Essentials of Anatomy & Physiology PDF

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This document is a set of lecture notes on the lymphatic system and immunity, part of a larger Essentials of Anatomy & Physiology textbook. The notes discuss the components, functions, and organization of the lymphatic system, including lymphocytes, lymphatic vessels, and lymphoid organs.

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Essentials of Anatomy & Physiology, 4th Edition
Martini / Bartholomew

The Lymphatic

14 System and
Immunity
PowerPoint® Lecture Outlines
prepared by Alan Magid, Duke University

Slides 1 to 87

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Lymphatic System Organization

Lymphatic System Definitions
Pathogens—Organisms that cause
disease
Lymphatic System —Cells, tissues, and
organs that play a central role in the
bodyʼs defenses against pathogens
Lymphatic system consists of lymphatic
vessels filled with lymph connected to
lymphatic organs

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 Lymphatic System Organization
The
Components
of the
Lymphatic
System

Figure 14-1
Lymphatic System Organization
Functions of the Lymphatic System
1. Produce, maintain, distribute lymphocytes
Lymphocytes attack invading organisms,
abnormal cells, foreign proteins
2. Maintain blood volume
3. Help keep local interstitial fluid
concentrations level

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Lymphatic System Organization

Lymphatic Vessels
Lymph fluid that flows inside
Begin as lymphatic capillaries in the
tissues
Lymph empties into circulatory
system
At thoracic duct
At right lymphatic duct

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Lymphatic System Organization
Lymphatic
Capillaries

Figure 14-2(a)
 Lymphatic System Organization
Lymphatic Capillaries

Figure 14-2(b)
 Lymphatic System Organization
The Lymphatic Ducts and the Venous System

Figure 14-3
Lymphatic System Organization
Three Classes of Lymphocytes
1. T cells
Thymus dependent
2. B cells
Bone marrow derived
3. NK cells
Natural Killer

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Lymphatic System Organization

Types of T Lymphocytes
1. Cytotoxic T cells
Provide cell-mediated immunity
Attack foreign and virus-infected cells
2. Regulatory T cells
Helper T cells
Suppressor T cells

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Lymphatic System Organization

B Lymphocytes
1. Can become plasma cells
Specific to a particular antigen
Produce antibodies that react
with that antigen
Antibodies are immunoglobulins
2. Responsible for humoral or
antibody-mediated immunity

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Lymphatic System Organization

NK Lymphocytes
1. Provide immunological surveillance
2. Attack cells
Foreign cells
Virally-infected cells
Cancerous cells

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Lymphatic System Organization
Lymphocyte Life Cycle
Continuously migrate between
lymphoid tissues and the blood
Production and development
(called lymphopoiesis) involves:
Bone marrow
Thymus

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Lymphatic System Organization
The Origins of Lymphocytes

Figure 14-4
Lymphatic System Organization

Lymphoid Nodules (like lymph nodes only different!)

Consists of loose connective tissue
containing densely packed
lymphocytes
Found in food and air passages
Tonsils are lymphoid nodules in the
pharynx wall
1. Pharyngeal (aka adenoids)
2. Palatine
3. Lingual
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Lymphatic System Organization
The Tonsils

Figure 14-5
Lymphatic System Organization

Lymphoid Organs
Important lymphoid organs
include:
1. Lymph nodes
2. Thymus
3. Spleen
Located in areas that are
vulnerable to pathogens

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Lymphatic System Organization

Lymph Nodes
1. What are they? Masses of
lymphoid tissue containing
lymphocytes
2. What do they do?
Monitor and filter lymph
Remove antigens
Initiate immune response

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Lymphatic System Organization
The Structure
of a Lymph
Node

Figure 14-6
Lymphatic System Organization

The Thymus
1. Where? Lies behind sternum
2. What happens there? T cells
divide and mature there
3. Shrinks after puberty
4. Produces thymosins
Hormones that regulate T cell
development

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Lymphatic System Organization
The Thymus

Figure 14-7
Lymphatic System Organization
The Thymus

Figure 14-7(a)
Lymphatic System Organization
The Thymus

Figure 14-7(b)
Lymphatic System Organization
The Thymus

Figure 14-7(c)
Lymphatic System Organization
The Spleen
White pulp
Resembles lymphoid nodules
Removes antigens
Initiates immune response
Red pulp
Contains red blood cells
Recycles damaged or out-dated RBCs
Stores iron from recycled RBCs

