BackgroundOsteoporosis, a chronic, progressive disease of
multifactorial etiology (see Etiology), is the most common
metabolic bone disease in the United States. It has been most
frequently recognized in elderly white women, although it does
occur in both sexes, all races, and all age groups. Screening
at-risk populations is essential (see Workup). Osteoporosis is a
systemic skeletal disease characterized by low bone mass and
microarchitectural deterioration of bone tissue, with a consequent
increase in bone fragility.[1] The disease often does not become
clinically apparent until a fracture occurs (see the following
image).Osteoporosis. Lateral radiograph demonstrates multiple
osteoporotic vertebral compression fractures. Kyphoplasty has been
performed at one level. Osteoporosis represents an increasingly
serious health and economic problem in the United States and around
the world.[2] Many individuals, male and female, experience pain,
disability, and diminished quality of life as a result of having
this condition. Despite the adverse effects of osteoporosis, it is
a condition that is often overlooked and undertreated, in large
part because it is so often clinically silent before manifesting in
the form of fracture. For example, a Gallup survey performed by the
National Osteoporosis Foundation revealed that 86% of all women
aged 45-75 years had never discussed osteoporosis with their
physicians, and more than 80% were unaware that osteoporosis is
directly responsible for disabling hip fractures.[3] Failure to
identify at-risk patients, to educate them, and to implement
preventive measures may lead to tragic consequences. Medical care
includes calcium, vitamin D, and antiresorptive agents such as
bisphosphonates, the selective estrogen receptor modulator (SERM)
raloxifene, calcitonin, and denosumab. One anabolic agent,
teriparatide (see Medication), is available as well. Surgical care
includes vertebroplasty and kyphoplasty (see Treatment).
Osteoporosis is a preventable disease that can result in
devastating physical, psychosocial, and economic consequences.
Prevention and recognition of the secondary causes of osteoporosis
are first-line measures to lessen the impact of this condition (see
the images below).Osteoporosis of the spine. Observe the
considerable reduction in overall vertebral bone density and note
the lateral wedge fracture of L2. Osteoporosis of the spine. Note
the lateral wedge fracture in L3 and the central burst fracture in
L5. The patient had suffered a recent fall. WHO definition of
osteoporosisBone mineral density (BMD) in a patient is related to
peak bone mass and, subsequently, bone loss. Whereas the T-score is
the patients bone density compared with the BMD of control subjects
who are at their peak BMD, the Z-score reflects a bone density
compared with that of patients matched for age and sex.[4, 5, 6, 7]
The World Health Organizations (WHO) definitions of osteoporosis
based on BMD measurements in white women are summarized in Table 1,
below.[6, 7] For each standard deviation (SD) reduction in BMD, the
relative fracture risk is increased 1.5-3 times. The WHO definition
applies to postmenopausal women and men aged 50 years or older.
Although these definitions are necessary to establish the
prevalence of osteoporosis, they should not be used as the sole
determinant of treatment decisions. This diagnostic classification
should not be applied to premenopausal women, men younger than 50
years, or children. Table 1. WHO Definition of Osteoporosis Based
on BMD Measurements by DXA (Open Table in a new window)Definition
Bone Mass Density Measurement T-Score
NormalBMD within 1 SD of the mean bone density for young adult
womenT-score 1
Low bone mass (osteopenia)BMD 12.5 SD below the mean for
young-adult womenT-score between 1 and 2.5
OsteoporosisBMD 2.5 SD below the normal mean for young-adult
womenT-score 2.5
Severe or established osteoporosisBMD 2.5 SD below the normal
mean for young-adult women in a patient who has already experienced
1 fracturesT-score 2.5 (with fragility fracture[s])
Sources:
(1) World Health Organization (WHO). WHO scientific group on the
assessment of osteoporosis at primary health care level: summary
meeting report. Available at:
http://www.who.int/chp/topics/Osteoporosis.pdf. Accessed February
6, 2012.[8]
(2) Kanis JA. Assessment of fracture risk and its application to
screening for postmenopausal osteoporosis: synopsis of a WHO
report. WHO Study Group. Osteoporos Int. Nov
1994;4(6):368-81.[7]
(3) Czerwinski E, Badurski JE, Marcinowska-Suchowierska E,
Osieleniec J. Current understanding of osteoporosis according to
the position of the World Health Organization (WHO) and
International Osteoporosis Foundation. Ortop Traumatol Rehabil.
Jul-Aug 2007;9(4):337-56.[6]
BMD = bone mass density; DXA = dual x-ray absorptiometry; SD =
standard deviation; T-score = a measurement expressed in SD units
from a given mean that is equal to a patient's BMD measured by DXA
minus the value in a young healthy person, divided by the SD
measurement in the population.[9] .
