Blood Vessels Congenital Anomalies Arteriosclerosis Aneurysms And Vasculitides PDF

Summary

This document provides a detailed overview of blood vessels, including congenital anomalies, arteriosclerosis, aneurysms, and vasculitides. It explores the normal anatomy, risk factors, pathogenesis, and clinical presentation associated with these conditions. The information is suitable for postgraduate medical studies in cardiovascular pathology.

Full Transcript

PATHOLOGY OF BLOOD
VESSELS
Congenital Anomalies
Arteriosclerosis
Aneurysm and Dissection
Vasculitides

DR O.O. WILLIAMS
 LEARNING OBJECTIVES
1. Describe the normal anatomy of blood vessels.
2. Describe the pathology of congenital anomalies
1
involving blood vessels.
3. Describe the risk factors, anatomic pathology and
2
complications of arteriosclerosis.
4. Explain the pathogenesis of aneurysm and dissection.
5. Describe the typical clinical presentation, gross and
3
microscopic pathology, immunopathology and
pathophysiology of the common vasculitides.
4
NORMAL ANATOMY OF BLOOD VESSELS
To fully comprehend the pathogenesis of vascular
disorders, it is important to first understand normal blood
1
vessels.
Blood vessels are fundamentally all flexible tubes compose
2
d of smooth muscle cells (SMCs) and extracellular matrix
(ECM) with an inner luminal face covered by a continuous
lining of endothelial cells (ECs). However, the relative
3
amounts of SMCs and ECM and the specific properties of
the ECs naturally vary throughout the vasculature
depending
4 on unique functional needs.
NORMAL ANATOMY OF BLOOD VESSELS
To properly accommodate pulsatile flow and higher blood pressures, arte
rial walls are thicker than veins and typically invested with several
reinforcing1 layers of SMCs.
As arteries narrow to arterioles, the ideal ratio of wall thickness to lumen
diameter progressively increases to allow more precise regulation of
2 pressure.
intravascular
Veins, on the other hand, are distensible thin-walled vessels with high
capacitance.
3 maximal diffusion, capillaries are essentially single-cell
To facilitate
linings of ECs lying on a basement membrane.

4
 NORMAL ANATOMY OF BLOOD VESSELS
Vessel walls are meticulously organized into three concentric layers: intima, media,
and adventitia. These distinct layers are present in all vessels but are most apparent
in larger vessels and particularly arteries.
The intima consists of an Endothelial Cell monolayer on a basement membrane
with minimal underlying extracellular matrix ECM; it is separated from the media
by a dense elastic membrane called the internal elastic lamina.
The media is composed predominantly of SMCs and ECM, surrounded by loose
connective tissue, nerve fibres and smaller vessels of the adventitia.
An external elastic lamina is present in some arteries and defines the transition
between media and adventitia.
Diffusion of oxygen and nutrients from the lumen is adequate to sustain thin-walled
vessels and the innermost SMCs of all vessels.
In large and medium-sized vessels, however, small arterioles within the adventitia
(called vasa vasorum — literally, ―vessels of the vessels‖) perfuse the outer half to
two-thirds of the media.
NORMAL ANATOMY OF BLOOD VESSELS
NORMAL ANATOMY OF BLOOD VESSELS
ELASTIC ARTERIES ("large arteries") include the aorta and at least the begi
nnings of its largest branches. These arteries both propel and dampen the
pulse wave. These are distinguished by a preponderance of elastic fibres in th
eir media. The subendothelium of their intimal layers thickens over the cours
e of life through the accumulation of collagen fibers and myointimal cells.
The elastic tissue proliferates here.
In older adults, the elastic is largely replaced by collagen. This also results in
lengthening and thus tortuosity seen in older people. The adventitia and outer
media are nourished by vasa vasorum.
All arteries depend on the blood within their lumens to nourish their intima
and inner media.
NORMAL ANATOMY OF BLOOD VESSELS
MUSCULAR ARTERIES ("medium-sized arteries", "distributing arteries")
exhibit smooth muscle in their walls, and may expand and contract to regulate
the calibre of the lumen and thus the flow of blood. The intima is similar to
that of the elastic arteries, and it thickens similarly. Smooth muscle may pass into
the intima through fenestrae in the internal elastic membrane. These
fenestrae may become wide in old age and be mistaken for damage from
previous vasculitis. The media is bounded on either side by an inner and
outer elastic membrane.
NORMAL ANATOMY OF BLOOD VESSELS
SMALL ARTERIES are the major site of autonomic regulation of
blood flow, and are the worse affected by hypertension.
The wall and lumen have the same thickness. Thickening of the
intima occurs here as well.
Hyaline arteriolar sclerosis worsens with age, especially with
diabetes or hypertension.
There's no outer elastic membrane, and the layers become progressive
ly less distinct as the arteries get smaller.
NORMAL ANATOMY OF BLOOD VESSELS
ARTERIOLES continue the anatomy of the small arteries. Two definitions
that have been offered: (1) Arterioles have five or fewer layers of smooth
muscle; (2) Arterioles have total diameter 100 microns or less.

