2283Approach to the Patient with Renal Disease or Urinary Tract Disease CHAPTER 308
well as hyperfibrinogenemia. RVT may present
with back pain or pulmonary emboli.
NS with heavy proteinuria or large kidneys on
ultrasound in advanced stages of chronic kidney
disease (CKD) is often noted in diabetic nephropathy, amyloid, HIVAN, and MN with RVT.
MN may be the presenting finding in cases of
SLE, whereas diffuse proliferative GN with low
C3, when associated with SLE, occurs in patients
who also have signs and symptoms of joint, skin,
or systemic organ involvement. A cause of very
early MN is an idiosyncratic reaction to NSAIDs,
even when taken in small amounts. Many other
drugs including penicillamine, mercury, and
gold can cause MN. Proteinuia from any cause
may present earlier, or increase, when DM,
obesity, partial nephrectomy, or increased renal
venous pressure exists.
Solid tumors, particularly lung, gastric, intestinal, bladder, breast, and prostate, may underlie
a paraneoplastic syndrome of MN. While it is
important to take a history and examine the
patient carefully for signs of cancer, it is not the
rule to work up every patient with MN exhaustively for cancer. But the neoplastic nephropathy
may be a sign of recurrent disease and may
even be recognized by tumor antigens. MN also
occurs in the context of many infectious diseases,
including syphilis, malaria, schistosomiasis, and
hepatitis B. Recently, 70% of patients with primary MN have been found to have circulating
levels of an autoantibody to the phospholipase
A2 receptor (anti-PLA2R) in the subepithelial
region of the glomerular basement membrane.
Patients who have a nephrotic and nephritic
sediment in childhood may have membranoproliferative glomerular nephritis (MPGN) with
low C3 as a primary disease (C3 glomerulopathy
or dense-deposit disease). The adult presenting
with a nephrotic and nephritic picture should be
considered to have an immune complex disorder
unless proven otherwise. In amyloidosis there
may be a simultaneous and severe tubular syndrome in addition to the albuminuria, consisting
of nephrogenic diabetes insipidus and a hyperkalemic RTA. When NS is associated with Fanconi’s
syndrome (glycosuria, phosphaturia, uricosuria,
and aminoaciduria), one must consider multiple
myeloma in the adult.
HEMATURIA AND LOWER
URINARY TRACT SYNDROMES
Because blood could enter the urinary tract from
any structure, identifying the source is a necessary
first step. As a rule, hematuria associated with
flank pain or ureteral colic is more characteristic
of a lower urinary tract source, such as a stone or
an obstructing lesion. However, when flank pain without colic is noted,
one has to consider swelling of the kidney and stretching of the renal
capsule, as might be seen in acute urinary obstruction, kidney infection,
interstitial nephritis, and, on occasion, acute glomerular nephritis. Heavy
bleeding with clots is more characteristic of lower tract bleeding but
could result from trauma to the kidney. In patients who have acute flank
pain and hypertension, assuming the pain is due to a kidney stone may
miss an occlusive vascular event from an embolus or in situ clot within
the arterial blood supply. Patients who engage in strenuous exercise may
develop hematuria that can be ruled out by retesting the urine after a
week or two of rest. True hematuria can be distinguished from hemoglobinuria and myoglobinuria by urinalysis.
Nephrotic
Syndrome
Membranoproliferative
Membranous
Focal segmental
glomerular
sclerosis
Minimal change
disease
Other
Primary
Secondary
Primary:
Idiopathic and
anti-PLA2R
Secondary
Primary
Secondary
Primary
Lymphoproliferative disorders
NSAIDs
Heroin
Adaptive injury:
obesity, DM
SLE
Malaria
Schistosomiasis
Cancer: GI,
prostate, breast,
lung, bladder
Cryoglobulins
Postinfectious
SBE
SLE
Drugs: ampicillin,
NSAIDs, gold
mercury,
penicillamine
Secondary
Diabetes
mellitus
HIV, COVID-19
Amyloidosis: AL,
SAA
FIGURE 308-3 Nephrotic syndrome. Different pathologic syndromes broken down into the idiopathic
and secondary causes. 70% of primary membranous nephropathy (MN) is associated with antibodies to
the integral subepithelial basement membrane antigen phospholipase A2
receptor (PLA2
R). The former
term for primary membrano-proliferative GN has been replaced by pathologic syndromes involving
complement deposition (C3 glomerulopathy and dense-deposit disease in children). AL amyloid is the
form of amyloidosis secondary to lambda light-chain deposition and SAA is the protein (serum amyloid
A) associated with chronic inflammatory diseases such as rheumatoid arthritis, familial Mediterranean
fever, and tuberculosis.
in the slit diaphragm, have been shown to be responsible for most cases
of hereditary nephrotic syndrome (see Table 308-2).
In children who have a serum albumin concentration <2 g/dL,
tissue ischemia may develop, causing a “nephrotic crisis,” in which
severe abdominal pain may be mistaken for a surgical abdomen. A
20-year-old presenting with NS may have MCD, FSGS, or membranous
nephropathy (MN).
