2304 PART 9 Disorders of the Kidney and Urinary Tract
can occasionally be seen in glomerulonephritis, vasculitis, or toxins/
medications that can affect the glomerulus as well as the tubulointerstitium (e.g., NSAIDs). AKI can also complicate cases of minimal change
disease, a cause of the nephrotic syndrome often associated with low
serum albumin concentrations (Chap. 309). If the dipstick is positive
for hemoglobin but few red blood cells are evident in the urine sediment, then rhabdomyolysis or hemolysis should be suspected.
Prerenal azotemia may present with hyaline casts or an unremarkable urine sediment examination. Postrenal AKI may also be associated with an unremarkable sediment, but hematuria and pyuria may
be seen depending on the cause of obstruction. AKI from ATN due
to ischemic injury, sepsis, or certain nephrotoxins has characteristic
urine sediment findings: pigmented “muddy brown” granular casts and
tubular epithelial cell casts. These findings may be absent in more than
20% of cases, however. Glomerulonephritis may lead to dysmorphic
red blood cells or red blood cell casts. Interstitial nephritis may lead to
white blood cell casts. The urine sediment findings overlap somewhat
in glomerulonephritis and interstitial nephritis, and a diagnosis is not
always possible on the basis of the urine sediment alone. Urine eosinophils have a limited role in differential diagnosis; they can be seen
in interstitial nephritis, pyelonephritis, cystitis, atheroembolic disease,
or glomerulonephritis. Crystalluria may be important diagnostically.
The finding of oxalate crystals in AKI should prompt an evaluation
for ethylene glycol toxicity. Abundant uric acid crystals may be seen in
tumor lysis syndrome.
■ BLOOD LABORATORY FINDINGS
Certain forms of AKI are associated with characteristic patterns in the
rise and fall of SCr. Prerenal azotemia typically leads to modest rises
in SCr that return to baseline with improvement in hemodynamic
status. Contrast nephropathy leads to a rise in SCr within 24–48 h,
peak within 3–5 days, and resolution within 5–7 days. In comparison,
atheroembolic disease usually manifests with more subacute rises in
SCr, although severe AKI with rapid increases in SCr can occur in this
setting. With many of the epithelial cell toxins such as aminoglycoside
antibiotics and cisplatin, the rise in SCr is characteristically delayed for
3–5 days to 2 weeks after initial exposure.
A complete blood count may provide diagnostic clues. Anemia is
common in AKI and is usually multifactorial in origin. It is not related
to an effect of AKI solely on production of red blood cells because this
effect in isolation takes longer to manifest. Myeloma can be diagnosed
with serum immunoelectrophoresis or free light chain assay, and it can
often be suspected if the blood anion gap is low due to unmeasured
cationic proteins. Peripheral eosinophilia can accompany interstitial
nephritis, atheroembolic disease, polyarteritis nodosa, and ChurgStrauss vasculitis. Severe anemia in the absence of bleeding may reflect
hemolysis, multiple myeloma, or thrombotic microangiopathy (e.g.,
hemolytic uremic syndrome [HUS] or TTP). Other laboratory findings
of thrombotic microangiopathy include thrombocytopenia, schistocytes on peripheral blood smear, elevated lactate dehydrogenase level,
and low haptoglobin content. Evaluation of patients suspected of having TTP or HUS includes measurement of levels of the von Willebrand
factor cleaving protease (ADAMTS13) and testing for Shiga toxin–
producing Escherichia coli. “Atypical HUS” constitutes the majority of
adult cases of HUS; genetic testing is important because it is estimated
that 60–70% of atypical HUS patients have mutations in genes encoding proteins that regulate the alternative complement pathway.
AKI often leads to hyperkalemia, hyperphosphatemia, and hypocalcemia. Marked hyperphosphatemia with accompanying hypocalcemia
may suggest rhabdomyolysis or tumor lysis syndrome. Serum creatine
kinase and uric acid levels are often elevated in rhabdomyolysis, while
tumor lysis syndrome can be associated with normal or marginally
elevated creatine kinase and markedly elevated serum uric acid. The
anion gap may be increased with any cause of uremia due to retention of anions such as phosphate, hippurate, sulfate, and urate. The
co-occurrence of an increased anion gap and an osmolal gap may
suggest ethylene glycol poisoning, which may also cause oxalate
crystalluria and oxalate deposition in kidney tissue. Low anion gap
may provide a clue to the diagnosis of multiple myeloma due to the
presence of unmeasured cationic proteins. Laboratory blood tests
helpful for the diagnosis of glomerulonephritis and vasculitis include
depressed complement levels and high titers of antinuclear antibodies
(ANAs), antineutrophil cytoplasmic antibodies (ANCAs), antiglomerular basement membrane (anti-GBM) antibodies, and cryoglobulins.
Anti-phospholiase A2 receptor antibodies will point to a diagnosis of
membranous nephropathy.
■ RENAL FAILURE INDICES
Several indices have been used to help differentiate prerenal azotemia
from intrinsic AKI when the tubules are malfunctioning. The low
Urinary sediment in AKI
Normal or few RBCs or
WBCs or hyaline casts
Prerenal
Postrenal
Arterial thrombosis
or embolism
Preglomerular
vasculitis
HUS or TTP
Scleroderma crisis
RBCs
RBC casts
GN
Vasculitis
Malignant
hypertension
Thrombotic
microangiopathy
Interstitial
nephritis
GN
Pyelonephritis
Allograft
rejection
Malignant
infiltration of the
kidney
ATN
Tubulointerstitial
nephritis
Acute cellular
allograft rejection
Myoglobinuria
Hemoglobinuria
ATN
GN
Vasculitis
Tubulo-
interstitial
nephritis
Allergic
interstitial
nephritis
Atheroembolic
disease
Pyelonephritis
Cystitis
Glomerulo-
nephritis
Acute uric acid
nephropathy
Calcium oxalate
(ethylene glycol
intoxication)
Drugs or toxins
(acyclovir,
indinavir,
sulfadiazine,
amoxicillin)
Abnormal
WBCs
WBC casts
Renal tubular
epithelial
(RTE) cells
RTE casts
Pigmented casts
Granular casts Eosinophiluria Crystalluria
FIGURE 310-6 Interpretation of urinary sediment findings in acute kidney injury (AKI). ATN, acute tubular necrosis; GN, glomerulonephritis; HUS, hemolytic-uremic
syndrome; RBCs, red blood cells; RTE, renal tubular epithelial; TTP, thrombotic thrombocytopenic purpura; WBCs, white blood cells. (Adapted from L Yang, JV Bonventre:
Diagnosis and clinical evaluation of acute kidney injury. In Comprehensive Nephrology, 4th ed. J Floege et al [eds]. Philadelphia, Elsevier, 2010.)
2305Acute Kidney Injury CHAPTER 310
tubular flow rate and increased renal medullary recycling of urea seen
in prerenal azotemia may cause a disproportionate elevation of the
BUN compared to creatinine. Other causes of disproportionate BUN
elevation need to be kept in mind, however, including upper gastrointestinal bleeding, hyperalimentation, increased tissue catabolism, and
glucocorticoid use.
The FeNa is the fraction of the filtered sodium load that is not
reabsorbed by the tubules, and is a measure of both the kidney’s ability
to reabsorb sodium as well as endogenously and exogenously administered factors that affect tubular reabsorption. As such, it depends on
sodium intake, effective intravascular volume, GFR, diuretic intake,
and intact tubular reabsorptive mechanisms. With prerenal azotemia,
the FeNa may be <1%, suggesting avid tubular sodium reabsorption.
In patients with CKD, a FeNa significantly >1% can be present despite
a superimposed prerenal state. The FeNa may also be >1% despite
hypovolemia due to treatment with diuretics. Low FeNa is often seen
early in glomerulonephritis and other disorders and, hence, should
not be taken as prima facie evidence of prerenal azotemia. Low FeNa
is therefore suggestive of, but not synonymous with, effective intravascular volume depletion, and should not be used as the sole guide for
volume management. The response of urine output to crystalloid or
colloid fluid administration may be both diagnostic and therapeutic in
prerenal azotemia. In ischemic AKI, the FeNa is frequently >1% because
of tubular injury and resultant impaired ability to reabsorb sodium.