VEINS
The muscle in the wall of a vein is thinner, and in the larger veins tends to be
less organized. Very large veins have some layers of elastic outside their musc
ular layer. In disease, veins do not usually show so much intimal proliferation
and fibrosis as do arteries.
Lymphatics run very close to arteries (even closer than the veins), and tend to
be small and to have thinner walls than the vein that runs with that artery. It's
not always possible to tell lymphatics from veins; if the vessel contains
red cells, it's most likely a vein.
NORMAL ANATOMY OF BLOOD VESSELS
NORMAL ANATOMY OF BLOOD VESSELS
ENDOTHELIUM : It is permeable to water and the small inorganic ions.
It transports small amounts of blood protein by pinocytosis. These are
recognised as Weibel-Palade bodies on electron microscopy. It can contract, to
regulate capillary
flow. It produces some of the subendothelial connective tissue.
It also makes substances:
(1) Prostacyclin (to keep its surface slippery)
(2) Von Willebrand's factor
(3) Endothelin (a vasoconstrictor peptide)
(4) Endothelial-derived relaxation factor (nitric oxide, EDRF).
NORMAL ANATOMY OF BLOOD VESSELS
VASCULAR SMOOTH MUSCLE also has special functions.
They participate in both normal vascular repair and pathologic processes such
as atherosclerosis. When stimulated by various factors, smooth muscles do the
following:
Proliferate
Upregulate ECM collagen, elastin, and proteoglycan production
Elaborate growth factors and cytokines
 CONGENITAL ANOMALIES
Although rarely symptomatic, unusual anatomic variants of blood vessels can
cause complications during surgery may occur when a vessel in an
unexpected location is injured.
Cardiac surgeons and interventional cardiologists must also be familiar with
coronary artery variants that can occur in up to 1% to 5% of patients.
The common vascular congenital anomalies include:
1) Berry aneurysms
These are thin-walled arterial outpouchings in cerebral vessels, classically at
branch points around the circle of Willis; they occur where the arterial media is
congenitally attenuated and can spontaneously rupture causing fatal subarachnoi
d haemorrhage.
CONGENITAL ANOMALIES
The Circle of Willis with berry aneurysms
 CONGENITAL ANOMALIES
2. Arteriovenous (AV) fistulas (malformations)
These are abnormal connections between arteries and veins without an
intervening capillary bed.
They occur most commonly as developmental defects but can
also result from rupture of arterial aneurysms into adjacent veins,
from penetrating injuries that pierce arteries and veins, or from
inflammatory necrosis of adjacent vessels.
AV fistulas can be created surgically to provide vascular access for
haemodialysis.
Extensive AV fistulas can cause high-output cardiac failure by shunting
large volumes of blood from the arterial to the venous circulation.
CONGENITAL ANOMALIES
Arteriovenous malformation
 CONGENITAL ANOMALIES
3. Fibromuscular dysplasia is a focal irregular thickening of the
walls of medium- and large-sized muscular arteries due to a com
bination of medial and intimal hyperplasia and fibrosis.
It can manifest at any age but occurs most frequently in young
women. The focal wall thickening results in luminal stenosis or
can be associated with vessel spasm that reduces vascular flow;
in the renal arteries, it can lead to renovascular hypertension.
Between the focal segments of thickened wall, the artery often
exhibits medial attenuation; vascular outpouchings can develop
in these portions of the vessel and sometimes rupture.
CONGENITAL ANOMALIES