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Lymphatic System Organization
The Spleen

Figure 14-8
Lymphatic System Organization
The Spleen

Figure 14-8(a)
Lymphatic System Organization
The Spleen

Figure 14-8(b)
Lymphatic System Organization

Overview of Bodyʼs Defenses
1. Non-specific defenses (7 types)
Protect against any threat
2. Specific defenses
Protect against particular threats
Responds to antigens

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Nonspecific Defenses
1. Physical Barriers
Skin, hair, & skin secretions
Digestive epithelia, & secretions

Figure 14-9 (1 of 7)
Nonspecific Defenses
2. Phagocytes
Microphages (neutrophils, eosinophils)
Macrophages

Figure 14-9 (2 of 7)
Nonspecific Defenses
3. Immunological Surveillance
NK cells
Find, kill cancer and virus-infected cells

Figure 14-9 (3 of 7)
Nonspecific Defenses
4. Interferons
Small proteins released by virus-infected
cells
Cytokines that trigger release of anti-viral
proteins that inhibit virus production

Figure 14-9 (4 of 7)
Nonspecific Defenses
5. Complement System
Complex system of proteins
Initiate chain reaction (positive feedback)
Destroy target cell membranes
Stimulate inflammation, attract phagocytes

Figure 14-9 (5 of 7)
Nonspecific Defenses

6. Inflammatory Response
Coordinated non-specific response
to tissue injury

Figure 14-9 (6 of 7)
Nonspecific Defenses

7. Fever
Temperature greater than 99ºF
Inhibits pathogens
Accelerates metabolism

Figure 14-9 (7 of 7)
Nonspecific Defenses
Events in Inflammation

Figure 14-10
Specific Defenses: Immunity
Types of Immunity
1. Innate immunity
Genetically determined
Present at birth
2. Acquired immunity
Active
Follows exposure to antigen
Passive
From transfer of antibodies
from outside source

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Specific Defenses: Immunity
Types of Immunity

Figure 14-11
Specific Defenses: Immunity
Properties of Specific Immunity
Four general characteristics
1. Specificity
2. Versatility
3. Memory
4. Tolerance

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Specific Defenses: Immunity
Properties of Specific Immunity
1. Specificity
T and B cell membrane receptors
recognize a unique antigen
2. Versatility
Responsive to millions of antigens
3. Memory
Memory cells recall earlier
encounters with an antigen
4. Tolerance
Ignores bodyʼs own antigens
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Specific Defenses: Immunity
Overview of the Immune Response
Purpose is to inactivate or destroy:
Pathogens
Abnormal cells
Foreign molecules
Based on activation of lymphocytes
by specific antigens by antigen
recognition

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 Direct
physical and
chemical
attack
CELL–MEDIATED IMMUNITY

ANTIGENS

Phagocytes T cells
SPECIFIC activated activated
Bacteria DEFENSES
(Immune Communication
response) and feedback
ANTIBODY–MEDIATED IMMUNITY
Viruses
B cells
activated
Attack by
circulating
antibodies

Figure 14-12
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 ANTIGENS

Bacteria

Viruses

Figure 14-12
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 ANTIGENS

SPECIFIC
Bacteria DEFENSES
(Immune
response)

Viruses

Figure 14-12
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 CELL–MEDIATED IMMUNITY

ANTIGENS

Phagocytes T cells
SPECIFIC activated activated
Bacteria DEFENSES
(Immune
response)

Viruses

Figure 14-12
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 CELL–MEDIATED IMMUNITY

ANTIGENS

Phagocytes T cells
SPECIFIC activated activated
Bacteria DEFENSES
(Immune Communication
response) and feedback
ANTIBODY–MEDIATED IMMUNITY
Viruses
B cells
activated

Figure 14-12
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 Direct
physical and
chemical
attack
CELL–MEDIATED IMMUNITY

ANTIGENS

Phagocytes T cells
SPECIFIC activated activated
Bacteria DEFENSES
(Immune Communication
response) and feedback
ANTIBODY–MEDIATED IMMUNITY
Viruses
B cells
activated

