3157Bone and Mineral Metabolism in Health and Disease CHAPTER 409
of type 2 diabetes. Metformin also reduces the incidence of diabetes, although the effect is less pronounced than that of lifestyle
intervention.
INSULIN RESISTANCE (SEE ALSO CHAP. 404)
Several drug classes (biguanides, thiazolidinediones [TZDs])
increase insulin sensitivity. Because insulin resistance is the primary pathophysiologic mechanism for the metabolic syndrome,
representative drugs in these classes reduce its prevalence. Both
metformin and TZDs enhance insulin action in the liver and
suppress endogenous glucose production. TZDs, but not metformin, also improve insulin-mediated glucose uptake in muscle and
adipose tissue. In a meta-analysis of nine trials involving 12,026
participants, the TZD pioglitazone versus placebo was associated
with reduction in ASCVD events in patients with insulin resistance
(metabolic syndrome), prediabetes and type 2 diabetes. However,
adverse effects including weight gain, bone fracture, and congestive
heart failure with/or without edema were seen. Benefit of TZDs has
been seen in patients with NAFLD, and with metformin in women
with polycystic ovary syndrome, and both drug classes have been
shown to reduce markers of inflammation.
■ FURTHER READING
Alberti KG et al: Harmonizing the metabolic syndrome: A joint
interim statement of the International Diabetes Federation Task
Force on Epidemiology and Prevention; National Heart, Lung, and
Blood Institute; American Heart Association; World Heart Federation; International Atherosclerosis Society; and International Association for the Study of Obesity. Circulation 120:1640, 2009.
Brown AE, Walker M: Genetics of insulin resistance and the metabolic syndrome. Curr Cardiol Rep 18:75, 2016.
Eckel RH et al: The metabolic syndrome. Lancet 365:1415, 2005.
Genser L et al: Obesity, type 2 diabetes, and the metabolic syndrome:
Pathophysiologic relationships and guidelines for surgical intervention. Surg Clin North Am 96:681, 2016.
Lechner K et al: High-risk atherosclerosis and metabolic phenotype:
The roles of ectopic adiposity, atherogenic dyslipidemia, and inflammation. Metab Syndr Relat Disord 18:176, 2020.
Lim S, Eckel RH: Pharmacological treatment and therapeutic perspective of metabolic syndrome. Rev Endocr Metab Disord 15:329, 2014.
Neeland IJ et al: Visceral and ectopic fat, atherosclerosis, and cardiometabolic disease: A position statement. Lancet Diabetes Endocrinol 7:715, 2019.
Section 4 Disorders of Bone and Mineral
Metabolism
409 Bone and Mineral
Metabolism in Health
and Disease
F. Richard Bringhurst, Henry M.
Kronenberg, Eva S. Liu
BONE STRUCTURE AND METABOLISM
Bone is a dynamic tissue that is remodeled constantly throughout life.
The arrangement of compact and cancellous bone provides strength
and density suitable for both mobility and protection. Compact or
cortical bone forms the roughly cylindrical shell of long bones; cancellous or trabecular bone forms the plate-like meshwork that internally
supports the cortical shell. In addition, bone provides a reservoir for
calcium, magnesium, phosphorus, sodium, and other ions necessary
for homeostatic functions. Bone also hosts and regulates hematopoiesis
by providing niches for hematopoietic cell proliferation and differentiation. The skeleton is highly vascular and receives ~10% of the cardiac
output. Remodeling of bone is accomplished by two distinct cell types:
osteoblasts produce bone matrix, and osteoclasts resorb the matrix.
The activities of these cells are coordinated by osteocytes, long-lived
regulatory cells embedded within bone matrix.
The extracellular components of bone consist of a solid mineral
phase in close association with an organic matrix, of which 90–95% is
type I collagen (Chap. 413). The noncollagenous portion of the organic
matrix is heterogeneous and contains serum proteins such as albumin as well as many locally produced proteins, whose functions are
incompletely understood. Those proteins include cell attachment/signaling proteins such as thrombospondin, osteopontin, and fibronectin;
calcium-binding proteins such as matrix gla protein and osteocalcin;
and proteoglycans such as biglycan and decorin. Some of the proteins
organize collagen fibrils; others influence mineralization and binding
of the mineral phase to the matrix.
The mineral phase is made up of calcium and phosphate and is best
characterized as a poorly crystalline hydroxyapatite. The mineral phase
of bone is deposited initially in intimate relation to the collagen fibrils
and is found in specific locations in the “holes” between the collagen
fibrils. This architectural arrangement of mineral and matrix results
in a two-phase material well suited to withstand mechanical stresses.
The organization of collagen influences the amount and type of mineral phase formed in bone. Although the primary structures of type I
collagen in skin and bone tissues are similar, there are differences in
posttranslational modifications and distribution of intermolecular
cross-links. The holes in the packing structure of the collagen are larger
in mineralized collagen of bone and dentin than in unmineralized
collagens such as those in tendon. Single amino acid substitutions in
the helical portion of either the α1 (COL1A1) or α2 (COL1A2) chains
of type I collagen disrupt the organization of bone in the disease, osteogenesis imperfecta. The severe skeletal fragility associated with this
group of disorders highlights the importance of the fibrillar matrix in
the structure of bone (Chap. 413).
Osteoblasts synthesize and secrete the organic matrix and regulate its mineralization. They are derived from cells of mesenchymal
origin (Fig. 409-1A). Active osteoblasts are found on the surface of
newly forming bone. As an osteoblast secretes matrix, which then is
mineralized, the cell may become an osteocyte, still connected with
its nutrient supply through a series of canaliculi. Osteocytes account
for the vast majority of the cells in bone. They are thought to be
the mechanosensors in bone that communicate signals to surface
osteoblasts and osteoclasts and their progenitors through the canalicular network and thereby serve as master regulators of bone formation
and resorption. Remarkably, osteocytes also secrete fibroblast growth
factor 23 (FGF23), a major hormonal regulator of phosphate metabolism (see below). Mineralization of the matrix, both in trabecular
bone and in osteones of compact cortical bone (Haversian systems),
begins soon after the matrix is secreted (primary mineralization) but
is not completed for several weeks or even longer (secondary mineralization). Although this mineralization takes advantage of the high
concentrations of calcium and phosphate, already near saturation in
serum, mineralization is a carefully regulated process that is dependent on the activity of osteoblast-derived alkaline phosphatase, which
probably works by hydrolyzing inhibitors of mineralization, such as
pyrophosphate.