Fibromuscular
Dysplasia.
The lumen is
narrowed by
focal thickening
of the vessel
wall( )
 ARTERIOSCLEROSIS
Arteriosclerosis literally means ―hardening of the arteries‖; it is a generic term reflecting
arterial wall thickening and loss of elasticity.
Four distinct types are recognized, each with different clinical and pathologic
causes and consequences:
Arteriolosclerosis affects small arteries and arterioles and may cause downstream ischaemic
injury. Associated with hypertension
Mönckeberg medial sclerosis is characterized by the presence of calcific deposits in
muscular arteries, usually centered on the internal elastic lamina, and typically in individuals
older than 50 years of age. The lesions do not encroach on the vessel lumen and usually
are not clinically significant.
Fibromuscular intimal hyperplasia is a non-atherosclerotic process that occurs in muscular
arteries larger than arterioles. This is predominantly an SMC- and ECM-rich
lesion driven by inflammation (as in a healed arteritis or transplant-associated arteriopathy, or
by mechanical injury (e.g., associated with stents or balloon angioplasty).
Atherosclerosis, from Greek root words for ―gruel‖ and ―hardening,‖ is the most frequent
and clinically important pattern. It is associated with lipid cholesterol deposition.
 ATHEROSCLEROSIS
Atherosclerosis is characterized by intimal lesions called atheromas
(or atheromatous or atherosclerotic plaques) that impinge on the vascular lumen
and can rupture to cause sudden occlusion.
It is a pathological process that causes damage to the aorta, cerebral vasculature,
coronary arteries and peripheral arteries.

Risk factors
Modifiable: Hypertension, diabetes, cigarette smoking, hyperlipidaemia(especially
hypercholesterolemia), stress and obesity.

Nonmodifiable: age, male gender, family history, genetic abnormalities (LDL
receptor gene mutations)