Z-scores should be used in premenopausal women, men younger than
50 years, and children. Z-scores adjusted for ethnicity or race
should be used, with Z-scores of 2.0 or lower defined as "below the
expected range for age" and with Z-scores above 2.0 being defined
as "within the expected range for age." The diagnosis of
osteoporosis in these groups should not be based on densitometric
criteria alone. For more information, see Pediatric Osteoporosis,
as well as Osteoporosis in Solid Organ Transplantation, Bone
Markers in Osteoporosis, and Nonoperative Treatment of Osteoporotic
Compression Fractures.PathophysiologyIt is increasingly being
recognized that multiple pathogenetic mechanisms interact in the
development of the osteoporotic state. Understanding the
pathogenesis of osteoporosis starts with knowing how bone formation
and remodeling occur. Normal bone formation and remodelingBone is
continually remodeled throughout our lives in response to
microtrauma. Bone remodeling occurs at discrete sites within the
skeleton and proceeds in an orderly fashion, and bone resorption is
always followed by bone formation, a phenomenon referred to as
coupling. Dense cortical bone and spongy trabecular or cancellous
bone differ in their architecture but are similar in molecular
composition. Both types of bone have an extracellular matrix with
mineralized and nonmineralized components. The composition and
architecture of the extracellular matrix is what imparts mechanical
properties to bone. Bone strength is determined by collagenous
proteins (tensile strength) and mineralized osteoid (compressive
strength).[10] The greater the concentration of calcium, the
greater the compressive strength. In adults, approximately 25% of
trabecular bone is resorbed and replaced each year, compared with
only 3% of cortical bone. Osteoclasts, derived from mesenchymal
cells, are responsible for bone resorption, whereas osteoblasts,
from hematopoietic precursors, are responsible for bone formation
(see the images below). The 2 types of cells are dependent on each
other for production and linked in the process of bone remodeling.
Osteoblasts not only secrete and mineralize osteoid but also appear
to control the bone resorption carried out by osteoclasts.
Osteocytes, which are terminally differentiated osteoblasts
embedded in mineralized bone, direct the timing and location of
bone remodeling. In osteoporosis, the coupling mechanism between
osteoclasts and osteoblasts is thought to be unable to keep up with
the constant microtrauma to trabecular bone. Osteoclasts require
weeks to resorb bone, whereas osteoblasts need months to produce
new bone. Therefore, any process that increases the rate of bone
remodeling results in net bone loss over time.[11] This image
depicts bone remodeling with osteoclasts resorbing one side of a
bony trabecula and osteoblasts depositing new bone on the other
side. Osteoclast, with bone below it. This image shows typical
distinguishing characteristics of an osteoclast: a large cell with
multiple nuclei and a "foamy" cytosol. In this image, several
osteoblasts display a prominent Golgi apparatus and are actively
synthesizing osteoid. Two osteocytes can also be seen. Furthermore,
in periods of rapid remodeling (eg, after menopause), bone is at an
increased risk for fracture because the newly produced bone is less
densely mineralized, the resorption sites are temporarily unfilled,
and the isomerization and maturation of collagen are impaired.[12]
The receptor activator of nuclear factor-kappa B ligand
(RANKL)/receptor activator of nuclear factor-kappa B
(RANK)/osteoprotegerin (OPG) system is the final common pathway for
bone resorption. Osteoblasts and activated T cells in the bone
marrow produce the RANKL cytokine. RANKL binds to RANK expressed by
osteoclasts and osteoclast precursors to promote osteoclast
differentiation. Osteoprotegerin is a soluble decoy receptor that
inhibits RANK-RANKL by binding and sequestering RANKL. Bone mass
peaks around the third decade of life and slowly decreases
afterward. A failure to attain optimal bone strength by this point
is one factor that contributes to osteoporosis, which explains why
some young postmenopausal women have low bone mineral density (BMD)
and why some others have osteoporosis. Therefore, nutrition and
physical activity are important during growth and development.
Nevertheless, hereditary factors play the principal role in
determining an individual's peak bone strength. In fact, genetics
account for up to 80% of the variance in peak bone mass between
individuals.[13, 14] Alterations in bone formation and
resorptionThe hallmark of osteoporosis is a reduction in skeletal
mass caused by an imbalance between bone resorption and bone
formation. Under physiologic conditions, bone formation and
resorption are in a fair balance. A change in eitherthat is,
increased bone resorption or decreased bone formationmay result in
osteoporosis. Osteoporosis can be caused both by a failure to build
bone and reach peak bone mass as a young adult and by bone loss
later in life. Accelerated bone loss can be affected by hormonal
status, as occurs in perimenopausal women; can impact elderly men
and women; and can be secondary to various disease states and
medications. Aging and loss of gonadal function are the 2 most
important factors contributing to the development of osteoporosis.
