Unit 3-inflammation and tissue repair.pdf

Transcript

Chapter 3:
Inflammation and Repair

Unit 3 Dr. Angela LI
School of MHS
 Inflammation is the second line of
defense.
Is one of the nonspecific defense.

Figure 3.1 Lines of defense.
Dr. Angela LI, School of MHS, Tung Wah College 2
 Dr. Angela LI, School of MHS, 3
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Inflammatory response
Inflammation: the host response that accomplished following
goals after injury
▫ Get rid of damaged or necrotic tissues and foreign invaders
Inflammatory response
▫ Acute inflammation: is considered an expected body response to
injury.
▫ Chronic inflammation: is presented as an altered inflammatory
response due to unrelenting injury.
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Sequential steps of inflammation
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The typical inflammatory reaction develops through a
series of sequential steps:
1. Recognition of the offending agent
2. Recruitment of leukocytes and plasma proteins
3. Activation of leukocytes and plasma proteins and
elimination of the offending substances
4. Reaction is controlled and terminated
5. Tissue repair
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Tung Wah College

Recognition of the offending agent

Recruitment of leukocytes and plasma
proteins

Activation of leukocytes and plasma
proteins and elimination of the
offending substances

Tissue repair
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Cause of inflammation
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Inflammatory reactions may be triggered by a variety of
stimuli:
▫ Infections
▫ Tissue necrosis: some molecules released from necrotic cells are
known to trigger inflammation
 Ischemia
 Trauma
 Physical and chemical injury
▫ Foreign bodies
▫ Immune reactions
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Tung Wah College

Part I

ACUTE INFLAMMATION
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Features of acute inflammation
Cardinal Signs:
▫ Rubor – Redness
▫ Tumor – Swelling
▫ Calor – Heat
▫ Dolor – Pain
▫ Functio laesa – Loss of function
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Manifestation of Acute Inflammation

Manifestation Rationale
Redness Vasodilation; increased blood flow to the injured area

Heat Vasodilation; increased blood flow to the injured area

Pain Chemical mediators directly elicit pain receptor;
Accumulated fluid (Edema) causes compression in the tissue

Edema and/or Exudate Increased vascular permeability; fluid accumulation in
extracellular space
Loss of function Tissue damage from injury;
Pain and swelling at the site limit the function
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Tung Wah College

Part I

A. Major Components of Acute
Inflammation
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Three major components of Acute
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Inflammation:
1. Increase blood flow to site of injury (vascular response)
2. Permit plasma protein and leukocytes to leave the
circulation (vascular response)
3. Leukocytes emigration and accumulation in the site of
injury (cellular response)
 To remove injured tissue and prepare for tissue repair
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The major local manifestations of acute
inflammation, compared to normal.
(1) vascular dilation and increased blood
flow (causing erythema and warmth);
(2) extravasation and extravascular
deposition of plasma fluid and proteins
(edema);
(3) leukocyte emigration and
accumulation in the site of injury
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Vascular
Cellular response
response
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1. Vascular Response
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Vascular reactions consist of changes in:
1. Increase blood flow
 Blood vessels dilate (vasodilation):
 by chemical mediators, notably histamine.
 Vascular congestion: stasis of blood flow
 Caused by increased permeability of the capillaries → loss of fluid
 Heat and redness at the site
2. Increase of permeability of the blood vessel
 Endothelial retraction induced by mediators.
 Endothelium injury, resulting in endothelial cell necrosis and
detachment.
▫ E.g. burns, microbial toxins, or leukocyte adhesion
 Edema (exudate) or swelling at the site of injury
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(1) vascular dilation and increased
blood flow (causing erythema and
warmth);
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2) Increase of permeability of the blood
vessel (causing swelling)
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Response of lymphatic vessels and Lymph
nodes
Lymphatic participate in acute inflammation
▫ Lymph flow increase, helping to drain extravascular fluid
▫ Secondarily inflamed when leukocytes, cell debris and
microbes go into the system
 Lymphangitis
 Lymphadenitis (inflamed lymph node)
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2. Cellular Response
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Deliver leukocytes to the site of injury and to activate the leukocytes to
eliminate the offending agents.
Most important leukocytes: neutrophils and macrophages.
Three steps for a successful cellular recruitment:
1. Adhesion to endothelium: attraction and binding
 Leukocytes adhere to endothelial cells near the site of injury
2. Migration through endothelium: move across endothelial cells.
3. Chemotaxis: moving cells to the site of injury.
 Migration in the tissues toward chemotactic factors
They are then free to participate in: (function)
▫ Removal of the offending agents
▫ Leukocyte-induced tissue injury
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Wah College