Genetic studies in humans and mice have identified several key
genes that control osteoblast development. Runx2 is a transcription
factor expressed specifically in chondrocyte (cartilage cells) and
osteoblast progenitors as well as in hypertrophic chondrocytes and
mature osteoblasts. Runx2 regulates the expression of several important osteoblast proteins, including osterix (another transcription factor
needed for osteoblast maturation), osteopontin, bone sialoprotein,
type I collagen, osteocalcin, and receptor-activator of nuclear factor
(NF)-κB (RANK) ligand. Runx2 expression is regulated in part by bone
morphogenic proteins (BMPs). Runx2-deficient mice are devoid of
3158 PART 12 Endocrinology and Metabolism
osteoblasts, whereas mice with a deletion of only one allele (Runx2 +/–)
exhibit a delay in formation of the clavicles and some cranial bones.
The latter abnormalities are similar to those in the human disorder cleidocranial dysplasia, which is also caused by heterozygous inactivating
mutations in Runx2.
The paracrine signaling molecule, Indian hedgehog (Ihh), also plays
a critical role in osteoblast development, as evidenced by Ihh-deficient
mice that lack osteoblasts in the type of bone formed on a cartilage
mold (endochondral ossification). Signals originating from members
of the wnt (an amalgam of “wingless,” the Drosophila developmental
gene and “int-1,” an analogous mammalian gene activated by integration of a mouse tumor viral genome nearby) family of paracrine factors
are also important for osteoblast proliferation and differentiation.
Osteocytes regulate osteoblasts partly by secreting a potent inhibitor
of wnt signaling called sclerostin. Numerous other growth-regulatory
factors affect osteoblast function, including the three closely related
transforming growth factor βs, fibroblast growth factors (FGFs) 2
and 18, platelet-derived growth factor, and insulin-like growth factors
(IGFs) I and II. Hormones such as parathyroid hormone (PTH) and
1,25-dihydroxyvitamin D [1,25(OH)2
D] activate receptors expressed
by osteoblasts to assure mineral homeostasis and influence a variety
of bone cell functions. Osteoclasts that resorb bone (see below) also
regulate osteoblasts by releasing growth factors from bone matrix and
by synthesizing proteins that can directly regulate osteoblastogenesis.
Resorption of bone is carried out mainly by osteoclasts, multinucleated cells that are formed by fusion of cells derived from the common
precursor of macrophages and osteoclasts. Thus, these cells derive
from the hematopoietic lineage, quite different from the mesenchymal
lineage cells that become osteoblasts. Multiple factors that regulate
osteoclast development have been identified (Fig. 409-1B). Factors
produced by osteocytes, osteoblasts, and marrow stromal cells allow
cells of the osteoblast lineage to control osteoclast development and
Mesenchymal
osteoblast
progenitor
Osteoblast
precursor
Collagen (I)
Alkaline phosphatase
Osteocalcin, osteopontin
Bone sialoprotein
c-src+
β3 integrin+
PYK2 kinase+
Cathepsin K+
TRAF+
Carbonic anhydrase II+
Runx 2
Hematopoietic
osteoclast
progenitor
M-CSF
BMPs PTH, Vit D, IGFs,
BMPs, Wnts
Osteoclast
precursor
Active
osteoblast
Mononuclear
osteoclast
Quiescent
osteoclast
Active
osteoclast
PU-1+ c-fos+
NKκB+
TRAF+
Commitment
RANK Ligand
Differentiation
M-CSF
RANK Ligand
IL-1, IL-6
Fusion
RANK Ligand
IL-1
A
B
FIGURE 409-1 Pathways regulating development of (A) osteoblasts and (B) osteoclasts. Hormones, cytokines, and growth factors that control cell proliferation and
differentiation are shown above the arrows. Transcription factors and other markers specific for various stages of development are depicted below the arrows. BMPs, bone
morphogenic proteins; IGFs, insulin-like growth factors; IL-1, interleukin 1; IL-6, interleukin 6; M-CSF, macrophage colony-stimulating factor; NFκB, nuclear factor-κB; PTH,
parathyroid hormone; PU-1, a monocyte- and B lymphocyte–specific ets family transcription factor; RANK ligand, receptor activator of NFκB ligand; Runx2, Runt-related
transcription factor 2; TRAF, tumor necrosis factor receptor–associated factor; Vit D, vitamin D; wnts, wingless-type mouse mammary tumor virus integration site. (Modified
with permission from T Suda et al: Modulation of osteoclast differentiation and function by the new members of the tumor necrosis factor receptor and ligand families.
Endocr Rev 20:345, 1999.)
activity. Macrophage colony-stimulating factor (M-CSF) plays a critical
role during several steps in the pathway and ultimately leads to fusion
of osteoclast progenitor cells to form multinucleated, active osteoclasts.
RANK ligand, a member of the tumor necrosis factor (TNF) family,
is expressed on the surface of osteocytes, osteoblasts, and stromal
fibroblasts. In a process involving cell-cell interactions, RANK ligand
binds to the RANK receptor on osteoclast progenitors, stimulating
osteoclast differentiation and activation. Alternatively, a soluble decoy
receptor, referred to as osteoprotegerin, can bind RANK ligand and
inhibit osteoclast differentiation. Several growth factors and cytokines
(including interleukins 1, 6, and 11; TNF; and interferon γ) modulate
osteoclast differentiation and function. Most hormones that influence
osteoclast function do not target these cells directly but instead target
cells of the osteoblast lineage to increase production of M-CSF and
RANK. Both PTH and 1,25(OH)2
D increase osteoclast number and
activity by this indirect mechanism. Calcitonin, in contrast, binds to its
receptor on the basal surface of osteoclasts and directly inhibits osteoclast function. Estradiol has multiple cellular targets in bone, including
osteoclasts, immune cells, and osteoblasts; actions on all these cells
serve to decrease osteoclast number and decreased bone resorption.