Figure 14-12
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 Direct
physical and
chemical
attack
CELL–MEDIATED IMMUNITY

ANTIGENS

Phagocytes T cells
SPECIFIC activated activated
Bacteria DEFENSES
(Immune Communication
response) and feedback
ANTIBODY–MEDIATED IMMUNITY
Viruses
B cells
activated
Attack by
circulating
antibodies

Figure 14-12
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Specific Defenses: Immunity
T CELLS & CELL MEDIATED IMMUNITY
1.T Cell Activation (T cells are usually activated
before B cells)
T cells donʼt recognize antigens by
themselves; usually recognize them when
they are bound to receptors on other cell
membranes
T cells have specific receptors that detect
these antigens
Activated T cells differentiate further

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Specific Defenses: Immunity

2. Differentiated Activated T Cells
1. Cytotoxic (killer) T cells
Provide cell-mediated immunity
Track down and attack bacteria, fungi,
protozoa, or foreign transplanted
tissues that contain the target antigen
How? Produce toxins and other
chemical compounds that get rid of
antigen by:
disrupting metabolism, genetically modifying target
cell genes, or rupturing target cell membrane

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Specific Defenses: Immunity
2. Helper T cells
Secrete cytokines (chemical messengers like
hormones)
2 jobs:
1). Coordinate specific and non-specific
defenses
2). Stimulate both cell-mediated and antibody-
mediated immunity

Once activated Helper T cells will divide to produce more
Helper T cells and Memory cells. They also have a function in
B cell activation (coming up later…)
Specific Defenses: Immunity
3. Memory T cells
Remember the activating antigen
“in reserve”
When same antigen appears a second
time, memory cells differentiate into
cytotoxic T cells and helper T cells
4. Suppressor T cells
Suppress other T and B cells
Limit the degree of the immune response
 ACTIVATION AND
Infected cell CELL DIVISION
Memory T
Viral or cells (inactive)
bacterial Class I
antigen MHC protein
Active cytotoxic
Inactive T cell T cells
cytotoxic receptor
T cell

Lymphotoxin Cytokine Perforin
release release release

Destruction
of cell
Disruption membrane
of cell
metabolism
Stimulation
of apoptosis

Figure 14-13
Lysed
cell DESTRUCTION
1 of 5 OF TARGET CELL
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 Infected cell

Viral or
bacterial Class I
antigen MHC protein

Inactive T cell
cytotoxic receptor
T cell

Figure 14-13
2 of 5

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 ACTIVATION AND
Infected cell CELL DIVISION
Memory T
Viral or cells (inactive)
bacterial Class I
antigen MHC protein
Active cytotoxic
Inactive T cell T cells
cytotoxic receptor
T cell

Figure 14-13
3 of 5

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 ACTIVATION AND
Infected cell CELL DIVISION
Memory T
Viral or cells (inactive)
bacterial Class I
antigen MHC protein
Active cytotoxic
Inactive T cell T cells
cytotoxic receptor
T cell

Lymphotoxin Cytokine Perforin
release release release

Destruction
of cell
Disruption membrane
of cell
metabolism
Stimulation
of apoptosis

Figure 14-13
4 of 5

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 ACTIVATION AND
Infected cell CELL DIVISION
Memory T
Viral or cells (inactive)
bacterial Class I
antigen MHC protein
Active cytotoxic
Inactive T cell T cells
cytotoxic receptor
T cell

Lymphotoxin Cytokine Perforin
release release release

Destruction
of cell
Disruption membrane
of cell
metabolism
Stimulation
of apoptosis

Figure 14-13
Lysed
cell DESTRUCTION
5 of 5 OF TARGET CELL
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Specific Defenses: Immunity
Key Note
Cell-mediated immunity depends on
direct contact between cytotoxic T cells
and foreign, abnormal, or infected cells.
T cell activation usually involves
antigen presentation by a phagocytic
cell. Cytotoxic T cells destroy target
cells with cytokines, lymphotoxins,
or perforin.
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Specific Defenses: Immunity
B CELLS & ANTIBODY-MEDIATED
IMMUNITY
1. B cells are first sensitized by exposure
to “their” antigen
2. Helper T cells for that antigen then
activate those B cells
3. Activated B cells divide to form:
Plasma cells
Produce antibodies against that
antigen
Memory B cells
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 Sensitization Activation Division and differentiation
Class II
Antigens MHC T cell receptor

