Lecture 3 Anatomy PDF

Summary

This document provides a lecture on muscular tissues, blood basics, heart and vessels in the cardiovascular system. It covers various aspects of the system including functions and classification.

Full Transcript

LECTURE 3

Muscular Tissues

The Cardiovascular system
Blood basics
Heart
Vessels
 Cardiovascular System
Functions:
1.Transport – nutrients, O2, CO2, enzymes,
hormones, ions, metabolic waste, leukocytes
2.Stabilization of body temperature
3.Prevention of the loss of body fluids via the
clotting process
4.Stabilization of pH and electrolyte balance
 Classification of Connective Tissue
Connective Tissues
can be divided into three types

Connective Tissue Proper Fluid Connective Tissue Supporting Connective Tissue

Loose Dense Blood Lymph Cartilage Bone

Fibers create Fibers densely Contained in Contained Solid, rubbery Solid,
loose, open packed cardiovascular in lymphatic matrix crystalline
framework dense regular system system hyaline cartilage matrix
areolar tissue dense elastic cartilage
adipose tissue irregular fibrous cartilage
reticular tissue elastic

Figure 3.11 A Classification of Connective Tissues
 Blood Basics
Blood represents ~ 8% of total body weight
Average volume
– Males: 4–6 liters
– Females: 4–5 liters
Hypovolemic: low blood volumes
Normovolemic: normal blood volumes
Hypervolemic: excessive blood volumes
pH: 7.35–7.45
 Blood Basics
Functions
1. Transport: gas, food, waste products, buffer,
heat
2. Protection: Cellular- Antibody, Fluid Loss-
Coagulation
3. Regulation: Tissue Fluid Volume & Content
The main components of blood

Fig 16-3 Silverthorn
 1. Plasma
Plasma Proteins
Albumins Major contributors to osmotic
(60%) pressure of plasma; transport
lipids, steroid hormones

Globulins Transport ions, hormones, lipids;
(35%) immune function

Fibrinogen Essential component of clotting
(4%) system; can be converted to
insoluble fibrin

Regulatory Enzymes, proenzymes,
proteins hormones
(< 1%)
consists of Plasma
(46–63%) PLASMA COMPOSITION
Plasma proteins 7% Other Solutes

Other solutes 1% Electrolytes Normal extracellular fluid ion
composition essential for vital
Water 92% cellular activities; ions contribute to
osmotic pressure of body fluids;
Transports organic and major plasma electrolytes are Na +,
inorganic molecules, K+, Ca2+, Mg2+, Cl–, HCO3–,
formed elements, and heat HPO4–, SO42–

b Components
of plasma Organic Used for ATP production, growth,
Sample of nutrients and maintenance of cells; include
whole blood lipids (fatty acids, cholesterol,
glycerides), carbohydrates (primarily
glucose), and amino acids

Organic Carried to sites of breakdown or
wastes excretion; include urea, uric acid,
creatinine, bilirubin, ammonium ions

Figure 20.1b © 2015 Pearson Education, Inc.
 2. Cells
Platelets

White Blood Cells

Formed
consists of elements FORMED ELEMENTS
(37–54%) Neutrophils
Platelets < 0.1% Eosinophils
(50–70%) (2–4%)
White blood cells < 0.1%

Red blood cells 99.9% 0 5 10 15
μm

c Formed elements
Monocytes
of blood (2–8%)

Sample of Basophils Lymphocytes
whole blood (< 1%) (20–30%)

Red Blood Cells

Figure 20.1c
Saladin Fig 18.1
 Blood Types & Surface Antigens

Glycoprotein Glycolipid

ABO blood types

Saladin Fig 18.14
 Blood Types
antigens on RBC surface

ABO blood types

glycosylation =
“antigens”

Saladin Fig 18.14
 Blood Type vs. Ab’s present

RBC’s

Plasma
Ab’s

Type A Type B Type AB Type O
Seeley, Stephens, Tate; Figure 19.13
 Blood Type vs. Ab’s present

RBC’s

Plasma
Ab’s

Type A Type B Type AB Type O
Seeley, Stephens, Tate; Figure 19.13
 Blood Type vs. Ab’s present

RBC’s

Plasma
Ab’s

Type A Type B Type AB Type O
Seeley, Stephens, Tate; Figure 19.13
 Transfusion –
correct blood type given
Seeley, Stephens, Tate; Figure 19.14

Type A donor
Type A
recipient

Type A donor
Type B
recipient
 Transfusion reaction –
incorrect blood type given!