Several causes of ischemia-associated and nephrotoxin-associated AKI
can present with FeNa <1%, however, including sepsis (often early in
the course), rhabdomyolysis, and contrast nephropathy.
The ability of the kidney to produce a concentrated urine is
dependent upon many factors and relies on good tubular function
in multiple regions of the kidney. In the patient not taking diuretics
and with good baseline kidney function, urine osmolality may be
>500 mOsm/kg in prerenal azotemia, consistent with an intact medullary concentration gradient and elevated serum vasopressin levels
causing water reabsorption by passive diffusion from the collecting
duct into a concentrated medullary interstitium, resulting in concentrated urine. In elderly patients and those with CKD, however, baseline
concentrating defects may exist, making urinary osmolality unreliable
in many instances. Loss of concentrating ability is common in most
forms of AKI that affect the tubules and interstitium, resulting in urine
osmolality <350 mOsm/kg, but this finding is not specific.
■ RADIOLOGIC EVALUATION
Postrenal AKI should always be considered in the differential diagnosis of AKI because treatment is usually successful if instituted early.
Simple bladder catheterization can rule out urethral obstruction.
Imaging of the urinary tract with renal ultrasound or CT scan should
be undertaken to investigate obstruction in individuals with AKI
unless an alternate diagnosis is apparent. Findings of obstruction
include dilation of the collecting system and hydroureteronephrosis.
Obstruction can be present without radiologic abnormalities in the
setting of volume depletion, retroperitoneal fibrosis, encasement
with tumor, and also early in the course of obstruction. If a high
clinical index of suspicion for obstruction persists despite normal
imaging, antegrade or retrograde pyelography should be performed.
Imaging may also provide additional helpful information about kidney size and echogenicity to assist in the distinction between acute
versus CKD. In CKD, kidneys are usually smaller unless the patient
has diabetic nephropathy, HIV-associated nephropathy, or infiltrative diseases. Normal-sized kidneys are expected in AKI. Enlarged
kidneys in a patient with AKI suggest the possibility of acute interstitial nephritis or infiltrative diseases. As described previously,
vascular imaging may be useful if venous or arterial obstruction is
suspected, but the risks of contrast administration should be kept in
mind. MRI with gadolinium-based contrast agents (GBCAs) should
be avoided if possible in severe AKI due to the possibility of inducing nephrogenic system fibrosis, a rare but serious complication
seen most commonly in patients with end-stage renal disease. The
recommendations regarding use of GBCAs in subjects with CKD
remain controversial.
■ KIDNEY BIOPSY
If the cause of AKI is not apparent based on the clinical context,
physical examination, laboratory studies, and radiologic evaluation,
kidney biopsy should be considered. The kidney biopsy can provide
definitive diagnostic and prognostic information about acute kidney
disease and CKD. The procedure is most often used in AKI when
prerenal azotemia, postrenal AKI, and ischemic or nephrotoxic AKI
have been deemed unlikely, and other possible diagnoses are being
considered such as glomerulonephritis, vasculitis, interstitial nephritis,
myeloma kidney, HUS and TTP, and allograft dysfunction. Kidney
biopsy is associated with a risk of bleeding, which can be severe and
organ- or life-threatening in patients with thrombocytopenia or coagulopathy, but the diagnostic and prognostic information obtained can
be invaluable.
■ NOVEL BIOMARKERS
BUN and creatinine are functional biomarkers of glomerular filtration rather than tissue injury biomarkers and, therefore, may be
suboptimal for the diagnosis of actual parenchymal kidney damage.
BUN and creatinine are also relatively slow to rise after kidney injury.
Several urine and blood biomarkers have been investigated and show
promise for earlier and accurate diagnosis of AKI and for predicting AKI prognosis. In cases of oliguric AKI, the urinary flow rate in
response to bolus intravenous furosemide 1.0–1.5 mg/kg can be used
a prognostic test: urine output <200 mL over 2 h after intravenous
furosemide may identify patients at higher risk of progression to more
severe AKI, and the need for renal replacement therapy. The severity
or risk of progressive AKI may also be reflected in findings on urine
microscopy. In one study involving review of fresh urine sediments by
board-certified nephrologists, a greater number of renal tubular epithelial
cells and/or granular casts in the urine sediment was associated with both
the severity and worsening of AKI. Protein biomarkers of kidney injury
have also been identified in animal models of AKI and have been used
in humans and found to be particularly useful in toxicity identification.
Kidney injury molecule-1 (KIM-1) is a type 1 transmembrane protein that
is abundantly expressed in proximal tubular cells injured by ischemia or
multiple, distinct nephrotoxins, such as cisplatin. KIM-1 is not expressed
in appreciable quantities in the absence of tubular injury or in extrarenal
tissues. KIM-1 can be detected after ischemic or nephrotoxic injury in
the urine and plasma. Neutrophil gelatinase associated lipocalin (NGAL,
also known as lipocalin-2 or siderocalin) is another biomarker of AKI.
NGAL was first discovered as a protein in granules of human neutrophils.
NGAL can bind to iron siderophore complexes and may have tissueprotective effects in the proximal tubule. NGAL is highly upregulated
after inflammation and kidney injury and can be detected in the plasma
and urine within 2 h of cardiopulmonary bypass–associated AKI. Soluble
urokinase plasminogen activator receptor (suPAR) is a signaling glycoprotein expressed in multiple cell types and thought to be involved in
the pathogenesis of certain kidney diseases; suPAR has been measured
in the plasma and found to predict the subsequent development of AKI.
In 2014, the U.S. Food and Drug Administration (FDA) approved the
marketing of a test based on the combination of the urinary concentrations of two cell-cycle arrest biomarkers, insulin-like growth factor
binding protein 7 (IGFBP7) and tissue inhibitor of metalloproteinase-2
(TIMP-2) as predictive biomarkers for higher risk of the development
of moderate to severe AKI in critically ill patients. In 2018 the FDA also
qualified a panel of urinary markers including KIM-1, NGAL, N-acetylbeta-D-glucosaminidase, osteopontin, cystatin-C, and clusterin for the
detection of kidney tubular injury in phase 1 trials in healthy volunteers. The optimal use of AKI biomarkers in clinical settings is an area
of ongoing investigation.
COMPLICATIONS OF AKI
The kidney plays a central role in homeostatic control of volume status,
blood pressure, plasma electrolyte composition, and acid-base balance,
and for excretion of nitrogenous and other waste products. Complications associated with AKI are, therefore, protean, and depend on the
severity of AKI and other associated conditions. Mild to moderate AKI
may be entirely asymptomatic, particularly early in the course.
2306 PART 9 Disorders of the Kidney and Urinary Tract
■ UREMIA
Buildup of nitrogenous waste products, manifested as an elevated
BUN concentration, is a hallmark of AKI. BUN itself poses little direct
toxicity at levels <100 mg/dL. At higher concentrations, mental status
changes and bleeding complications can arise. Other toxins normally
cleared by the kidney may be responsible for the symptom complex
known as uremia. Few of the many possible uremic toxins have been
definitively identified. The correlation of BUN and SCr concentrations
with uremic symptoms is extremely variable, due in part to differences
in urea and creatinine generation rates across individuals.
■ HYPERVOLEMIA AND HYPOVOLEMIA
Expansion of extracellular fluid volume is a major complication of
oliguric and anuric AKI, due to impaired salt and water excretion. The
result can be weight gain, dependent edema, increased jugular venous
pressure, and pulmonary edema; the latter can be life threatening. Pulmonary edema can also occur from volume overload and hemorrhage
in pulmonary renal syndromes. AKI may also induce or exacerbate
acute lung injury characterized by increased vascular permeability and
inflammatory cell infiltration in lung parenchyma. Recovery from AKI
is often heralded by an increase in urine output. This “polyuric” phase
of recovery may be due to an osmotic diuresis from retained urea and
other waste products as well as delayed recovery of tubular reabsorptive
functions.