Antigen
Class II MHC ANTIBODY
PRODUCTION
Antibodies
B T
Inactive B cell cell cell
Antigens bound to
antibody molecules
Stimulation
by cytokines

Plasma cells
Antigen
binding

Sensitized Helper T cell
B cell Activated B cells

Sensitized
B cell
Memory B cells
(inactive)

Figure 14-14
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 Sensitization

Antigens

Class II MHC
Antibodies
Inactive B cell
Antigens bound to
antibody molecules

Antigen
binding

Sensitized
B cell

Figure 14-14
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 Sensitization Activation
Class II
Antigens MHC T cell receptor

Antigen
Class II MHC
Antibodies
B T
Inactive B cell cell cell
Antigens bound to
antibody molecules

Antigen
binding

Sensitized Helper T cell
B cell
Sensitized
B cell

Figure 14-14
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 Sensitization Activation Division and differentiation
Class II
Antigens MHC T cell receptor

Antigen
Class II MHC
Antibodies
B T
Inactive B cell cell cell
Antigens bound to
antibody molecules
Stimulation
by cytokines

Antigen
binding

Sensitized Helper T cell
B cell Activated B cells

Sensitized
B cell
Memory B cells
(inactive)

Figure 14-14
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 Sensitization Activation Division and differentiation
Class II
Antigens MHC T cell receptor

Antigen
Class II MHC ANTIBODY
PRODUCTION
Antibodies
B T
Inactive B cell cell cell
Antigens bound to
antibody molecules
Stimulation
by cytokines

Plasma cells
Antigen
binding

Sensitized Helper T cell
B cell Activated B cells

Sensitized
B cell
Memory B cells
(inactive)

Figure 14-14
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Specific Defenses: Immunity
Antibody Structure and Function
Two pairs of parallel polypeptide chains
Four Fixed segments
Provides basic structure
Four Variable segments
Provides specific antigen-binding
structure
Antigen-antibody complex forms
Antigen determinant site binds to
antibody

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Specific Defenses: Immunity
Antibody Structure

Figure 14-15
Specific Defenses: Immunity
Classes of Antibodies
Immunoglobulin G (IgG)
Resistance to pathogens
Immunoglobulin M (IgM)
First antibody secreted
Immunoglobulin A (IgA)
Found in glandular secretions
Immunoglobulin E (IgE)
Stimulates inflammation
Immunoglobulin D (IgD)
Found on surface of B cells
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Specific Defenses: Immunity
How Antibodies Can Eliminate Antigens
1. Neutralization -- bind to viruses or
bacteria making them incapable of
attaching to a cell
2. Precipitation -- 1 antibody can bind 2
antigens together and create a large
complex. When it is insoluble in a body
fluid (like bacterial toxin) it settles out
3. Agglutination -- formation of large
complexes ; clumping of RBCʼs when
incompatable blood types are mixed

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Specific Defenses: Immunity
4. Complement System activation
5. Attraction of phagocytes
6. Stimulation of phagocytosis
7. Stimulation of inflammation
Specific Defenses: Immunity
Key Note
Antibody-mediated immunity depends
on specific antibodies from plasma
cells derived from activated B cells by
(1) antigen recognition, through binding
to surface antibodies, and (2)
stimulation by a helper T cell activated
by the same antigen. The antibodies
bind to the target antigen and either
inhibit it, destroy it, remove it from
solution, or promote its phagocytosis.
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Specific Defenses: Immunity
Primary and Secondary Immune Response
Primary response—Antibodies produced by
plasma cells after first exposure to antigen
Secondary response—Maximum antibody
levels produced by subsequent exposure to
the same antibody

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Specific Defenses: Immunity
The Primary and Secondary
Immune Responses

Figure 14-16
Specific Defenses: Immunity

Key Note
Immunization produces a primary
response to a specific antigen. If
the same antigen is encountered
at a later date, it triggers a
powerful secondary response that
usually prevents infection and
disease.

