3209Paget’s Disease and Other Dysplasias of Bone CHAPTER 412
of glucocorticoid-induced osteoporosis (GCIO). Glucocorticoids are
used widely in the treatment of a variety of disorders, including chronic
lung disorders, rheumatoid arthritis and other connective tissue
diseases, and inflammatory bowel disease, and after transplantation.
Osteoporosis and related fractures are serious side effects of chronic
glucocorticoid therapy. Because the effects of glucocorticoids on the
skeleton are often superimposed on the consequences of aging and
menopause, it is not surprising that women and the elderly are most
frequently affected. The skeletal response to steroids is remarkably
heterogeneous, however, and even young, growing individuals treated
with glucocorticoids can present with fractures.
The risk of fractures depends on the dose and duration of glucocorticoid therapy, although recent data suggest that there may be no
completely safe dose. Bone loss is more rapid during the early months
of treatment, and trabecular bone is affected more severely than cortical bone. As a result, fractures have been shown to increase within
3 months of steroid treatment. There is an increase in fracture risk in
both the axial skeleton and the appendicular skeleton, including risk of
hip fracture. Bone loss can occur with any route of steroid administration, including high-dose inhaled glucocorticoids and intra-articular
injections. Alternate-day delivery does not appear to ameliorate the
skeletal effects of glucocorticoids.
■ PATHOPHYSIOLOGY
Glucocorticoids increase bone loss by multiple mechanisms, including (1) inhibition of osteoblast function and an increase in osteoblast
apoptosis, resulting in impaired synthesis of new bone; (2) stimulation of bone resorption, probably as a secondary effect; (3) impairment of the absorption of calcium across the intestine, probably by
a vitamin D–independent effect; (4) increase of urinary calcium loss
and perhaps induction of some degree of secondary hyperparathyroidism; (5) reduction of adrenal androgens and suppression of ovarian
and testicular secretion of estrogens and androgens; and (6) induction
of glucocorticoid myopathy, which may exacerbate effects on skeletal
and calcium homeostasis as well as increase the risk of falls.
■ EVALUATION OF THE PATIENT
Because of the prevalence of GCIO, it is important to evaluate the status of the skeleton in all patients starting or already receiving long-term
glucocorticoid therapy. Modifiable risk factors should be identified,
including those for falls. Examination should include testing of height
and muscle strength. Laboratory evaluation should include an assessment of 24-h urinary calcium. All patients on long-term (>3 months)
glucocorticoids should have measurement of bone mass at both the
spine and the hip using DXA. If only one skeletal site can be measured,
it is best to assess the spine in individuals <60 years and the hip in
those >60 years.
■ PREVENTION
Bone loss caused by glucocorticoids can be prevented, and the risk
of fractures significantly reduced. Strategies must include using the
lowest dose of glucocorticoid for disease management. Topical and
inhaled routes of administration are preferred, where appropriate. Risk
factor reduction is important, including smoking cessation, limitation
of alcohol consumption, and participation in weight-bearing and resistance exercise, when appropriate. All patients should receive an adequate calcium and vitamin D intake from the diet or from supplements.
TREATMENT
Glucocorticoid-Induced Osteoporosis
Several bisphosphonates (alendronate, risedronate, and zoledronic
acid) have been demonstrated in large clinical trials to reduce the
risk of fractures in patients being treated with glucocorticoids and
are FDA approved for the treatment of GCIO. Teriparatide is also
approved for treatment of GCIO. In one trial comparing teriparatide to alendronate, BMD increases were much greater and vertebral fracture risk reduction far more substantial with teriparatide
compared to alendronate. A study of denosumab indicates greater
efficacy of denosumab compared with risedronate for treatment
of GCIO. The American College of Rheumatology has published
guidelines for the management of GCIO.
■ FURTHER READING
Black DM, Rosen CJ: Postmenopausal osteoporosis. N Engl J Med
374:2096, 2016.
Black DM et al: Atypical femur fracture risk versus fragility fracture
prevention with bisphosphonates. N Engl J Med 383:743, 2020.
Compston J: Glucocorticoid-induced osteoporosis: An update. Endocrine 61:7, 2018.
Cosman F et al: Spine fracture prevalence in a nationally representative sample of US women and men aged >/=40 years: results from
the National Health and Nutrition Examination Survey (NHANES)
2013–2014. Osteoporos Int 28:2319, 2017.
Cosman F et al: Treatment sequence matters: Anabolic and antiresorptive therapy for osteoporosis. J Bone Miner Res 32:198, 2017.
Khosla S, Hofbauer LC: Osteoporosis treatment: Recent developments and ongoing challenges. Lancet Diabetes Endocrinol 5:898,
2017.
Reid IR: A broader strategy for osteoporosis interventions. Nat Rev
Endocrinol 16:333, 2020.
Roux C, Briot K: Imminent fracture risk. Osteoporos Int 28:1765,
2017.
PAGET’S DISEASE OF BONE
Paget’s disease is a localized bone-remodeling disorder that affects
widespread, noncontiguous areas of the skeleton. The pathologic process is initiated by overactive osteoclastic bone resorption followed by
a compensatory increase in osteoblastic new bone formation, resulting
in a structurally disorganized mosaic of woven and lamellar bone.
Pagetic bone is expanded, less compact, and more vascular; thus, it is
more susceptible to deformities and fractures. Although most patients
are asymptomatic, symptoms resulting directly from bony involvement
(bone pain, secondary arthritis, fractures) or secondarily from the
expansion of bone causing compression of surrounding neural tissue
are not uncommon.
Epidemiology There is a marked geographic variation in the
frequency of Paget’s disease, with high prevalence in Western Europe
(Great Britain, France, and Germany, but not Switzerland or Scandinavia)
and among those who have immigrated to Australia, New Zealand,
South Africa, and North and South America. The disease is rare in
native populations of the Americas, Africa, Asia, and the Middle East;
when it does occur, the affected subjects usually have evidence of
European ancestry, supporting the migration theory. For unclear reasons,
the prevalence and severity of Paget’s disease are decreasing, and the
age of diagnosis is increasing.