Chemotaxis
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1. Adhesion to Endothelium
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Margination and Rolling and Adhesion
Margination:
▫ Stasis of blood flow causing leukocytes to settle-out of the central flow column and
“marginate” along the endothelial surface
Rolling:
▫ Endothelial cells and leukocytes have complementary surface adhesion molecules
which briefly stick and release causing the leukocyte to roll along the endothelium
like a tumbleweed until it eventually comes to a stop as mutual adhesion reaches a
peak
▫ Mediated by selectins
▫ Regulated by cytokines
Adhesion:
▫ Rolling comes to a stop and adhesion results
▫ Mediated by integrins
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2. Migration through Endothelium
(diapedesis)
Move across endothelial cells.
Adhesion molecules in intercellular junctions are involved.
Cross basement membrane by secreting collagenases
Migrate toward the chemotactic gradient
Genetic deficiencies in leukocyte adhesion molecules result
in recurrent bacterial infections
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3. Chemotaxis
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Leukocytes follow chemical gradient to site of injury (chemotaxis)
▫ Chemotactic agents bind surface receptors inducing calcium mobilization and assembly
of cytoskeletal contractile elements
Endogenous chemoattractants: chemical mediators:
▫ Cytokines; components of complement system; AA metabolites
The nature of the leukocyte infiltrate varies with the age of the inflammatory
response and the type of stimulus
▫ Early in inflammatory: mostly neutrophils.
▫ Progression of inflammation: monocytes, lymphocytes, etc.
 Neutrophil: short-lived
 Monocytes: long-lived. Dominant in chronic inflammation

Figure 03-06C. Nature of leukocyte infiltrates in inflammatory reactions. The photomicrographs show an inflammatory reaction in the
myocardium after ischemic necrosis (infarction). A, Early (neutrophilic) infiltrates and congested blood vessels. B, Later (mononuclear) cellular
infiltrates. C, The approximate kinetics of edema and cellular infiltration. For simplicity, edema is shown as an acute transient response,
although secondary waves of delayed edema and neutrophil infiltration can also occur.
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Phagocytosis and clearance of the offending agent
Once leukocytes have been recruited to a site of infection or cell death,
the must be activated to perform their functions.
Recognition and activation of leukocyte
▫ The responses of leukocytes in site of infection or cell death include
two sequential sets of events
▫ Recognition
 Express several receptors then deliver signals to initiate activation
▫ Activation
 Increases cytosolic Ca2+ and activation of enzymes
 Important for phagocytosis and intracellular killing
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Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

Phagocytosis and clearance of the offending agent

Phagocytosis – Removal of the offending agents
Once at site of injury, leukocytes:
▫ Recognize and attach
▫ Engulfment
 Formation of vacuole which fuses with lysosomal granule membrane
(phagolysosome)
▫ Kill (degrade)
 Destruction of ingested particles with phagolysosome by lysosomal enzyme and by
reactive oxygen and nitrogen species.
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Dr. Angela LI, School of MHS,
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Other functional responses of activated leukocytes.
Play role in wound repair and anti-inflammation.
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Termination of the Acute inflammatory
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Response
Inflammation declines after the offending agents are
removed.
▫ Mediators are produced in rapid bursts
 Short half-lives
 Degraded after release
▫ Neutrophils have short half-lives
▫ Inflammation process triggers a variety of stop signals
 Switch AA metabolite from proinflammatory leukotriens to anti-inflammatory
lipoxins
 Release anti-inflammatory cytokines
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Part I

B. Chemical Mediators
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Chemical mediators
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Are the substances that initiate and regulate inflammatory
reactions
Come from cells or plasma
Produced in response to various stimuli
One can stimulate the release of other one
Mediators vary in their range of cellular targets
Short-lived:
▫ Quickly decay (AA metabolites), are inactivated enzymatically (kininase), or are
scavenged (antioxidants)
Most important mediator of acute inflammation:
▫ Vasoactive amines, lipid products (prostaglandins and leukotrienes), cytokines and
products of complement activation
Vascular Cellular
response response