Osteoclast-mediated resorption of bone takes place in scalloped
spaces (Howship’s lacunae) where the osteoclasts are attached through
a specific αvβ3 integrin to components of the bone matrix such as
osteopontin. The osteoclast forms a tight seal to the underlying matrix
and secretes protons, chloride, and proteinases into a confined space
that has been likened to an extracellular lysosome. The active osteoclast
surface forms a ruffled border that contains a specialized proton pump
ATPase that secretes acid that solubilizes the mineral phase. Carbonic
anhydrase (type II isoenzyme) within the osteoclast generates the
needed protons. The bone matrix is resorbed in the acid environment
adjacent to the ruffled border by proteases, such as cathepsin K, that
act at low pH.
3159Bone and Mineral Metabolism in Health and Disease CHAPTER 409
In the embryo and the growing child, bone develops mostly by
replacing previously calcified cartilage (endochondral bone formation)
with subsequent remodeling or, in a few bones, is formed without a
cartilage matrix (intramembranous bone formation). During endochondral bone formation, chondrocytes proliferate, secrete and mineralize a matrix, enlarge (hypertrophy), and then die, enlarging bone
and providing the matrix and factors that stimulate endochondral
bone formation. This program is regulated by both local factors such
as IGF-I and -II, Ihh, parathyroid hormone–related peptide (PTHrP),
BMPs, and FGFs and by systemic hormones such as growth hormone,
glucocorticoids, and estrogen. Some hypertrophic chondrocytes do
not die but, instead, through still poorly understood steps, can become
osteoblasts and bone stromal cells.
New bone, whether formed in infants or in adults during repair,
has a relatively high ratio of cells to matrix and is characterized by
coarse fiber bundles of collagen that are interlaced and randomly
dispersed (woven bone). In adults, the more mature bone is organized with fiber bundles regularly arranged in parallel or concentric
sheets (lamellar bone). In long bones, deposition of lamellar bone in
a concentric arrangement around blood vessels forms the Haversian
systems. Growth in length of bones is dependent on proliferation of
cartilage cells and the endochondral sequence at the growth plate.
Growth in width and thickness is accomplished by formation of bone
at the periosteal surface and by resorption at the endosteal surface,
with the rate of formation exceeding that of resorption. In adults, after
the growth plates of cartilage close through the actions of estrogen,
growth in length and endochondral bone formation cease. Even in
adults, however, remodeling of bone (within Haversian systems as
well as along the surfaces of trabecular bone) continues throughout
life. In adults, ~4% of the surface of trabecular bone (such as iliac
crest) is involved in active resorption, whereas 10–15% of trabecular
surfaces are covered with osteoid, unmineralized new bone formed by
osteoblasts. Radioisotope studies indicate that as much as 18% of the
total skeletal calcium is deposited and removed each year. Thus, bone
is an active metabolizing tissue that requires an intact blood supply.
The cycle of bone resorption and formation is a highly orchestrated
process, directed by osteocytes and carried out by the basic multicellular unit, which is composed of a group of osteoclasts and osteoblasts
(Fig. 409-2).
The response of bone to fractures, infection, and interruption of
blood supply and to expanding lesions is relatively limited. Dead bone
must be resorbed, and new bone must be formed, a process carried
out in association with growth of new blood vessels into the involved
area. In injuries that disrupt the organization of the tissue, such as a
fracture, in which apposition of fragments is poor or when motion
exists at the fracture site, progenitor stromal cells recapitulate the
endochondral bone formation of early development and form cartilage
that is replaced by bone and, variably, fibrous tissue. When there is
good apposition with fixation and little motion at the fracture site,
repair occurs predominantly by formation of new bone without other
mediating tissue.
Remodeling of bone occurs along lines of force generated by
mechanical stress. The signals from these mechanical stresses are
sensed by osteocytes, which transmit signals to osteoclasts and
osteoblasts or their precursors. One such signal made by osteocytes is
sclerostin, an inhibitor of wnt signaling. Mechanical forces suppress
sclerostin production and thus increase bone formation by osteoblasts.
Expanding lesions in bone such as tumors induce resorption at the
surface in contact with the tumor by producing ligands such as PTHrP
that stimulate osteoclast differentiation and function. Thus, bone
plasticity reflects the interaction of cells with each other and with the
environment.
Measurement of the products of osteoblast and osteoclast activity can assist in the diagnosis and management of bone diseases.
Osteoblast activity can be assessed by measuring serum bone-specific
alkaline phosphatase. Similarly, osteocalcin, a protein secreted from
osteoblasts, is made virtually only by osteoblasts. Measurement of an
amino-terminal fragment of procollagen I is also an effective index of
bone formation. Osteoclast activity can be assessed by measurement of
products of collagen degradation. Collagen molecules are covalently
linked to each other in the extracellular matrix through the formation
of hydroxypyridinium cross-links (Chap. 413). After digestion by
osteoclasts, these cross-linked peptides can be measured both in urine
and in blood.
CALCIUM METABOLISM
Over 99% of the 1–2 kg of calcium present normally in the adult
human body resides in the skeleton, where it provides mechanical stability and serves as a reservoir sometimes needed to maintain extracellular fluid (ECF) calcium concentration (Fig. 409-3). Skeletal calcium
accretion first becomes significant during the third trimester of fetal
life, accelerates throughout childhood and adolescence, reaches a peak
in early adulthood, and gradually declines thereafter at rates that rarely
exceed 1–2% per year. These slow changes in total skeletal calcium content contrast with relatively high daily rates of closely matched fluxes of
calcium into and out of bone (~250–500 mg each), a process mediated
by coupled osteoblastic and osteoclastic activity. Another 0.5–1% of
skeletal calcium is freely exchangeable (e.g., in chemical equilibrium)
with that in the ECF.
The concentration of ionized calcium in the ECF must be maintained within a narrow range because of the critical role calcium plays
in a wide array of cellular functions, especially those involved in neuromuscular activity, secretion, and signal transduction. Intracellular
cytosolic free calcium levels are ~100 nmol/L and are 10,000-fold lower
than ionized calcium concentration in
the blood and ECF (1.1–1.3 mmol/L).
Cytosolic calcium does not play the
structural role played by extracellular
calcium; instead, it serves a signaling
function. The steep chemical gradient
of calcium from outside to inside the
cell promotes rapid calcium influx
through various membrane calcium
channels that can be activated by hormones, metabolites, or neurotransmitters, swiftly changing cellular function.