The prevalence is greater in males and increases with age. Autopsy
series reveal Paget’s disease in ~3% of those over age 40. Prevalence of
positive skeletal radiographs in patients aged >55 years is 2.5% for men
and 1.6% for women. Elevated alkaline phosphatase (ALP) levels in
asymptomatic patients have an age-adjusted incidence of 12.7 and 7 per
100,000 person-years in men and women, respectively.
Etiology The etiology of Paget’s disease of bone remains unknown,
but evidence supports both genetic and viral etiologies. A positive
412 Paget’s Disease and Other
Dysplasias of Bone
Rajesh K. Jain, Tamara J. Vokes
3210 PART 12 Endocrinology and Metabolism
family history is found in 15–25% of patients and, when present, raises
the prevalence of the disease seven- to tenfold among first-degree
relatives.
A clear genetic basis has been established for several rare familial
bone disorders that clinically and radiographically resemble Paget’s
disease but have more severe presentation and earlier onset. A homozygous deletion of the TNFRSF11B gene, which encodes osteoprotegrin
(Fig. 412-1), causes juvenile Paget’s disease, also known as familial
idiopathic hyperphosphatasia, a disorder characterized by uncontrolled
osteoclastic differentiation and resorption. Familial patterns of disease
in several large kindred are consistent with an autosomal dominant
pattern of inheritance with variable penetrance. Familial expansile
osteolysis, expansile skeletal hyperphosphatasia, and early-onset Paget’s
disease are associated with mutations in the TNFRSF11A gene, which
encodes RANK (receptor activator of nuclear factor-κB), a member of
the tumor necrosis factor superfamily critical for osteoclast differentiation (Fig. 412-1). A mutation in profilin 1, a small actin protein that
acts as a tumor suppressor, also causes early-onset Paget’s disease with
a predisposition for the development of osteosarcoma. Finally, mutations in the gene for valosin-containing protein cause a rare syndrome
with autosomal dominant inheritance and variable penetrance known
as inclusion body myopathy with Paget’s disease and frontotemporal
dementia (IBMPFD). The role of genetic factors is less clear in the
more common form of late-onset Paget’s disease. The most common
mutations identified in familial and sporadic cases of Paget’s disease
have been in the SQSTM1 gene (sequestasome-1 or p62 protein) in
the C-terminal ubiquitin-binding domain. The other candidate genes
include CSF1 (1p13), which encodes macrophage colony-stimulating
factor (M-CSF), a cytokine that is required for osteoclast differentiation; RIN3 (14q32), which encodes a guanine exchange factor called
Rab and Ras interactor 3; OPTN (10p13), which is involved in regulating nuclear factor (NF)-κB; TNFRSF11A (18q21), which encodes
Mesenchymal cell
Collagen
osteocalcin Osteoclast
Osteoclast
precursor
Osteoblasts
Osteoblasts
IGF-1
IGF-2
OPG
M-CSF
IL-1, IL-6
c-fms
+
RANK L
RANK
FIGURE 412-1 Diagram illustrating factors that promote differentiation and
function of osteoclasts and osteoblasts and the role of the RANK pathway. Stromal
bone marrow (mesenchymal) cells and differentiated osteoblasts produce multiple
growth factors and cytokines, including macrophage colony-stimulating factor
(M-CSF), to modulate osteoclastogenesis. RANKL (receptor activator of nuclear
factor-κB [NF-κB] ligand) is produced by osteoblast progenitors and mature
osteoblasts and can bind to a soluble decoy receptor known as osteoprotegerin
(OPG) to inhibit RANKL action. Alternatively, a cell-cell interaction between
osteoblast and osteoclast progenitors allows RANKL to bind to its membranebound receptor, RANK, thereby stimulating osteoclast differentiation and function.
RANK binds intracellular proteins called tumor necrosis factor receptor–associated
factors (TRAFs) that mediate receptor signaling through transcription factors such
as NF-κB. M-CSF binds to its receptor, c-fms, which is the cellular homologue of
the fms oncogene. See text for the potential role of these pathways in disorders
of osteoclast function such as Paget’s disease and osteopetrosis. IGF, insulin-like
growth factor; IL, interleukin.
receptor activator of NF-κB (RANK), a receptor that is essential for
osteoclast differentiation; and TM7SF4, which encodes dendritic
cell–specific transmembrane protein (DC-STAMP), a molecule that
is essential for fusion of the osteoclast. The phenotypic variability in
patients with SQSTM1 mutations suggests that additional factors, such
as other genetic influences or viral infection, may influence clinical
expression of the disease.
Several lines of evidence suggest that a viral infection may contribute to the clinical manifestations of Paget’s disease, including (1) the
presence of cytoplasmic and nuclear inclusions resembling paramyxoviruses (measles and respiratory syncytial virus) in pagetic osteoclasts
and (2) viral mRNA in precursor and mature osteoclasts. The viral
etiology is further supported by conversion of osteoclast precursors
to pagetic-like osteoclasts by vectors containing the measles virus
nucleocapsid or matrix genes. The decline in the incidence of Paget’s
disease coincides with the widespread vaccination against measles, also
consistent with the potential role of virus in the development of the disease. However, the viral etiology has been questioned by the inability to
culture a live virus from pagetic bone and by failure to clone the fulllength viral genes from material obtained from patients with Paget’s
disease. Furthermore, patients with Paget’s disease do not have higher
antibody levels against paramyxoviruses or measles as compared to
controls, nor do antibody levels correlate with disease severity in those
with Paget’s disease.
Pathophysiology The principal abnormality in Paget’s disease is
the increased number and activity of osteoclasts. Pagetic osteoclasts
are large, increased 10- to 100-fold in number, and have a greater number of nuclei (as many as 100 compared to 3–5 nuclei in the normal
osteoclast). The overactive osteoclasts may create a sevenfold increase
in resorptive surfaces and an erosion rate of 9 μg/d (normal is 1 μg/d).