Figure 3.3 Concept map. An overview of the importance of chemical mediators in the vascular and cellular
responses of inflammation. PMNs, polymorphonuclear neutrophils.
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Chemical mediators
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Cell-derived:
▫ Preformed, sequestered and released (mast cell histamine)
▫ Synthesized as needed (prostaglandin)
▫ Including: vasoactive amines, AA metabolite, cytokines and
chemokines and others
▫ Major cell type produce these mediators are:
 macrophages, dendritic cells and mast cells
Plasma-derived:
▫ Complement, kinins, coagulation factors
▫ Many in “pro-form” requiring activation (enzymatic cleavage)
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Tung Wah College

Cell-derived Chemical mediators
Vasoactive amines,
AA metabolite,
cytokines and chemokines
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Tung Wah College

Vasoactive amines
Histamine and serotonin are the two major vasoactive amines,
having important actions on blood vessels. Stored in the cell and are
the first mediators released.
▫ Histamine:
 Riches in mast cells.
 Released in response to variety of stimulus.
 Cause dilation of arterioles and increase the permeability of venules.
▫ Serotonin:
 Present in platelet and neuroendocrine cells in GI tract;
 Release triggered by platelet aggregation
 Vasodilator (mainly) and vasoconstrictor (unclear in inflammation)
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Arachidonic Acid Metabolites
Dr. Angela LI, School of MHS,
Tung Wah College

The lipid mediators, prostaglandins and leukotrienes, are produced
from AA. Stimulating vascular and cellular reactions in acute
inflammation.
▫ Prostaglandins and thromboxane:
 Produced by mast cells, macrophages, endothelial cells and others
 In AA pathway, generated via cyclooxygenase (COX) pathway;
 Involve in the vascular and systemic reaction of inflammation.
 Prostaglandins :Vasodilation (PGI2, PGD2, PGE2) and systemic reactions
(fever, pain);
 Thromboxane: Vasoconstriction and aggregation of platelet
 But also protective (gastric mucosa);
 COX blocked by aspirin and NSAIDS (anti-inflammatory drug)
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Arachidonic Acid Metabolites (Cont.)
lipid mediators: (Cont.)
▫ Leukotrienes:
 Produced by leukocytes and mast cells by lipoxygenase pathway;
 Involved in vascular and smooth muscle reactions and leukocyte recruitment.
 Functions:
 Attract neutrophils (5-HETE),
 Vasoconstriction, bronchospasm, and increased permeability of venules (LTC4, LTD4, and
LTE4)
 Effect of bronchospasm and increasing vascular permeability is more potent than
histamine.
 Inhibit by leukotriene receptor antagonist
▫ Lipoxins
 Produced by leukocytes by lipoxygenase pathway;
 Suppress inflammation by inhibiting the recruitment of WBC
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Dr. Angela LI, School of MHS,
Tung Wah College

Table 3-5 Principal Inflammatory Actions of Arachidonic Acid
Metabolites (Eicosanoid)
Action Eicosanoid
Vasodilation PGI2 (prostacyclin), PGE1, PGE2, PGD2

Vasoconstriction Thromboxane A2, leukotrienes C4, D4, E4

Increased vascular permeability Leukotrienes C4, D4, E4

Chemotaxis, leukocyte adhesion Leukotrienes B4, HETE
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Cytokines and chemokines: Dr. Angela LI, School of MHS,
Tung Wah College

Cytokines
▫ Proteins produced by many cell types (principally activated lymphocytes, macrophages,
and dendritic cells. Also by endothelial cells and connective tissue cells)
▫ Act as a message to other cells, telling them how to behave. Mediate and regulate
immune and inflammatory reactions
▫ Tumor necrosis factor (TNF) and interleukin-1 (IL-1)
 Mainly produced by activated macrophages and dendritic cells
 Contribute to the local and systemic reaction of inflammation:
 Increase endothelial cell adhesion molecule expression,
 Activation and aggregation of PMNs, etc.
 Systemic acute-phase response: fever
 TNF antagonists used to treat chronic inflammatory disease
Chemokines
▫ Family of small proteins
▫ Act primarily as chemoattractants for specific type of WBC
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Dr. Angela LI, School of MHS,
Tung Wah College

Principal local and systemic actions of tumor necrosis factor (TNF) and interleukin-1 (IL-1)
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Plasma protein-derived mediators
Complement
Clotting system
Kinins
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Complement system Tung Wah College

Function mainly in host defense against microbes and in pathologic
inflammatory reactions
▫ Complement proteins are in inactive forms in the plasma, and activated by different
pathways.
▫ Then to further degrade other complement proteins to produce the active enzymes.
Three main function of the complement system:
 Inflammation
 Stimulate histamine release from mast cells: vasodilation, vascular permeability
 Chemotactic agents for WBC, e.g. neutrophils, monocytes, etc.
 Activate lipoxygenase pathway of AA metabolism, cause further releasing of
inflammatory mediators
 Opsonization and phagocytosis
 Cell lysis
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Dr. Angela LI, School of MHS,