In blood, total calcium concentration is
normally 2.2–2.6 mM (8.5–10.5 mg/dL),
of which ~50% is ionized. The remainder
is bound ionically to negatively charged
proteins (predominantly albumin and
immunoglobulins) or loosely complexed
with phosphate, citrate, sulfate, or other
anions. Alterations in serum protein concentrations directly affect the total blood
calcium concentration even if the ionized
~3 weeks ~3 months
Osteoid
Osteoclast
precursor
Osteocyte
Osteoclast Active osteoclast
Osteoblast
precursors Bone
remodeling
unit
Osteoblast
Lining cells
Activation
Resorption
Bone formation Mineralization
Cement
line
Reversal
Resting
bone
surface
FIGURE 409-2 Schematic representation of bone remodeling. The cycle of bone remodeling is carried out by the
basic multicellular unit (BMU), which consists of a group of osteoclasts and osteoblasts. In cortical bone, the BMUs
tunnel through the tissue, whereas in cancellous bone, they move across the trabecular surface. The process of
bone remodeling is initiated by the recruitment of osteoclast precursors, perhaps to sites of microdamage. These
precursors fuse to form multinucleated, active osteoclasts that mediate bone resorption. Osteoclasts adhere to bone
and subsequently remove it by acidification and proteolytic digestion. As the BMU advances, osteoclasts leave the
resorption site and osteoblasts, derived from marrow precursors and previously inactive bone lining cells, move in
to cover the excavated area and begin the process of new bone formation by secreting osteoid, which eventually is
mineralized into new bone. After osteoid mineralization, osteoblasts flatten and form a layer of lining cells over new
bone, become osteocytes, or die.
3160 PART 12 Endocrinology and Metabolism
calcium concentration remains normal. An algorithm to correct for protein changes adjusts the total serum calcium (in mg/dL) upward by 0.8
times the deficit in serum albumin (g/dL) or by 0.5 times the deficit
in serum immunoglobulin (in g/dL). Such corrections provide only
rough approximations of actual free calcium concentrations, however,
and may be misleading, particularly during acute illness. Acidosis also
alters ionized calcium by reducing its association with proteins. The
best practice is to measure blood ionized calcium directly by a method
that employs calcium-selective electrodes in acute settings during
which calcium abnormalities might occur.
Control of the ionized calcium concentration in the ECF ordinarily
is accomplished by adjusting the rates of calcium movement across
intestinal and renal epithelia and into and out of bone. These adjustments are mediated mainly via changes in blood levels of the hormones PTH and 1,25(OH)2
D. Acting via binding to calcium-sensing
receptors (CaSRs) on the surface of parathyroid cells, blood ionized
calcium suppresses PTH secretion by reducing levels of PTH mRNA
and promoting the cleavage of PTH to inactive peptides. Also, ionized
calcium indirectly affects PTH secretion by lowering 1,25(OH)2
D
production. This active vitamin D metabolite inhibits PTH production by an incompletely understood mechanism of negative feedback
(Chap. 410).
Normal dietary calcium intake in the United States varies widely,
ranging from 10 to 37 mmol/d (400–1500 mg/d). A National Academy
of Medicine (formerly, Institute of Medicine) analysis recommends
a daily allowance of 25–30 mmol (1000–1200 mg) for most adults.
Intestinal absorption of ingested calcium involves both active (transcellular) and passive (paracellular) mechanisms. Passive calcium
absorption is nonsaturable and approximates 5% of daily calcium
intake, whereas active absorption involves apical calcium entry via specific ion channels (TRPV5 in the kidney and TRPV6 in the intestine),
whose expression is controlled principally by 1,25(OH)2
D. This active
transport mechanism normally accounts for absorption of 20–70%
of dietary calcium. Active calcium transport occurs mainly in the
proximal small bowel (duodenum and proximal jejunum), although
some active calcium absorption occurs in most segments of the small
intestine. Optimal rates of calcium absorption require gastric acid.
This is especially true for weakly dissociable calcium supplements such
as calcium carbonate. In fact, large boluses of calcium carbonate are
poorly absorbed because of their neutralizing effect on gastric acid.
In achlorhydric subjects and for those taking drugs that inhibit gastric
acid secretion, supplements should be taken with meals to optimize
their absorption. Use of calcium citrate may be preferable in these circumstances. Calcium absorption may also be blunted in disease states
such as pancreatic or biliary insufficiency, in which ingested calcium
remains bound to unabsorbed fatty acids or other food constituents. At
high levels of calcium intake, synthesis of 1,25(OH)2
D is reduced; this
decreases the rate of active intestinal calcium absorption. The opposite
occurs with dietary calcium restriction. Some calcium, ~2.5–5 mmol/d
(100–200 mg/d), is excreted as an obligate component of intestinal
secretions and is not regulated by calciotropic hormones.
The feedback-controlled hormonal regulation of intestinal absorptive efficiency results in a relatively constant daily net calcium absorption of ~5–10 mmol/d (200–400 mg/d) despite large changes in daily
dietary calcium intake. This daily load of absorbed calcium is excreted
by the kidneys in a manner that is also tightly regulated by the concentration of ionized calcium in the blood. Approximately 8–10 g/d
of calcium is filtered by the glomeruli, of which only 2–3% appears in
the urine. Most filtered calcium (65%) is reabsorbed in the proximal
tubules via a passive, paracellular route that is coupled to concomitant
NaCl reabsorption and not specifically regulated. The cortical thick
ascending limb of Henle’s loop (cTAL) reabsorbs roughly another 20%
of filtered calcium, also via a paracellular mechanism. Calcium reabsorption in the cTAL requires a tight-junctional protein called paracellin-1 and is inhibited by increased blood concentrations of calcium or
magnesium, acting via the CaSR, which is highly expressed on basolateral membranes in this nephron segment. Operation of the renal CaSR
provides a mechanism, independent of those engaged directly by PTH
or 1,25(OH)2
D, by which serum ionized calcium can control renal
calcium reabsorption. Finally, ~10% of filtered calcium is reabsorbed
in the distal convoluted tubules (DCTs) by a transcellular mechanism.
