Joint Diseases PDF

Summary

This document provides an overview of joint pathology, covering various joint types, diseases (like osteoarthritis and rheumatoid arthritis), and their characteristics. It also includes information on the morphology and pathogenesis of these conditions.

Full Transcript

JOINT PATHOLOGY
 JOINTS

Joints allow movement while providing mechanical stability.
They are classified as solid (nonsynovial) and cavitated (synovial).
The solid joints, also known as synarthroses, provide structural
integrity and allow only minimal movement.
They lack a joint space and are grouped according to the type of
connective tissue (fibrous tissue or cartilage) that bridges the ends
of the bones.
Fibrous synarthroses include the cranial sutures and the bonds
between roots of teeth and the jawbones.
Cartilaginous synarthroses (synchondroses) are represented by the
symphyses between the sternum and the ribs and between bones
of the pelvis.
 JOINTS

Synovial joints, in contrast, have a joint space that allows
for a wide range of motion.
Synovial membranes enclose these joints.
The synovial lining lacks a basement membrane, which
allows for efficient exchange of nutrients, wastes, and gases
between blood and synovial fluid.
Synovial fluid is a plasma filtrate containing hyaluronic acid
produced by synovial cells that acts as a viscous lubricant
and provides nutrition for the articular cartilage
 JOINTS
Hyaline cartilage is a unique connective tissue ideally
suited to serve as an elastic shock absorber and
wearresistant surface.
It lacks a blood supply, lymphatic drainage, and
innervation.
Hyaline cartilage is composed of water (70%), type II
collagen (10%), proteoglycans (8%), and chondrocytes.
The collagen resists tensile stresses and transmits
vertical loads.
The water and proteoglycans resist compression and
limit friction.
The chondrocytes synthesize the matrix as well as
enzymatically digest it.
Chondrocytes secrete degradative enzymes in inactive
forms and enrich the matrix with enzyme inhibitors.
CLASSIFICATION OF JOINT DISEASES

Degenerative disease disease: Osteoarthritis
Autoimmune arthritis: Rheumatoid Arthritis
Arthritis seen in intestinal diseases.
Infectious arthritis
 OSTEOARTHRITIS
It is the degeneration of the articular cartilage.
It is the most common joint disease.
Occurs with advanced age: OVER AGE 50: primary osteoarthritis.
Rarely at a young age (less than 5% of the cases), in the presence of
underlying predisposing factors (on the basis of obesity, systemic disease,
previous trauma, developmental deformities): secondary osteoarthritis.
Most common in hand, knee, hip and spine joints.
Osteophyte protrusions on the fingers in women: Heberden nodes and
Bouchard nodes: characteristic.
Pain that increases with movement, morning stiffness, crepitation (a
clicking sensation) in the joint, limitation of movement, and neurological
deficits in the vertebrae due to nerve root compression by osteophytes.
 OSTEOARTHRITIS

It is characterized by degeneration of cartilage that results in structural
and functional failure of synovial joints.

Osteoarthritis implies an inflammatory disease.

It is considered an intrinsic disorder of cartilage in which chondrocytes
respond to biochemical and mechanical stresses resulting in the
breakdown of the matrix and failure of its repair.

Inflammatory mediators take place in OA whose release is triggered by
joint injury continue and worsen the damage.

In most instances OA appears insidiously, without apparent initiating
cause, as an aging phenomenon (idiopathic or primary osteoarthritis).
 OSTEOARTHRITIS

In these cases the disease is usually oligoarticular (affects few joints). In
about 5% of cases, OA appears in younger individuals with some
predisposing condition,

- such as joint deformity,
- a previous joint injury,
- an underlying systemic disease that places joints at risk.
- In these settings the disease is called secondary osteoarthritis.
- The prevalence of OA increases exponentially beyond the age of 50,
and about 40% of people older than 70 are affected.
OSTEOPHYTES=BONE SPURS