Clotting system Tung Wah College

Inflammation and blood clotting are often intertwined, with
each promoting the other.
▫ Hageman factor (factor XII): collagen, basement membrane,
activated platelets converts XII to XIIa (active form). Ultimately
converts soluble fibrinogen to insoluble fibrin clot (blood clotting)
▫ XIIa initiates four systems involved in the inflammatory responses:
 Kinin system: vasoactive
 Clotting system: induces formation of thrombin
 Fibrinolytic system: to prevent continuous clot propagation
 Complement system: produces anaphylatoxins and other mediators.
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Dr. Angela LI, School of MHS,
Tung Wah College

Kinins
Kinins are vasoactive peptides derived from plasma proteins
called kiniogens.
Leads to formation of bradykinin from cleavage of precursor
Functions of bradykinin:
▫ Increase vascular permeability
▫ Non-vascular smooth muscle contraction (e.g., bronchial smooth muscle)
▫ Arteriolar dilation
▫ Causes pain
▫ Rapidly inactivated (kininases)
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Table 3-7 Role of Mediators in Different Reactions of inflammation
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Role in Inflammation Mediators
Vasodilation Prostaglandins
Nitric oxide
Histamine
Increased vascular Histamine and serotonin
permeability C3a and C5a (by liberating vasoactive amines from mast cells,
other cells)
Bradykinin
Leukotrienes C4, D4, E4
PAF
Substance P
Chemotaxis, TNF, IL-1
leukocyte recruitment and Chemokines
activation C3a and C5a
Leukotrienes B4 (bacterial products)
Fever IL-1, TNF
Prostaglandin
Pain Prostaglandin
Bradykinin
Tissue damage Lysosomal enzymes of leukocytes
Reactive oxygen species
Nitric oxide
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Morphologic Patterns of Acute Inflammation
Serous inflammation
▫ Watery fluid with small amounts proteins and cells
▫ Causes: allergic chemicals, burns
Fibrinous inflammation
▫ Thick, sticky, increase cell fibrin content
▫ Increase risk of scar tissue
Purulent inflammation: abscess
▫ Thick, yellow-green (pus); increase leukocytes, cell debris, microbes.
Indicates bacterial infection.
Ulcers
▫ Ulcers are circumscribed, open, craterlike lesion of the skin or mucous
membranes.
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Serous inflammation
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Fibrinous inflammation
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Purulent inflammation:
abscess
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Ulcers
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Part I

C. Systemic effects of
inflammations
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Systemic effects of inflammations

Inflammation, even if it is localized, is associated with
cytokine-induced systemic reactions that are collectively
called the acute-phase responses.
Cytokines, TNF, IL-1 and IL-6 are important mediators of the
acute-phase reaction.
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Acute-phase responses
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Tung Wah College

Clinical and pathologic changes:
Fever
▫ Most prominent manifestations, especially infective injury
▫ Pyrogens: substances that induce fever
 Exogenous pyrogens: LPS – bacterial product
 Endogenous pyrogens: Cytokines (IL-1 and TNF) and PGE2
Leukocytosis: Elevated white blood cell count
▫ Bacterial infection (neutrophilia)
▫ Parasitic infection (eosinophilia)
▫ Viral infection (lymphocytosis)
Acute-phase proteins:
▫ Plasma proteins: C-reactive protein (CRP), Fibrinogen, serum amyloid A
(SAA)
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Possible outcomes of acute inflammation
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All acute inflammatory reactions typically have one of three
outcomes below.
Complete resolution
▫ The acute inflammatory response is self-limited.
▫ Once the offending agent has been destroyed and removed, the inflammatory
response will be deactivated, allowing the tissue to heal.
▫ Little tissue damage
▫ Capable of regeneration
Scarring or fibrosis (fibrosis occurs in chronic condition)
▫ In tissues unable to regenerate
▫ Excessive fibrin deposition organized into fibrous tissue
Chronic inflammation
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Dr. Angela LI, School of MHS,
Tung Wah College

Part II

CHRONIC
INFLAMMATION
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Chronic inflammation
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Tung Wah College