Studies have shown that bone loss in women accelerates rapidly in
the first years after menopause. The lack of gonadal hormones is
thought to up-regulate osteoclast progenitor cells. Estrogen
deficiency leads to increased expression of RANKL by osteoblasts
and decreased release of OPG; increased RANKL results in
recruitment of higher numbers of preosteoclasts as well as
increased activity, vigor, and lifespan of mature osteoclasts.
Estrogen deficiencyEstrogen deficiency not only accelerates bone
loss in postmenopausal women but also plays a role in bone loss in
men. Estrogen deficiency can lead to excessive bone resorption
accompanied by inadequate bone formation. Osteoblasts, osteocytes,
and osteoclasts all express estrogen receptors. In addition,
estrogen affects bones indirectly through cytokines and local
growth factors. The estrogen-replete state may enhance osteoclast
apoptosis via increased production of transforming growth factor
(TGF)beta. In the absence of estrogen, T cells promote osteoclast
recruitment, differentiation, and prolonged survival via IL-1,
IL-6, and tumor necrosis factor (TNF)alpha. A murine study, in
which either the mice's ovaries were removed or sham operations
were performed, found that IL-6 and granulocyte-macrophage CFU
levels were much higher in the ovariectomized mice.[15] This
finding provided evidence that estrogen inhibits IL-6 secretion and
that IL-6 contributes to the recruitment of osteoclasts from the
monocyte cell line, thus contributing to osteoporosis. IL-1 has
also been shown to be involved in the production of osteoclasts.
The production of IL-1 is increased in bone marrow mononuclear
cells from ovariectomized rats. Administering IL-1 receptor
antagonist to these animals prevents the late stages of bone loss
induced by the loss of ovarian function, but it does not prevent
the early stages of bone loss. The increase in the IL-1 in the bone
marrow does not appear to be a triggered event but, rather, a
result of removal of the inhibitory effect of sex steroids on IL-6
and other genes directly regulated by sex steroids. T cells also
inhibit osteoblast differentiation and activity and cause premature
apoptosis of osteoblasts through cytokines such as IL-7. Finally,
estrogen deficiency sensitizes bone to the effects of parathyroid
hormone (PTH). AgingIn contrast to postmenopausal bone loss, which
is associated with excessive osteoclast activity, the bone loss
that accompanies aging is associated with a progressive decline in
the supply of osteoblasts in proportion to the demand. This demand
is ultimately determined by the frequency with which new
multicellular units are created and new cycles of remodeling are
initiated. After the third decade of life, bone resorption exceeds
bone formation and leads to osteopenia and, in severe situations,
osteoporosis. Women lose 30-40% of their cortical bone and 50% of
their trabecular bone over their lifetime, as opposed to men, who
lose 15-20% of their cortical bone and 25-30% of trabecular bone.
Calcium deficiencyCalcium, vitamin D, and PTH help maintain bone
homeostasis. Insufficient dietary calcium or impaired intestinal
absorption of calcium due to aging or disease can lead to secondary
hyperparathyroidism. PTH is secreted in response to low serum
calcium levels. It increases calcium resorption from bone,
decreases renal calcium excretion, and increases renal production
of 1,25-dihydroxyvitamin D (1,25[OH]2 D)an active hormonal form of
vitamin D that optimizes calcium and phosphorus absorption,
inhibits PTH synthesis, and plays a minor role in bone resorption.
Vitamin D deficiencyVitamin D deficiency can result in secondary
hyperparathyroidism via decreased intestinal calcium absorption.
Interestingly, the effects of PTH and 1,25[OH]2 D on bone are
mediated via binding to osteoblasts and stimulating the RANKL/RANK
pathway. Osteoclasts do not have receptors for PTH or 1,25[OH]2
D.[10] Osteoporotic fracturesOsteoporotic fractures represent the
clinical significance of these derangements in bone. They can
result both from low-energy trauma, such as falls from a sitting or
standing position, and from high-energy trauma, such as a
pedestrian struck in a motor vehicle accident. Fragility fractures,
which occur secondary to low-energy trauma, are characteristic of
osteoporosis. Fractures occur when bones fall under excess stress.