Several causes for the increased number and activity of pagetic osteoclasts have been identified: (1) osteoclastic precursors are hypersensitive to 1,25(OH)2
D3
; (2) osteoclasts are hyperresponsive to RANK
ligand (RANKL), the osteoclast stimulatory factor that mediates the
effects of most osteotropic factors on osteoclast formation; (3) marrow
stromal cells from pagetic lesions have increased RANKL expression;
(4) osteoclast precursor recruitment is increased by interleukin (IL) 6,
which is increased in the blood of patients with active Paget’s disease
and is overexpressed in pagetic osteoclasts; (5) expression of the protooncogene c-fos, which increases osteoclastic activity, is increased; and
(6) the antiapoptotic oncogene Bcl-2 in pagetic bone is overexpressed.
Numerous osteoblasts are recruited to active resorption sites and produce large amounts of new bone matrix. As a result, bone turnover is
high, and bone mass is normal or increased, not reduced, unless there
is concomitant deficiency of calcium and/or vitamin D.
The characteristic feature of Paget’s disease is increased bone resorption accompanied by accelerated bone formation. An initial osteolytic
phase involves prominent bone resorption and marked hypervascularization. Radiographically, this manifests as an advancing lytic wedge,
or “blade of grass” lesion. The second phase is a period of very active
bone formation and resorption that replaces normal lamellar bone
with haphazard (woven) bone. Fibrous connective tissue may replace
normal bone marrow. In the final sclerotic phase, bone resorption
declines progressively and leads to a hard, dense, less vascular pagetic
or mosaic bone, which represents the so-called burned-out phase of
Paget’s disease. All three phases may be present at the same time at
different skeletal sites.
Clinical Manifestations Diagnosis is often made in asymptomatic patients because they have elevated ALP levels on routine blood
chemistry testing or an abnormality on a skeletal radiograph obtained
for another indication. The skeletal sites most commonly involved
are the pelvis, vertebral bodies, skull, femur, and tibia. Familial cases
with an early presentation often have numerous active sites of skeletal
involvement.
The most common presenting symptom is pain, which may result
from increased bony vascularity, expanding lytic lesions, fractures,
bowing, or other deformities. Bowing of the femur or tibia causes
3211Paget’s Disease and Other Dysplasias of Bone CHAPTER 412
gait abnormalities and abnormal mechanical stresses with secondary
osteoarthritis of the hip or knee joints. Long bone bowing also causes
extremity pain by stretching the muscles attached to the bone softened
by the pagetic process. Back pain results from enlarged pagetic vertebrae, vertebral compression fractures, spinal stenosis, degenerative
changes of the joints, and altered body mechanics with kyphosis and
forward tilt of the upper back. Rarely, spinal cord compression may
result from bone enlargement or from the vascular steal syndrome.
Skull involvement may cause headaches, symmetric or asymmetric
enlargement of the parietal or frontal bones (frontal bossing), and
increased head size. Cranial expansion may narrow cranial foramens
and cause neurologic complications including hearing loss from
cochlear nerve damage from temporal bone involvement, cranial nerve
palsies, and softening of the base of the skull (platybasia) with the risk
of brainstem compression. Pagetic involvement of the facial bones may
cause facial deformity; loss of teeth and other dental conditions; and,
rarely, airway compression.
Fractures are serious complications of Paget’s disease and usually
occur in long bones at areas of active or advancing lytic lesions. Common fracture sites are the femoral shaft and subtrochanteric regions.
Neoplasms arising from pagetic bone are rare (<0.5%). The incidence
of sarcoma appears to be decreasing, possibly because of earlier, more
effective treatment with potent antiresorptive agents. The majority of
tumors are osteosarcomas, which usually present with new pain in a
long-standing pagetic lesion. Osteoclast-rich benign giant cell tumors
may arise in areas adjacent to pagetic bone, and they respond to glucocorticoid therapy.
Cardiovascular complications may occur in patients with involvement of large (15–35%) portions of the skeleton and a high degree of
disease activity (ALP four times above normal). The extensive arteriovenous shunting and marked increases in blood flow through the
vascular pagetic bone lead to a high-output state and cardiac enlargement. However, high-output heart failure is relatively rare and usually
develops in patients with concomitant cardiac pathology. In addition,
calcific aortic stenosis and diffuse vascular calcifications have been
associated with Paget’s disease.
Diagnosis The diagnosis may be suggested on clinical examination
by the presence of an enlarged skull with frontal bossing, bowing of an
extremity, or short stature with simian posturing. An extremity with an
area of warmth and tenderness to palpation may suggest an underlying
pagetic lesion. Other findings include bony deformity of the pelvis,
skull, spine, and extremities; arthritic involvement of the joints adjacent to lesions; and leg-length discrepancy resulting from deformities
of the long bones.
Paget’s disease is usually diagnosed from radiologic and biochemical abnormalities. Radiographic findings typical of Paget’s disease
include enlargement or expansion of an entire bone or area of a long
bone, cortical thickening, coarsening of trabecular markings, and
typical lytic and sclerotic changes. Skull radiographs (Fig. 412-2)
reveal regions of “cotton wool,” or osteoporosis circumscripta, thickening of diploic areas, and enlargement and sclerosis of a portion or
all of one or more skull bones. Vertebral cortical thickening of the
superior and inferior end plates creates a “picture frame” vertebra.