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Specific Defenses: Immunity
Hormones of the Immune System
Interleukins (IL)
Sensitize T cells
Stimulate B cells
Enhance non-specific defenses
Interferons
Slow the spread of viruses locally
Tumor necrosis factors (TNF)
Slows growth, kills tumor cells
Phagocytic regulators

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Specific Defenses: Immunity
Key Note
Viruses replicate inside cells,
whereas bacteria usually live
outside. Antibodies work outside of
cells, so they are primarily effective
against bacteria rather than viruses.
T cells, NK cells, and interferons are
the primary defenses against viral
infection.

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Patterns of Immune Response
A Summary of the
Immune Response
and Its
Relationship to
Nonspecific
Defenses

Figure 14-17
Patterns of Immune Response

Immune Disorders
Autoimmune disorders
Mistaken attack on bodyʼs own tissues
Immunodeficiency disease
Result of some kind of infection (e.g.,
AIDS) or a congenital block of
immunity; meaning immune system
doesnʼt develop properly
Allergies
Inappropriate or excessive response to
allergens
Age-related loss of effectiveness
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Patterns of Immune Response
Types of Allergies
1. Immediate hypersensitivity (Type I)
Hay fever causes inflammatory response
2. Cytotoxic reaction (Type II)
Blood transfusion
3. Immune complex disorders (Type III)
Inflammation in blood vessels and kidneys
due to decreased phagocytosis
4. Delayed hypersensitivity (Type IV)
Inflammatory response that occurs 2-3
days after exposure to an antigen (poison
ivy)
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Patterns of Immune Response
Anaphylaxis:
Type I
Changes in capillary permeability
produces swelling in the dermis
Hives
Smooth muscle in respiratory passages
contracts
Vasodialation causes BP to drop which
leads to Anaphylactic Shock
 The Lymphatic System
in Perspective

FIGURE 14-18
Functional Relationships Between
the Lymphatic System and Other Systems

Figure 14-18
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The Integumentary System

Provides physical barriers to
pathogen entry; macrophages in
dermis resist infection and
present antigens to trigger
immune response; mast cells
trigger inflammation, mobilize
cells of lymphatic system
Provides IgA antibodies for
secretion onto integumentary
surfaces

Figure 14-18
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The Skeletal System

Lymphocytes and other cells
involved in the immune
response are produced and
stored in bone marrow
Assists in repair of bone after
injuries; macrophages fuse to
become osteoclasts

Figure 14-18
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The Muscular System

Protects superficial lymph
nodes and the lymphatic
vessels in the abdominopelvic
cavity; muscle contractions
help propel lymph along
lymphatic vessels
Assists in repair after injuries

Figure 14-18
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The Nervous System

Microglia present antigens
that stimulate specific
defenses; glial cells secrete
cytokines; innervation
stimulates antigen-presenting
cells
Cytokines affect hypothalamic
production of CRH and TRH

Figure 14-18
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The Endocrine System

Glucocorticoids have anti-
inflammatory effects;
thymosins stimulate
development and maturation
of lymphocytes; many
hormones affect immune
function
Thymus secretes thymosins;
cytokines affect cells
throughout the body

Figure 14-18
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The Cardiovascular System

Distributes WBCs; carries
antibodies that attack
pathogens; clotting response
helps restrict spread of
pathogens; granulocytes and
lymphocytes produced in
bone marrow
Fights infections of
cardiovascular organs;
returns tissue fluid to
circulation

Figure 14-18
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The Respiratory System

Alveolar phagocytes present
antigens and trigger specific
defenses; provides oxygen
required by lymphocytes and
eliminates carbon dioxide
generated during their
metabolic activities
Tonsils protect against
infection at entrance to
respiratory tract
Figure 14-18
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The Digestive System

Provides nutrients required by
lymphatic tissues; digestive acids
and enzymes provide nonspecific
defense against pathogens
Tonsils and lymphoid nodules of
the intestine defend against
infection and toxins absorbed
from the digestive tract;
lymphatics carry absorbed lipids
to venous system

Figure 14-18
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The Urinary System

Eliminates metabolic wastes
generated by cellular
activity; acid pH of urine
provides nonspecific
defense against urinary tract
infection
Provides specific defenses
against urinary tract
infections
Figure 14-18
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The Reproductive System

Lysozymes and bactericidal
chemicals in secretions
provide nonspecific defense
against reproductive tract
infections
Provides IgA antibodies for
secretion by epithelial glands

Figure 14-18
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