Additional factors: Inflammation(C-Reactive Protein levels independently predict
the risk for myocardial infarction, stroke, peripheral arterial disease, and sudden c
ardiac death, even among apparently healthy individuals)
 ATHEROSCLEROSIS
Additional factors: Hyperhomocysteinaemia, Metabolic syndrome
Lipoprotein (a)
 ATHEROSCLEROSIS
The currently held view of pathogenesis is embodied in the
response-to-injury hypothesis.
This model views atherosclerosis as a chronic inflammatory response of the arterial wall to
endothelial injury. Lesion progression involves interaction of modified lipoproteins, monocyte
derived macrophages, T lymphocytes and the cellular constituents of the arterial wall.
According to this model, atherosclerosis results from the following pathogenic events:
EC injury— and resultant endothelial dysfunction—leading to increased permeability,
leukocyte adhesion, and thrombosis
Accumulation of lipoproteins (mainly oxidized LDL and cholesterol crystals) in the vessel wall
Platelet adhesion
Monocyte adhesion to the endothelium, migration into the intima, and differentiation into
macrophages and foam cells
Lipid accumulation within macrophages, which respond by releasing inflammatory cytokines
SMC recruitment due to factors released from activated platelets, macrophages, and vascular
wall cells
SMC proliferation and ECM production
1. Chronic endothelial injury
With resultant endothelial
dysfunction, causing increased
permeability, leukocyte adhesion
and thrombosis.
Accumulation of lipoproteins
This is mainly Low-density lipoprotein
molecules LDL and its oxidized forms in
the vessel wall. LDL becoming oxidized by free
radicals, particularly oxygen free (ROS).
When oxidized LDL comes in contact
with an artery wall, a series of reactions
occur to repair the damage to the artery
wall caused by oxidized LDL.
Monocyte adhesion to the endothelium
Followed by migration into the intima and
transformation into macrophages and foam
cells.
The body's immune system responds to
the damage to the artery wall caused by
oxidized LDL by sending specialized white
blood cells (macrophages and T
lymphocytes) to absorb the oxidized-LDL
forming specialized foam cells.
Unfortunately, these white blood cells are
not able to process the oxidized-LDL, and
ultimately grow then rupture, depositing a
greater amount of oxidized cholesterol into t
he artery wall. This triggers more white
blood cells, continuing the cycle. Various
chemotactic and growth factors are released
from activated platelets, macrophages and
vascular wall cells, inducing SMC
recruitment, either from the media or from
the circulating precursors.
 SMC proliferations and ECM production.
Eventually, the artery becomes
Inflamed with progressive fibrosis.
The cholesterol plaque causes
the smooth muscle cells to enlarge and
form a hard cover over the affected area.
This hard cover is what causes a
narrowing of the artery, reduces the
blood flow and increases blood pressure.
Lipid accumulation occurs both extracellularly
and within cells (macrophages and SMC‘s).
Accumulation of lipid-containing macrophages
in the intima gives rise to ―fatty streaks‖, with
further evolution, a fibrofatty atheroma
consisting of proliferated SMC, foam cells,
extracellular lipid, and ECM is formed.
The periphery of the lesions shows neovascularization
(proliferating small blood vessels).
Plaques generally progressively enlarge over time through cell
death and degeneration, synthesis and degradation of ECM (remo
deling) and thrombus organization.
Atheromas also often undergo calcification
COMPLICATIONS OF ATHEROSCLEROSIS
1. Occlusion of vessel
2. Disruption of plaque: Haemorrhage within plaque or rupture
or ulceration of plaque (with exposure of the thrombogenic
components) can result in thrombus formation.
Stable plaques have densely collagenized and thickened fibrous
caps with minimal inflammation and negligible underlying atheromatous cores,
whereas vulnerable plaques have thin fibrous caps, large lipid cores, and
increased inflammation.
3. Emboli: Plaque can break free and be carried in the blood
stream farther down the vessel.
The above listed complications can lead to ischemia and infarcts of organs.
Symptoms, signs, and results depend upon organ supplied.
COMPLICATIONS OF ATHEROSCLEROSIS
COMPLICATIONS OF ATHEROSCLEROSIS
4. Aneurysm: Atherosclerosis begins as an intimal process, but
over time the thickened intima puts pressure on and causes
atrophy of the media, often resulting in an aneurysm (i.e.,
dilation or saccular outpouching of the vessel).This can lead to rupture
of the vessel and resultant haemorrhage

5. Peripheral vascular disease
Clinical presentation: Claudication, which is characterized
by ache or cramping in the extremities with exertion that is
relieved by standing still. Patients also have cool extremities, diminished
distal pulses, and shiny, hairless skin.
Patients with severe peripheral vascular disease have pain
at rest. Ischemic ulcerations are a common cause of morbidity.
 ANEURYSM AND DISSECTION

This is a localised abnormal dilatation of a blood vessel or wall of the heart.
When an aneurysm is bounded by the arterial wall components or attenuated wall
of heart its called a ―true aneurysm‖.
Atherosclerotic, syphillitic and congenital vascular aneurysms and left ventricular
aneurysm that can follow a myocardial infarction are true aneurysms are true aneurysms.
―False aneurysm‖ (also called pseudoaneurysm) is a breach in the vascular wall
leading to extravascular haematoma that freely communicates with intravascular
space (pulsating haematoma).
The most common false aneurysms are:
1) Post myocardial infarction rupture
2) Leak at junction(anastomosis) of a vascular graft with a natural artery.
 ANEURYSM AND DISSECTION
Dissection arises when blood enters the wall of artery a haematoma and dissecting
through its layers.
Dissections may but do not always arise in aneurysmal arteries.
Both true and false aneurysms as well as dissections can rupture.