Nearly all hip fractures are related to falls.[16] The frequency
and direction of falls can influence the likelihood and severity of
fractures. The risk of falling may be amplified by neuromuscular
impairment due to vitamin D deficiency with secondary
hyperparathyroidism or corticosteroids. Vertebral bodies are
composed primarily of cancellous bone with interconnected
horizontal and vertical trabeculae. Osteoporosis not only reduces
bone mass in vertebrae but also decreases interconnectivity in
their internal scaffolding.[10] Therefore, minor loads can lead to
vertebral compression fractures. An understanding of the
biomechanics of bone provides greater appreciation as to why bone
may be susceptible to an increased risk of fracture. When vertical
loads are placed on bone, such as tibial and femoral metaphyses and
vertebral bodies, a substantial amount of bony strength is derived
from the horizontal trabecular cross-bracing system. This system of
horizontal cross-bracing trabeculae assists in supporting the
vertical elements, thus limiting lateral bowing and fractures that
may occur with vertical loading. Disruption of such trabecular
connections is known to occur preferentially in patients with
osteoporosis, particularly in postmenopausal women, making females
more at risk than males for vertebral compression fractures (see
the images below).Osteoporosis is defined as a loss of bone mass
below the threshold of fracture. This slide (methylmethacrylate
embedded and stained with Masson's trichrome) demonstrates the loss
of connected trabecular bone. The bone loss of osteoporosis can be
severe enough to create separate bone "buttons" with no connection
to the surrounding bone. This easily leads to insufficiency
fractures. Rosen and Tenenhouse studied the unsupported trabeculae
and their susceptibility to fracture within each vertebral body and
found an extraordinarily high prevalence of trabecular fracture
callus sites within vertebral bodies examined at autopsy, typically
200-450 healing or healed fractures per vertebral body.[17] These
horizontal trabecular fractures are asymptomatic, and their
accumulation reflects the impact of lost trabecular bone and
greatly weakens the cancellous structure of the vertebral body. The
reason for preferential osteoclastic severance of horizontal
trabeculae is unknown. Some authors have attributed this phenomenon
to overaggressive osteoclastic resorption. Osteoporosis versus
osteomalaciaOsteoporosis may be confused with osteomalacia. The
normal human skeleton is composed of a mineral component, calcium
hydroxyapatite (60%), and organic material, mainly collagen (40%).
In osteoporosis, the bones are porous and brittle, whereas in
osteomalacia, the bones are soft. This difference in bone
consistency is related to the mineral-to-organic material ratio. In
osteoporosis, the mineral-to-collagen ratio is within the reference
range, whereas in osteomalacia, the proportion of mineral
composition is reduced relative to organic mineral content.
Additional factors and conditionsEndocrinologic conditions or
medications that lead to bone loss (eg, glucocorticoids) can cause
osteoporosis. Corticosteroids inhibit osteoblast function and
enhance osteoblast apoptosis.[18] Polymorphisms of IL-1, IL-6 and
TNF-alpha, as well as their receptors, have been found to influence
bone mass. Other factors implicated in the pathogenesis of
osteoporosis include polymorphisms in the vitamin D receptor;
alterations in insulin-like growth factor-1, bone morphogenic
protein, prostaglandin E2, nitrous oxide, and leukotrienes;
collagen abnormalities; and leptin-related adrenergic
signaling.[11] EpigeneticsPrenatal and postnatal factors contribute
to adult bone mass. In one study, the health of the mother in
pregnancy, the infants birth weight, and the childs weight at age 1
year were predictive of adult bone mass in the seventh decade for
men and women.[19] It is postulated that growth in the first year
of life programs growth hormone that is maintained into the seventh
decade.[20] Larger babies and rapid growth in the first year of
life predicted increased bone mass in adults aged 65-75 years.
EtiologyOsteoporosis has been divided into several classifications
according to etiology and localization in the skeleton.
Osteoporosis is initially divided into localized and generalized
categories, and these 2 main categories are further classified
further into primary and secondary osteoporosis. Postmenopausal
osteoporosis (PMO) is primarily due to estrogen deficiency, senile
osteoporosis is primarily due to an aging skeleton and calcium
deficiency. Primary osteoporosisPatients are said to have primary
osteoporosis when a secondary cause of osteoporosis cannot be
identified, including juvenile and idiopathic osteoporosis.