■ HYPONATREMIA
Abnormalities in plasma electrolyte composition can be mild or life
threatening. The dysfunctional kidney has limited ability to regulate
electrolyte balance. Administration of excessive hypotonic crystalloid or isotonic dextrose solutions can result in hypoosmolality and
hyponatremia, which, if severe, can cause neurologic abnormalities,
including seizures.
■ HYPERKALEMIA
An important complication of AKI is hyperkalemia. Marked hyperkalemia is particularly common in rhabdomyolysis, hemolysis, and
tumor lysis syndrome due to release of intracellular potassium from
damaged cells. Muscle weakness may be a symptom of hyperkalemia.
Potassium affects the cellular membrane potential of cardiac and neuromuscular tissues. The more serious complication of hyperkalemia
is due to effects on cardiac conduction, leading to potentially fatal
arrhythmias.
■ ACIDOSIS
Metabolic acidosis, usually accompanied by an elevation in the anion
gap, is common in AKI, and can further complicate acid-base and
potassium balance in individuals with other causes of acidosis, including sepsis, diabetic ketoacidosis, or respiratory acidosis.
■ HYPERPHOSPHATEMIA AND HYPOCALCEMIA
AKI can lead to hyperphosphatemia, particularly in highly catabolic
patients or those with AKI from rhabdomyolysis, hemolysis, and
tumor lysis syndrome. Metastatic deposition of calcium phosphate can
lead to hypocalcemia. AKI-associated hypocalcemia may also arise
from derangements in the vitamin D–parathyroid hormone–fibroblast
growth factor-23 axis. Hypocalcemia is often asymptomatic but can
lead to perioral paresthesias, muscle cramps, seizures, carpopedal
spasms, and prolongation of the QT interval on electrocardiography.
Calcium levels should be corrected for the degree of hypoalbuminemia,
if present, or ionized calcium levels should be followed. Mild, asymptomatic hypocalcemia does not require treatment.
■ BLEEDING
Hematologic complications of AKI include anemia and bleeding, both
of which are exacerbated by coexisting disease processes such as sepsis, liver disease, and disseminated intravascular coagulation. Direct
hematologic effects from AKI-related uremia include decreased erythropoiesis and platelet dysfunction.
■ INFECTIONS
Infections are a common precipitant of AKI and also a dreaded complication of AKI. Impaired host immunity has been described in ESKD
and may be operative in severe AKI.
■ CARDIAC COMPLICATIONS
The major cardiac complications of AKI are arrhythmias, pericarditis,
and pericardial effusion. In addition, volume overload and uremia
may lead to cardiac injury and impaired cardiac function. In animal
studies cellular apoptosis and capillary vascular congestion as well as
mitochondrial dysfunction have been described in the heart after renal
ischemia reperfusion.
■ MALNUTRITION
AKI is often a severely hypercatabolic state, and therefore malnutrition
is a major complication.
■ PREVENTION AND TREATMENT OF AKI
The management of individuals with and at risk for AKI varies according to the underlying cause (Table 310-3). Common to all are several
principles. Optimization of hemodynamics, correction of fluid and
electrolyte imbalances, discontinuation of nephrotoxic medications,
and dose adjustment of administered medications are all critical.
Common causes of AKI such as sepsis and ischemic ATN do not yet
have specific therapies once injury is established, but meticulous clinical attention is needed to support the patient until (if) AKI resolves.
The kidney possesses remarkable capacity to repair itself after even
severe, dialysis-requiring AKI, when baseline renal function was intact.
However, many patients with AKI, particularly when superimposed
on preexisting CKD, undergo maladaptive repair processes and do
not recover fully and may remain dialysis dependent. It has become
increasingly apparent that AKI predisposes to accelerated progression
of CKD, and CKD is an important risk factor for AKI.
Prerenal Azotemia Prevention and treatment of prerenal azotemia
require optimization of renal perfusion. The composition of replacement fluids should be targeted to the type of fluid lost. Severe acute
blood loss should be treated with packed red blood cells. In AKI,
oliguria alone is not an indication for fluid administration. Intravascular hypovolemia should be the only indication. Optimal fluid composition is not well defined. Crystalloid solutions are less expensive
than albumin-containing solutions, and albumin does not provide a
survival benefit compared to crystalloid. Albumin may decrease fluid
requirements but does not reduce the need for renal replacement therapy. Buffered crystalloid solutions (e.g., Ringer’s Lactate, Hartmann’s
solution, Plasma-Lyte) are recommended for patients with AKI who
are not hypochloremic; 0.9% saline is recommended for hypovolemic
hypochloremic patients if the serum chloride concentration is closely
monitored. Excessive chloride administration from 0.9% saline may
lead to hyperchloremic metabolic acidosis and may impair GFR.
Hydroxyethyl starch solutions increase the risk of severe AKI and are
contraindicated. Bicarbonate-containing solutions (e.g., dextrose water
with 150 mEq sodium bicarbonate) can be used if metabolic acidosis
is a concern.
Optimization of cardiac function in AKI may require use of inotropic agents, preload- and afterload-reducing agents, antiarrhythmic
drugs, and mechanical aids such as ventricular assist devices. Invasive
hemodynamic monitoring to guide therapy may be necessary.
Cirrhosis and Hepatorenal Syndrome Fluid management in
individuals with cirrhosis, ascites, and AKI is challenging because of
the frequent difficulty in ascertaining intravascular volume status.
Administration of intravenous fluids as a volume challenge may be
required diagnostically as well as therapeutically. Excessive volume
administration may, however, result in worsening ascites and pulmonary compromise in the setting of hepatorenal syndrome or AKI due
to superimposed spontaneous bacterial peritonitis. Peritonitis should
be ruled out by culture of ascitic fluid. Albumin may prevent AKI in
those treated with antibiotics for spontaneous bacterial peritonitis. The
definitive treatment of the hepatorenal syndrome is orthotopic liver
2307Acute Kidney Injury CHAPTER 310
transplantation. Bridge therapies that have shown promise include
terlipressin (a vasopressin analog), with albumin, or, when terlipressin
is not available, combination therapy with octreotide (a somatostatin
analog) and midodrine (an α1
-adrenergic agonist), in combination
with intravenous albumin (25–50 g, maximum 100 g/d).
Intrinsic AKI Several agents have been tested and have failed to
show benefit in the treatment of acute tubular injury. These include
atrial natriuretic peptide, low-dose dopamine, endothelin antagonists,
erythropoietin, loop diuretics, calcium channel blockers, α-adrenergic
receptor blockers, prostaglandin analogs, antioxidants, antibodies
against leukocyte adhesion molecules, and insulin-like growth factor,
among many others. Most studies have enrolled patients with severe
and well-established AKI, and treatment may have been initiated too
late. Kidney injury biomarkers described previously may provide an
opportunity to test agents earlier in the course of AKI.
AKI due to acute glomerulonephritis or vasculitis may respond to
immunosuppressive agents and/or plasmapheresis (Chap. 309). Allergic interstitial nephritis due to medications requires discontinuation
of the offending agent. Glucocorticoids have been used but not tested
in randomized trials, in cases where AKI persists or worsens despite
discontinuation of the suspected medication. AKI due to scleroderma
(scleroderma renal crisis) should be treated with ACE inhibitors. Idiopathic TTP is a medical emergency and should be treated promptly
with plasma exchange. Pharmacologic blockade of complement activation may be effective in atypical HUS.
Early and aggressive volume repletion is mandatory in patients
with rhabdomyolysis, who may initially require 10 L of fluid per day.
Alkaline fluids (e.g., 75 mmol/L sodium bicarbonate added to 0.45%
saline) may be beneficial in preventing tubular injury and cast formation, but carry the risk of worsening hypocalcemia. Diuretics may
be used if fluid repletion is adequate but unsuccessful in achieving
urinary flow rates of 200–300 mL/h. There is no specific therapy for
established AKI in rhabdomyolysis, other than dialysis in severe cases
or general supportive care to maintain fluid and electrolyte balance
and tissue perfusion. Careful attention must be focused on calcium and
phosphate status because of precipitation in damaged tissue and release
when the tissue heals.