Diffuse radiodense enlargement of a vertebra is referred to as “ivory
vertebra.” Pelvic radiographs may demonstrate disruption or fusion of
the sacroiliac joints; porotic and radiodense lesions of the ilium with
whorls of coarse trabeculation; thickened and sclerotic iliopectineal
line (brim sign); and softening with protrusio acetabuli, with axial
migration of the hips and functional flexion contracture. Radiographs
of long bones reveal bowing deformity and typical pagetic changes of
cortical thickening and expansion and areas of lucency and sclerosis
(Fig. 412-3). Radionuclide 99mTc bone scans are less specific but are
more sensitive than standard radiographs for identifying sites of active
skeletal lesions. Although computed tomography (CT) and magnetic
resonance imaging (MRI) studies are not necessary in most cases,
CT may be useful for the assessment of possible fracture, and MRI
is necessary to assess the possibility of sarcoma, giant cell tumor, or
FIGURE 412-2 A 48-year-old woman with Paget’s disease of the skull. Left. Lateral radiograph showing areas of both bone resorption and sclerosis. Right. 99mTc
hydroxymethylene diphosphonate (HDP) bone scan with anterior, posterior, and lateral views of the skull showing diffuse isotope uptake by the frontal, parietal, occipital,
and petrous bones.
FIGURE 412-3 Radiograph of a 73-year-old man with Paget’s disease of the right
proximal femur. Note the coarsening of the trabecular pattern with marked cortical
thickening and narrowing of the joint space consistent with osteoarthritis secondary
to pagetic deformity of the right femur.
3212 PART 12 Endocrinology and Metabolism
metastatic disease in pagetic bone. Definitive diagnosis of malignancy
often requires bone biopsy.
Biochemical evaluation is useful in the diagnosis and management
of Paget’s disease. The marked increase in bone turnover can be monitored using biochemical markers of bone formation and resorption.
The parallel rise in markers of bone formation and resorption confirms
the coupling of bone formation and resorption in Paget’s disease. The
degree of bone marker elevation reflects the extent and severity of the
disease. For most patients, serum total ALP remains the test of choice
both for diagnosis and assessing response to therapy. Occasionally, a
symptomatic patient with evidence of progression at a single site may
have a normal total ALP level but increased bone-specific ALP. For
unclear reasons, serum osteocalcin, another marker of bone formation,
is not always elevated and is not recommended for use in diagnosis or
management of Paget’s disease. In contrast, bone formation marker
P1NP does reflect the activity of the disease and can be used instead
of total ALP. Bone resorption markers (serum or urine N-telopeptide
or C-telopeptide measured in the blood or urine) are also elevated in
active Paget’s disease and decrease more rapidly in response to therapy
than does ALP.
Serum calcium and phosphate levels are normal in Paget’s disease.
Immobilization of a patient with active Paget’s disease may rarely cause
hypercalcemia and hypercalciuria and increase the risk for nephrolithiasis. However, the discovery of hypercalcemia, even in the presence of
immobilization, should prompt a search for another cause of hypercalcemia. In contrast, hypocalcemia or mild secondary hyperparathyroidism may develop in Paget’s patients with very active bone formation
and insufficient calcium and vitamin D intake, particularly during
bisphosphonate therapy when bone resorption is rapidly suppressed
and active bone formation continues. Therefore, adequate calcium
and vitamin D intake should be instituted prior to administration of
bisphosphonates.
TREATMENT
Paget’s Disease of Bone
The development of effective and potent pharmacologic agents
(Table 412-1) has changed the treatment philosophy from treating
only symptomatic patients to treating asymptomatic patients who
are at risk for complications. According to the Endocrine Society
Clinical Practice Guidelines published in 2014, pharmacologic
therapy is indicated for most patients with active Paget’s disease
who are at risk of complications. Treatment may be initiated to
control symptoms caused by metabolically active Paget’s disease
such as bone pain, fracture, headache, pain from pagetic radiculopathy or arthropathy, or neurologic complications; to decrease local
blood flow and minimize operative blood loss in patients who need
surgery at an active pagetic site; to reduce hypercalciuria that may
occur during immobilization; and to decrease the risk of complications when disease activity is high (elevated ALP) and when the
site of involvement involves weight-bearing bones, areas adjacent to
TABLE 412-1 Pharmacologic Agents Approved for Treatment of
Paget’s Disease
NAME
DOSE AND MODE OF
DELIVERY
NORMALIZATION
OF ALKALINE
PHOSPHATASE (ALP)
Zoledronic acid 5 mg IV over 15 min 90% of patients at 6 mo
Pamidronate 30 mg/d IV over 4 h on
3 days
~50% of patients
Risedronate 30 mg/d PO for 2 mo 73% of patients
Alendronate 40 mg/d PO for 6 mo 63% of patients
Tiludronate 800 mg/d PO for 3 mo 35% of patients
Etidronate 200–400 mg/d PO × 6 mo 15% of patients
Calcitonin (Miacalcin) 100 U SC daily for 6–18 mo
(may reduce to 50 U 3×
per week)
(Reduction of ALP by
up to 50%)
major joints, vertebral bodies, and the skull. Whether or not early
therapy prevents late complications remains to be determined.
Randomized studies from the United Kingdom showed no difference in bone pain, fracture rates, quality of life, and hearing loss
between patients who received pharmacologic therapy to control
symptoms (bone pain) and those receiving bisphosphonates to
normalize serum ALP. However, the conclusions of these studies
are debatable since the majority of subjects had already received
bisphosphonate therapy in the past, perhaps limiting generalizability, and because the bone deformities that occur with Paget’s
disease may take many years to manifest. It seems likely that the
restoration of normal bone architecture following suppression of
pagetic activity will prevent further deformities and complications.
Agents approved for treatment of Paget’s disease suppress the
very high rates of bone resorption and secondarily decrease the
high rates of bone formation (Table 412-1). As a result of decreasing
bone turnover, pagetic structural patterns, including areas of poorly
mineralized woven bone, are replaced by more normal cancellous
or lamellar bone. Reduced bone turnover can be documented by a
decline in serum formation markers (ALP and P1NP) and urine or
serum resorption markers (N-telopeptide, C-telopeptide).