Calcium enters the luminal surface of the cell through specific apical
calcium channels (TRPV5), whose number is regulated. It then moves
across the cell in association with a specific calcium-binding protein
(calbindin-D28k) that buffers cytosolic calcium concentrations from
the large mass of transported calcium. Ca2+-ATPases and Na+/Ca2+
exchangers actively extrude calcium across the basolateral surface and
thereby maintain the transcellular calcium gradient. All these processes
are stimulated directly or indirectly by PTH. The DCT is also the site of
action of thiazide diuretics, which lower urinary calcium excretion by
inducing sodium depletion and thereby augmenting proximal calcium
reabsorption. Conversely, dietary sodium loads, or increased distal
sodium delivery caused by loop diuretics or saline infusion, induce
calciuresis.
The homeostatic mechanisms that normally maintain a constant
serum ionized calcium concentration may fail at extremes of calcium
intake or when the hormonal systems or organs involved are compromised. Thus, even with maximal activity of the vitamin D–dependent intestinal active transport system, sustained calcium intakes
<5 mmol/d (<200 mg/d) cannot provide enough net calcium absorption to replace obligate losses via the intestine, the kidney, sweat,
and other secretions. In this case, increased blood levels of PTH and
1,25(OH)2
D activate osteoclastic bone resorption to obtain needed
calcium from bone, which leads to progressive bone loss and negative
calcium balance. Increased PTH and 1,25(OH)2
D also enhance renal
calcium reabsorption, and 1,25(OH)2
D enhances calcium absorption
in the gut. At very high calcium intakes (>100 mmol/d [>4 g/d]),
passive intestinal absorption continues to deliver calcium into the ECF
despite maximally downregulated intestinal active transport and renal
tubular calcium reabsorption. This can cause severe hypercalciuria,
nephrocalcinosis, progressive renal failure, and hypercalcemia (e.g.,
“milk-alkali syndrome”). Deficiency or excess of PTH or vitamin D,
intestinal disease, and renal failure represent other commonly encountered challenges to normal calcium homeostasis (Chap. 410).
PHOSPHORUS METABOLISM
Although 85% of the ~600 g of body phosphorus is present in bone
mineral, phosphorus is also a major intracellular constituent both as
the free anion(s) and as a component of numerous organophosphate
compounds, including structural proteins, enzymes, transcription
Kidney
Bone
ECF
1–2 g
Intestine
1000–2000 g
0.25–0.5 g
0.25–0.5 g
0.15–.3 g
0.3–1 g
0.4–1.5 g
8–10 g 7.9–9.7 g
0.25–0.5 g
0.1–0.2 g
FIGURE 409-3 Calcium homeostasis. Schematic illustration of calcium content of
extracellular fluid (ECF) and bone as well as of diet and feces; magnitude of calcium
flux per day as calculated by various methods is shown at sites of transport in
intestine, kidney, and bone. Ranges of values shown are approximate and were
chosen to illustrate certain points discussed in the text. In conditions of calcium
balance, rates of calcium release from and uptake into bone are equal.
3161Bone and Mineral Metabolism in Health and Disease CHAPTER 409
factors, carbohydrate and lipid intermediates, high-energy stores (ATP
[adenosine triphosphate], creatine phosphate), and nucleic acids.
Unlike calcium, phosphorus exists intracellularly at concentrations
close to those present in ECF (e.g., 1–2 mmol/L). In cells and in the
ECF, phosphorus exists in several forms, predominantly as H2
PO4
–
or
NaHPO4
–
, with perhaps 10% as HPO4
2–. This mixture of anions will
be referred to here as “phosphate.” In serum, ~12% of phosphorus is
bound to proteins. Concentrations of phosphates in blood and ECF
generally are expressed in terms of elemental phosphorus, with the
normal range in adults being 0.75–1.45 mmol/L (2.5–4.5 mg/dL).
Because the volume of the intracellular fluid compartment is twice that
of the ECF, measurements of ECF phosphate may not accurately reflect
phosphate availability within cells that follows even modest shifts of
phosphate from one compartment to the other.
Phosphate is widely available in foods and is absorbed efficiently
(65%) by the small intestine even in the absence of vitamin D. However, phosphate absorptive efficiency may be enhanced (to 85–90%) via
active transport mechanisms that are stimulated by 1,25(OH)2
D. These
mechanisms involve activation of Na+/PO4
2– co-transporters, such as
Npt2b, that move phosphate into intestinal cells against an unfavorable
electrochemical gradient. Daily net intestinal phosphate absorption
varies widely with the composition of the diet but is generally in the
range of 500–1000 mg/d. Phosphate absorption can be inhibited by
large doses of calcium salts or by sevelamer hydrochloride (Renagel),
strategies commonly used to control levels of serum phosphate in
renal failure. Aluminum hydroxide antacids also reduce phosphate
absorption but are used less commonly because of the potential for
aluminum toxicity. Low serum phosphate stimulates renal proximal
tubular synthesis of 1,25(OH)2
D, perhaps by suppressing blood levels
of FGF23 (see below).
Serum phosphate levels vary by as much as 50% on a normal day.
This reflects the effect of food intake but also an underlying circadian
rhythm that produces a nadir between 7 and 10 a.m. Carbohydrate
administration, especially as IV dextrose solutions in fasting subjects,
can decrease serum phosphate by >0.7 mmol/L (2 mg/dL) during
treatment of ketoacidosis or during metabolic or respiratory alkalosis.
Because of this wide variation in serum phosphate, it is best to perform
measurements in the basal, fasting state.
Control of serum phosphate is determined mainly by the rate of
renal tubular reabsorption of the filtered load, which is ~4–6 g/d.
Because intestinal phosphate absorption is highly efficient, urinary
excretion is not constant but varies directly with dietary intake. The
fractional excretion of phosphate (ratio of phosphate to creatinine
clearance) is generally in the range of 10–15%. The proximal tubule is
the principal site at which renal phosphate reabsorption is regulated.
This is accomplished by changes in the levels of apical expression and
activity of specific Na+/PO4
2– co-transporters (NaPi-2a and NaPi-2c) in
the proximal tubule. Levels of these transporters at the apical surface of
these cells are reduced rapidly by PTH, a major hormonal regulator of
renal phosphate excretion. FGF23 can impair phosphate reabsorption
dramatically by a similar mechanism. Activating FGF23 mutations
cause the rare disorder autosomal dominant hypophosphatemic rickets
(ADHR). In contrast to PTH, FGF23 also leads to reduced synthesis of
1,25(OH)2
D, which may worsen the resulting hypophosphatemia by
lowering intestinal phosphate absorption. Renal reabsorption of phosphate is responsive to changes in dietary intake such that experimental
dietary phosphate restriction leads to a dramatic lowering of urinary
phosphate within hours, preceding any decline in serum phosphate
(e.g., filtered load). This physiologic renal adaptation to changes in
dietary phosphate availability occurs independently of PTH and may
be mediated in part by changes in levels of serum FGF23. Findings
in FGF23-knockout mice suggest that FGF23 normally acts to lower
blood phosphate and 1,25(OH)2
D levels. In turn, elevation of blood
phosphate increases blood levels of FGF23.