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BOUCHARD AND HEBERDEN NODES

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 OSTEOARTHRITIS PATHOGENESIS
The function of the articular cartilage is to limit the increased range of
motion (ROM) during movement and distribute the load on the joint equally
to the bone.
Therefore the cartilage at the insertion points must be elastic (with
proteoglycans) and resistant to tension (with type II collagen).
Chondrocytes synthesize proteoglycans and collagen.
As a result of mechanical stress and aging, this function of chondrocytes
decreases:
Matrix loss occurs in the cartilage.
The tensile resistance of the cartilage breaks down.
Degeneration occurs in the cartilage and the subchondral bone.
 OSTEOARTHRITIS MORPHOLOGY
Cracks in the articular cartilage: Chondromalacia.
Polished appearance, ivory-like appearance due to friction on the
subchondral bone below, with complete stripping of the cartilage surface:
Eburnation.
Bone or bone fragments falling into the joint cavity as a result of small
fractures: Joint Mouse.
Mushroom-shaped bone protrusions on the edges of joint surfaces:
Osteophyte.
Cysts in the subchondral bone.
Joint deformities.
Unlike rheumatoid arthritis, fusion does not develop in the joint
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 eburnation

Joint mouse

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 OSTEOARTHRITIS

EBURNATIO
N

osteophytes
 ROMATOID ARTHRITIS

It is a systemic autoimmune disease that mainly affects the joints and many
other tissues.
It is characterized by a chronic progressive inflammation.
It causes a non-suppurative proliferative synovitis and arthritis that
progresses to disability with fusion in the joints.
Female predominance
20s-40s.
Symmetrical involvement.
Polyarticular.
Small joints: hand, foot, wrist, ankle, knee, elbow, shoulder joints.
 ROMATOID ARTHRITIS
Unlike osteoarthritis, hip joint involvement is rare and distal
interphalangeal joints are spared in the early stages of the disease.
Morning pain in the joints, joint stiffness, limitation of movement and
systemic symptoms (mild fever, weakness: due to inflammatory cytokines)
Radial deviation of the wrist.
Ulnar deviation in fingers.
Swan neck deformity of fingers, boutonniere deformity.
Juvenile RA: Begins before age 16 and lasts more than 6 weeks. Systemic
form: Still's disease.
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 ROMATOID ARTHRITIS- PATHOGENESIS

Genetic factors (increased susceptibility in people with certain HLA groups)
Environmental factors: infectious agents, smoking.
In genetically susceptible individuals, the main factors are the triggering
environmental factors and the cytokines released from CD4+ T lymphocytes
that are stimulated against a microbial agent or self-antigens and their
inflammatory stimulation.
Immune complexes accumulate in the joints with the production of
autoantibodies against CCP (cyclic citrullated peptide).
The production of autoantibodies against one's own IgG and the accumulation
of the resulting immune complexes in the joints: RHEUMATOID FACTOR.
The presence of anti-CCP antibodies in serum and demonstration of
Rheumatoid factor (RF) positivity are diagnostic.
 ROMATOID ARTHRITIS-
PATHOGENESIS

The pathologic changes are mediated by antibodies against
self-antigens.
Inflammation caused by cytokines, predominantly secreted
by CD4+ T cells.
CD4+ T helper (TH) cells may initiate the autoimmune
response in RA by reacting with an arthritogen, (perhaps
microbial or a chemically modified self-antigen).
The T cells produce cytokines that stimulate other
inflammatory cells to effect tissue injury:
IFN-γ from TH1 cells activates macrophages and synovial
IL-17 from TH17 cells recruits neutrophils and monocytes.
 ROMATOID ARTHRITIS-
PATHOGENESIS

RANKL expressed on activated T cells stimulates osteoclasts and
bone resorption.
TNF and IL-1 from macrophages stimulate resident synovial cells
to secrete proteases that destroy hyaline cartilage.
TNF has been most firmly implicated in the pathogenesis of RA.
TNF antagonists have proved to be effective therapies for the
disease.
 ROMATOID ARTHRITIS-
PATHOGENESIS
The synovium of RA contains germinal centers with secondary follicles
and abundant plasma cells that produce antibodies, some of which
may be against selfantigens.
Many of the serum autoantibodies detected in patients are specific for
citrullinated peptides in which arginine residues are posttranslationally
converted to citrulline.
In RA, complexes of antibodies with citrullinated fibrinogen, type II
collagen, α-enolase, and vimentin deposit in the joints.
Evidence suggests that the anti-citrullinated protein antibodies (ACPA)
in combination with a T cell response to the citrullinated proteins
contribute to disease chronicity.
Approximately 30% of RA patients do not have ACPA in the blood.
About 80% of patients have serum IgM or IgA autoantibodies that bind
to the Fc portions of their own IgG.
These autoantibodies are called rheumatoid factor and may also
deposit in joints as immune complexes, although they are not
uniformly present in all patients with RA.
 RA GENETICS
It is estimated that 50% of the risk of developing RA is related to inherited
genetic susceptibility.
The HLA class II locus is associated with ACPA-positive RA.
Evidence suggests that an epitope on a citrullinated protein, vinculin,
mimics an epitope on many microbes and is the target of CD4+ T cells
when presented by predisposing HLA-DQ alleles.
A second gene linked to RA, PTPN22, encodes a protein tyrosine
phosphatase and it inhibits T cell activation.
Numerous other genetic associations have been reported.