Postrenal AKI Prompt recognition and relief of urinary tract
obstruction can forestall the development of permanent structural
damage induced by urinary stasis. The site of obstruction defines
the treatment approach. Transurethral or suprapubic bladder catheterization may be all that is needed initially for urethral strictures or
functional bladder impairment. Ureteric obstruction may be treated
by percutaneous nephrostomy tube placement or ureteral stent placement. Relief of obstruction is usually followed by an appropriate diuresis for several days. In rare cases, severe polyuria persists due to tubular
dysfunction and may require continued administration of intravenous
fluids and electrolytes for a period of time.
■ SUPPORTIVE MEASURES FOR AKI
Volume Management Hypervolemia in oliguric or anuric AKI
may be life threatening due to acute pulmonary edema, especially
because many patients have coexisting pulmonary disease, and AKI
likely increases pulmonary vascular permeability. Fluid and sodium
should be restricted, and diuretics may be used to increase the urinary flow rate. There is no evidence that increasing urine output
itself improves the natural history of AKI, but diuretics may help to
avoid the need for dialysis in some cases. In severe cases of volume
overload, furosemide may be given as a bolus (200 mg) followed by
an intravenous drip (10–40 mg/h), with or without a thiazide diuretic.
In decompensated heart failure, stepped diuretic therapy was found
to be superior to ultrafiltration in preserving renal function. Diuretic
therapy should be stopped if there is no response. Dopamine in low
doses may transiently increase salt and water excretion by the kidney
in prerenal states, but clinical trials have failed to show any benefit in
patients with intrinsic AKI. Because of the risk of arrhythmias and
potential bowel ischemia, the risks of dopamine outweigh the benefits
if used specifically for the treatment or prevention of AKI.
Electrolyte and Acid-Base Abnormalities The treatment of
dysnatremias and hyperkalemia is described in Chap. 53. Metabolic acidosis is generally not treated unless severe (pH <7.20 and
serum bicarbonate <15 mmol/L). Acidosis can be treated with oral
TABLE 310-3 Management of Acute Kidney Injury
General Issues
1. Optimization of systemic and renal hemodynamics through volume
resuscitation and judicious use of vasopressors
2. Elimination of nephrotoxic agents (e.g., ACE inhibitors, ARBs, NSAIDs,
aminoglycosides) if possible
3. Initiation of renal replacement therapy when indicated
Specific Issues
1. Nephrotoxin-specific
a. Rhabdomyolysis: aggressive intravenous fluids; consider forced alkaline
diuresis
b. Tumor lysis syndrome: aggressive intravenous fluids and allopurinol or
rasburicase
2. Volume overload
a. Salt and water restriction
b. Diuretics
c. Ultrafiltration
3. Hyponatremia
a. Restriction of enteral free water intake, minimization of hypotonic
intravenous solutions including those containing dextrose
b. Hypertonic saline is rarely necessary in AKI. Vasopressin antagonists are
generally not needed.
4. Hyperkalemia
a. Restriction of dietary potassium intake
b. Discontinuation of potassium-sparing diuretics, ACE inhibitors, ARBs,
NSAIDs
c. Loop diuretics to promote urinary potassium loss
d. Potassium binding ion-exchange resin (sodium polystyrene sulfonate)
e. Insulin (10 units regular) and glucose (50 mL of 50% dextrose) to promote
entry of potassium intracellularly
f. Inhaled beta-agonist therapy to promote entry of potassium intracellularly
g. Calcium gluconate or calcium chloride (1 g) to stabilize the myocardium
5. Metabolic acidosis
a. Sodium bicarbonate (if pH <7.2 to keep serum bicarbonate >15 mmol/L)
b. Administration of other bases, e.g., THAM
c. Renal replacement therapy
6. Hyperphosphatemia
a. Restriction of dietary phosphate intake
b. Phosphate binding agents (calcium acetate, sevelamer hydrochloride,
aluminum hydroxide—taken with meals)
7. Hypocalcemia
a. Calcium carbonate or calcium gluconate if symptomatic
8. Hypermagnesemia
a. Discontinue Mg2+ containing antacids
9. Hyperuricemia
a. Acute treatment is usually not required except in the setting of tumor lysis
syndrome (see above)
10. Nutrition
a. Sufficient protein and calorie intake (20–30 kcal/kg per day) to avoid
negative nitrogen balance. Nutrition should be provided via the enteral
route if possible.
11. Drug dosing
a. Careful attention to dosages and frequency of administration of drugs,
adjustment for degree of renal failure
b. Note that serum creatinine concentration may overestimate renal function
in the non–steady state characteristic of patients with AKI.
Abbreviations: ACE, angiotensin-converting enzyme; AKI, acute kidney infection;
ARBs, angiotensin receptor blockers; NSAIDs, nonsteroidal anti-inflammatory
drugs; THAM, tris (hydroxymethyl) aminomethane.
2308 PART 9 Disorders of the Kidney and Urinary Tract
or intravenous sodium bicarbonate (Chap. 55), but overcorrection
should be avoided because of the possibility of metabolic alkalosis,
hypocalcemia, hypokalemia, and volume overload. Hyperphosphatemia is common in AKI and can usually be treated by limiting intestinal
absorption of phosphate using phosphate binders (calcium carbonate,
calcium acetate, lanthanum, sevelamer, or aluminum hydroxide).
Symptomatic hypocalcemia should be treated with calcium gluconate
or calcium chloride. Ionized calcium should be monitored rather than
total calcium when hypoalbuminemia is present.
Malnutrition Increased catabolism with protein energy wasting is
common in severe AKI, particularly in the setting of multisystem organ
failure. Inadequate nutrition may lead to starvation ketoacidosis and
protein catabolism. Excessive nutrition may increase the generation
of nitrogenous waste and lead to worsening azotemia. Total parenteral nutrition requires large volumes of fluid administration and may
complicate efforts at volume control. According to the Kidney Disease
Improving Global Outcomes (KDIGO) guidelines, patients with AKI
should achieve a total energy intake of 20–30 kcal/kg per day. Protein
intake should vary depending on the severity of AKI: 0.8–1.0 g/kg per
day in noncatabolic AKI without the need for dialysis; 1.0–1.5 g/kg per
day in patients on dialysis; and up to a maximum of 1.7 g/kg per day
if hypercatabolic and receiving continuous renal replacement therapy.
Trace elements and water-soluble vitamins should also be supplemented in AKI patients treated with dialysis and continuous renal
replacement therapy.
Anemia The anemia seen in AKI is usually multifactorial and is not
improved by erythropoiesis-stimulating agents, due to their delayed
onset of action and the presence of bone marrow resistance in critically ill patients. Uremic bleeding may respond to desmopressin or
estrogens, but may require dialysis for treatment in the case of longstanding or severe uremia. Gastrointestinal prophylaxis with proton
pump inhibitors or histamine (H2
) receptor blockers is required. It is
important to recognize, however, that proton pump inhibitors have
been associated with AKI from interstitial nephritis, a relationship that
is increasingly being recognized. Venous thromboembolism prophylaxis is important and should be tailored to the clinical setting; lowmolecular-weight heparins and factor Xa inhibitors have unpredictable
pharmacokinetics in severe AKI and should generally be avoided if
possible.