Seeley, Stephens, Tate; Figure 19.14

Type A donor
Type A
recipient

Type A donor
Type B
recipient
Transfusion reaction – “agglutination”

innate antibodies
react with donor cells
when the wrong
blood type is given
cause agglutination,
hemolysis, death

Saladin Fig 18.17
 Which blood type is the universal donor?
Blood type O

WHY?
- They don’t have A or B antigens
- Their erythrocytes will not be attacked by
either anti-A or anti-B antibodies

- But they can only receive type O blood

Which blood type is the universal recipient??
Cardiovascular System
Outline
The heart
Histology of the heart
Superficial anatomy
Coronary arteries and veins
Heart chambers and valves
Cardiac cycle
Blood vessels
 The Heart
beats ~ 100,000 times per day (~70 beats/min)
pumps ~ 1.5 million gallons of blood per year
– about 2.9 gallons per minute
– 5 - 30 liters per minute
4 chambers – 2 atria and 2 ventricles
pumps blood into 2 circuits
– Pulmonary circuit
– Systemic circuit
Pulmonary Circuit Systemic Circuit
Pulmonary arteries Systemic arteries
Pulmonary veins Systemic veins

Capillaries in
head, neck,
upper limbs
Capillaries
in lungs
Left atrium
Right atrium

Right
ventricle
Left
ventricle

Capillaries in
trunk and
lower limbs

© 2015 Pearson Education, Inc.
Figure 21.1
 The Pericardium
The heart is near the anterior chest wall and
directly posterior to the sternum in the
pericardial cavity
Pericardium is the serous membrane lining the
pericardial cavity
Forms two layers:
1. Visceral pericardium
Also called the epicardium
2. Parietal pericardium
reinforced by a layer called the fibrous pericardium
The parietal pericardium and fibrous pericardium
constitute the pericardial sac
 The Pericardium

Air space
(corresponds
to pericardial
Cut edge of
cavity)
parietal pericardium

Pericardial Cut edge of
cavity containing epicardium
pericardial fluid (visceral pericardium)

Balloon

Central tendon
Figure 21.2b
 Structure of the Heart Wall
(3 layers)
2. Myocardium Pericardial cavity
(cardiac muscle
Periatal
cells)
Pericardium

3. Endocardium
(Endothelial lining)

1. Epicardium
(visceral pericardium)
l
rt wal
Hea
 Myocardium
Cardiac Muscle Cells
Cardiac muscle cells are interconnected by
intercalated discs

Intercalated disc

Figure 21.3c
 Gap junction

Intercalated disc

Z lines bound
to opposing cell
membranes

Desmosomes

e The structure of an intercalated disc.

Figure 21.3de
 Orientation & Superficial
Anatomy of Heart
Superior border
Base of heart

1 1
Ribs
2 2
3 3
4 Right
4
border Left
5 5
6
border
6
7 7
Apex of
8 heart
8
9 9
10 10
Inferior border

Fig. 21- 4
 Orientation and Superficial
Anatomy of Heart
The 4 chambers are identified by sulci:
Interatrial groove separates the left and right
atria
Coronary sulcus separates the atria and the
ventricles
Anterior/Posterior interventricular sulcus
separates the left and right ventricles
 Anterior & Posterior Views

Fat in
coronary
sulcus

RIGHT RIGHT
ATRIUM
LEFT ATRIUM
VENTRICLE
RIGHT RIGHT
Fat in VENTRICLE VENTRICLE
coronary LEFT
sulcus VENTRICLE Fat in posterior
interventricular
sulcus
Fat in anterior
ANTERIOR interventricular POSTERIOR
sulcus
Figure 21.5a
 Orientation and Superficial
Anatomy of Heart
Left and Right Atria
– superior to the coronary sulcus
– Both have thin walls
– Both consist of expandable extensions called
auricles
Left and Right Ventricles
– inferior to the coronary sulcus
– Much of the left ventricle forms the diaphragmatic
surface
 Anterior & Posterior Views

LEFT
ATRIUM

RIGHT RIGHT
ATRIUM ATRIUM
LEFT
VENTRICLE
RIGHT RIGHT
VENTRICLE VENTRICLE
LEFT
VENTRICLE

ANTERIOR POSTERIOR

Figure 21.5a
 Anterior & Posterior Views

Anterior
interventricular Right atrium
Right atrium sulcus
Left Left atrium
Right
ventricle
Coronary ventricle Left
sulcus ventricle
Posterior
Right ventricle
interventricular
sulcus