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 RA ETIOPATHOGENESIS
Many candidate environmental factors whose antigens promote
autoimmunity have been postulated.
At least 70% of RA patients have ACPA in their blood, which may
be produced during inflammation.
Insults such as:
infection (including periodontitis) and
smoking may promote citrullination of self-proteins, creating
new epitopes that trigger autoimmune reactions.
The inflammation localizes to the joint, recruiting macrophages
and triggering activation and/or proliferation of synovial cells,
chondrocytes, and fibroblasts.
The production of proteolytic enzymes and cytokines
contributes to the destruction of cartilage and, through
increased osteoclast activity, bone destruction.
 CLINICAL PICTURE
Clinical Course RA can be distinguished from other forms of
polyarticular inflammatory arthritis:
ACPA in serum and by characteristic radiographic findings.
In about half of patients, RA begins slowly and insidiously with
malaise, fatigue, and generalized musculoskeletal pain.
After several weeks to months, the joints become involved.
The pattern of joint involvement is generally symmetrical.
The hands and feet, wrists, ankles, elbows, and knees are most
commonly affected.
The metacarpophalangeal (MCP) and proximal interphalangeal
(PIP) joints are frequently involved (in contrast to OA).
Involved joints are swollen, warm, and painful.
In contrast to OA, the joints are stiff when patient rises in the
morning or following inactivity.
 CLINICAL PICTURE
Patients have progressive joint enlargement and decreased
range of motion pursuing a chronic waxing and waning course.
In a minority of patients, especially those lacking RF and ACPA,
the disease may stabilize or even regress.
Inflammation in the tendons, ligaments, and occasionally the
adjacent skeletal muscle frequently accompanies the arthritis
and produces:
- the characteristic ulnar deviation of the fingers and flexion-
hyperextension of the fingers (swan-neck deformity and
boutonnière deformity).
Radiographic hallmarks are joint effusions and juxtaarticular
osteopenia with erosions and narrowing of the joint space and
loss of articular cartilage
ROMATOID ARTHRITIS- MORPHOLOGY
Synovial cell proliferation
Inflammatory cell infiltration in the synovium: T lymphocytes, plasma cells,
macrophages, lymphoid follicles
Vascular proliferation.
Organized fibrin and neutrophils covering the surface of the joint cavity and
synovium.
Chronic papillary synovitis.

Fibrous synovial tissue on the joint surface in severe cases: Pannus

In advanced stages, the pannus fills the joint space🡪.
Fibrosis and
Fusion in bone: Ankylosis
RHEUMATOID ARTHRITIS
RHEUMATOID ARTHRITIS

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 RHEUMATOID ARTHRITIS
Subcutaneous nodules on the extensor side of the forearm and
parenchymal nodules in other organs: RHEUMATOID NODULE
Fibrinoid necrosis in the middle
Macrophages surrounding necrosis
Outside: granulation tissue
RHEUMATOID ARTHRITIS EXTRA-
ARTICULAR CLINICAL SYMPTOMS

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OSTEOARTHRITIS – RHEUMATOID ARTHRITIS
 RA TREATMENT

Corticosteroids
Methotrexate
TNF antagonists.
Long term treatment with TNF antagonists carries with it
increased risk of infections with organisms such as M.
tuberculosis.
JUVENILE IDIOPATHIC ARTHRITIS