Idiopathic osteoporosis can be further subdivided into
postmenopausal (type I) and age-associated or senile (type II)
osteoporosis, as described in Table 2, below. Table 2. Types of
Primary Osteoporosis (Open Table in a new window)Type of Primary
OsteoporosisCharacteristics
Juvenile osteoporosis Usually occurs in children or young adults
of both sexes Normal gonadal function Age of onset: usually 8-14
years Hallmark characteristic: abrupt bone pain and/or a fracture
following trauma
Idiopathic osteoporosis
Postmenopausal osteoporosis (type I osteoporosis) Occurs in
women aged 50-65 years Characterized by a phase of accelerated bone
loss, primarily from trabecular bone Fractures of the distal
forearm and vertebral bodies common
Age-associated or senile osteoporosis (type II osteoporosis)
Occurs in women and men older than 70 years Represents bone loss
associated with aging Fractures occur in cortical and trabecular
bone Wrist, vertebral, and hip fractures often seen in patients
with type II osteoporosis
Secondary osteoporosisSecondary osteoporosis occurs when an
underlying disease, deficiency, or drug causes osteoporosis (see
Table 3, below). Up to one third of postmenopausal women, as well
as many men and premenopausal women, have a coexisting cause of
bone loss,[21, 22] of which renal hypercalciuria is one of the most
important secondary causes of osteoporosis and treatable with
thiazide diuretics.[23] Table 3. Causes of Secondary Osteoporosis
in Adults (Open Table in a new window)Cause Examples
Genetic/congenital Renal hypercalciuria one of the most
important secondary causes of osteoporosis; can be treated with
thiazide diuretics Cystic fibrosis Ehlers-Danlos syndrome Glycogen
storage disease Gaucher disease Marfan syndrome Menkes steely hair
syndrome Riley-Day syndrome Osteogenesis imperfecta Hemochromatosis
Homocystinuria Hypophosphatasia Idiopathic hypercalciuria Porphyria
Hypogonadal states
Hypogonadal states Androgen insensitivity Anorexia
nervosa/bulimia nervosa Female athlete triad Hyperprolactinemia
Panhypopituitarism Premature menopause Turner syndrome Klinefelter
syndrome
Endocrine disorders[24] Cushing syndrome Diabetes mellitus
Acromegaly Adrenal insufficiency Estrogen deficiency
Hyperparathyroidism Hyperthyroidism Hypogonadism Pregnancy
Prolactinoma
Deficiency states Calcium deficiency Magnesium deficiency
Protein deficiency Vitamin D deficiency[24, 25] Bariatric surgery
Celiac disease Gastrectomy Malabsorption Malnutrition Parenteral
nutrition Primary biliary cirrhosis
Inflammatory diseases Inflammatory bowel disease Ankylosing
spondylitis Rheumatoid arthritis Systemic lupus erythematosus
Hematologic and neoplastic disorders Hemochromatosis Hemophilia
Leukemia Lymphoma Multiple myeloma Sickle cell anemia Systemic
mastocytosis Thalassemia Metastatic disease
Medications Anticonvulsants: phenytoin, barbiturates,
carbamazepine (these agents are associated with treatment-induced
vitamin D deficiency) Antipsychotic drugs Antiretroviral drugs
Aromatase inhibitors: exemestane, anastrozole
Chemotherapeutic/transplant drugs: cyclosporine, tacrolimus,
platinum compounds, cyclophosphamide, ifosfamide, high-dose
methotrexate[26] Furosemide Glucocorticoids and corticotropin[27] :
prednisone (5 mg/day for 3 mo)[28] Heparin (long term)
Hormonal/endocrine therapies: gonadotropin-releasing hormone (GnRH)
agonists, luteinizing hormone-releasing hormone (LHRH) analogues,
depomedroxyprogesterone, excessive thyroxine Lithium Selective
serotonin reuptake inhibitors (SSRIs)
Miscellaneous Alcoholism Amyloidosis Chronic metabolic acidosis
Congestive heart failure Depression Emphysema Chronic or end-stage
renal disease Chronic liver disease HIV/AIDS Idiopathic scoliosis
Immobility Multiple sclerosis Ochronosis Organ transplantation
Pregnancy/lactation Sarcoidosis Weightlessness
Sources:
(1) American Association of Clinical Endocrinologists medical
guidelines for clinical practice for the prevention and treatment
of postmenopausal osteoporosis: 2001 edition, with selected updates
for 2003. Endocr Pract. Nov-Dec 2003;9(6):544-64.[21]
(2) Kelman A, Lane NE. The management of secondary osteoporosis.
Best Pract Res Clin Rheumatol. Dec 2005;19(6):1021-37.[22]
Risk factorsRisk factors for osteoporosis, such as advanced age
and reduced bone mineral density (BMD), have been established by
virtue of their direct and strong relationship to the incidence of
fractures; however, many other factors have been considered risk
factors based on their relationship to BMD as a surrogate indicator
of osteoporosis. Risk factors for osteoporosis include the
following[29, 30, 31] : Advanced age (50 years) Female sex White or
Asian ethnicity Genetic factors, such as a family history of
osteoporosis Thin build or small stature (eg, body weight less than
127 lb) Amenorrhea Late menarche Early menopause Postmenopausal
state Physical inactivity or immobilization[32] Use of drugs:
anticonvulsants, systemic steroids, thyroid supplements, heparin,
chemotherapeutic agents, insulin Alcohol and tobacco use
Androgen[33] or estrogen deficiency Calcium deficiency Dowager
humpA potentially useful mnemonic for osteoporotic risk factors is
OSTEOPOROSIS, as follows: L O w calcium intake S eizure meds
(anticonvulsants) T hin build E thanol intake Hyp O gonadism P
revious fracture Thyr O id excess R ace (white, Asian) O ther
relatives with osteoporosis S teroids I nactivity S moking A study
by Cummings et al evaluated 9516 white women aged 65 years for an
average of 4.1 years and found an indirect relationship between the
number of risk factors and bone density values.[34] The study also
identified factors that did not increase the risk of fracture,
including hair color, number of children breastfed, prior smoking
history, or use of short-acting benzodiazepines. An interesting
finding of this study was that dietary intake of calcium was not
correlated with the risk of hip fracture; however, the authors of
the study did agree with other experts that dietary calcium would
only help if the patient was calcium deficient.