Recurrent or persistent inflammation lasting several weeks or
longer
Inflammation, tissue injury and attempts of repair coexist, in
varying combinations.
▫ Causes: when acute phase cannot be resolved
 Persistent injury or infection (ulcer, TB)
 Prolonged toxic agent exposure (silica)
 Autoimmune disease states (RA, SLE)
Leukocyte-induced tissue injury in acute and chronic inflammation
▫ Important causes of injury to normal cells and tissues under several circumstances
 Injure to adjacent tissues as part of normal reaction
 Inappropriately against host tissue, such as autoimmune disease
 Excessively reaction, such as allergic
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Chronic inflammation
Morphologic Features:
▫ Mononuclear cell infiltration, e.g. lymphocyte, macrophage,
plasma cell
▫ Tissue destruction: by inflammatory cells
▫ Attempts at repair with fibrosis and angiogenesis (new
vessel formation)
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destruction of
epithelium
collection of chronic
inflammatory cells
*

fibrosis

* leukocyte
recruitment

Congestion
caused by
vasodilation
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Tung Wah College

Cells and Mediators of Chronic inflammation
Macrophages
The dominant cells in most chronic inflammatory reactions.
▫ Derived from blood monocytes. Scattered all over (microglia, Kupffer
cells, lymph nodes, alveolar macrophages, etc.)
▫ Circulate as monocytes and reach site of injury within 24 – 48 hrs and
transform
▫ Become activated by:
 Classical pathways: microbicidal action and inflammation
 Alternative pathways: tissue repair, fibrosis and anti-inflammation T cell-
derived cytokines, endotoxins, and other products of inflammation
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Macrophages Tung Wah College

Productions of macrophages helps to eliminate injurious agents and
initiate the process of repair, but also responsible for the tissue injury
in chronic inflammation
Functions:
▫ Phagocytosis and destruction of debris & bacteria
▫ Initiate the process of tissue repair and involve in scar formation and
fibrosis
▫ Secrete mediators of inflammation,
 Synthesis; not only cytokines, but also complement components, blood
clotting factors, proteases
▫ Processing and presentation of antigen to immune system.
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Granulomatous Inflammation
A form of chronic inflammation characterized by collections of
activated macrophages, often with T cells, and sometimes associated
with central necrosis.
Cellular attempt to contain an offending agent that is difficult to
eradicate.
Granuloma: wall outside, macrophages and harmful substances inside.
▫ Macrophages develop and begin to resemble squamous cells, therefore called
“epithelioid” cells
▫ Some activated macrophages fuse, forming multinucleate “giant cells”
Dr. Angela LI, School of MHS, Tung Wah College 66
epithelioid cell

central necrosis

*
giant cell

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Consequences of defective or excessive
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inflammation
Defective inflammation
▫ Increased susceptibility to infections
▫ Delayed wound healing
Excessive inflammation
▫ Cause the abnormal reaction of body, e.g., allergies,
autoimmune diseases
▫ Prolonged inflammation induces fibrosis and tissue
injuries.
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Part III

Tissue Repair
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Tissue Repair
Dr. Angela LI, School of MHS,
Tung Wah College

Repair, also called healing, refers to the restoration of tissue
architecture and function after an injury
▫ Tissue healing can only occur with an effective inflammatory
response
Two types of reactions in healing:
▫ Regeneration: restores normal tissue
 Proliferation of cells and tissues to replace lost structures
▫ Connective tissue deposition (scar formation):
 Repair by laying down of connective (fibrous) tissue, and may result in scar
formation.
▫ Both reactions contribute in varying degrees to ultimate repair.
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Dr. Angela LI, School of MHS,

Cell and Tissue Regeneration
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The regeneration of injured cells and tissues involves cell
proliferation, which driven by growth factors and is critically
dependent on the integrity of the extracellular matrix (ECM)
and by the development of mature cells from stems cells.
Repair to injured tissue depends on:
▫ Ability of regeneration of injured parenchymal cells (cell types)
▫ Degree of injury (the original framework remains or not)
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Figure 3-2 Role of the extracellular matrix in regeneration and
repair. Liver regeneration with restoration of normal tissue after
injury requires an intact cellular matrix. If the matrix is damaged,
the injury is repaired by fibrous tissue deposition and scar
formation
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Cell Proliferation
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The ability of tissues to repair themselves depends on their
intrinsic proliferative capacity.
Classification of cells by their proliferative potential
▫ Labile (continuous dividing)
 epithelium of skin, respiratory tract, gastrointestinal tract and urinary
tract, hematopoietic cells, et al
▫ Stable (quiescent)
 parenchymal cells in liver, kidney, pancreas, salivary gland, et al
▫ Permanent (nondividing)
 myocardium, skeletal muscle, neuron
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Dr. Angela LI, School of MHS,
Tung Wah College