Juvenile idiopathic arthritis (JIA) is a heterogeneous group
of disorders of unknown cause that present with arthritis
before age 16 and persist for at least 6 weeks.
In contrast to RA, in JIA:
oligoarthritis is more common,
systemic disease is more frequent,
large joints are affected more often than small joints,
rheumatoid nodules and rheumatoid factor are usually
absent, and
anti-nuclear antibody (ANA) seropositivity is common.
 SERONEGATIVE
SPONDYLOARTHROPATHIES
Unlike rheumatoid arthritis and other arthritis:
Pathological changes start from the ligaments of the bone, not from the
synovium.
Sacroiliac joints are involved: SACROILEITIS
Rheumatoid Factor (-): ''SERONEGATIVE''
They are associated with HLA-B27
Prototype: Ankylosing Spondylitis
Reiter's syndrome: Post inflammatory reactive arthritis.
Psoriatic arthritis: is also a seronegative spondyloarthropathy.
Spondylitis associated with inflammatory bowel disease.
Reactive arthropathies that develop after infections.
Pathogenesis unknown: Triggering infections: Yersinia, Shigella,
Salmonella, Helicobacter, or Campylobacter and immune mechanisms.
 SERONEGATIVE
SPONDYLOARTHROPATHIES-
ANKYLOSING SPONDILITIS
The manifestations are immune mediated and are triggered by a
T cell response presumably directed against an undefined
antigen, possibly infectious, that may crossreact with antigens
expressed on cells of the musculoskeletal system.
Ankylosing spondylitis, the prototypical spondyloarthritis, causes
destruction of articular cartilage and bony ankylosis, especially
of the sacroiliac joints.
AS becomes symptomatic in the second and third decades of life
as lower back pain and spinal immobility.
Involvement of peripheral joints, such as the hips, knees, and
shoulders, occurs in at least one-third of affected individuals.
Approximately 90% of patients are HLA-B27 positive, but how
the B27 allele contributes to the disease is not known.
 SERONEGATIVE
SPONDYLOARTHROPATHIES- REACTIVE
ARTHRITIS
Reactive arthritis is defined by a triad of arthritis,
nongonococcal urethritis or cervicitis, and conjunctivitis.
Most affected individuals are men in their 20s or 30s, and
more than 80% are HLA-B27 positive.
The disease is probably caused by an autoimmune reaction
initiated by previous infection of the genitourinary system
(Chlamydia) or the gastrointestinal tract (Shigella,
Salmonella, Yersinia, Campylobacter). Within several
weeks of urethritis or diarrhea, patients experience low
back pain. The ankles, knees, and feet are affected most
often, frequently in an asymmetric pattern. Patients with
severe chronic disease have involvement of the spine that
is indistinguishable from ankylosing spondylitis.
 INFECTIOUS ARTHRITIS

Joints can become infected from:
- hematogenous dissemination,
- direct inoculation through the skin, or
- from contiguous spread from a soft tissue abscess or
osteomyelitis.
Infectious arthritis is potentially serious, because it can cause
rapid, permanent joint destruction.
 SUPPURATIVE ARTHRITIS

Bacterial infections that cause acute suppurative arthritis
usually enter the joints from distant sites by
hematogenous spread.
In neonates, however, contiguous spread from underlying
epiphyseal osteomyelitis may occur.
H. influenza arthritis predominates in children younger
than 2 years of age.
S. aureus is the main agent in older children and adults
Gonococcus is prevalent during late adolescence and
young adulthood.
Individuals with sickle cell disease are prone to infection
with Salmonella.
 SUPPURATIVE ARTHRITIS

Sudden onset of pain, redness, swelling in the joint.
Fever, leukocytosis, increased sedimentation (systemic
symptoms).
Usually occurs in a single joint (usually knee).
 LYME ARTHRITIS

Lyme arthritis is the leading arthropod-borne disease in the
United States.
It is caused by infection with the spirochete Borrelia
burgdorferi.
It is transmitted by deer ticks of the Ixodes ricinus complex.
In its classic form, Lyme disease progressively involves
multiple organ systems through three clinical phases
The initial infection of the skin, or early localized stage, is
followed by an early disseminated stage involving skin,
cranial nerves, heart, and meninges.
 LYME ARTHRITIS