ANTERIOR POSTERIOR
 Coronary Blood Vessels
Originate at the base of the ascending aorta
– Supply the cardiac muscle tissue
– Select coronary vessels:
Right coronary artery (RCA)

Left coronary artery (LCA)
 Coronary Blood Vessels
Right Coronary Artery
– Passes between the right auricle & pulmonary
trunk
– Major branches off the right coronary artery:
Atrial branches
Right marginal branch
Posterior interventricular branch
Conducting system branches
 Coronary Blood Vessels
Left Coronary Artery
– Major branches off the left coronary artery
Circumflex branch
– Branches to form the left marginal branch
– Branches to form the posterior left ventricular branch
Anterior interventricular branch
– Branches that lead to the posterior interventricular branch
called anastomoses
 Left common carotid Left subclavian artery
artery
Brachiocephalic Aortic
trunk arch
Pulmonary
trunk
Left coronary Artery
Right coronary Circumflex branch
artery of LCA
Diagonal branch
RIGHT
ATRIUM of LCA

Anterior
interventricular
LEFT branch of LCA
Atrial branches RIGHT VENTRICLE
VENTRICLE
of RCA

Marginal branch
of RCA
Figure 21.10a
 Circumflex Atrial branch of LCA
branch of LCA
Marginal branch of
LCA

LEFT
ATRIUM
Posterior
left ventricular
branch of LCA
LEFT
VENTRICLE
RIGHT
ATRIUM

Right coronary
RIGHT
artery (RCA)
VENTRICLE

Right marginal
branch of RCA
Posterior interventricular
branch of RCA
 Coronary Blood Vessels
Coronary Veins
– Drain cardiac venous blood into the right atrium
– Select coronary veins:
Great cardiac vein
– Delivers blood to the coronary sinus
Middle cardiac vein
– Delivers blood to the coronary sinus
Coronary sinus
– Drains directly into the posterior aspect of the right atrium
 Coronary Blood Vessels
The Coronary Veins
– Select coronary veins (continued)
Posterior vein of the left ventricle
– Parallels the posterior left ventricular branch
Small cardiac vein
– Parallels the right coronary artery
Anterior cardiac veins
– Branches from the right ventricle cardiac cells
 Left common carotid Left subclavian artery
artery
Brachiocephalic Aortic
trunk arch
Pulmonary
trunk
LEFT ATRIUM

RIGHT
ATRIUM

Great cardiac vein
LEFT
RIGHT VENTRICLE
VENTRICLE

Small cardiac vein

Anterior cardiac
veins
Great cardiac vein

Posterior vein
of left ventricle LEFT
ATRIUM

Coronary
sinus
LEFT
VENTRICLE
RIGHT
ATRIUM

Small cardiac
vein
RIGHT
VENTRICLE

Middle cardiac
vein
 Internal Anatomy of the Heart
Left common carotid artery

Left subclavian artery

Superior Pulmonary trunk
vena cava Aortic arch
Pulmonary valve
Right
pulmonary Left pulmonary
arteries arteries
Ascending
aorta Left pulmonary
veins
LEFT
ATRIUM
Interatrial septum
Aortic valve

Cusp of right AV Left AV (mitral) valve
(tricuspid) valve
Interventricular
RIGHT VENTRICLE
septum
Inferior vena cava

Descending aorta

Figure 21.7b
Chordae tendineae
Papillary muscle
 Internal Anatomy of the Heart
Left vs Right Ventricles
Right ventricle Left ventricle
Thinner wall Thicker wall
Weaker contraction Powerful contraction
Has a moderator band 6-7x more powerful than the
right ventricle
 Internal Anatomy of the Heart
Valves
There are four valves in the heart
Two AV valves: Tricuspid (right) and bicuspid valves (left)
Two semilunar valves: Aortic and pulmonary valves
 Transverse Sections, Superior View, Atria and Vessels Removed Frontal Sections through Left Atrium and Ventricle

POSTERIOR
Ventricular Diastole

Left AV (bicuspid)
Fibrous Pulmonary
skeleton valve (open) veins

RIGHT
VENTRICLE
LEFT
VENTRICLE
LEFT Left AV
ATRIUM
(bicuspid)
valve (open)
Chordae
Aortic valve tendineae
(closed) (loose)
Right AV Papillary
(tricuspid) muscles
valve (open) (relaxed)
Aortic valve LEFT
(closed) VENTRICLE
(dilated)