Renal phosphate reabsorption is impaired by hypocalcemia, hypomagnesemia, and severe hypophosphatemia. Phosphate clearance is
enhanced by ECF volume expansion and impaired by dehydration.
Phosphate retention is an important pathophysiologic feature of renal
insufficiency (Chap. 311).
■ HYPOPHOSPHATEMIA
Causes Hypophosphatemia can occur by one or more of three
primary mechanisms: (1) inadequate intestinal phosphate absorption,
(2) excessive renal phosphate excretion, and (3) rapid redistribution of
phosphate from the ECF into bone or soft tissue (Table 409-1). Because
phosphate is so abundant in foods, inadequate intestinal absorption is
almost never observed now that aluminum hydroxide antacids, which
bind phosphate in the gut, are no longer widely used. Fasting or starvation, however, may result in depletion of body phosphate and predispose to subsequent hypophosphatemia during refeeding, especially if
this is accomplished with IV glucose alone.
Chronic hypophosphatemia usually signifies the presence of a persistent renal tubular phosphate-wasting disorder. Excessive activation
of PTH/PTHrP receptors in the proximal tubule as a result of primary
or secondary hyperparathyroidism or because of the PTHrP-mediated
hypercalcemia syndrome in malignancy (Chap. 410) is among the
more common causes of renal hypophosphatemia. Familial hypocalciuric hypercalcemia and Jansen’s chondrodystrophy are rare examples of
genetic disorders in this category (Chap. 410).
Several genetic and acquired diseases cause PTH/PTHrP receptor-independent tubular phosphate wasting with associated rickets and
osteomalacia. All these diseases manifest severe hypophosphatemia;
renal phosphate wasting, sometimes accompanied by aminoaciduria;
inappropriately low blood levels of 1,25(OH)2
D; low-normal serum
levels of calcium; and evidence of impaired cartilage or bone mineralization. Analysis of these diseases led to the discovery of the hormone
FGF23, which is an important physiologic regulator of phosphate
metabolism. FGF23 decreases phosphate reabsorption in the proximal
tubule and also suppresses the 1α-hydroxylase responsible for synthesis
of 1,25(OH)2
D. FGF23 is synthesized by cells of the osteoblast lineage,
primarily osteocytes. High-phosphate diets increase FGF23 levels, and
low-phosphate diets decrease them. ADHR was the first disease linked
to abnormalities in FGF23. ADHR results from activating mutations
in the gene that encodes FGF23. These mutations alter a cleavage site
that ordinarily allows for inactivation of intact FGF23. Several other
genetic disorders feature elevated FGF23 and hypophosphatemia. The
most common of these is X-linked hypophosphatemic rickets (XLH),
which results from inactivating mutations in an endopeptidase termed
PHEX (phosphate-regulating gene with homologies to endopeptidases
on the X chromosome) that is expressed most abundantly on the surface of osteocytes and mature osteoblasts. Patients with XLH usually
have high FGF23 levels, and ablation of the FGF23 gene reverses the
hypophosphatemia found in the mouse version of XLH. How inactivation of PHEX leads to increased levels of FGF23 has not been determined. Two rare autosomal recessive hypophosphatemic syndromes
associated with elevated FGF23 are due to inactivating mutations of
dentin matrix protein 1 (DMP1) and ectonucleotide pyrophosphatase/
phosphodiesterase 1 (ENPP1), respectively, both of which normally are
highly expressed in bone and presumably regulate FGF23 production.
An unusual hypophosphatemic disorder, tumor-induced osteomalacia
(TIO), is an acquired disorder in which tumors, usually of mesenchymal origin and generally histologically benign, secrete FGF23 that
induces renal phosphate wasting. The hypophosphatemic syndrome
resolves completely within hours to days after successful resection of
the responsible tumor. Such tumors typically express large amounts
of FGF23 mRNA, and patients with TIO usually exhibit elevations of
FGF23 in their blood.
Dent’s disease is an X-linked recessive disorder caused by inactivating mutations in CLCN5, a chloride transporter expressed in
endosomes of the proximal tubule; features include hypercalciuria,
hypophosphatemia, and recurrent kidney stones. Renal phosphate
wasting is common among poorly controlled diabetic patients and
alcoholics, who therefore are at risk for iatrogenic hypophosphatemia
when treated with insulin or IV glucose, respectively. Diuretics and
certain other drugs and toxins can cause defective renal tubular phosphate reabsorption (Table 409-1).