EpidemiologyAccording to the National Osteoporosis Foundation
(NOF), 10 million Americans have osteoporosis. Another 34 million
have low bone mass, which leaves them at increased risk for
osteoporosis.[35] In the United States, 1.5 million osteoporotic
fractures occur each year. Of these, 700,000 are spinal fractures;
300,000 are hip fractures; and 200,000 are wrist fractures. Most
studies assessing the prevalence and incidence of osteoporosis use
the rate of fracture as a marker for the presence of this disorder,
although BMD also relates to risk of disease and fracture. The risk
of new vertebral fractures increases by a factor of 2-2.4 for each
standard deviation (SD) decrease of BMD measurement. Women and men
with metabolic disorders associated with secondary osteoporosis
have a 2- to 3-fold higher risk of hip and vertebral fractures.
Globally, osteoporosis is by far the most common metabolic bone
disease, and it is estimated to affect over 200 million people
worldwide.[36] An estimated 75 million people in Europe, the United
States, and Japan have osteoporosis.[37] Approximately 1 in 2 women
and 1 in 5 men older than 50 years will eventually experience
osteoporotic fractures.[35] By 2050, the worldwide incidence of hip
fracture is projected to increase by 240% in women and 310% in
men.[38] Age demographicsRisk for osteoporosis increases with age
as BMD declines. Senile osteoporosis is most common in persons aged
70 years or older. Secondary osteoporosis, however, can occur in
persons of any age. Although bone loss in women begins slowly, it
speeds up around the time of menopause, typically at about or after
age 50 years. The frequency of postmenopausal osteoporosis is
highest in women aged 50-70 years. The number of osteoporotic
fractures increases with age. Wrist fractures typically occur
first, when individuals are aged approximately 50-59 years.
Vertebral fractures occur more often in the seventh decade of life.
Jensen et al studied Danish women aged 70 years and found a 21%
prevalence of vertebral fractures.[39] Melton et al reported that
27% of women in their study had evidence of vertebral fractures by
age 65 years.[40] Ninety percent of hip fractures occur in persons
aged 50 years or older, occurring most often in the eighth decade
of life.[41] Sex demographicsWomen are at a significantly higher
risk for osteoporosis. According to the NOF, of the estimated 10
million Americans who have osteoporosis, 80% are women.[35] Men
have a higher prevalence of secondary osteoporosis, with an
estimated 45-60% of cases being a consequence of hypogonadism,
alcoholism, or glucocorticoid excess.[27] Only 35-40% of
osteoporosis diagnosed in men is considered primary in nature.
Overall, osteoporosis has a female-to-male ratio of 4:1.[42] Fifty
percent of all women and 25% of all men older than 50 years
experience one or more osteoporosis-related fracture in their
lifetime. Eighty percent of hip fractures occur in women.[41] Women
have a 2-fold increase in the number of fractures resulting from
nontraumatic causes, as compared with men of the same age. Racial
demographicsOsteoporosis can occur in persons of all races and
ethnicities. In general, however, whites (especially of northern
European descent) and Asians are at increased risk. In particular,
non-Hispanic white women and Asian women are at higher risk for
osteoporosis. In the most recent government census, 178 million
Chinese were over age 60 years in 2009, a number that the United
Nations estimates may reach 437 millionone-third of the
populationby 2050.[43] These numbers suggest that approximately 50%
of all hip fractures will occur in Asia in the next century. Table
4, below, summarizes some osteoporosis prevalence statistics among
racial/ethnic groups. Note that this disease is underrecognized and
undertreated in white and black women.[42] Relative to other
racial/ethnic groups, the risk of developing osteoporosis is
increasing fastest among Hispanic women.[42] Table 4. Prevalence of
Osteoporosis Among Racial and Ethnic Groups (Open Table in a new
window)Race/Ethnicity Sex (age 50 y) % Estimated to have
osteoporosis % Estimated to have low bone mass
Non-Hispanic white; AsianWomen2052
Men735
Non-Hispanic blackWomen5*
Men419
HispanicWomen1049
Men323
Source: National Osteoporosis Foundation. Fast facts. Available
at: http://www.nof.org/node/40. Accessed: February 16,
2012.[42]
* Low bone density is present in an additional 35% of black
women, increasing their risk of developing osteoporosis.