If left untreated, arthritis, especially of the knee, occurs
weeks to months after infection.
Currently, arthritis occurs in less than 10% of cases because
most patients are cured at an earlier stage.
However, if left untreated approximately 60% to 80% of
individuals develop a migratory arthritis (Lyme arthritis)
lasting for weeks to months.
Spirochetes can only be identified in about 25% of joints
with arthritis, but the diagnosis can be confirmed by
serologic testing for anti-Borrelia antibodies.
 CRYSTAL INDUCED ARTHRITIS
Crystal-Induced Arthritis Articular crystal deposits are
associated with a variety of joint disorders.
Endogenous crystals shown to be pathogenic include
monosodium urate (MSU) (gout), calcium pyrophosphate
dehydrate (pseudogout), and basic calcium phosphate.
Exogenous crystals, such as silicone, polyethylene, and
methyl methacrylate used in prosthetic joints, and the
debris that accumulates with their erosion, may result in
local arthritis.
Crystals produce disease by triggering an inflammatory
reaction that destroys cartilage
 GOUT DISEASE
It occurs when uric acid, the end product of purine metabolism, accumulates
in tissues and body fluids, causing monosodium urate crystals to precipitate
and trigger an inflammatory response.
Hyperuricemia (plasma urate level above 6.8 mg/dL) is necessary, but not
sufficient, for the development of gout.

1% frequency, common in men.

It most commonly begins as acute arthritis in the big toe.

Forefoot, ankle, heel, wrist

Risk factors: obesity, diabetes, excessive alcohol, purine-rich diet, kidney
failure
 URIC ACID METABOLISM

Synthesis. Uric acid is the end product of purine catabolism.
Increased synthesis typically reflects some abnormality in
purine production.
The synthesis of purine nucleotides, in turn, involves two
interlinked pathways. In the de novo pathway, purine
nucleotides are synthesized from nonpurine precursors, and
in salvage pathways they are synthesized from free purine
bases obtained through the diet or the catabolism of purine
nucleotides.
Excretion. Uric acid is filtered from the circulation by the
glomerulus and virtually completely resorbed by the proximal
tubule of the kidney. A small fraction of the resorbed uric acid
is secreted by the distal nephron and excreted in the urine.
 GOUT PATHOLOGY
Primary gout: Elevated uric acid most commonly results from
reduced excretion, the basis of which is unknown in most
patients.
A small minority of primary gout is caused by uric acid
overproduction as a result of identifiable enzymatic defects.
For example, partial deficiency of hypoxanthine guanine
phosphoribosyl transferase (HGPRT) interrupts the salvage
pathway, so purine metabolites cannot be salvaged and are,
instead, degraded into uric acid.
Secondary gout: Complete absence of HGPRT also results in
hyperuricemia, but significant neurologic manifestations of this
condition (Lesch-Nyhan syndrome).
2◦ gout can also be caused by increased production (rapid cell lysis
during chemotherapy for leukemia, so-called tumor lysis
syndrome) or decreased excretion (chronic renal disease).
 GOUT PATHOLOGY

The inflammation in gout is triggered by precipitation of
urate crystals in the joints, stimulating the production of
cytokines that recruit leukocytes.
Macrophages and neutrophils phagocytose the crystals,
which activates a cytosolic sensor, the inflammasome.
The inflammasome activates caspase-1, which is involved
in the production of active IL-1β.
IL-1 is proinflammatory, and promotes accumulation of
more neutrophils and macrophages in the joint.
 GOUT PATHOLOGY
Inflammatory cells release other cytokines, free radicals,
proteases, and arachidonic acid metabolites.
The ingested crystals also damage the membranes of
phagolysosomes, leading to leakage of these mediators.
Activation of complement by the alternative pathway may
contribute to more leukocyte recruitment.
The result is an acute arthritis, which typically remits
spontaneously in days to weeks.
Repeated attacks of acute arthritis lead eventually to the
formation of tophi, aggregates of urate crystals and
inflammatory tissue.in the inflamed synovial membranes and
periarticular tissue.
Severe damage to the cartilage develops and the function of
the joints is compromised.
 FACTORS CONTRIBUTING GOUT