Bisphosphonates are the mainstay of pharmacologic therapy of
Paget’s disease. Among them, zoledronic acid is currently recommended as the first choice, particularly for those who have severe
disease or need rapid normalization of bone turnover (neurologic
symptoms, severe bone pain due to a lytic lesion, risk of an impending fracture, or pretreatment prior to elective surgery in an area of
active disease). Zoledronic acid normalized bone turnover faster
and in a high proportion of patients (>90%) than oral bisphosphonates with the therapeutic effect persisting for months or even
years. It is given at a dose of 5 mg as an intravenous infusion over
20 min, although slower rates of infusion are recommended for
elderly or those with mild impairment of renal function. More significant renal impairment (glomerular filtration rate <35 mL/min)
is a contraindication for use of zoledronic acid due to higher risk of
further deterioration of renal function. About 20–25% of patients
experience a flulike syndrome after the first infusion, which can be
partly ameliorated by pretreatment with acetaminophen or nonsteroidal anti-inflammatory drugs (NSAIDs). Oral bisphosphonates,
alendronate and risedronate, can be used in subjects who have mild
disease or some degree of renal impairment. Oral bisphosphonates
should be taken first thing in the morning on an empty stomach,
followed by maintenance of upright posture with no food, drink, or
other medications for 30–60 min. The first clinically useful agent,
etidronate, is no longer used due to its low potency and higher risk
of inducing osteomalacia. The efficacy of different agents, based
on their ability to normalize or decrease ALP levels, is summarized
in Table 412-1, although the response rates are not comparable
because they are obtained from different studies.
The subcutaneous injectable form of salmon calcitonin is
approved for the treatment of Paget’s disease but is rarely used due
to its low potency and should be reserved for patients who either
do not tolerate bisphosphonates or have a contraindication to their
use. For patients with contraindication to bisphosphonates, another
alternative is denosumab, an antibody to RANKL, which has been
reported to result in reduction in ALP. However, it has not been
approved for this indication and has less complete and less durable
effect than bisphosphonates.
SCLEROSING BONE DISORDERS
■ OSTEOPETROSIS
Osteopetrosis refers to a group of disorders caused by severe impairment of osteoclast-mediated bone resorption. Other terms that are
often used include marble bone disease, which captures the solid x-ray
appearance of the involved skeleton, and Albers-Schonberg disease,
which refers to the milder, adult form of osteopetrosis also known
as autosomal dominant osteopetrosis type II. The major types of
3213Paget’s Disease and Other Dysplasias of Bone CHAPTER 412
osteopetrosis include malignant (severe, infantile, autosomal recessive)
osteopetrosis and benign (adult, autosomal dominant) osteopetrosis
types I and II. A rare autosomal recessive intermediate form has a more
benign prognosis. Autosomal recessive carbonic anhydrase (CA) II
deficiency produces osteopetrosis of intermediate severity associated
with renal tubular acidosis and cerebral calcification.
Etiology and Genetics Naturally occurring and gene-knockout
animal models with phenotypes similar to those of the human disorders
have been used to explore the genetic basis of osteopetrosis. The primary defect in osteopetrosis is the loss of osteoclastic bone resorption
and preservation of normal osteoblastic bone formation. Osteoprotegerin (OPG) is a soluble decoy receptor that binds osteoblast-derived
RANK ligand, which mediates osteoclast differentiation and activation
(Fig. 412-1). Transgenic mice that overexpress OPG develop osteopetrosis, presumably by blocking RANK ligand. Mice deficient in RANK
lack osteoclasts and develop severe osteopetrosis.
Recessive mutations of CA II prevent osteoclasts from generating an
acid environment in the clear zone between its ruffled border and the
adjacent mineral surface. Absence of CA II, therefore, impairs osteoclastic bone resorption. Other forms of human disease have less clear
genetic defects. About one-half of the patients with malignant infantile
osteopetrosis have a mutation in the TCIRG1 gene encoding the osteoclast-specific subunit of the vacuolar proton pump, which mediates the
acidification of the interface between bone mineral and the osteoclast
ruffled border. Mutations in the CLCN7 chloride channel gene cause
autosomal dominant osteopetrosis type II.
Clinical Presentation The incidence of autosomal recessive severe
(malignant) osteopetrosis ranges from 1 in 200,000 to 1 in 500,000 live
births. As bone and cartilage fail to undergo modeling, paralysis of one
or more cranial nerves may occur due to narrowing of the cranial foramens. Failure of skeletal modeling also results in inadequate marrow
space, leading to extramedullary hematopoiesis with hypersplenism
and pancytopenia. Hypocalcemia due to lack of osteoclastic bone
resorption may occur in infants and young children. The untreated
infantile disease is fatal, often before age 5.
Adult (benign) osteopetrosis is an autosomal dominant disease
that is usually diagnosed by the discovery of typical skeletal changes
in young adults who undergo radiologic evaluation of a fracture.
The prevalence is 1 in 100,000 to 1 in 500,000 adults. The course is
not always benign, because fractures may be accompanied by loss of
vision, deafness, psychomotor delay, mandibular osteomyelitis, and
other complications usually associated with the juvenile form. In some
kindred, nonpenetrance results in skip generations, while in other families, severely affected children are born into families with benign disease. The milder form of the disease does not usually require treatment.
Radiography Typically, there are generalized symmetric increases
in bone mass with thickening of both cortical and trabecular bone.
Diaphyses and metaphyses are broadened, and alternating sclerotic and
lucent bands may be seen in the iliac crests, at the ends of long bones,
and in vertebral bodies. The cranium is usually thickened, particularly
at the base of the skull, and the paranasal and mastoid sinuses are
underpneumatized.
Laboratory Findings The only significant laboratory findings
are elevated serum levels of osteoclast-derived tartrate-resistant acid
phosphatase (TRAP) and the brain isoenzyme of creatine kinase.
Serum calcium may be low in severe disease, and parathyroid hormone
and 1,25-dihydroxyvitamin D levels may be elevated in response to
hypocalcemia.