Melton et al reported that the prevalence of hip fractures is
higher in white populations, regardless of geographic location.[44]
Another study indicated that, in the United States and South
Africa, the incidence of hip fractures was lower in black persons
than in age-matched white persons. Cauley et al found that the
absolute fracture incidence across bone mineral density (BMD)
distribution was 30-40% lower in black women than in white women.
This lower fracture risk was independent of BMD and other risk
factors.[45] PrognosisThe prognosis for osteoporosis is good if
bone loss is detected in the early phases and proper intervention
is undertaken. Patients can increase BMD and decrease fracture risk
with the appropriate anti-osteoporotic medication. In addition,
patients can decrease their risk of falls by participating in a
multifaceted approach that includes rehabilitation and
environmental modifications. Worsening of medical status can be
prevented by providing appropriate pain management and, if
indicated, orthotic devices. Effect of fractures on prognosisMany
individuals experience morbidity associated with the pain,
disability, and diminished quality of life caused by
osteoporosis-related fractures. According to a 2004 Surgeon
General's report, osteoporosis and other bone diseases are
responsible for about 1.5 million fractures per year.
Osteoporosis-related fractures result in annual direct care
expenditures of $12.2 billion to $17.9 billion.[46] In 2005, over 2
million osteoporosis-related fractures occurred in the United
States.[47] Osteoporosis is the leading cause of fractures in the
elderly. Women aged 50 years have about a 50% lifetime fracture
rate as a result of osteoporosis. Osteoporosis is associated with
80% of all the fractures in people aged 50 years or older. If full
recovery is not achieved, osteoporotic fractures may lead to
chronic pain, disability, and, in some cases, death. This is
particularly true of vertebral and hip fractures. Vertebral
fracturesVertebral compression fractures (see the images below) are
associated with increased morbidity and mortality rates. In
addition, the impact of vertebral fractures increases as they
increase in number. As posture worsens and kyphosis progresses,
patients experience difficulty with balance, back pain, respiratory
compromise, and an increased risk of pneumonia. Overall function
declines, and patients may lose their ability to live
independently.Osteoporosis. Lateral radiograph demonstrates
multiple osteoporotic vertebral compression fractures. Kyphoplasty
has been performed at one level. Osteoporosis. Lateral radiograph
of the patient seen in the previous image following kyphoplasty
performed at 3 additional levels. In one study, Cooper et al found
that vertebral fractures increased the 5-year risk of mortality by
15%.[48] In a subsequent study, Kado et al[49] demonstrated that
women with one or more fractures had a 1.23-fold increased
age-adjusted mortality rate and that women with 5 or more vertebral
fractures had a 2.3-fold increased age-adjusted mortality rate.
Furthermore, mortality rate was correlated with number of vertebral
fractures, with 19 per 1000 woman-years in women with no fracture,
versus 44 per 1000 woman-years in women with 5 or more fractures.
Vertebral fractures were related to risk of subsequent cancer and
pulmonary death, and severe kyphosis was further correlated with
pulmonary deaths. Only one third of people with radiographic
vertebral fractures are diagnosed clinically.[50] Symptoms of
vertebral fracture may include back pain, height loss, and
disabling kyphosis. Compression deformities can lead to restrictive
lung disease, abdominal pain, and early satiety. Hip fracturesMore
than 250,000 hip fractures are attributed to osteoporosis each
year.[34] Like vertebral fractures, they are associated with
significantly increased morbidity and mortality rates in men and
women. In the year following hip fracture, excess mortality rates
can be as high as 20%.[48, 51] Men have higher mortality rates
following hip fracture than do women. Patients with hip fractures
incur decreased independence and a diminished quality of life. Of
all patients with hip fracture, approximately 20% require long-term
nursing care.[35] Among women who sustain a hip fracture, 50% spend
time in a nursing home while recovering. Approximately 50% of
previously independent individuals become partially dependent, and
one third become completely dependent.[52] Only one third of
patients return to their prefracture level of function.[53]
Secondary complications of hip fractures include nosocomial
infections and pulmonary thromboembolism.Additional
fracturesPatients who have sustained one osteoporotic fracture are
at increased risk for developing additional osteoporotic
fractures.[37] For example, the presence of at least one vertebral
fracture results in a 5-fold increased risk of developing another
vertebral fracture. One in 5 postmenopausal women with a new
vertebral fracture incurs another vertebral fracture within one
year.[54] Patients with previous hip fracture have a 2-fold[55] to
10-fold increased risk of sustaining a second hip fracture. In
addition, patients with ankle, knee, olecranon, and lumbar spine
fractures have a 1.5-, 3.5-, 4.1-, and 4.8-fold increased risk of
subsequent hip fracture, respectively. WHO fracture-risk
algorithmThe World Health Organization fracture-risk algorithm