Only about 10% of patients with hyperuricemia develop
clinical gout.
Age of the individual and duration of the hyperuricemia.
Gout usually appears after 20 to 30 years of hyperuricemia.
Genetic predisposition. In addition to the well-defined X-
linked abnormalities of HGPRT, polymorphisms in genes
involved with urate or ion transport and possibly
inflammation are also associated with gout.
Alcohol consumption.
Obesity.
Drugs (e.g., thiazides) that reduce excretion of urate.
GOUT DISEASE

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 GOUT DISEASE
MORPHOLOGY:
ACUTE ARTHRITIS: Neutrophils and long, needle-shaped monosodium urate
crystals are seen in the synovium and synovial fluid. The acute attack
subsides after the crystals dissolve.
CHRONIC TOPHUS ARTHRITIS: After recurrent attacks, proliferation and
fibrosis and pannus tissue develop in the synovium. Destruction of the
underlying cartilage, erosions in the juxtaarticular bone and development of
ankylosis in the bone.
TOPHUS is diagnostic: It consists of large crystals, foreign body type
multinucleated giant cells trying to phagocytose them, and inflammatory
cells. It can occur in articular cartilage, ligaments, tendons, and all kinds of
soft tissues.

GOUT NEPHROPATHY: Urate accumulation in the kidney, tophus, urate
stones, urinary obstruction and pyelonephritis. 20% die from kidney failure
GOUT DISEASE

Tophu
s
GOUT DISEASE
 PSEUDOGOUT
"CHONDROCALCINOSIS=CALCIUM
PYROPHOSPHATE DISEASE"’
Crystal arthritis occurs due to calcium pyrophosphate accumulation and
stimulation of inflammation.
In cartilage: crystal accumulation
Calcium precipitation on meniscus, intervertebral disc and joint surfaces
It occurs over the age of 50 and its incidence increases with age.
Etiology?
Knee, wrist elbow, shoulder ankles
 PSEUDOGOUT
"CHONDROCALCINOSIS=CALCIUM
PYROPHOSPHATE DISEASE"’
The crystals first develop in the articular cartilage, menisci,
and intervertebral discs, and as the deposits enlarge they
may rupture and seed the joint.
The crystals form chalky, white friable deposits, which are
seen histologically in hematoxylin- and eosinstained
preparations as oval blue-purple aggregates.
Individual crystals are rhomboid, 0.5 to 5 µm in greatest
dimension and are positively birefringent.
Inflammation is usually milder than in gout.
 JOINT TUMORS & TUMOR-LIKE
LESIONS
Primary tumors of the joints are rare and are usually benign.
Tumor-like lesions: the most common lesions.
Ganglion, Synovial cyst (in popliteal fossa: Baker cyst)
They develop secondary to trauma or degenerative processes.
Benign Tumor: Giant cell tumor of the tendon sheath: tenosynovial
giant cell tumor.

GANGLION:
A cystic formation, usually less than 1.5 cm in diameter, that develops
close to the joint capsule or tendon sheath.
Most common: in the wrist.
It is formed by the cystic degeneration in the connective tissue and
does not have a true lining epithelium.
GANGLION= SO CALLED GANGLION
CYST

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 TENOSYNOVIAL GIANT CELL TUMOR
(GIANT CELL TUMOR OF THE TENDON SHEATH)

20-40 years of age.
Benign tumor of the synovium.
DIFFUSE FORM:
Most common in the knee
It mimics arthritis: pain, swelling, limitation of movement in the joint.
Diffuse proliferation throughout the joint synovium, finger-like villous
protrusions.

LOCALIZED FORM:
Painless mass in wrist and fingers.
It is the most common soft tissue tumor of the hand.
Nodular mass style

MORPHOLOGY:
Stromal mononuclear cells resembling synovial cells, hemosiderin pigment,
foamy macrophages, osteoclastic benign giant cells
 TENOSYNOVIAL GIANT CELL TUMOR
(GIANT CELL TUMOR OF THE TENDON SHEATH)

Tenosynovial giant cell tumor, Diffuse type
TENOSYNOVIAL GIANT CELL TUMOR
(GIANT CELL TUMOR OF THE TENDON SHEATH)

Tenosynovial giant cell tumor, Localized
type=
"Nodular Tenosynovitis’’