TREATMENT
Osteopetrosis
Allogeneic human leukocyte antigen (HLA)–identical bone marrow transplantation has been successful in some children. Following transplantation, the marrow contains progenitor cells and
normally functioning osteoclasts. With long-term follow-up after
transplantation, radiographic improvements, such as improvements
in Erlenmeyer flask deformities, are seen, although there is not
complete normalization. A cure is most likely when children are
transplanted before age 4. Marrow transplantation from nonidentical HLA-matched donors has a much higher failure rate. Limited
studies in small numbers of patients have suggested variable benefits
following treatment with interferon γ-1β, 1,25-dihydroxyvitamin D
(which stimulates osteoclasts directly), methylprednisolone, and a
low-calcium/high-phosphate diet.
Surgical intervention is indicated to decompress optic or auditory nerve compression. Orthopedic management is required for
the surgical treatment of fractures and their complications, including malunion and postfracture deformity.
■ PYKNODYSOSTOSIS
This is an autosomal recessive form of osteosclerosis that is believed
to have affected the French impressionist painter Henri de ToulouseLautrec. The molecular basis involves mutations in the gene that
encodes cathepsin K, a lysosomal metalloproteinase highly expressed
in osteoclasts and important for bone-matrix degradation. Osteoclasts
are present but do not function normally. Pyknodysostosis is a form of
short-limb dwarfism that presents with frequent fractures but usually a
normal life span. Clinical features include short stature; kyphoscoliosis
and deformities of the chest; high arched palate; proptosis; blue sclerae;
dysmorphic features including small face and chin, fronto-occipital
prominence, pointed beaked nose, large cranium, and obtuse mandibular angle; and small, square hands with hypoplastic nails. Radiographs
demonstrate a generalized increase in bone density, but in contrast to
osteopetrosis, the long bones are normally shaped. Separated cranial
sutures, including the persistent patency of the anterior fontanel, are
characteristic of the disorder. There may also be hypoplasia of the
sinuses, mandible, distal clavicles, and terminal phalanges. Persistence
of deciduous teeth and sclerosis of the calvarium and base of the skull
are also common. Histologic evaluation shows normal cortical bone
architecture with decreased osteoblastic and osteoclastic activities.
Serum chemistries are normal, and unlike osteopetrosis, there is no
anemia. There is no known treatment for this condition, and there are
no reports of attempted bone marrow transplant.
■ PROGRESSIVE DIAPHYSEAL DYSPLASIA
Also known as Camurati-Engelmann disease, progressive diaphyseal
dysplasia is an autosomal dominant disorder that is characterized
radiographically by diaphyseal hyperostosis and a symmetric thickening
and increased diameter of the endosteal and periosteal surfaces of the
diaphyses of the long bones, particularly the femur and tibia, and, less
often, the fibula, radius, and ulna. The genetic defect responsible for the
disease has been localized to the area of chromosome 19q13.2 encoding
tumor growth factor (TGF)-β1. The mutation promotes activation of
TGF-β1. The clinical severity is variable. The most common presenting symptoms are pain and tenderness of the involved areas, fatigue,
muscle wasting, and gait disturbance. The weakness may be mistaken
for muscular dystrophy. Characteristic body habitus includes thin limbs
with little muscle mass yet prominent and palpable bones and, when
the skull is involved, large head with prominent forehead and proptosis.
Patients may also display signs of cranial nerve palsies, hydrocephalus,
central hypogonadism, and Raynaud’s phenomenon. Radiographically,
patchy progressive endosteal and periosteal new bone formation is
observed along the diaphyses of the long bones. Bone scintigraphy
shows increased radiotracer uptake in involved areas.
Treatment with low-dose glucocorticoids relieves bone pain and
may reverse the abnormal bone formation. Intermittent bisphosphonate therapy has produced clinical improvement in a limited number of patients. Disease activity may also attenuate as patients enter
adulthood.
■ HYPEROSTOSIS CORTICALIS GENERALISATA
This is also known as van Buchem’s disease; it is an autosomal recessive
disorder characterized by endosteal hyperostosis in which osteosclerosis involves the skull, mandible, clavicles, and ribs. The major
3214 PART 12 Endocrinology and Metabolism
manifestations are due to narrowed cranial foramens with neural
compressions that may result in optic atrophy, facial paralysis, and
deafness. Adults may have an enlarged mandible. Serum ALP levels
may be elevated, which reflect the uncoupled bone remodeling with
high osteoblastic formation rates and low osteoclastic resorption. As
a result, there is increased accumulation of normal bone. Endosteal
hyperostosis with syndactyly, known as sclerosteosis, is a more severe
form. The genetic defects for both sclerosteosis and van Buchem’s disease have been associated with mutations in the SOST gene.
■ MELORHEOSTOSIS
Melorheostosis (Greek, “flowing hyperostosis”) may occur sporadically
or follow a pattern consistent with an autosomal recessive disorder. The
major manifestation is progressive linear hyperostosis in one or more
bones of one limb, usually a lower extremity. The name comes from the
radiographic appearance of the involved bone, which resembles melted
wax that has dripped down a candle. Symptoms appear during childhood as pain or stiffness in the area of sclerotic bone. There may be
associated ectopic soft tissue masses, composed of cartilage or osseous
tissue, and skin changes overlying the involved bone, consisting of
scleroderma-like areas and hypertrichosis. The disease does not progress in adults, but pain and stiffness may persist. Laboratory tests are
unremarkable. Somatic mutations in MAP2K1, which increases MEK1
activity downstream of the RAS pathway, and SMAD3, which upregulates the TGF-β/SMAD pathway, have been identified in affected bone
in patients with melorheostosis. There is no specific treatment. Surgical
interventions to correct contractures are often unsuccessful.
■ OSTEOPOIKILOSIS
The literal translation of osteopoikilosis is “spotted bones”; it is a
benign autosomal dominant condition in which numerous small,
variably shaped (usually round or oval) foci of bony sclerosis are seen
in the epiphyses and adjacent metaphyses. The lesions may involve any
bone except the skull, ribs, and vertebrae. They may be misidentified
as metastatic lesions. The main differentiating points are that bony
lesions of osteopoikilosis are stable over time and do not accumulate
radionucleotide on bone scanning. In some kindred, osteopoikilosis is
associated with connective tissue nevi known as dermatofibrosis lenticularis disseminata, also known as Buschke-Ollendorff syndrome. Most
cases are caused by mutations in LEMD3, which is involved with bone
morphogenetic protein (BMP) signaling. Histologic inspection reveals
thickened but otherwise normal trabeculae and islands of normal cortical bone. No treatment is indicated.
