Inflammation PDF

Summary

These notes cover the topic of inflammation. They explain the different types of inflammation, including acute and chronic inflammation, and describe the various components, mediators, and outcomes of the inflammatory response. The document also discusses the role of different cells, including macrophages and lymphocytes, in the inflammatory process.

Full Transcript

INFLAMMATION
At the end of the unit, the student must be able to:
1. explain terms related to
inflammation and repair.
2. discuss the importance of body
response to inflammation.
3. identify the clinical manifestations
in the presence of inflammation. 4. identify the causes of
inflammation and its preventive measures and
possible management
 May also be harmful
– Hypersensitivity reactions
– Organ damage
 General Characteristics
2 main components:
– vascular wall response
– inflammatory cell response

Effects mediated by circulating plasma proteins
and by factors produced locally by vessel wall or
inflammatory cells.

Terminated when offending agent is eliminated
and the secreted mediators are removed.
 Patterns
Acute Inflammation Chronic Inflammation
Early onset Later onset
Short duration Longer duration
Involves fluid exudation Induces blood vessel
proliferation and scarring
Polymorphonuclear cell Lymphocytes and
emigration macrophages
 5 Classic Clinical Signs
Heat /Calor
Redness/Rubor
Edema/Tumor
Pain/Dolor
Loss of Function/
Functio Laesa
ACUTE INFLAMMATION
 3 Major Components
Alteration in vascular
caliber
Structural changes in
the microvasculature
Leukocyte emigration
from blood vessels and
accumulation at the site
of injury
 VASCULAR CHANGES
Normal fluid exchange depends on an intact
endothelium and is modulated by:
– Hydrostatic Pressure (Kicking force)
– Plasma colloid osmotic pressure (keeping force)
 Increased Vascular Permeability
– Formation of venule intracellular endothelial gaps
– Direct endothelial injury
– Increased transcytosis
– Leakage from new blood vessels
 CELLULAR EVENTS
Leukocyte Extravasation
– Margination, Rolling, Adhesion to the
endothelium
– Transmigration across the endothelium
(Diapedesis)
– Migration in interstitial tissues toward a
chemotactic factor
 Chemotaxis
Process by which leukocytes are attracted to
and move toward an injury.
Mediated by diffusible chemical agents.
Phagocytosis
3 Steps:
Recognition and binding
Engulfment
Killing and degradation
 Products Released by Leukocytes
(Induce Tissue Injury)

Lysosomal Enzymes
Oxygen-derived active metabolites
Products of arachidonic acid metabolism
Termination of the Acute Inflammatory
Response
Inflammation must be regulated because of its
inherent capacity to cause damage.

As inflammation develops, the process also
triggers stop signals
– Switching production of arachidonate metabolites
to anti-inflammatory forms
– Production of anti-inflammatory cytokines (TGF-
β)
 CHEMICAL MEDIATORS
Mediate the vascular and cellular events of
inflammation
Derived from plasma or from cells
Induced primarily by microbial products
Most are short-lived
also have potentially harmful effects
 Plasma Proteins
3 interrelated plasma-derived mediators play
key roles in inflammation
1. Complement
2. Kinin
3. Clotting Systems
 Complement System
Biologic functions of the Complement System
1. Inflammation
C3a and C5a
– stimulate histamine release → increased vascular
permeability, vasodilation
C5a
– powerful chemotactic agent for neutrophils, monocytes,
eosinophils, and basophils.
– activates the lipoxygenase pathway of AA metabolism in
neutrophils and monocytes, causing further release of
inflammatory mediators.
2. Phagocytosis
C3b when fixed to a microbial cell wall, act as an
opsonin and promote phagocytosis

3. Cell lysis
deposition of the MAC on cells makes these cells
permeable to water and ions and results in death (lysis)
of the cells.
 Kinin System
Converts prekallikrein to kallikrein
Kallikrein
– Has chemotactic activity
– Causes neutrophil aggregation
– produce Bradykinin (causes vasodilation and
increased vascular permeability)
 Clotting System
Divided into 2 interrelated systems that
converge to activate a hemostatic mechanism
Fibrinopeptides
– Induce vascular permeability
– Chemotactic for leukocytes
Thrombin
– Has inflammatory properties
– Causes increased leukocyte adhesion to
endothelium
 Factor XIIa
– can also induce the fibrinolytic system, producing
plasmin
– Plasmin contributes to inflammation by cleaving
C3 to produce C3 fragments, forming FSPs that
increase vascular permeability.
 Arachidonic Acid Metabolites
Cyclooxygenase
– Generates prostaglandins and thromboxanes