Dialysis Indications and Modalities (See also Chap. 312)
Dialysis is indicated when medical management fails to control volume overload, hyperkalemia, or acidosis; in some toxic ingestions; and
when there are severe complications of uremia (asterixis, pericardial
rub or effusion, encephalopathy, uremic bleeding). Late initiation of
dialysis carries the risk of avoidable volume, electrolyte, and metabolic
complications of AKI. On the other hand, initiating dialysis too early
may unnecessarily expose individuals to intravenous lines and invasive
procedures, with the attendant risks of infection, bleeding, procedural
complications, and hypotension. In randomized controlled trials,
earlier versus later initiation of dialysis has not been demonstrated
to improve survival, and may increase the risk of adverse events. The
initiation of dialysis should not, however, await the development of a
life-threatening complication of renal failure. Many nephrologists initiate dialysis for AKI empirically when the BUN exceeds a certain value
(e.g., 100 mg/dL) in patients without clinical signs of recovery of kidney
function. The available modes for renal replacement therapy in AKI
require either access to the peritoneal cavity (for peritoneal dialysis)
or the large blood vessels (for hemodialysis, hemofiltration, and other
hybrid procedures). Small solutes are removed across a semipermeable
membrane down their concentration gradient (“diffusive” clearance)
and/or along with the movement of plasma water (“convective”
clearance). Hemodialysis can be used intermittently or continuously
and can be done through convective clearance, diffusive clearance,
or a combination of the two. Vascular access is through the femoral,
internal jugular, or subclavian veins. Hemodialysis is an intermittent
procedure that removes solutes through diffusive and convective clearance. Hemodialysis is typically performed 3–4 h per day, three to four
times per week, and is the most common form of renal replacement
therapy for AKI. One of the major complications of hemodialysis is
hypotension, particularly in the critically ill, which can perpetuate AKI
by causing ischemic injury to the recovering organ.
Continuous intravascular procedures were developed in the early
1980s to treat hemodynamically unstable patients without inducing
the rapid shifts of volume, osmolarity, and electrolytes characteristic
of intermittent hemodialysis. Continuous renal replacement therapy
(CRRT) can be performed by convective clearance (continuous venovenous hemofiltration [CVVH]), in which large volumes of plasma
water (and accompanying solutes) are forced across the semipermeable
membrane by means of hydrostatic pressure; the plasma water is then
replaced by a physiologic crystalloid solution. CRRT can also be performed by diffusive clearance (continuous venovenous hemodialysis
[CVVHD]), a technology similar to hemodialysis except at lower blood
flow and dialysate flow rates. A hybrid therapy combines both diffusive
and convective clearance (continuous venovenous hemodiafiltration
[CVVHDF]). To achieve some of the advantages of CRRT without the
need for 24-h staffing of the procedure, some physicians favor slow
low-efficiency dialysis (SLED) or extended daily dialysis (EDD). In this
therapy, blood flow and dialysate flow are higher than in CVVHD, but
the treatment time is reduced to ≤12 h. The choice of modality is often
dictated by the immediate availability of technology and the expertise
of medical staff.
The optimal dose of dialysis for AKI for any particular patient is
not clear. Daily intermittent hemodialysis and high-dose CRRT do
not confer a demonstrable survival or renal recovery advantage, but
care should be taken to avoid undertreatment. Studies have failed to
show that continuous therapies are superior to intermittent therapies
when measuring survival rates. If available, CRRT is often preferred
in patients with severe hemodynamic instability, cerebral edema, or
significant volume overload.
Peritoneal dialysis can be performed through a temporary intraperitoneal catheter. It is rarely used in the United States for AKI in
adults (although it was “rediscovered” during the COVID-19 pandemic owing to inadequate numbers of continuous and intermittent
hemodialysis machines). Peritoneal dialysis has enjoyed widespread
use internationally, particularly when hemodialysis technology is not
as readily available. Dialysate solution is instilled into and removed
from the peritoneal cavity at regular intervals in order to achieve
diffusive and convective clearance of solutes across the peritoneal
membrane; ultrafiltration of water is achieved by the presence of an
osmotic gradient across the peritoneal membrane achieved by high
concentrations of dextrose in the dialysate solution. Because of its
continuous nature, it is often better tolerated than intermittent procedures like hemodialysis in hypotensive patients. Peritoneal dialysis
may not be sufficient for hypercatabolic patients due to inherent limitations in dialysis efficacy.
OUTCOME AND PROGNOSIS
The development of AKI is associated with a significantly increased
risk of in-hospital and long-term mortality, longer length of stay, and
increased costs. AKI is also associated with an increased risk of later
cardiovascular disease events, though the mechanisms are not well
understood. Prerenal azotemia, with the exception of the cardiorenal
and hepatorenal syndromes, and postrenal azotemia carry a better
prognosis than most cases of intrinsic AKI. The kidneys may recover
even after severe, dialysis-requiring AKI. Survivors of an episode of
AKI requiring temporary dialysis, however, are at extremely high risk
for progressive CKD, and up to 10% may develop ESKD requiring
dialysis or transplantation. AKI and CKD are increasingly seen as
interrelated syndromes: CKD is a major risk factor for the development
of AKI, and AKI is a risk factor for the future development of CKD.
Measurement of albuminuria after an AKI episode can help predict
the risk of kidney disease progression and can serve as a valuable riskstratification tool. Postdischarge care after AKI under the supervision
of a nephrologist for aggressive secondary prevention of kidney disease
is prudent.
2309Chronic Kidney Disease CHAPTER 311
Chronic kidney disease (CKD) encompasses a spectrum of pathophysiologic processes associated with abnormal kidney function, often with
a progressive decline in glomerular filtration rate (GFR). The risk of
worsening CKD is closely linked to both the GFR and the amount of
albuminuria. Figure 311-1 provides a staging of CKD stratified by the
estimates for further progressive decline of GFR based on these two
parameters.
The dispiriting term end-stage renal disease represents a stage of
CKD where the accumulation of toxins, fluid, and electrolytes normally
excreted by the kidneys leads to death unless the toxins are removed
by renal replacement therapy, using dialysis or kidney transplantation.
These interventions are discussed in Chaps. 312 and 313. End-stage
renal disease will be supplanted in this chapter by the term stage 5 CKD.
■ PATHOPHYSIOLOGY OF CKD
The pathophysiology of CKD involves two broad mechanisms of damage: (1) specific initiating mechanisms particular to the underlying
311 Chronic Kidney Disease
Joanne M. Bargman, Karl Skorecki
etiology (e.g., genetic abnormalities in kidney development, immune
complex deposition, and inflammation in certain types of glomerulonephritis, or toxin exposure in certain diseases of the renal tubules
and interstitium), and (2) nonspecific mechanisms involving hyperfiltration and hypertrophy of the remaining viable nephrons, which
are common consequences of long-term reduction of renal mass,
irrespective of underlying etiology. The responses to reduction in
nephron number are mediated by vasoactive hormones, cytokines,
and growth factors. Eventually, the short-term adaptations of hyperfiltration and hypertrophy to maintain GFR become maladaptive as
the increased pressure and flow within the nephron predisposes to
distortion of glomerular architecture, abnormal podocyte function,
and disruption of the filtration barrier, leading to sclerosis and dropout
of the remaining nephrons (Fig. 311-2). Increased intrarenal activity of
the renin-angiotensin system (RAS) appears to contribute both to the
initial compensatory hyperfiltration and to the subsequent maladaptive
hypertrophy and sclerosis. This process explains why a reduction in
renal mass from an isolated insult may lead to a progressive decline
in renal function over many years and the efficacy of pharmacologic
approaches that attenuate this response (Fig. 311-3).
■ IDENTIFICATION OF RISK FACTORS
AND STAGING OF CKD
There has been significant recent progress in the identification of risk
factors that increase the risk for CKD, even in individuals with normal
GFR (Table 311-1).
Adults with such risk factors should be monitored at least every 2
years for albuminuria, decline in eGFR, and blood pressure abnormalities, so that a clinical management pathway can be planned.