Two most important causes of aneurysms
1) Atherosclerosis
2) Cystic medial degeneration of arterial media
Others : Traumatic (arteriovenous aneurysms), saccular (berry) aneurysms, Mycotic
(infectious) aneurysms, syphillitic aneurysm, some vasculitides.
 ANEURYSM AND DISSECTION
Aneurysms can be classified by shape and size
Saccular aneurysms: spherical, 5-20cm, often partially or completely filled by thrombus.
Fusiform aneurysms: involving a long segment, many involve the entire ascending
and transverse portion of the aortic arch.
These shapes and sizes are not specific for any disease or clinical manifestations
ABDOMINAL AORTIC ANEURYSM
Arteriosclerosis the most frequent aetiology.
Morphology:
Usually positioned below the renal arteries and above the bifurcation
of the aorta.
It may be saccular of fusiform
It is a prime site for the formation of atheroemboli.
Pathogenesis :
AAAs rarely develop before age 50 years and are more common in men.
There is genetic susceptibility to AAA beyond the genetic predisposition
to atherosclerosis.
As in Marfan syndrome: genetic defects in connective tissue component
which is responsible for strength of the aorta. Matrix metalloproteinases (M
MPs) produced by macrophages degrade extracellular matric proteins.
ABDOMINAL AORTIC ANEURYSM
This EC matrix includes (collagens, elastins, proteoglycans, laminin and
fibronectin).
Decreased levels of tissue inhibitor of metalloproteinases (TIMP) have also
been reported in aortic aneurysms.
Clinical course:
Rupture into the peritoneal cavity or retroperitoneal tissues with massive
fatal haemorrhage.
Obstruction of vessel (iliac, renal or mesenteric) leading to ischaemic tissue
injury.
Embolism from atheroma or mural thrombus.
Impingement on adjacent structures such as compression of the ureter or
erosion of the vertebrae.
Presentation is often as an abdominal mass (often pulsating) that simulates a
tumour.
Contrast xray angiography of the abdomen An abdominal aortic aneurysm seen
showing an abdominal aneurysm. at autopsy
SYPHILLITIC (LEUTIC) ANEURYSM
This may involve the ascending aorta in tertiary syphilis (late
stage).
Syphilitic (luetic) aortitis causes an obliterative endarteritis of the
vasa vasorum, leading to ischaemia and smooth-muscle atrophy of the
aortic media.
Syphilitic aneurysms may dilate the aortic valve ring, causing
aortic insufficiency.
It may present with respiratory difficulties, feeding difficulties, persistent cou
gh, pain cardiac symptoms, rupture
Aneurysm of the arch of the aorta which Dissection of the heart and arch of the aorta
has eroded through the sternum causing revealing a massive aneurysm.
a large pulsatile anterior chest swelling.
AORTIC DISSECTION (DISSECTING HAEMATOMA)
This is the dissection of blood between and along the laminar planes of the
Media with formation of blood filled channels within aortic wall which often rupt
ures outward causing massive haemorrhage.
Aortic dissection may or may not be associated with marked dilatation of the
aorta.
For this reason the old term ‗dissecting aneurysm‘ is discouraged.
The aetiology usually involves degeneration (cystic medial degeneration) of
The tunica media. Aortic dissection presents with severe tearing pain beginning i
n the anterior chest and radiating to the back and then moving downwards as the
dissection progresses.
If there is an aneurysm present, it may compress and obstruct the aortic branches
(e.g., renal or coronary arteries).
Hypertension and Marfan syndrome are the predisposing factors. It may be
iatrogenic and unknown.
Thoracic aorta with a dissection Photomicrograph of the aortic wall showing
haematoma. blood dissecting along the media.
 VASCULITIDES
Overview

The vasculitides are the various forms of vasculitis.
Which is the inflammation of the blood vessels. It is most
commonly caused by infectious or immune-mediated mechanisms.
Infectious causes of vasculitis include Neisseria, Rickettsiae, and syphilis.
Immune-mediated vasculitis occurs due to one of three mechanisms include
1) Immune-complex deposition,
2) ANCA-mediated
3) Direct antibody interaction.
In many cases, the pathogenesis of vasculitis is unknown.
 VASCULITIDES
IMMUNE COMPLEX DEPOSITION–MEDIATED VASCULITIS

Mechanism: Antibodies induced by the disease process bind
antigens. This interaction forms a complex that deposits within
the vessel wall. The immune complex causes vasculitis through
activation of complement.
Diseases associated with immune complex deposition–
mediated vasculitis: Patients with hepatitis B and hepatitis C
infections and systemic lupus erythematosus can develop an
immune complex deposition–mediated vasculitis. Drug induced vasculitis,
which often involves the skin, is due to immune-complex deposition.
 VASCULITIDES
ANCA-MEDIATED VASCULITIS