■ HEPATITIS C–ASSOCIATED OSTEOSCLEROSIS
Hepatitis C–associated osteosclerosis (HCAO) is a rare acquired diffuse osteosclerosis in adults with prior hepatitis C infection. After a
latent period of several years, patients develop diffuse appendicular
bone pain and a generalized increase in bone mass with elevated serum
ALP. Bone biopsy and histomorphometry reveal increased rates of
bone formation, decreased bone resorption with a marked decrease in
osteoclasts, and dense lamellar bone. One patient had increased serum
OPG levels, and bone biopsy showed large numbers of osteoblasts
positive for OPG and reduced osteoclast number. Empirical therapy
includes pain control, and there may be beneficial response to bisphosphonate. Long-term antiviral therapy may reverse the bone disease.
DISORDERS ASSOCIATED WITH
DEFECTIVE MINERALIZATION
■ HYPOPHOSPHATASIA
This is a rare inherited disorder that presents as rickets in infants and
children or osteomalacia in adults with paradoxically low serum levels
of ALP. The frequency of the severe neonatal and infantile forms is
about 1 in 100,000 live births in Canada, where the disease is most
common because of its high prevalence among Mennonites and Hutterites. It is rare in African Americans. The severity of the disease is
remarkably variable, ranging from intrauterine death associated with
profound skeletal hypomineralization at one extreme to premature
tooth loss as the only manifestation in some adults. Severe cases are
inherited in an autosomal recessive manner, but the genetic patterns
are less clear for the milder forms. The disease is caused by a deficiency
of tissue nonspecific (bone/liver/kidney) ALP (TNSALP), which,
although ubiquitous, results only in bone abnormalities. Protein levels
and functions of the other ALP isozymes (germ cell, intestinal, placental) are normal. Defective ALP permits accumulation of its major
naturally occurring substrates including phosphoethanolamine (PEA),
inorganic pyrophosphate (PPi), and pyridoxal 5′-phosphate (PLP). The
accumulation of PPi interferes with mineralization through its action
as a potent inhibitor of hydroxyapatite crystal growth.
Perinatal hypophosphatasia becomes manifest during pregnancy
and is often complicated by polyhydramnios and intrauterine death.
The infantile form becomes clinically apparent before the age of
6 months with failure to thrive, rachitic deformities, functional craniosynostosis despite widely open fontanels (which are actually hypomineralized areas of the calvarium), raised intracranial pressure, and flail
chest with predisposition to pneumonia. Hypercalcemia and hypercalciuria are common. This form has a mortality rate of ~50%. Prognosis
seems to improve for the children who survive infancy. Childhood
hypophosphatasia has variable clinical presentation. Premature loss of
deciduous teeth (before age 5) is the hallmark of the disease. Rickets
causes delayed walking with waddling gait, short stature, and dolichocephalic skull with frontal bossing. The disease often improves during
puberty but may recur in adult life. Adult hypophosphatasia presents
during middle age with painful, poorly healing metatarsal stress fractures or thigh pain due to femoral pseudofractures. Presentation may
be subtle with muscle pain or recurring headaches as the predominant
symptoms. It is important to recognize hypophosphatasia in adults
because treatment with bisphosphonates can result in increased rather
than decreased bone fragility.
Laboratory investigation reveals low ALP levels and normal or
elevated levels of serum calcium and phosphorus despite clinical and
radiologic evidence of rickets or osteomalacia. Serum parathyroid
hormone, 25-hydroxyvitamin D, and 1,25-dihydroxyvitamin D levels
are normal. The elevation of PLP is specific for the disease and may
even be present in asymptomatic parents of severely affected children.
Because vitamin B6
increases PLP levels, vitamin B6
supplements
should be discontinued 1 week before testing. Clinical testing is available to detect loss-of-function mutation(s) within the ALPL gene that
encodes TNSALP.
In contrast to other forms of rickets and osteomalacia, calcium and
vitamin D supplementation should be avoided because they may aggravate hypercalcemia and hypercalciuria. A low-calcium diet, glucocorticoids, and calcitonin have been used in a small number of patients
with variable responses. Because fracture healing is poor, placement of
intramedullary rods is best for acute fracture repair and for prophylactic prevention of fractures. In 2015, asfotase alfa, a tissue-nonspecific
ALP was approved as enzyme replacement therapy for the perinatal/
infantile- and juvenile-onset forms. With 7 years of therapy, children
with perinatal/infantile forms showed sustained improvements in
mineralization, along with improvements in other features, such as
respiratory function and growth.
■ AXIAL OSTEOMALACIA
This is a rare disorder characterized by defective skeletal mineralization
despite normal serum calcium and phosphate levels. Clinically, the disorder presents in middle-aged or elderly men with chronic axial skeletal
discomfort. Cervical spine pain may also be present. Radiographic findings are mainly osteosclerosis due to coarsened trabecular patterns typical of osteomalacia. Spine, pelvis, and ribs are most commonly affected.
Histologic changes show defective mineralization and flat, inactive
osteoblasts. The primary defect appears to be an acquired defect in
osteoblast function. The course is benign, and there is no established
treatment. Calcium and vitamin D therapies are not effective.
■ FIBROGENESIS IMPERFECTA OSSIUM
This is a rare condition of unknown etiology. It presents in both sexes;
in middle age or later; and with progressive, intractable skeletal pain
3215Paget’s Disease and Other Dysplasias of Bone CHAPTER 412
and fractures; worsening immobilization; and a debilitating course.