Lipoxygenase
– Produces leukotrienes and lipoxins
 Platelet-Activating Factor
Produced by mast cells and other leukocytes
functions
– platelet aggregation and release
– Bronchoconstriction
– Vasodilation
– Increased vascular permeability
– Increased leukocyte adhesion
– Leukocyte chemotaxis
 Cytokines and Chemokines
Cytokines
– Proteins produced by activated lymphocytes and
macrophages
– Modulate the function of other cell types

Chemokines
– Cytokines that also stimulate leukocyte
movement
 Tumor Necrosis Factor and
Interleukin 1
Major cytokines mediating inflammation
Produced by activated macrophages
 Chemokines
Act as chemoattractants and activators for
leukocytes
they stimulate leukocyte recruitment in
inflammation
control the normal migration of cells through
various tissues.
 Nitric Oxide
a.k.a. endothelium-derived relaxation factor
Causes relaxation by relaxing smooth muscles
Also inhibits platelet aggregation and
adhesion and kills certain microbes and tumor
cells (via free radical formation)
 Oxygen-Derived Free Radicals
Effects:
– Endothelial cell damage
– Injury to multiple cell types (tumor cells, red cells,
parenchymal cells)
 Protect tissues from ROS
– Ceruloplasmin
– Transferrin
– Superoxide dismutase
– Catalase
– Glutathione peroxidase
OUTCOMES OF ACUTE
INFLAMMATION
 MORPHOLOGIC PATTERNS OF ACUTE
INFLAMMATION
morphologic hallmarks:
– dilation of small blood vessels
– slowing of blood flow
– accumulation of leukocytes and fluid in the
extravascular tissue
 Special Morphologic Patterns
Serous Inflammation
– Reflected by tissue fluid
accumulation
– indicates a modest
increase in vascular
permeability
– Effusion: when in the
pleural, peritoneal and
pericardial cavities
 Fibrinous Inflammation
– More marked increase in
vascular permeability
– With exudates containing
large amounts of
fibrinogen.
– The fibrinogen is
converted to fibrin
through coagulation
system activation
 Suppurative
Inflammation
– Production of purulent
exudate consisting of
leukocytes and necrotic
cells
– Abscess: localized
collection of purulent
inflammatory tissue
accompanied by
liquefactive necrosis
 Ulcers
– Local erosions of
epithelial surfaces
– Produced by sloughing
of inflamed necrotic
tissue.
CHRONIC INFLAMMATION
 A prolonged process in which active
inflammation, tissue destruction, and
attempts at healing may all be proceeding
simultaneously.
 Characterized by:
– Infiltration with
mononuclear
inflammatory cells
(macrophages,
lymphocytes, plasma cells)
– Tissue destruction
– Attempts at healing by
connective tissue
replacement accomplished
by vascular proliferation
(angiogenesis) and fibrosis
 Mononuclear Cell Infiltration
Macrophages:
– Dominant cellular players in chronic inflammation
– Derive from circulating monocytes induced to
emigrate across the cell membrane by
chemokines. In the extravascular tissue,
monocytes transform into macrophages.
 Other Cells in Chronic Inflammation
Lymphocytes
– Mobilized in antibody- and cell-mediated immune
reactions
– Activates macrophages, influence T (and B)
lymphocyte function
– PLASMA CELLS: produce antibodies
 Eosinophils
– Characteristic of immune reactions mediated by
IgE and in parasitic infections.
– Granules contain MBP (toxic to parasites but also
lyses mammalian epithelium)
 Mast Cells
– Participate in both acute and chronic
inflammation
– In acute reactions, binding of antigens to IgE Abs
leads to mast cell degranulation and histamine
release (anaphylactic reactions)
 Granulomatous Inflammation
Granuloma
– a cellular attempt to contain an offending agent
that is difficult to eradicate.
– strong activation of T lymphocytes leading to
macrophage activation, which can cause injury to
normal tissues.
– Examples:
Tuberculosis
Sarcoidosis
cat-scratch disease
lymphogranuloma inguinale
Leprosy
brucellosis
Syphilis
some mycotic infections
berylliosis,
reactions of irritant lipids
some autoimmune diseases
 2 Types of Granulomas
Foreign body granulomas
– incited by relatively inert foreign bodies.
– Epithelioid cells and giant cells are apposed to the
surface of the foreign body
– The foreign material can usually be identified in
the center of the granuloma
Foreign body granuloma
 Immune granulomas
– Formed by immune T-cell mediated responses to
persistent antigens.
– IFN-y from activated T cells causes macrophage
transformation to epithelioid cells and
multinucleate giant cells.
– prototype : Tuberculosis
granuloma is referred to as a tubercle.
characterized by the presence of central caseous
necrosis
Tuberculous granuloma
 Systemic Effects of Inflammation
Acute Phase Response
– Systemic changes associated with inflammation
– In severe cases: Systemic Inflammatory Response
Syndrome (SIRS)