ANCAs are antineutrophil cytoplasmic antibodies.
Mechanism: Unknown for certain; however, one possible explanation is that ANCAs
cause degranulation of neutrophils.
The degranulation of the neutrophils releases substances that have toxic effects on
vessels and surrounding tissue.
Two types of ANCA
c-ANCA: Antibody against PR-3.
p-ANCA: Antibody against myeloperoxidase.
Disease associations:
Patients with Wegener granulomatosis have c-ANCA.
Patients with microscopic polyarteritis and Churg-Strauss syndrome can have p-ANCA.
 VASCULITIDES
DIRECT ANTIBODY INTERACTION–MEDIATED
VASCULITIS
Mechanism: Antibodies bind directly to the antigens in the target organ.
Disease associations: Goodpasture syndrome, which is caused by antibodies to the
glomerular basement membrane, and Kawasaki syndrome, which has anti-endothelial
antibodies.
 VASCULITIDES
CLASSIFICATION OF
VASCULITIDES
Large Vessel Vasculitis
Giant cell / temporal arteritis
Takayasu arteritis

Medium-sized Vessel Vasculitis
Polyarteritis nodosa (pANCA negative)
Kawasaki Disease

Small Vessel Vasculitis
Wegener's Granulomatosis (cANCA positive)
Microscopic polyangiitis (pANCA positive)
Churg-Strauss (eosinophils, usually pANCA positive)
Henoch-Schonlein
Cryoglobulinemia
Leukocytoclastic vasculitis
 VASCULITIDES
MAJOR VASCULITIDES

Giant cell arteritis,
Takayasu arteritis,
Polyarteritis nodosa,
Wegener granulomatosis,
Buerger disease,
Kawasaki disease,
Microscopic polyarteritis
Churg-Strauss syndrome.
 VASCULITIDES
GIANT CELL ARTERITIS (TEMPORAL ARTERITIS)

Vessels affected: Aorta and branches of the carotid arteries such as the
ophthalmic and temporal (arteries that run along both sides of your head).
Complications: Thoracic aortic aneurysms.
Epidemiology: Women older than 50 years of age.
Microscopic morphology: Granulomatous inflammation of vessel wall
with disruption of elastic lamellae
Clinical presentation of giant cell arteritis: Includes visual disturbances
(e.g., diplopia and visual loss) and unilateral temporal headache and jaw
claudication.
Patients can have an elevated erythrocyte sedimentation rate.
Diagnosis: Definitive diagnosis requires biopsy.
Treatment of giant cell arteritis: Steroid therapy
 VASCULITIDES
GIANT CELL ARTERITIS (TEMPORAL ARTERITIS)
 VASCULITIDES
TAKAYASU ARTERITIS