(FRAX) was developed to calculate the 10-year probability of a hip
fracture and the 10-year probability of any major osteoporotic
fracture (defined as clinical spine, hip, forearm, or humerus
fracture) in a given patient. These calculations account for
femoral neck bone mineral density (BMD) and other clinical risk
factors, as follows[56] : Age Sex Personal history of fracture Low
body mass index Use of oral glucocorticoid therapy Secondary
osteoporosis (ie, coexistence of rheumatoid arthritis) Parental
history of hip fracture Current smoking status Alcohol intake (3 or
more drinks per day)The National Osteoporosis Foundation (NOF)
recommends osteoporosis treatment in patients with low bone mass in
whom a US-adapted WHO 10-year probability of a hip fracture is 3%
or more or in whom the risk for a major osteoporosis-related
fracture is 20% or more.[35] Note that osteoporosis is, by
definition, present in those with a fragility fracture,
irrespective of their T-score. Algorithms such as the FRAX
algorithm are useful in identifying patients with low bone mass
(T-scores in the osteopenic range) who are most likely to benefit
from treatment. A study by Leslie et al demonstrated the effects of
including a patient's 10-year fracture risk along with DXA results
in Manitoba, Canada.[57] The authors found an overall reduction in
dispensation of osteoporosis medications as more women were
reclassified into lower fracture risk categories. One study sought
to determine if the femoral neck BMD score and FRAX score are
associated with hip and nonspine fracture risk in older adults with
type 2 diabetes mellitus (DM). Using data from 3 prospective
observational studies, statistics from self-reported incidence of
fractures in 9449 women and 7436 men in the United States were
analyzed. The results found that participants with type 2 DM had a
higher fracture risk and T-score than those without type 2 DM,
concluding that the femoral neck BMD T-score and FRAX score were
associated with higher hip and nonvertebral fracture risk in older
adult patients with type 2 DM.[58] ComplicationsVertebral
compression fractures often occur with minimal stress, such as
coughing, lifting, or bending. The vertebrae of the middle and
lower thoracic spine and upper lumbar spine are involved most
frequently. In many patients, vertebral fracture can occur slowly
and without symptoms. Hip fractures are the most devastating and
occur most commonly at the femoral neck and intertrochanteric
regions (see the image below). Hip fractures are associated with
falls. The likelihood of sustaining a hip fracture during a fall is
related to the direction of the fall. Fractures are more likely to
occur in falls to the side; less subcutaneous tissue is available
to dissipate the impact. Secondary complications of hip fractures
include nosocomial infections and pulmonary thromboembolism.Stable
intertrochanteric fracture of the femur. Fractures can cause
further complications, including chronic pain from vertebral
compression fractures and increased morbidity and mortality
secondary to vertebral compression fractures and hip fractures.
Patients with multiple fractures have significant pain, which leads
to functional decline and a poor quality of life (QOL).[59] They
are also at risk for the complications associated with immobility,
including deep vein thrombosis (DVT) and pressure ulcers.
Respiratory compromise can occur in patients with multiple
vertebral fractures that result in severe kyphosis. Patients with
osteoporosis develop spinal deformities and a dowager's hump, and
they may lose 1-2 inches of height by their seventh decade of life.
These patients can lose their self-esteem and are at increased risk
for depression. Patient EducationPatient education is paramount in
the treatment of osteoporosis. Many patients are unaware of the
serious consequences of osteoporosis, including increased morbidity
and mortality, and only become concerned when osteoporosis
manifests in the form of fracture; accordingly, it is important to
educate them regarding these consequences. Early prevention and
treatment are essential in the appropriate management of
osteoporosis. The focus of patient education is on the prevention
of osteoporosis. Prevention has 2 components, behavior modification
and pharmacologic interventions. Appropriate preventive measures
may include adequate calcium and vitamin D intake, exercise,
cessation of smoking, and moderation of alcohol consumption.
Patients should be educated about the risk factors for
osteoporosis, with a special emphasis on family history and the
effects of menopause. Patients also need to be educated about the
benefits of calcium and vitamin D supplements, as well as
strategies to prevent falls in the elderly (see Primary
CareRelevant Interventions to Prevent Falling in Older Adults: A
Systematic Evidence Review for the US Preventive Services Task
Force [USPSTF]). All postmenopausal women older than 65 years
should be offered bone densitometry, as well as some younger women
and men. These patients should understand the benefits of bone
density monitoring. Society at large also should be educated about
the benefits of exercise with regard to osteoporosis. For patient
education information, see the Osteoporosis Center, Digestive
Disorders Center, and Women's Health Center, as well as
Osteoporosis, Anorexia Nervosa, Inflammatory Bowel Disease, and
Menopause.
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