Most recently identified risk factors for which there is now a consensus include a past episode of apparently recovered acute kidney injury
(AKI), tobacco use, and many forms of apparently resolved childhood
and adolescent kidney disease. There is also an increasing awareness of
the role of genetic risk factors, which account for 15–40% of adult-onset
CKD, with the percentage often depending on the contribution of
demographic structure and history to the genetic variation for any population. Many rare inherited forms of CKD follow a Mendelian inheritance pattern, often as part of a systemic syndrome, with the most
Mildly decreased
Mildly to moderately
decreased
Moderately to
severely decreased
Severely decreased
Kidney failure
Normal or high
Normal to
mildly
increased
<30 mg/g
<3 mg/mmol
30–300 mg/g
3–30 mg/mmol
>300 mg/g
>30 mg/mmol
Moderately
increased
Severely
increased
60–89
45–59
30–44
15–29
<15
G1 ≥90
G2
G4
G5
G3a
G3b
GFR categories (mL/min/1.73 m2)
description and range
Prognosis of CKD by GFR
and albuminuria categories:
KDIGO 2012
Persistent albuminuria categories
description and range
A1 A2 A3
FIGURE 311-1 Kidney Disease Improving Global Outcome (KDIGO) classification of chronic kidney disease (CKD). Gradation of color from green to red corresponds to
increasing risk and progression of CKD. GFR, glomerular filtration rate. (Reproduced with permission from KDIGO 2012 Clinical Practice Guideline for the Evaluation and
Management of Chronic Kidney Disease. Kidney Int Suppl 3:5, 2013.)
■ FURTHER READING
Bonventre JV, Yang L: Cellular pathophysiology of ischemic acute
kidney injury. J Clin Invest 121:4210, 2011.
Hoste EAJ et al: Global epidemiology and outcomes of acute kidney
injury. Nature Rev Nephrol 14:607, 2018.
Kidney Disease: Improving Global Outcomes (KDIGO) Acute
Kidney Injury Work Group: KDIGO Clinical Practice Guidelines
for Acute Kidney Injury. Kidney Int Supp 2:1, 2012.
STARRT-AKI Investigators for the Canadian Critical Care Trials
Group: Timing of initiation of renal-replacement therapy in acute
kidney injury. N Engl J Med 383:240, 2020.
2310 PART 9 Disorders of the Kidney and Urinary Tract
common in this category being autosomal dominant polycystic kidney
disease (ADPKD). In addition, it is now appreciated that many unique,
kindred-specific, site-specific copy number variants and microdeletions, as well as functional variants at >60 genetic loci known to harbor
systemic and kidney-only disease pathogenic mutations, also contribute to risk for pleiotropic presentations of CKD (Table 311-2). Many
of the genes with identified CKD-causing mutations are expressed in
the podocytes of the renal glomeruli or in the glomerular basement
membrane, but others are expressed in tubule segments with a primary
tubulointerstitial process and secondary glomerular injury. Given the
significant contribution of monogenic disease etiologies, consideration is now given to chromosomal microarray and genome or exome
sequencing for CKD of unknown cause in young adults, as noted below
under Evaluation and Management of Patients with CKD.
In addition, recent research in the genetics of predisposition to
common complex diseases has revealed DNA sequence variants at a
Distal
Af tubule ferent
arteriole
Efferent
arteriole
Normal
endothelium
Basement
membrane
Podocytes
Enlarged
arteriole
Damaged
endothelium
Sclerosis
Normal Glomerulus Hyperfiltering Glomerulus
FIGURE 311-2 Left: Schema of the normal glomerular architecture. Right: Secondary glomerular changes associated with a reduction in nephron number, including
enlargement of capillary lumens and focal adhesions, which are thought to occur consequent to compensatory hyperfiltration and hypertrophy in the remaining nephrons.
(From JR Ingelfinger: Is microanatomy destiny?. N Engl J Med 348:99, 2003. Copyright © 2003, Massachusetts Medical Society. Reprinted with permission from Massachusetts
Medical Society.)
Glomerulus
Increased
intraglomerular
pressure
Normal
kidney
Afferent
arteriole
Ang II
Afferent
arteriole
Distal tubule Distal tubule
Efferent
arteriolar
constricted
Efferent
arteriole
Tubule Tubule
Urinary protein
A B
Ang II
FIGURE 311-3 Schematic representation of the effect of intraglomerular hypertension on nephron survival.
2311Chronic Kidney Disease CHAPTER 311
number of genetic loci that are associated with common forms of CKD.
A striking example is the finding of allelic versions of the APOL1 gene,
of West African population ancestry, which contributes to the severalfold higher frequency of certain common etiologies of nondiabetic
CKD (e.g., focal segmental glomerulosclerosis) observed among African and Hispanic Americans, in major regions of continental Africa
and the global African diaspora. The prevalence in West African populations seems to have arisen as an evolutionary adaptation conferring
protection from tropical pathogens. As in other common diseases with
a heritable component, environmental triggers (e.g., a viral pathogen)
transform genetic risk into disease.
To stage CKD, it is necessary to estimate the GFR rather than relying
on serum creatinine concentration (Table 311-3). Many laboratories now
report an estimated GFR, or eGFR, using one of these equations. These
equations are valid only if the patient is in steady state, that is, the serum
creatinine is neither rising nor falling over days. The societal implications
of adjustment for a construct of race have been the subject of important
recent discourse, with the idea that more individually sound adjustments
without potentially negative racial categorizations be developed.
The normal annual mean decline in GFR with age from the peak
GFR (~120 mL/min per 1.73 m2
) attained during the third decade of
life is ~1 mL/min per year per 1.73 m2
, reaching a mean value of 70 mL/
min per 1.73 m2
at age 70, with considerable interindividual variability.
Although reduced GFR is expected with aging, the lower GFR signifies
a true loss of kidney function with attendant consequences in terms
of risk of CKD complications and requirement for dose adjustment
of medications. The mean GFR is lower in women than in men. For
example, a woman in her eighties with a laboratory report of serum
creatinine in the normal range may have a GFR of <50 mL/min per 1.73 m2
.
Relatedly, even a mild elevation in serum creatinine concentration often
signifies a substantial reduction in GFR in older individuals.
Measurement of albuminuria is also helpful for monitoring
nephron injury and the response to therapy in many forms of
CKD, especially chronic glomerular diseases. The cumbersome
24-h urine collection has been replaced by measurement of urinary
albumin-to-creatinine ratio (UACR) in one and preferably several
spot first-morning urine samples as a measure pointing to glomerular injury. Even in patients with negative conventional urinary
dipstick tests for protein, persistent UACR >2.5 mg/mmol (male) or
>3.5 mg/mmol (female) on two to three occasions serves as a marker
not only for early detection of primary kidney disease but for systemic microvascular disease as well.
TABLE 311-2 Monogenic Risk Loci for Chronic Kidney Disease
Copy number variants
17q12
22q11.2
16p11.2
Single nucleotide variants at four most predominant genetic loci with mendelian
inheritance
Genes for autosomal dominant polycystic kidney disease
ADPKD1
ADPKD2
GANAB
DNAJBll
ALG9
Genes for type IV collagen-associated nephropathy
COL4A3
COL4A4
COL4A5
Genes for autosomal dominant tubulointerstitial kidney disease
UMOD
MUCl
REN
HNFlB
SEC6lAl
Genes with known common variants that confer increased risk with odds ratio
exceeding 2 with non-Mendelian inheritance patterns
APOL1
TABLE 311-1 Risk Factors for Chronic Kidney Disease (CKD) in
Adulthood by Categorya
Chronic Nonrenal (Systemic) Disease
Diabetes and metabolic syndrome
Autoinflammatory disease (e.g., lupus, vasculitis, cancer immunotherapy)
Infections (e.g., HIV, HBV, HCV)
Absence of infection (JCV)
Nephrotoxic exposure (including many antineoplastic therapies)
Hypertension (risk, cause, or consequence)
Demographic, Anthropomorphic, Ancestry, Geographic
Age
Sex
Population ancestry
Family history
Region-specific CKD risk of uncertain etiology (e.g., Central America,
Sri Lanka, and indigenous peoples of Australia and New Zealand)
Childhood and Adolescent States and Diseases
Premature and SGA birth
Increased BMI
Persistent asymptomatic microscopic hematuria
Elevated blood pressure
Childhood kidney disease (even resolved)
Treated childhood cancer
Adult Onset
Prior acute kidney injury
Preeclampsia
Kidney donation (or other acquired nephrectomy)
Genetic
Monogenic Mendelian inheritance
Polygenic complex inheritance
Viral Infection
HIV infection (HIVAN)
SARS-CoV-2 (COVAN)
Lifestyle
Smoking
Diet
Physical activity
a
Not biomarkers.