Regulation of cell proliferation

Cell proliferation is driven by signals provided by growth
factors and from the ECM.
Mechanisms of cell growth and tissue repair
▫ Growth factors (soluble factors)
 Signal transduction pathways (ligand-receptor with intrinsic tyrosine
kinase activity)
▫ Signal from ECM (insoluble)
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Regulation of cell proliferation

Growth factors are polypeptide molecules causing an expansion of cell
populations which include an increase in cell size, mitotic activity and
protection from apoptotic death (survival).
Growth factors induce the synthesis or activity of transcription factors
In addition to stimulating cellular proliferation, they promote cellular
migration, differentiation, contractibility, as well as enhancing the
synthesis of special proteins such as collagen by fibroblasts.
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Dr. Angela LI, School of MHS,
Tung Wah College
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Table 1-1 Growth factors and Cytokines Involved in Regeneration and Wound Healing
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Growth Factor Symbol sources Function Tung Wah College

Epidermal growth α EGF Platelets, macrophages, saliva, Mitogenic for keratinocytes and fibroblasts; stimulates
urine, milk, plasma keratinocyte migration and granulation tissue
formation
Transforming growth TGF-α Macrophages, T lymphocytes, Similar to EGF; stimulates replication of hepatocytes
factor α keratinocytes, and many tissues and most epithelial cells

Hepatocyte growth HGF Mesenchymal cells Enhances proliferation of hepatocytes, epithelial
factor/ scatter factor cells, and endothelial cells; increases cell motility,
keratinocyte replication
Vascular endothelial VEGF Many types of cells Increases vascular permeability; mitogenic for
cell growth factor endothelial cells (see table 3-3); angiogenesis
Platelet-derived growth PDGF Platelets, macrophages, Chemotactic for PMNs, macrophages, fibroblasts,
factor endothelial cells, keratinocytes, and smooth muscle cells; activates PMNs,
smooth muscle cells macrophages, and fibroblasts; mitogenic for
fibroblasts, endothelial cells, and smooth muscle
cells; stimulates production of MMPs, fibronectin, and
HA; stimulates angiogenesis and wound contraction
Fibroblast growth factor FGF Macrophages, mast cells, T Chemotactic for fibroblasts; mitogenic for fibroblasts
1, 2, and family lymphocytes, endothelial cells, and keratinocytes; stimulates keratinocyte migration,
fibroblasts angiogenesis, wound contraction, and matrix
deposition
Transforming growth TGF- β Platelets, T lymphocytes, Chemotactic for PMNs, macrophages, lymphocytes,
factor β macrophages, endothelial cells, fibroblasts, and smooth muscle cells; stimulates TIMP
keratinocytes, smooth muscle synthesis, angiogenesis, and fibroplasia; inhibits
cells, fibroblasts production of MMPs and keratinocyte proliferation
Keratinocyte growth KGF fibroblasts Stimulates keratinocyte migration, proliferation, and
factor differentiation
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Regulation of cell proliferation
Tissue repair and regeneration depend not only on the
activity of soluble factors, but also on interactions between
cells and the components of the extracellular matrix (ECM)
Roles of ECM
▫ Mechanical support for cell anchorage
▫ Determination of cell orientation (polarity)
▫ Control cell growth
▫ Maintenance of cell differentiation
▫ Scaffolding for tissue renewal
▫ Establishment of tissue microenvironments, storage and presentation
of regulatory molecules
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Dr. Angela LI, School of MHS,
Tung Wah College

The Extracellular Matrix
A dynamic, constantly, remodeling, macromolecular complex
▫ Interstitial matrix
▫ Basement membrane (BM)
Three types of macromolecules
1. Fibrous structural proteins:
▫ Collagens and Elastin
▫ Provide framework, tensile strength and recoil
2. Adhesive proteins (cell adhesion molecules, CAM)
▫ Four main families: immunoglobulin family CAM, cadherins, integrins,
and selectins
▫ Connect the matrix elements to one another and to cells
3. Proteoglycans and hyaluronan
▫ Provide resilience and lubrication
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

The Extracellular Matrix

The Cell-Matrix Interactions
Cell growth and differentiation involve at least two types of
signals acting in concert.
One derives from soluble molecules such as polypeptide
growth factors and growth inhibitors.
The other involves insoluble elements of the ECM
interacting with cellular integrins.
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