In hospitalized patients, hypophosphatemia is often attributable to
massive redistribution of phosphate from the ECF into cells. Insulin
3162 PART 12 Endocrinology and Metabolism
TABLE 409-1 Causes of Hypophosphatemia
I. Reduced renal tubular phosphate reabsorption
A. PTH/PTHrP-dependent
1. Primary hyperparathyroidism
2. Secondary hyperparathyroidism
a. Vitamin D deficiency/resistance
b. Calcium starvation/malabsorption
c. Bartter’s syndrome
d. Autosomal recessive renal hypercalciuria with hypomagnesemia
3. PTHrP-dependent hypercalcemia of malignancy
4. Familial hypocalciuric hypercalcemia
B. PTH/PTHrP-independent
1. Excess FGF23 or other “phosphatonins”
a. X-linked hypophosphatemic rickets (XLH)
b. Autosomal recessive hypophosphatemia (ARHP)
c. Autosomal recessive hypophosphatemic rickets (ARHR) (DMP1,
ENPP1 deficiency)
d. Tumor-induced osteomalacia syndrome (TIO)
e. McCune-Albright syndrome (fibrous dysplasia)
f. Epidermal nevus syndrome
2. Intrinsic renal disease
a. Fanconi’s syndrome(s)
b. Cystinosis
c. Wilson’s disease
d. NaPi-2a or NaPi-2c mutations
3. Other systemic disorders
a. Poorly controlled diabetes mellitus
b. Alcoholism
c. Hyperaldosteronism
d. Hypomagnesemia
e. Amyloidosis
f. Hemolytic-uremic syndrome
g. Renal transplantation or partial liver resection
h. Rewarming or induced hyperthermia
4. Drugs or toxins
a. Ethanol
b. Acetazolamide, other diuretics
c. High-dose estrogens or glucocorticoids
d. Heavy metals (lead, cadmium, saccharated ferric oxide)
e. Toluene, N-methyl formamide
f. Cisplatin, ifosfamide, foscarnet, rapamycin
II. Impaired intestinal phosphate absorption
A. Aluminum-containing antacids
B. Sevelamer
III. Shifts of extracellular phosphate into cells
A. Intravenous glucose
B. Insulin therapy for prolonged hyperglycemia or diabetic ketoacidosis
C. Catecholamines (epinephrine, dopamine, albuterol)
D. Acute respiratory alkalosis
E. Gram-negative sepsis, toxic shock syndrome
F. Recovery from starvation or acidosis
G. Rapid cellular proliferation
1. Leukemic blast crisis
2. Intensive erythropoietin, other growth factor therapy
IV. Accelerated net bone formation
A. After parathyroidectomy
B. Treatment of vitamin D deficiency, Paget’s disease
C. Osteoblastic metastases
Abbreviations: PTH, parathyroid hormone; PTHrP, parathyroid hormone–related
peptide.
therapy for diabetic ketoacidosis is a paradigm for this phenomenon, in which the severity of the hypophosphatemia is related to the
extent of antecedent depletion of phosphate and other electrolytes
(Chap. 404). The hypophosphatemia is usually greatest at a point
many hours after initiation of insulin therapy and is difficult to predict
from baseline measurements of serum phosphate at the time of presentation, when prerenal azotemia can obscure significant phosphate
depletion. Other factors that may contribute to such acute redistributive hypophosphatemia include antecedent starvation or malnutrition,
administration of IV glucose without other nutrients, elevated blood
catecholamines (endogenous or exogenous), respiratory alkalosis, and
recovery from metabolic acidosis.
Hypophosphatemia also can occur transiently (over weeks to
months) during the phase of accelerated net bone formation that follows parathyroidectomy for severe primary hyperparathyroidism or
during treatment of vitamin D deficiency or lytic Paget’s disease. This is
usually most prominent in patients who preoperatively have evidence
of high bone turnover (e.g., high serum levels of alkaline phosphatase).
Osteoblastic metastases can also lead to this syndrome.
Clinical and Laboratory Findings The clinical manifestations of
severe hypophosphatemia reflect a generalized defect in cellular energy
metabolism because of ATP depletion, a shift from oxidative phosphorylation toward glycolysis, and associated tissue or organ dysfunction.
Acute, severe hypophosphatemia occurs mainly or exclusively in hospitalized patients with underlying serious medical or surgical illness and
preexisting phosphate depletion due to excessive urinary losses, severe
malabsorption, or malnutrition. Chronic hypophosphatemia tends to
be less severe, with a clinical presentation dominated by musculoskeletal complaints such as bone pain, osteomalacia, pseudofractures, and
proximal muscle weakness or, in children, rickets and short stature.
Neuromuscular manifestations of severe hypophosphatemia are
variable but may include muscle weakness, lethargy, confusion, disorientation, hallucinations, dysarthria, dysphagia, oculomotor palsies,
anisocoria, nystagmus, ataxia, cerebellar tremor, ballismus, hyporeflexia, impaired sphincter control, distal sensory deficits, paresthesia,
hyperesthesia, generalized or Guillain-Barré–like ascending paralysis,
seizures, coma, and even death. Serious sequelae such as paralysis,
confusion, and seizures are likely only at phosphate concentrations
<0.25 mmol/L (<0.8 mg/dL). Rhabdomyolysis may develop during
rapidly progressive hypophosphatemia. The diagnosis of hypophosphatemia-induced rhabdomyolysis may be overlooked, as up to 30%
of patients with acute hypophosphatemia (<0.7 mM) have creatine
phosphokinase elevations that peak 1–2 days after the nadir in serum
phosphate, when the release of phosphate from injured myocytes may
have led to a near normalization of circulating levels of phosphate.
Respiratory failure and cardiac dysfunction, which are reversible
with phosphate treatment, may occur at serum phosphate levels of
0.5–0.8 mmol/L (1.5–2.5 mg/dL). Renal tubular defects, including
tubular acidosis, glycosuria, and impaired reabsorption of sodium and
calcium, may occur. Hematologic abnormalities correlate with reductions in intracellular ATP and 2,3-diphosphoglycerate and may include
erythrocyte microspherocytosis and hemolysis; impaired oxyhemoglobin dissociation; defective leukocyte chemotaxis, phagocytosis, and
bacterial killing; and platelet dysfunction with spontaneous gastrointestinal hemorrhage.
TREATMENT
Hypophosphatemia
Severe hypophosphatemia (<0.75 mmol/L [<2 mg/dL]), particularly
in the setting of underlying phosphate depletion, constitutes a dangerous electrolyte abnormality that should be corrected promptly.
Unfortunately, the cumulative deficit in body phosphate cannot be
predicted directly from knowledge of the circulating level of phosphate, and therapy must be approached empirically. The threshold
for IV phosphate therapy and consequently the dose of phosphate to
be administered should reflect consideration of renal function, the
likely severity and duration of the underlying phosphate depletion,
3163Bone and Mineral Metabolism in Health and Disease CHAPTER 409
and the presence and severity of symptoms consistent with those
of hypophosphatemia. In adults, phosphate may be safely administered IV as neutral mixtures of sodium or potassium phosphate
salts at initial doses of 0.2–0.8 mmol/kg of elemental phosphorus
over 6 h (e.g., 10–50 mmol over 6 h), with doses >20 mmol/6 h
reserved for those who have serum levels <0.5 mmol/L (1.5 mg/dL)
and normal renal function. A suggested approach is presented in
Table 409-2. Serum levels of phosphate and calcium must be monitored closely (every 6–12 h) throughout treatment. It is necessary to
avoid a serum calcium-phosphorus product >50 mg2
/dL2
to reduce
the risk of heterotopic calcification. Hypocalcemia, if present,
should be corrected before administering IV phosphate. Less severe
hypophosphatemia, in the range of 0.5–0.8 mmol/L (1.5–2.5 mg/
dL), usually can be treated with oral phosphate in divided doses of
750–2000 mg/d as elemental phosphorus; higher doses can cause
bloating and diarrhea.