Abbreviations: BMI, body mass index; COVAN, COVID-19–associated nephropathy;
HBV, hepatitis B virus; HCV, hepatitis C virus; HIVAN, HIV-associated nephropathy;
JCV, JC virus; SGA, small for gestational age.
TABLE 311-3 Recommended Equations for Estimation of Glomerular
Filtration Rate (GFR) Using Serum Creatinine Concentration (SCR),
Age, Sex, Race, and Body Weight
1. Equation from the Modification of Diet in Renal Disease Study
Estimated GFR (mL/min per 1.73 m2
) = 1.86 × (SCr)
−1.154 × (age)−0.203
Multiply by 0.742 for women
Multiply by 1.21 for African ancestry (currently under review)
2. CKD-EPI Equation
GFR = 141 × min(SCr/κ, 1)α × max(SCr/κ, 1)–1.209 × 0.993Age
Multiply by 1.018 for women
Multiply by 1.159 for African ancestry (currently under review)
where SCr is serum creatinine in mg/dL, κ is 0.7 for females and 0.9 for males, α is
–0.329 for females and –0.411 for males, min indicates the minimum of SCr/κ or 1,
and max indicates the maximum of SCr/κ or 1.
Abbreviation: CKD-EPI, Chronic Kidney Disease Epidemiology Collaboration.
2312 PART 9 Disorders of the Kidney and Urinary Tract
A Kidney Failure Risk (KFR) equation has been devised to predict
the risk of progression to stage 5 dialysis-dependent kidney disease.
The equation is available on many sites online (for example, www
.kidneyfailurerisk.com) and uses age, sex, region (North American
or non–North American), GFR, and UACR. It has been validated in
several cohorts around the world, although the risk for progression
appears to be greater in North America, accounting for the regional
adjustment in the equation.
Stages 1 and 2 CKD are usually asymptomatic, such that the recognition of CKD occurs more often as a result of laboratory testing in
clinical settings other than suspicion of kidney disease. Moreover, in
the absence of the risk factors noted above, population-wide screening is not recommended. With progression to CKD stages 3 and 4,
clinical and laboratory complications become more prominent.
Virtually all organ systems are affected, but the most evident complications include anemia with easy fatigability; decreased appetite
with progressive malnutrition; abnormalities in calcium, phosphorus,
and mineral-regulating hormones, such as 1,25(OH)2
D3
(calcitriol),
parathyroid hormone (PTH), and fibroblast growth factor 23 (FGF23); and abnormalities in sodium, potassium, water, and acid-base
homeostasis. Many patients, especially older individuals, will have
eGFR values compatible with stage 2 or 3 CKD. However, the majority of these patients will show no further deterioration of kidney
function. In this setting, it is advised to recheck kidney function,
and if it is stable and not associated with proteinuria, the patient
can usually be followed with interval repeat testing without referral
to a nephrologist. However, caution should be exercised in terms of
potential exposure to potential nephrotoxins or interventions that
risk AKI and also with respect to medication dose adjustment. If
repeat testing shows declining GFR, albuminuria, or uncontrolled
hypertension, referral to a nephrologist is appropriate. If the patient
progresses to stage 5 CKD (GFR <15 mL/min), toxins accumulate
such that patients usually experience a disturbance in their activities
of daily living, well-being, nutritional status, and water and electrolyte homeostasis, eventuating in the uremic syndrome.
■ ETIOLOGY AND EPIDEMIOLOGY
It has been estimated from population data that at least 6% of the
adult population in the United States has CKD at stages 1 and 2. An
additional 4.5% of the U.S. population is estimated to have stages 3
and 4 CKD. Table 311-4 lists the five most frequent categories of
causes of CKD, cumulatively accounting for >90% of the CKD disease burden worldwide. The relative contribution of each category
varies among different geographic regions. The most frequent cause
of CKD in North America and Europe is diabetic nephropathy, most
often secondary to type 2 diabetes mellitus. Patients with newly
diagnosed CKD often have hypertension. When no overt evidence
for a primary glomerular or tubulointerstitial kidney disease process
is present, CKD is frequently attributed to hypertension. However, it
is now appreciated that some of these patients may have a subclinical
primary glomerulopathy, such as focal segmental or global glomerulosclerosis. In other patients, progressive nephrosclerosis and hypertension are the renal correlates of a systemic vascular disease, often
also involving large and small vessels elsewhere, such as the heart and
brain. This latter combination is especially common in older patients,
among whom chronic kidney ischemia as a cause of CKD may be
underdiagnosed.
■ PATHOPHYSIOLOGY AND BIOCHEMISTRY
OF UREMIA
Although serum urea and creatinine concentrations are used to measure the excretory capacity of the kidneys, accumulation of these two
molecules themselves does not account for the symptoms and signs
that characterize the uremic syndrome in advanced CKD. Large numbers of toxins that accumulate when GFR declines have been implicated
in the uremic syndrome. These include water-soluble, hydrophobic,
protein-bound, charged, and uncharged nitrogen-containing nonvolatile products of metabolism. It is thus evident that the serum concentrations of urea and creatinine should be viewed as being readily
measured but very incomplete surrogate markers for retained toxins,
and monitoring the levels of urea and creatinine in the patient with
impaired kidney function represents a vast oversimplification of the
uremic state.
The uremic syndrome involves more than renal excretory failure.
A host of metabolic and endocrine functions normally performed by
the kidneys are also impaired and can result in anemia, malnutrition,
and abnormal metabolism of carbohydrates, fats, and proteins. Furthermore, plasma levels of many hormones, including PTH, FGF-23,
insulin, glucagon, steroid hormones including vitamin D and sex
hormones, and prolactin change with CKD as a result of reduced
excretion, decreased degradation, or abnormal regulation. Finally,
CKD is associated with increased systemic inflammation. Elevated
levels of C-reactive protein are detected along with other acute-phase
reactants, whereas levels of so-called negative acute-phase reactants, such
as albumin and fetuin, decline. Thus, the inflammation associated with
CKD is important in the malnutrition-inflammation-atherosclerosis/
calcification syndrome, which contributes in turn to the acceleration of
vascular disease and morbidity associated with advanced kidney disease.
In summary, the pathophysiology of the uremic syndrome can be
divided into manifestations in three spheres of dysfunction: (1) those
consequent to the accumulation of toxins that normally undergo renal
excretion; (2) those consequent to the loss of other kidney functions,
such as fluid and electrolyte homeostasis and hormone regulation; and
(3) progressive systemic inflammation and its vascular and nutritional
consequences.
CLINICAL AND LABORATORY
MANIFESTATIONS OF CKD AND UREMIA
Uremia leads to disturbances in the function of virtually every organ
system. Chronic dialysis can reduce the incidence and severity of many
of these disturbances, so that the florid manifestations of uremia have
largely disappeared in the modern health care setting. However, even
optimal dialysis therapy is not completely effective as renal replacement therapy because some disturbances resulting from impaired
kidney function fail to respond to dialysis.
■ FLUID, ELECTROLYTE, AND
ACID-BASE DISORDERS
Sodium and Water Homeostasis With normal kidney function,
tubular excretion of filtered sodium and water matches intake. Many
forms of kidney disease disrupt this balance such that dietary intake of
sodium exceeds its excretion, leading to sodium retention and attendant extracellular fluid volume (ECFV) expansion. This expansion
may contribute to hypertension, which itself can accelerate nephron
hyperfiltration and injury. As long as water intake does not exceed
the capacity for renal water clearance, the ECFV expansion will be
isonatric and the patient will have a normal plasma sodium concentration. Hyponatremia is not commonly seen in CKD patients but,
when present, often responds to water restriction. The patient with
ECFV expansion (peripheral edema, sometimes hypertension poorly
responsive to therapy) should be counseled regarding salt restriction.