Repair by Connective Tissue Deposition
If repair cannot be accomplished by regeneration alone, it
occurs by replacement of the injured cells with connective
tissues, leading scar formation.
Steps of Scar formation:
▫ Angiogenesis
▫ Formation of granulation tissue
▫ Remodeling of connective tissue
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

Cutaneous Wound Healing

First intention: the usual case with a surgical wound, in
which there is a clean wound with well-apposed edges, and
minimal clot formation
Second intention: when wound edges cannot be apposed,
(e.g., following wound infection), then the wound slowly fills
with granulation tissue from the bottom up. A large scar
usually results.
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Dr. Angela LI, School of MHS,
Tung Wah College

Healing by first Intention
When the injury involves only the epithelia layer, the primary
mechanism of repair is epithelial regeneration.
Sequence of events in wound healing
▫ Inflammation
▫ Proliferation of epithelial and other cells
▫ Maturation of the connective tissue scar
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Dr. Angela LI, School of MHS,
Tung Wah College

Cutaneous Wound Healing
Stages of Wound Healing
Inflammatory phase
▫ Clot formation
▫ Chemotaxis
Proliferative phase
▫ Angiogenesis and granulation tissue formation,
Proliferation, migration of connective tissue, re-
epithelialization of wound
Maturational or remodeling phase
▫ ECM deposition, tissue remodeling, and wound
contraction
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

1. Formation of blood clot

Coagulation pathway activated
Blood clot serves to cover the wound, stop bleeding, and as a
scaffold for migrating cells (neutrophil)
▫ Neutrophil appear in 24 hours
▫ Release proteolytic enzymes that clean out debris and invading
bacteria
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Dr. Angela LI, School of MHS,
Tung Wah College

2. Formation of Granulation Tissue
1. 24 to 72 hours, the induction of fibroblast and endothelial cell
proliferation form granulation tissue, which is a hallmark of tissue
repair.
2. Granulation tissue which is pink and soft, with a granular
appearance such as seen underneath the scab of an injured skin.
3. Reach to peak around day 5.
4. Histologically, it is composed of proliferating fibroblasts, newly
formed thin capillaries and loose ECM.
5. Amount of granulation tissue depends on the size of tissue deficit
and the intensity of inflammation.
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Dr. Angela LI, School of MHS,
Tung Wah College
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Angiogenesis Dr. Angela LI, School of MHS,
Tung Wah College

The process of new blood vessel development from existing vessels.
Steps of angiogenesis
▫ Vasodilation and increased permeability induced by VEGF
▫ Proteolytic degradation of the parent vessel basement membrane (BM), allowing
formation of a capillary sprout
▫ Migration of endothelial cells from the original capillary toward an angiogenetic
stimulus
▫ Proliferation of the endothelial cells behind the leading edge of migrating cells
▫ Maturation of endothelial cells with inhibition of growth and organization into
capillary tubes
▫ Recruitment of periendothelial cells to for the mature vessel
VEGF is the most important growth factor in adult angiogenesis. Secreted by
many types of cells.
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Dr. Angela LI, School of MHS,
Tung Wah College

Steps in the process of angiogenesis
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

Roles of Granulation Tissue in Fibrous Repair

Growth into the necrotic tissue, hemorrhage, thrombi,
inflammatory exudate and replace them(organization)
Connect the separated tissue, restore the lost tissue and
support them to keep the integrity of body
Protect the wound and anti-infection
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Dr. Angela LI, School of MHS,
Tung Wah College

3. Cell proliferation and collagen deposition
Macrophages replace neutrophils by 48-96 hours.
▫ Key cellular constituents of tissue repair
▫ Cleaning extracellular debris, fibrin and foreign materials; promoting
angiogenesis and ECM deposition
▫ Main resource for chemokines and growth factors in this process
Migration and proliferation of fibroblasts at the injury site, and
deposition of collagen fibers by fibroblasts.
Epithelial cells proliferate from edge to center of wound from 24-
48 hours after injury
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College

4. Scar formation
During the second week
The granulation tissue becomes a scar composed of inactive
spindle-shaped fibroblasts, dense collagen, fragments of elastic
tissue, and other ECM components.
A progressive vascular regression results in a pale avascular scar.
By the end of the first month, the scar is made up of acellular
connective tissue devoid of inflammatory infiltrate, covered by
intact epidermis
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Dr. Angela LI, School of MHS,