– Response to cytokines produced by either
bacterial products or by other inflammatory
stimuli
 Fever
– Produced in response to pyrogens, substances
that stimulate prostaglandin synthesis in the
hypothalamus. PGE2 stimulates intracellular
second signals (cAMP) that reset the temperature
set point.
 Acute-phase proteins
– Plasma proteins, mostly synthesized in the liver,
whose synthesis increases in response to
inflammatory stimuli
– C-reactive Protein (CRP), Fibrinogen, Serum
amyloid A (SAA)
– CRP and SAA
bind to microbial cell walls
May act as opsonins
Fix complement
also bind chromatin, possibly aiding in the clearing of
necrotic cell nuclei.
– Fibrinogen
binds to red cells and causes them to form stacks
(rouleaux) that sediment more rapidly (basis for
measuring ESR)
 Hepcidin:
iron-regulating peptide
Chronically elevated plasma concentrations of hepcidin
reduce the availability of iron and are responsible for
the anemia associated with chronic inflammation
 Leukocytosis
– Occurs by accelerated release of bone marrow
cells (typically with a shift to the left)
– Prolonged infection also induces proliferation of
bone marrow precursors due to the increased
WBC production
– Leukocyte counts:
15,000-20,000 cells/uL
May reach 40,000-100,000 cells/uL (Leukemoid
Reaction)
– Bacterial Infections: Neutrophils
– Viral infections: Lymphocytes
– Parasitic infections and allergic reactions:
Eosinophils
 Other Manifestations of the Acute Phase
Response
– Increased pulse and blood pressure
– Decreased sweating
– Rigors
– Chills
– Anorexia
– Somnolence
– Malaise
 In sepsis:
– Large amounts of organisms and endotoxin in the
blood stimulate the production of enormous
quantities of several cytokines (TNF and IL-1)
– High levels of these cytokines result in a clinical
triad of DIC, Hypoglycemia and Cardiovascular
Failure
 Consequences of Defective
Inflammation
results in increased susceptibility to infections
delayed wound healing, because inflammation
is essential for clearing damaged tissues and
debris
 Consequences of Excessive
Inflammation
Basis of many categories of human disease
– Allergies
individuals mount unregulated immune responses
against commonly encountered environmental antigens
– Autoimmune diseases
immune responses develop against normally tolerated
self-antigens
disorders in which the fundamental cause of tissue
injury is inflammation
 Inflammation also plays a role in the
pathogenesis of diseases that are not
primarily disorders of the immune system
– atherosclerosis and ischemic heart disease
– Alzheimer disease
 Prolonged inflammation and the fibrosis that
accompanies it are also responsible for much
of the pathology in many infectious,
metabolic, and other diseases.
 Factors that causes poor wound
healing
Infection
Diabetes.
Nutritional status has profound effects on repair; protein malnutrition and vitamin C deficiency, for
example, inhibit collagen synthesis and retard healing.
Glucocorticoids (steroids) have well-documented antiinflammatory effects, and their administration
may result in weak scars because they inhibit TGF-β production and diminish fibrosis. In some
instances, however, the anti-inflammatory effects of glucocorticoids are desirable. For example, in
corneal infections, glucocorticoids may be prescribed (along with antibiotics) to reduce the
likelihood of opacity due to collagen deposition.
Mechanical factors such as increased local pressure or torsion may cause wounds to pull apart
(dehisce).
Poor perfusion, resulting either from arteriosclerosis and diabetes or from obstructed venous
drainage (e.g., in varicose veins), also impairs healing.
Foreign bodies such as fragments of steel, glass, or even bone impede healing. The type and
extent of tissue injury affects the subsequent repair. Complete restoration can occur only in tissues
composed of cells capable of proliferating; even then, extensive injury will probably result in
incomplete tissue regeneration and at least partial loss of function. Injury to tissues composed of
nondividing cells must inevitably result in scarring; such is the case with healing of a myocardial
infarct.
 The type and extent of tissue injury affects the
subsequent repair. Complete restoration can
occur only in tissues composed of cells
capable of proliferating; even then, extensive
injury will probably result in incomplete tissue
regeneration and at least partial loss of
function.
 The location of the injury and the character of
the tissue in which the injury occurs also are
important. For example, in inflammation
arising in tissue spaces (e.g., pleural,
peritoneal, synovial cavities), small exudates
may be resorbed and digested by the
proteolytic enzymes of leukocytes, resulting in
resolution
Thank
You!