Thiazide diuretics have limited utility in stages 3–5 CKD, such that
administration of loop diuretics, including furosemide, bumetanide,
or torsemide, may be needed. Resistance to loop diuretics in CKD
often mandates use of higher doses than those used in patients with
higher GFR. The combination of loop diuretics with metolazone may
TABLE 311-4 Leading Categories of Etiologies of Chronic Kidney
Disease (CKD)a
• Diabetic nephropathy
• Glomerulonephritis
• Hypertension-associated CKD (includes vascular and ischemic kidney disease
and primary glomerular disease with associated hypertension)
• Autosomal dominant polycystic kidney disease
• Other cystic and tubulointerstitial nephropathy
a
Relative contribution of each category varies with geographic region and race.
2313Chronic Kidney Disease CHAPTER 311
be helpful. Diuretic resistance with intractable edema and hypertension
in advanced CKD may serve as an indication to initiate dialysis.
Rarely, patients with CKD may have impaired renal conservation
of sodium and water. When an extrarenal cause for fluid loss, such as
gastrointestinal (GI) loss, is present, these patients may be prone to
ECFV depletion because of the inability of the failing kidney to reclaim
filtered sodium adequately. Any depletion of ECFV, whether due to GI
losses, renal sodium loss, or overzealous diuretic therapy, can further
compromise kidney function through underperfusion, or a “prerenal”
state, leading to acute-on-chronic kidney failure. In this setting, holding or adjusting the diuretic dose or even cautious volume repletion
with normal saline may return the ECFV to normal and restore renal
function to baseline.
Potassium Homeostasis In CKD, the decline in GFR is not
necessarily accompanied by a parallel decline in urinary potassium
excretion, which is predominantly mediated by aldosterone-dependent
secretion in the distal nephron. Another defense against potassium
retention in these patients is augmented potassium excretion in the
GI tract. Notwithstanding these two homeostatic responses, hyperkalemia may be precipitated in certain settings. These include increased
dietary potassium intake, hemolysis, transfusion of stored red blood
cells, and metabolic acidosis. Importantly, a host of medications can
inhibit renal potassium excretion and lead to hyperkalemia. The most
important medications in this respect include the RAS inhibitors and
spironolactone and other potassium-sparing diuretics such as amiloride, eplerenone, and triamterene. The benefits of the RAS inhibitors
in ameliorating hyperfiltration and progression of CKD often favor
their cautious and judicious use with very close monitoring of plasma
potassium concentration. Coadministration of potassium-lowering
agents such as patiromer may allow for the use of RAS inhibitors with
reduced risk of hyperkalemia.
Certain causes of CKD can be associated with earlier and more
severe disruption of potassium secretory mechanisms in the distal
nephron, out of proportion to the decline in GFR. These include conditions associated with hyporeninemic hypoaldosteronism, such as
diabetes, and renal diseases that preferentially affect the distal nephron,
such as obstructive uropathy and sickle cell nephropathy.
Hypokalemia is not common in CKD and usually reflects markedly
reduced dietary potassium intake, especially in association with excessive diuretic therapy or concurrent GI losses. The use of potassium
supplements and potassium-sparing diuretics may be risky in patients
with impaired renal function and needs to be monitored closely.
Metabolic Acidosis Metabolic acidosis is a common disturbance
in CKD. The majority of patients can still acidify the urine, but they
produce less ammonia and, therefore, cannot excrete the quantity
of protons required to maintain acid-base balance in most diets.
Hyperkalemia, if present, further depresses ammonia production. The
combination of hyperkalemia and hyperchloremic metabolic acidosis
is often present, even at earlier stages of CKD, in patients with diabetic
nephropathy or in those with predominant tubulointerstitial disease or
obstructive uropathy. With further declining GFR, the total urinary net
daily acid excretion may be severely limited to less than 30–40 mmol,
and the accumulation of anions of retained organic acids can then
lead to an anion-gap metabolic acidosis. Thus, the non-anion-gap
metabolic acidosis seen in earlier stages of CKD may be complicated
by the addition of an anion-gap metabolic acidosis as CKD progresses.
In most patients, the metabolic acidosis is mild; the pH is rarely <7.32
and can usually be corrected with oral sodium bicarbonate supplementation. Studies have suggested that even modest degrees of metabolic
acidosis may be associated with the development of protein catabolism
and progression of CKD.
TREATMENT
Fluid, Electrolyte, and Acid-Base Disorders
Dietary salt restriction and the use of loop diuretics, occasionally in combination with metolazone, may be needed to
maintain euvolemia. Water restriction is indicated only if there is
hyponatremia.
Hyperkalemia often responds to dietary restriction of potassium,
the use of kaliuretic diuretics, and both avoidance of potassium supplements (including occult sources, such as dietary salt substitutes)
and dose reduction or avoidance of potassium-retaining medications (especially RAS inhibitors). Kaliuretic diuretics promote
urinary potassium excretion, whereas potassium-binding resins,
such as calcium resonium, sodium polystyrene, or patiromer, can
promote potassium loss through the GI tract and may reduce the
incidence of hyperkalemia. Intractable hyperkalemia is an indication (although uncommon) to consider institution of dialysis in a
CKD patient. The renal tubular acidosis and subsequent anion-gap
metabolic acidosis in progressive CKD will respond to alkali supplementation, typically with sodium bicarbonate. Recent studies
suggest that this replacement should be considered when the serum
bicarbonate concentration falls below 20–23 mmol/L to avoid the
protein catabolic state seen with even mild degrees of metabolic
acidosis and to slow the progression of CKD. The sodium load
in sodium bicarbonate supplementation needs to be taken into
account, when ECFV expansion is present.
■ DISORDERS OF CALCIUM AND
PHOSPHATE METABOLISM
The principal complications of abnormalities of calcium and phosphate
metabolism in CKD occur in the skeleton and the vascular bed, with
occasional involvement of soft tissues. It is likely that disorders of bone
turnover and disorders of vascular and soft tissue calcification are
related to each other.
Bone Manifestations of CKD The major disorders of bone
disease can be classified into those associated with high bone turnover with increased PTH levels (including osteitis fibrosa cystica, the
classic lesion of secondary hyperparathyroidism), osteomalacia due to
reduced effect of the active forms of vitamin D, and low bone turnover
with low or normal PTH levels (adynamic bone disease) or most often
combinations of the foregoing.
The pathophysiology of secondary hyperparathyroidism and the
consequent high-turnover bone disease is related to abnormal mineral
metabolism through the following series of interrelated mechanisms:
(1) declining GFR leads to reduced excretion of phosphate and, thus,
phosphate retention; (2) the retained phosphate stimulates increased
synthesis of both FGF-23 by osteocytes and of PTH and also stimulates
growth of parathyroid gland mass; and (3) PTH production is stimulated by decreased levels of ionized calcium, which, in turn, result from
decreased levels of renal calcitriol production with reduced kidney
mass and suppression of calcitriol production due to phosphate retention and elevated levels of FGF-23, which also increases degradation
of calcitriol. Low calcitriol levels contribute to hyperparathyroidism,
both by leading to hypocalcemia and also by a direct effect on PTH
gene transcription. In addition, the normal inhibitory effect of FGF23 on PTH production is Klotho-dependent and is also attenuated in
CKD. These changes start to occur when the GFR falls below 60 mL/
min, though some studies point to retention of phosphate as an event
antedating measurable reduction in GFR, together with early elevation
of FGF-23 as well. FGF-23 is part of a family of phosphatonins that
promotes phosphate excretion, and high levels of FGF-23 are an independent risk factor for left ventricular hypertrophy and are associated
with increased mortality due to several classes of complications in
CKD, dialysis, and kidney transplant patients.
Hyperparathyroidism stimulates bone turnover and leads to osteitis
fibrosa cystica. Bone histology shows abnormal osteoid, bone and bone
marrow fibrosis, and, in advanced stages, the formation of bone cysts,
sometimes with hemorrhagic elements so that they appear brown in
color; hence, the term brown tumor. Clinical manifestations of severe
hyperparathyroidism include bone pain and fragility, brown tumors,
compression syndromes, and resistance to erythropoiesis-stimulating
agents (ESA) in part related to the bone marrow fibrosis. Furthermore,
PTH itself is considered a uremic toxin, and high levels are associated
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