5. Connective tissue Remodeling
Tung Wah College

The balance between ECM synthesis and degradation results
in remodeling of the connective tissue framework
A scar after surgical operation or trauma will become softer,
smaller because of degradation of collagens and other
elements of ECM by matrix metalloproteinases (MMPs)
After 3 months, the skin reaches about 70-80% of the tensile
strength of unwounded skin. And lower tensile strength in the
healed wound area may persist for life.
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Dr. Angela LI, School of MHS,
Tung Wah College

Phase of wound healing. Wound contraction occurs
only in healing by the second intension
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Healing by Second Intention
Dr. Angela LI, School of MHS,
Tung Wah College

When cell or tissue loss is more extensive, such as in large
wounds, abscesses, ulceration, and ischemic necrosis
(infarction), the repair process involves a combination of
regeneration and scaring.
Features:
▫ Inflammatory reaction is more intense
▫ Abundant granulation tissue
▫ Accumulation of ECM
▫ Formation of a large scar
 The dermal appendage that have been destroyed are permanently lost
▫ Sound contraction by the action of myofibroblasts
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Dr. Angela LI, School of MHS,

Healing by Second Intention
Tung Wah College

Wound Contraction
▫ Generally occurs in large surface wounds, an important
feature in healing by secondary union.
▫ Helps to close the wound by decreasing the gap between its
dermal edges and by reducing the wound area.
▫ Myofibroblasts account for contraction, and represent an
intermediate type of cell, between a fibroblast and a myocyte.
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Dr. Angela LI, School of MHS,
Tung Wah College

The Healing in second intension-- Skin Ulcer
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Healing by Second Intention
Dr. Angela LI, School of MHS,
Tung Wah College

Fibrosis
Excessive deposition of collagen in a tissue in chronic disease
Is a pathologic process induced by persistent injurious
stimuli.
▫ Chronic infection
▫ Immunologic reaction
Is typically associated with loss of tissue.
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Dr. Angela LI, School of MHS,
Tung Wah College
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Dr. Angela LI, School of MHS,
Tung Wah College
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Factors that Influence Wound Healing
Dr. Angela LI, School of MHS,
Tung Wah College

Systemic factors
Overall nutrition:
▫ Vitamin and protein deficiencies lead to poor wound healing, especially vitamin C,
which is involved in collagen synthesis
Metabolic status:
▫ Vascular supply (diabetics heal poorly)
Circulatory status:
▫ Poor blood supply
Hormones
▫ Corticosteroids drastically impair wound healing, because of their profound effect on
inflammatory cells
Age: younger is definitely better!
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Dr. Angela LI, School of MHS,
Tung Wah College

Factors that Influence Wound Healing
Local factors
Infection
▫ Delays wound healing and leads to more granulation tissue and
scarring
Type, size, and location of the wound
Movement
▫ Wounds over joints do not heal well due to traction
Foreign bodies
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Abnormalities in Tissue Repair
Dr. Angela LI, School of MHS,
Tung Wah College

Defective granulation tissue or scar formation
▫ Dehiscence or ulceration
▫ Usually due to:
 Wound infection (common); malnutrition (rare); hypoxia with ulceration, usually due to
inadequate vascularity in a skin flap (common)
Excessive scar formation (keloid)
▫ Keloids (hypertrophic scars) are the result of over-exuberant production of scar
tissue, primarily composed of type III collagen.
 Thought to be due to genetic factors, perhaps due to lack of the proper
metalloproteinases to degrade type III collagen
Contraction
▫ Excessive contraction of a wound is known as a contracture. They are a special
problem in the treatment of extensive burns
▫ Limit joint movement.
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Dr. Angela LI, School of MHS,
Tung Wah College

Ulcer

Dehiscence
Keloids
Excessive scar formation
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Dr. Angela LI, School of MHS,
Tung Wah College

Fixed joint

Figure 3-24 Wound contracture. Severe contracture of a
wound after deep burn injury.
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Dr. Angela LI, School of MHS,
Tung Wah College
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Content
Dr. Angela LI, School of MHS,
Tung Wah College

Part I: Acute inflammation Part III: Tissue Repair
▫ Cardinal signs ▫ Regeneration
A. Major Components of Acute  Cell proliferation and regulation of
Inflammation cell proliferation
 Vascular response ▫ Scar formation
 Cellular response ▫ Cutaneous wound healing
B. Chemical Mediators ▫ Factors that Influence Wound
 Cell-derived Healing
 Plasma-derived ▫ Abnormalities in Tissue Repair
C. Systemic effects of
inflammations
Part II: Chronic inflammation