Management of chronic hypophosphatemia requires knowledge
of the cause(s) of the disorder. Hypophosphatemia related to the
secondary hyperparathyroidism of vitamin D deficiency usually
responds to treatment with vitamin D and calcium alone. XLH,
ADHR, TIO, and related renal tubular disorders usually are managed with divided oral doses of phosphate, often with calcium and
1,25(OH)2
D supplements to bypass the block in renal 1,25(OH)2
D
synthesis and prevent secondary hyperparathyroidism caused by
suppression of ECF calcium levels. Care must be taken to be sure
that oral calcium and phosphate are not administered at the same
time, to avoid precipitation before absorption. Thiazide diuretics
may be used to prevent nephrocalcinosis in patients who are managed this way. Complete normalization of hypophosphatemia is
generally not possible in these conditions. Burosumab, a human
monoclonal antibody that inhibits FGF23, has been approved for
the treatment of XLH. It corrects hypophosphatemia, improves
bone pain, and heals fractures in both adults and children.
Optimal therapy for TIO is extirpation of the responsible tumor,
which may be localized by radiographic skeletal survey or bone
scan (many are located in bone) or by radionuclide scanning
using sestamibi or labeled octreotide. Successful treatment of TIOinduced hypophosphatemia with octreotide has been reported in a
small number of patients. Burosumab treatment, originally used for
XLH, also shows promise as a treatment for TIO.
■ HYPERPHOSPHATEMIA
Causes When the filtered load of phosphate and glomerular filtration rate (GFR) are normal, control of serum phosphate levels is
achieved by adjusting the rate at which phosphate is reabsorbed by
the proximal tubular NaPi-2 co-transporters. The principal hormonal
regulators of NaPi-2 activity are PTH and FGF23. Hyperphosphatemia,
defined in adults as a fasting serum phosphate concentration >1.8
mmol/L (5.5 mg/dL), usually results from impaired glomerular filtration, hypoparathyroidism, excessive delivery of phosphate into the ECF
(from bone, gut, or parenteral phosphate therapy), or a combination of
these factors (Table 409-3). The upper limit of normal serum phosphate concentrations is higher in children and neonates (2.4 mmol/L
[7 mg/dL]). It is useful to distinguish hyperphosphatemia caused by
impaired renal phosphate excretion from that which results from
excessive delivery of phosphate into the ECF (Table 409-3).
In chronic renal insufficiency, reduced GFR leads to phosphate
retention. Hyperphosphatemia in turn further impairs renal synthesis
of 1,25(OH)2
D, increases FGF23 levels, and stimulates PTH secretion
and parathyroid gland hypertrophy both directly and indirectly (by
lowering blood ionized calcium levels). Thus, hyperphosphatemia is
a major cause of the secondary hyperparathyroidism of renal failure
and must be addressed early in the course of the disease (Chaps. 311
and 410).
Hypoparathyroidism leads to hyperphosphatemia via increased
expression of NaPi-2 co-transporters in the proximal tubule. Hypoparathyroidism, or parathyroid suppression, has multiple potential
causes, including autoimmune disease; developmental, surgical, or
radiation-induced absence of functional parathyroid tissue; vitamin D
intoxication or other causes of PTH-independent hypercalcemia; cellular PTH resistance (pseudohypoparathyroidism or hypomagnesemia);
infiltrative disorders such as Wilson’s disease and hemochromatosis;
and impaired PTH secretion caused by hypermagnesemia, severe
hypomagnesemia, or activating mutations in the CaSR. Hypocalcemia
may also contribute directly to impaired phosphate clearance, as calcium infusion can induce phosphaturia in hypoparathyroid subjects.
Increased tubular phosphate reabsorption also occurs in acromegaly,
during heparin administration, and in tumoral calcinosis. Tumoral
TABLE 409-2 Intravenous Therapy for Hypophosphatemia
CONSIDER
Likely severity of underlying phosphate depletion
Concurrent parenteral glucose administration
Presence of neuromuscular, cardiopulmonary, or hematologic complications of
hypophosphatemia
Renal function (reduce dose by 50% if serum creatinine >220 μmol/L [>2.5 mg/dL])
Serum calcium level (correct hypocalcemia first; reduce dose by 50% in
hypercalcemia)
Guidelines
SERUM PHOSPHORUS,
MM (MG/DL)
RATE OF
INFUSION,
MMOL/H DURATION, H
TOTAL
ADMINISTERED,
MMOL
<0.8 (<2.5) 2 6 12
<0.5 (<1.5) 4 6 24
<0.3 (<1) 8 6 48
Note: Rates shown are calculated for a 70-kg person; levels of serum calcium
and phosphorus must be measured every 6–12 h during therapy; infusions can
be repeated to achieve stable serum phosphorus levels >0.8 mmol/L (>2.5 mg/dL);
most formulations available in the United States provide 3 mmol/mL of sodium or
potassium phosphate.
TABLE 409-3 Causes of Hyperphosphatemia
I. Impaired renal phosphate excretion
A. Renal insufficiency
B. Hypoparathyroidism
1. Developmental
2. Autoimmune
3. After neck surgery or radiation
4. Activating mutations of the calcium-sensing receptor
C. Parathyroid suppression
1. Parathyroid-independent hypercalcemia
a. Vitamin D or vitamin A intoxication
b. Sarcoidosis, other granulomatous diseases
c. Immobilization, osteolytic metastases
d. Milk-alkali syndrome
2. Severe hypermagnesemia or hypomagnesemia
D. Pseudohypoparathyroidism
E. Acromegaly
F. Tumoral calcinosis
G. Heparin therapy
II. Massive extracellular fluid phosphate loads
A. Rapid administration of exogenous phosphate (intravenous, oral, rectal)
B. Extensive cellular injury or necrosis
1. Crush injuries
2. Rhabdomyolysis
3. Hyperthermia
4. Fulminant hepatitis
5. Cytotoxic therapy
6. Severe hemolytic anemia
C. Transcellular phosphate shifts
1. Metabolic acidosis
2. Respiratory acidosis
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