediately beneath the endocardium is a
Note from this diagram that the coronary plexus of subendocardial arteries.
capillary blood flow in the left ventricle
During systole, blood flow through the
muscle falls to a low value during systole,
subendocardial plexus of the left ventricle, where
which is opposite to flow in vascular beds
the intramuscular coronary vessels are
elsewhere in the body.
compressed greatly by ventricular muscle
The reason for this phenomenon is strong contraction, tends to be reduced.
compression of the intramuscular blood
However, the extra vessels of the subendocardial
vessels by the left ventricular muscle
plexus normally compensate for this reduction.
during systolic contraction.
Later in the chapter, we explain how this peculiar
During diastole, the cardiac muscle difference between blood flow in the epicardial
relaxes and no longer obstructs blood and subendocardial arteries plays an important
flow through the left ventricular muscle role in certain types of coronary ischemia.
capillaries, so blood flows rapidly during
all of the diastole. SOURCE: GUYTON AND HALL. 14TH ED. PAGE 263.
Blood flow through the coronary
capillaries of the right ventricle also
undergoes phasic changes during the 3. DISCUSS THE DIFFERENT FACTORS CONTROLLING
cardiac cycle but, because the force of CORONARY BLOOD FLOW IN RELATION TO:
contraction of the right ventricular A. LOCAL MUSCLE METABOLISM (PRIMARY
muscle is far less than that of the left CONTROLLER OF CORONARY BLOOD
ventricular muscle, the inverse phasic FLOW)
changes are only partial, in contrast to Blood flow through the coronary
those in the left ventricular muscle. system is regulated mostly by
local arteriolar vasodilation in
SOURCE: GUYTON AND HALL. 14TH ED. PAGE response to the nutritional needs
262-263. of cardiac muscle.
That is, whenever the vigor of
2. STATE THE DIFFERENCE BETWEEN EPICARDIAL
cardiac contraction is increased,
VERSUS SUBENDOCARDIAL CORONARY BLOOD
the rate of coronary blood flow
 27
also increases. prostaglandins, and nitric oxide.
Conversely, decreased heart The mechanisms of coronary vasodilation during
activity is accompanied by increased cardiac activity have not been fully
decreased coronary flow. explained by adenosine.
This local regulation of coronary Pharmacologic agents that block or partially
blood flow is similar to that which block the vasodilator effect of adenosine do not
occurs in many other tissues of completely prevent coronary vasodilation
the body, especially in the caused by increased heart muscle activity.
skeletal muscles. Studies in skeletal muscle have also shown that
the continued infusion of adenosine maintains
Oxygen Demand Is a Major Factor in Local Coronary vascular dilation for only 1 to 3 hours, yet muscle
Blood Flow Regulation. activity still dilates the local blood vessels, even
when the adenosine can no longer dilate them.
Blood flow in the coronary arteries usually is Therefore, the other vasodilator mechanisms
regulated almost exactly in proportion to the listed earlier should be remembered.
need of the cardiac musculature for oxygen.
Normally, about 70% of the oxygen in the B. NERVOUS CONTROL
coronary arterial blood is removed as the blood
flows through the heart muscle. Because not Stimulation of the autonomic nerves to the heart
much oxygen is left, little additional oxygen can can affect coronary blood flow directly and
be supplied to the heart musculature unless the indirectly.
coronary blood flow increases. The direct effects result from action of the
Fortunately, the coronary blood flow increases nervous transmitter substances acetylcholine
almost in direct proportion to any additional from the vagus nerves and norepinephrine from
metabolic consumption of oxygen by the heart. the sympathetic nerves on the coronary vessels.
The exact means whereby increased oxygen The indirect effects result from secondary
consumption causes coronary dilation has not changes in coronary blood flow caused by
been determined. increased or decreased activity of the heart.
Many researchers have speculated that a The indirect effects, which are mostly opposite to
decrease in oxygen concentration in the heart the direct effects, play a far more important role
causes vasodilator substances to be released in the normal control of coronary blood flow.
from the muscle cells and that these substances Thus, sympathetic stimulation, which releases
dilate the arterioles. norepinephrine from the sympathetic nerves and
A substance with great vasodilator propensity is epinephrine, as well as norepinephrine from the
adenosine. In the presence of very low adrenal medullae, increases both heart rate and
concentrations of oxygen in the muscle cells, a heart contractility and increases the rate of
large proportion of the cell’s ATP degrades to metabolism of the heart.
adenosine monophosphate (AMP). In turn, the increased metabolism of the heart
Small portions of this substance are then further sets off local blood flow regulatory mechanisms
degraded and release adenosine to the tissue for dilating the coronary vessels and blood flow
fluids of the heart muscle, with a resultant increases approximately in proportion to the
increase in local coronary blood flow. metabolic needs of the heart muscle.
After adenosine causes vasodilation, much of it is In contrast, vagal stimulation, with its release of
reabsorbed into the cardiac cells to be reused acetylcholine, slows the heart and has a slightly
for production of ATP. depressive effect on heart contractility.
Adenosine is not the only vasodilator product These effects decrease cardiac oxygen
that has been identified; others include consumption and, therefore, indirectly constrict
adenosine phosphate compounds, potassium the coronary arteries.
ions, hydrogen ions, carbon dioxide,
 28
Direct Effects of Nervous Stimuli on Coronary Vasculature. However, glycolysis consumes large quantities of
The distribution of parasympathetic (vagal) nerve the blood glucose and, at the same time, forms
fibers to the ventricular coronary system is not large amounts of lactic acid in the cardiac tissue.
very great. However, the acetylcholine released This is probably one of the causes of cardiac pain
by parasympathetic stimulation has a direct in cardiac ischemic conditions, as discussed later
effect to dilate the coronary arteries. in this chapter.
Much more extensive sympathetic innervation of As is true in other tissues, more than 95% of the
the coronary vessels occurs. In Chapter 61, we metabolic energy liberated from foods is used to
see that the sympathetic transmitter substances form ATP in the mitochondria.
norepinephrine and epinephrine can have This ATP in turn acts as the conveyer of energy for
vascular constrictor or vascular dilator effects, cardiac muscular contraction and other cellular
depending on the presence or absence of functions.
constrictor or dilator receptors in the blood vessel In severe coronary ischemia, the ATP degrades
walls. first to adenosine diphosphate and then to AMP
The constrictor receptors are called alpha and adenosine.
receptors, and the dilator receptors are called Because the cardiac muscle cell membrane is
beta receptors. Both alpha and beta receptors slightly permeable to adenosine, much of this
exist in the coronary vessels. agent can diffuse from the muscle cells into the
In general, the epicardial coronary vessels have circulating blood.
a preponderance of alpha receptors, whereas The released adenosine is believed to be one of
the intramuscular arteries may have a the substances that causes dilation of the
preponderance of beta receptors. coronary arterioles during coronary hypoxia, as
Therefore, sympathetic stimulation can, at least discussed earlier.
theoretically, cause slight overall coronary However, loss of adenosine also has a serious
constriction or dilation, but usually c