The only biochemical abnormality is elevated ALP. Radiographic
evaluation reveals generalized osteomalacia, osteopenia, and occasional pseudofractures. Histologic features include a tangled pattern
of collagen fibrils with abundant osteoblasts and osteoclasts. Use of
growth hormone led to substantial short-term clinical improvement
in two adult patients, but long-term outcomes are unknown. No other
effective treatment is known. Spontaneous remission has been reported
in a small number of patients.
FIBROUS DYSPLASIA AND MCCUNEALBRIGHT SYNDROME
Fibrous dysplasia is a sporadic disorder characterized by the presence
of one (monostotic) or more (polyostotic) expanding fibrous skeletal
lesions composed of bone-forming mesenchyme. The association of
the polyostotic form with café au lait spots and hyperfunction of an
endocrine system such as pseudoprecocious puberty of ovarian origin
is known as McCune-Albright syndrome (MAS). A spectrum of the
phenotypes is caused by activating mutations in the GNAS1 gene,
which encodes the α subunit of the stimulatory G protein (Gs
α). As the
postzygotic mutations occur at different stages of early development,
the extent and type of tissue affected are variable and explain the mosaic
pattern of skin and bone changes. GTP binding activates the Gs
α regulatory protein and mutations in regions of Gs
α that selectively inhibit
GTPase activity, which results in constitutive stimulation of the cyclic
AMP–protein kinase A signal transduction pathway. Such mutations
of the Gs
α protein–coupled receptor may cause autonomous function
in bone (parathyroid hormone receptor); skin (melanocyte-stimulating
hormone receptor); and various endocrine glands including ovary
(follicle-stimulating hormone receptor), thyroid (thyroid-stimulating
hormone receptor), adrenal (adrenocorticotropic hormone receptor),
and pituitary (growth hormone–releasing hormone receptor). The skeletal lesions are composed largely of mesenchymal cells that do not differentiate into osteoblasts, resulting in the formation of imperfect bone.
In some areas of bone, fibroblast-like cells develop features of osteoblasts
in that they produce extracellular matrix that organizes into woven bone.
Calcification may occur in some areas. In other areas, cells have features
of chondrocytes and produce cartilage-like extracellular matrix.
Clinical Presentation Fibrous dysplasia occurs with equal frequency in both sexes, whereas MAS with precocious puberty is more
common (10:1) in girls. The monostotic form is the most common and
is usually diagnosed in patients between 20 and 30 years of age without
associated skin lesions. The polyostotic form typically manifests in
children <10 years old and may progress with age. Early-onset disease
is generally more severe. Lesions may become quiescent in puberty
and progress during pregnancy or with estrogen therapy. In polyostotic
fibrous dysplasia, the lesions most commonly involve the maxilla and
other craniofacial bones, ribs, and metaphyseal or diaphyseal portions
of the proximal femur or tibia. Expanding bone lesions may cause pain,
deformity, fractures, and nerve entrapment. Sarcomatous degeneration
involving the facial bones or femur is infrequent (<1%). The risk of
malignant transformation is increased by radiation, which has proven
to be ineffective treatment. In rare patients with widespread lesions,
renal phosphate wasting and hypophosphatemia may cause rickets or
osteomalacia. Hypophosphatemia may be due to production of a phosphaturic factor by the abnormal fibrous tissue.
MAS patients may have café au lait spots, which are flat, hyperpigmented skin lesions that have rough borders (“coast of Maine”) in contrast to the café au lait lesions of neurofibromatosis that have smooth
borders (“coast of California”). The most common endocrinopathy is
isosexual pseudoprecocious puberty in girls. Other less common endocrine disorders include thyrotoxicosis, Cushing’s syndrome, acromegaly, hyperparathyroidism, hyperprolactinemia, and pseudoprecocious
puberty in boys.
Radiographic Findings In long bones, the fibrous dysplastic
lesions are typically well-defined, radiolucent areas with thin cortices and a ground-glass appearance. Lesions may be lobulated with
trabeculated areas of radiolucency (Fig. 412-4). Involvement of facial
bones usually presents as radiodense lesions, which may create a leonine appearance (leontiasis osea). Expansile cranial lesions may narrow
foramens and cause optic lesions, reduce hearing, and create other
manifestations of cranial nerve compression.
Laboratory Results Serum ALP is occasionally elevated, but calcium,
parathyroid hormone, 25-hydroxyvitamin D, and 1,25-dihydroxyvitamin D levels are normal. Patients with extensive polyostotic lesions
may have hypophosphatemia, hyperphosphaturia, and osteomalacia.
The hypophosphatemia and phosphaturia are directly related to the
levels of fibroblast growth factor 23 (FGF23). Biochemical markers of
bone turnover may be elevated.
TREATMENT
Fibrous Dysplasia and MAS
Spontaneous healing of the lesions does not occur, and there is
no established effective treatment. Improvement in bone pain and
partial or complete resolution of radiographic lesions have been
reported after IV bisphosphonate therapy. Denosumab given every
3 months is effective in reducing bone turnover markers and could
be a therapeutic option in difficult cases. Surgical stabilization is
used to prevent pathologic fracture or destruction of a major joint
space and to relieve nerve root or cranial nerve compression or
sinus obstruction.
OTHER DYSPLASIAS OF BONE
AND CARTILAGE
■ PACHYDERMOPERIOSTOSIS
Pachydermoperiostosis, or hypertrophic osteoarthropathy (primary
or idiopathic), is an autosomal dominant disorder characterized by
periosteal new bone formation that involves the distal extremities. The
lesions present as clubbing of the digits and hyperhidrosis and thickening of the skin, primarily of the face and forehead. The changes usually
appear during adolescence, progress over the next decade, and then
become quiescent. During the active phase, progressive enlargement
FIGURE 412-4 Radiograph of a 16-year-old male with fibrous dysplasia of the right
proximal femur. Note the multiple cystic lesions, including the large lucent lesion
in the proximal midshaft with scalloping of the interior surface. The femoral neck
contains two lucent cystic lesions.
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