ANTERIOR
Pulmonary
valve (closed)

Aortic valve closed

Figure 21.9a
 Right AV Left AV
(tricuspid) valve Fibrous (bicuspid) valve
(closed) skeleton
(closed)
LEFT Aorta LEFT
RIGHT
VENTRICLE VENTRICLE ATRIUM Left AV
Aortic sinus (bicuspid)
Aortic valve valve (closed)
Ventricular Systole

Chordae
(open)
tendineae
(tense)

Aortic valve Papillary
(open) muscles
(contracted)
Left ventricle
Pulmonary
(contracted)
valve (open)
b

Aortic valve open
 The Cardiac Cycle
alternate periods of contraction & relaxation
– Contraction is systole
Blood is ejected into the ventricles
Blood is ejected into the pulmonary trunk and the
ascending aorta
– Relaxation is diastole
Chambers are filling with blood
 The Cardiac Cycle
Coordinated by conducting cells:
1. Nodal cells
Sinoatrial nodes and atrioventricular nodes
Establish the rate of contractions
Cell membranes automatically depolarize
2. Conducting fibers
Distribute the contractile stimulus to the myocardium
 Sinoatrial (SA) node
contains pacemaker cells that initiate
the electrical impulse

Atrioventricular (AV) node
slows the electrical impulse

Left bundle branch
Right bundle branch
Moderator band
relays the stimulus from the ventricle
to the papillary muscles, before the
ventricles contract
Purkinje fibers
convey the impulses rapidly to the contractile
cells of the ventricular myocardium
 The Cardiac Cycle
Movement of Electrical Impulses through the Conducting System

1 2 3 4 5
Time = 0 Elapsed time = 50 msec Elapsed time = 150 msec Elapsed time = 175 msec Elapsed time = 225 msec

AV bundle
Bundle Moderator Purkinje
SA node AV node band
branches fibers
Atrial contraction begins. Impulse spreads to Purkinje fibers
AV node delays the spread & throughout the ventricular
SA node depolarIzes,
of electrical activity to the myocardium.
Atrial activation begins.
AV bundle by 100 msecs. Atrial contraction is completed &
ventricular contraction begins.

Impulses travel along the AV bundle
in the interventricular septum
Depolarization spreads
& reaches the AV node.
Impulses also spread to papillary
muscles of the right ventricle by the
moderator band.

Figure 21.11
 Atrial systole begins:
Start Atrial contraction forces blood into
the relaxed ventricles.

Atrial systole ends;
atrial diastole begins.

800 0 100
msec msec msec

Ventricular systole—
Cardiac first phase: Ventricular
contraction pushes the
Ventricular diastole—late: cycle AV valves closed but
does not create enough
All chambers are relaxed.
pressure to open the
The AV valves open and the
semilunar valves.
ventricles fill passively.
370
msec

Ventricular systole—
second phase: As ventricular
pressure rises and exceeds
Ventricular diastole—early: As the the pressure in the arteries,
ventricles relax, the ventricular blood pressure the semilunar valves open
drops until reverse blood flow pushes the and blood is ejected.
cusps of the semilunar valves together. Blood
now flows into the relaxed atria. Figure 21.11
 Vessels
Outline
Types of blood vessels
Histology of arteries and veins
Capillaries
Veins
Overview of arterial & venous system
 Structure of blood vessels

Adventia
Collagen fibres

internal elastic membrane
 TYPES OF BLOOD VESSELS

Smooth muscle
Collagen fibres

Fig. 22- 1
 Histology of Arteries and Veins
Adventitia
Adventitia
Media
Lumen
Media
Intima of vein
Intima
Smooth muscle

Smooth
muscle
Lumen
of
artery

Endothelium
Endothelium
Elastic fiber
Artery and Vein LM × 60

ARTERY VEIN
 Structure of Capillaries

Basal lamina
Endothelial cell

Nucleus

Continuous Fenestrated
capillary capillary
Endosomes

Endosomes
Fenestrations,
or pores

Boundary Boundary
Basal between between Basal
lamina endothelial lamina
endothelial
cells cells Figure 22.2
 Organization of a Capillary Bed
Vein
Collateral
Smooth arteries
muscle cells Venule
Arteriole

Metarterioles
Capillaries

Section of
precapillary Interconnected
sphincter Network

Small
venule

Precapillary
sphincters
Arteriovenous
KEY
anastomosis
Consistent
Figure 22.3 blood flow
Precapillary sphincters don’t even exist!!