Vessels affected: Aorta, branch vessels to upper extremities,
and pulmonary arteries. The condition is also called ―pulseless
disease.‖
Complications: Thoracic aortic aneurysms.
Epidemiology: Women younger than 50 years of age; Asians.
Morphology of Takayasu arteritis
Gross: Vessel wall with near occlusion of lumen by thick
intima.
Microscopic: Varies from a mononuclear inflammatory
infiltrate to granulomatous inflammation. Intimal proliferation and fibrosis is
present.
 VASCULITIDES
TAKAYASU ARTERITIS
Clinical presentation of Takayasu arteritis: Weak pulses in
upper extremities; arthralgias, myalgias, night sweats, visual
disturbances, and fever. Patients can have an elevated erythrocyte sedimentation rate.
Important point: Because giant cell arteritis and Takayasu arteritis can have similar mi
croscopic and gross features, the diagnosis is based largely upon epidemiology. Some
texts use the term giant cell arteritis to designate both temporal arteritis and
Takayasu arteritis, with the two conditions separated by epidemiology and symptoms
 VASCULITIDES
POLYARTERITIS NODOSA
Vessels affected: Small or medium-sized muscular arteries.
Polyarteritis nodosa does not involve the smaller vessels (i.e.,
venules, capillaries, or arterioles) or pulmonary arteries. Commonly involved
vessels are the renal and visceral arteries.
Epidemiology: Usually young adults.
Important point: About 30% of cases are associated with hepatitis B and C infection.
Morphology of polyarteritis nodosa
Microscopic: Transmural inflammation of vessels in combination with fibrinoid
necrosis (i.e., smudgy, pink degeneration of wall), which leads to scarring
Important point: Patients have lesions in various stages (i.e.,some inflammation,
some scarring); in other words, the lesions are of different ages (referred to as
temporally heterogeneous).
 VASCULITIDES
POLYARTERITIS NODOSA
Clinical presentation of polyarteritis nodosa
Polyarteritis nodosa presents a challenging clinical diagnosis
since a multitude of symptoms are possible. Hypertension
and abdominal pain are common. Arthritis and myalgias are
present in more than 60% of cases.
Polyarteritis nodosa is not associated with glomerulonephritis; however,
renal artery involvement is usually prominent and often the cause of death.
There is no association with ANCA
 Polyarteritis nodosa. Note the prominent fibrinoid
necrosis (smudgy eosinophilic changes) of the wall of this vessel
and the accompanying inflammatory infiltrate.
 VASCULITIDES
WEGENER GRANULOMATOSIS
Vessels affected: Small vessels in upper and lower respiratory
tract and kidney.
Microscopic morphology: Granulomatous inflammation.
Clinical presentation of Wegener granulomatosis
Acute necrotizing granulomas of the upper and lower respiratory tract,
causing chronic sinusitis.
Necrotizing and granulomatous vasculitis of organs: Most
prominently involve the lungs, forming nodules and infiltrates and causing
pneumonitis.
Focal necrotizing or crescentic glomerulonephritis, causing
renal disease.
 VASCULITIDES
WEGENER GRANULOMATOSIS
Important point regarding Wegener granulomatosis: In addition to the above
described classic clinical triad, Wegener granulomatosis is also associated with c-
ANCA.
 VASCULITIDES
BUERGER DISEASE (THROMBOANGIITIS OBLITERANS)
Vessels affected: Small and medium-sized arteries, most commonly radial and
tibial arteries.
Epidemiology: More common in Israel, India, and Japan than in the United
States. Almost completely limited to cigarette smokers.
Pathogenesis of Buerger disease: Unknown, but possibly due to the direct toxic
effects of tobacco on vessels or a hypersensitivity reaction to the tobacco products.Increased prevalence of HLA-A9 and HLA-B5 is identified in patients with
Buerger disease.
Microscopic morphology: Segmental acute and chronic vasculitis; can have
thrombosis of the lumen; thrombus can contain microabscesses.
Complications of Buerger disease: Ulcers of toes, feet, or fingers.
Clinical presentation: Severe pain with activity or rest, most likely due to neural in
volvement and digital ulceration.
 VASCULITIDES
KAWASAKI DISEASE (MUCOCUTANEOUS
LYMPH NODE SYNDROME)
Vessels affected: Most important is involvement of the coronary arteries.
Complications of Kawasaki disease: Includes aneurysms of the coronary arteries an
d myocardial infarction. These are late complications occurring many years
after acute disease.
Microscopic morphology: Similar to polyarteritis nodosa but with less prominent
fibrinoid necrosis.
Clinical presentation of acute disease: Kawasaki disease classically presents in
children younger than 5 years of age who present with a high fever (up to 40°C, or
104°F) for more than 5 days; with conjunctivitis, strawberry tongue, cervical lympha
denopathy; and with peeling erythematous rash of lips, palms, and soles of feet.
 VASCULITIDES
MICROSCOPIC POLYARTERITIS
Vessels affected: Smaller vessels than those that are affected by
polyarteritis nodosa.
Organs involved: Skin, kidney (causing glomerulonephritis),
and lungs (causing pulmonary capillaritis).
Microscopic morphology of microscopic polyarteritis: Temporally homogeneous
lesions.
Clinical presentation: Associated with p-ANCA.
 VASCULITIDES
CHURG-STRAUSS SYNDROME
Vessels affected: Small to medium-sized arteries.
Microscopic morphology: Granulomatous vasculitis.
Clinical presentation: Asthma, eosinophilia, and pulmonary
infiltrates.
 Thanks
for
listening
ANY QUESTIONS ?