Dr. Graham Fraser
Memorial University
Dr. Chris Ellis
UWO
 Valves in the Venous System
Valve
closed

Valve opens above
contracting muscle

Valve
closed

Valve closes below
contracting muscle
Figure 22.4
What happens if the valves don’t
work?
The Distribution of Blood

Large veins

3%
18%

s
rie
2%

te
es

ar
ri
lla

y
pi

ar
a %
s4

on
c
ry in

lm
a ve
Large venous on ry

Pu
a
networks (liver, ulm lmon
P Pu
bone marrow, skin)
21% Heart 7%

Aorta
Elas 2%
tic a
Mu rter
sc ies

Sy
ula 4%

ste
ra
Venules and rte

mic
rie
medium-sized veins s
5%
cap

Ar
25%

te
illa

rio
rie

le
s
s7

2%
%

Figure 22.5
 The End
Questions??

1 more lecture before the midterm!!!
Dr. Deborah O’Leary
Dr. Stephen Withers
 Vertebral

Brachiocephalic
trunk Right common carotid

An Overview
Left common carotid
Right subclavian
Left subclavian
Aortic arch Axillary

of the Systemic
Ascending Pulmonary trunk
aorta Descending aorta

Celiac trunk Diaphragm

Arterial System
Brachial Renal
Superior mesenteric
Gonadal
Inferior mesenteric
Radial
Common iliac
Ulnar
Internal iliac

Deep
Palmar
femoral
arches
Femoral
External
iliac
Descending
Popliteal genicular

Posterior tibial

Anterior tibial

Fibular

Dorsalis pedis

Plantar arch

Figure 22.8
 Vertebral
External jugular

An Overview
Internal jugular
Subclavian
Brachiocephalic
Axillary
Cephalic Superior vena cava

of the Systemic
Brachial Intercostal
Basilic
Inferior vena cava
Hepatic
Renal

Median cubital Gonadal

Venous System Radial
Median antebrachial

Ulnar
Lumbar

Left and right
common iliac
External iliac
Palmar venous arches
Internal iliac

Digital Deep
femoral

Femoral
Great saphenous

Popliteal

Small saphenous Posterior tibial
Anterior tibial
Fibular

KEY

Figure 22.18
Superficial veins
Dorsal venous arch Deep veins
Plantar venous arch
 Rh factor (+ or -) and RhoGam therapy
“D” Antigen: YES NO

Rh+ Rh-

Majority of population
in addition to ABO
Rh factor (D) also an antigen
Rh- people: no anti-D antibodies (IgG)
unless previously exposed to the antigen (e.g., pregnancy)
“Rh immune globulin” (RhoGam) binds D antigen in fetus
prevents anti-D antibodies in mom (Rh-)
 Rh factor
1. 2. 3.

Treatment
Treatment
with RhoGam
with
RhoGam

Saladin Fig 18.17
 Parallel Muscles Convergent Muscles

a Parallel muscle b Parallel muscle with c Wrapping d Convergent muscle
(Biceps brachii muscle) tendinous bands muscle (Pectoralis muscles)
(Rectus abdominis (Supinator)
muscle)

Tendon

Base of
muscle

(h) Fascicle
(d)
Cross
(g) section
Body
(a) (belly)
(b)
Cross section
(e)
(c)

(f)
Pennate Muscles Circular Muscles

e Unipennate f Bipennate g Multipennate muscle h Circular muscle
Muscle (Extensor muscle (Deltoid muscle) (Orbicularis oris muscle)
digitorum muscle) (Rectus femoris
muscle)

Contracted

Tendons

Extended
tendon
Relaxed

Cross section
© 2015 Pearson Education, Inc.
Figure 9.12
 Review
The structures within the muscle fiber that shorten to
cause skeletal muscle fiber contraction are (the)
________.

A) myoneural junctions
B) myofibrils
C) myosatellite cells
D) neuromuscular synapses
E) myoblasts
A bundle of muscle fibers within a skeletal muscle belly is
called a ________.
A) fascicle
B) perimysium
C) muscle sheath
D) myofiber
E) myofilament
A lever in which the load is between the fulcrum and the
applied force is a ________.
A) first-class lever
B) third-class lever
C) second-class lever
D) simple lever
E) complex lever