Like MCD, MN exists as primary or secondary etiology. Whereas NS
is a cause of a hypercoagulable state, particularly when it is accompanied by severe hypoalbuminemia (<2 g/dL), MN is the NS most often
associated with renal vein thrombosis (RVT) for a number of reasons,
among them the urinary loss of antithrombin-3 and plasminogen, as
2284 PART 9 Disorders of the Kidney and Urinary Tract
Symptoms of lower urinary tract disorders are dysuria, urinary
frequency, urgency, incomplete emptying, hematuria that is most
pronounced at the beginning of the stream, as well as a poor urinary
stream. Among these disorders are urinary tract infection and prostatic
hypertrophy. Hematuria of recent onset noted in the fourth decade of
life or beyond should undergo a urologic evaluation and most likely
cystoscopic examination of the bladder. However, chronic hematuric
conditions may be associated with chronic glomerular disease such as
thin basement membrane, hereditary nephritis, or IgA nephropathy.
That is why it is so important to search for previous examinations such
as insurance, military, or employment exams done in the past to determine if hematuria was present in order to establish chronicity.
ACUTE KIDNEY INJURY
Acute kidney injury (AKI) is defined by the retention of nitrogenous
solutes such as urea, uric acid, and creatinine. The creatinine concentration goes up primarily related to the amount of water absorbed
along the nephron. Because the urea but not creatinine has a reabsorptive component, the clearance of urea is less than the clearance
of creatinine. With a constant catabolic rate, a decrease in glomerular
filtration alone will affect the BUN and creatinine proportionately. In
contrast, a disorder associated with enhanced urinary concentration
(high ADH), in which urea as well as water has increased reabsorption
in the process of concentrating the urine, the retention of urea nitrogen
exceeds that of creatinine, accounting for an elevated BUN-to-creatinine ratio. Oliguric or oligoanuric states are often characterized as
prerenal, meaning preglomerular vascular disease or low perfusion
states; renal, indicating intrinsic renal disease; or postrenal, indicating
obstructive nephropathy or uropathy (see Table 308-1).
Prerenal states are often related to a decreased perfusion pressure
to the glomerular capillaries or some other interference with filtration.
The differential diagnosis includes proliferative GN (the bloodless
capillary); a preglomerular vascular disease such as scleroderma or
thrombotic microangiopathy; the use of pressors for the maintenance
of blood pressure; vasoconstrictive substances including cocaine,
iodinated IV contrast media, hemoglobin or myoglobin, and certain
antibiotics like vancomycin, cyclosporine, and tacrolimus (calcineurin
inhibitors); other vasoconstrictive drugs like nonsteroidals; and renal
nerve stimulation. Hypercalcemia and hypoxia are also vasoconstrictive. Correcting hypoxemia has a diuretic effect.
Intrinsic Renal Disease All of these will decrease perfusion pressure and decrease GFR while stimulating sodium and water reabsorption.
Therefore, the characteristic urinary findings are low urinary sodium
excretion and concentrated urine. The urine sodium concentration is usually low and the urine to plasma creatinine concentration is usually >40.
The same result could occur in bilateral renal artery stenosis, heart failure,
and other circulatory collapse. If damage is done to the renal tubules, socalled intrinsic renal disease, there may or may not be oliguria and in
fact there could be polyuria (unresponsiveness to ADH), sodium-wasting,
potassium-wasting, and acid-base disorders, each of which may predominate. One of the most frequent causes of oliguric acute renal failure is
acute tubular necrosis (ATN), caused by gram-negative sepsis, hemodynamic collapse, hemoglobinuria or myoglobinuria, and medication or
toxin ingestion. Examples are crush injury, heroin and alcohol stupor, and
compartment syndrome. Drug causes include NSAIDs, aminoglycosides,
and chemotherapeutic drugs like cisplatinum and methotrexate.
Postrenal States Postrenal states accompanied by anuria suggest
complete obstruction to the flow of urine, while polyuria and bland
urinary sediment suggest incomplete obstruction combined with
ADH unresponsiveness. The fractional excretion of sodium is usually
>1–2%, whereas in oliguric prerenal syndromes the fractional excretion of sodium is usually <1%. Exception to the low sodium excretion
would be in the case of hyperchloremic metabolic alkalosis, where
chloride is being conserved and sodium excreted with bicarbonate.
Urinary tract obstruction is usually characterized by hydronephrosis
visualized on ultrasound images or large volumes of urine removed
by bladder catheterization, indicating bladder outlet obstruction.
Exceptions to finding hydronephrosis on an imaging study include the
extrinsic obstructive compression of the kidney or ureter in retroperitoneal disease; cases in which imaging was done too soon, for example
<4 days after obstruction; or when the patient was simultaneously
obstructed and volume depleted.
As mentioned earlier, acute tubular diseases that are not primarily
due to inflammation can be caused by intratubular obstruction, from
hyperoxaluric states, or by uric acid or phosphates in tumor lysis syndrome following chemotherapy for lymphoproliferative disorders.
Other drug therapies that cause tubular injury include cisplatinum,
ifosfamide, methotrexate, aminoglycosides, and amphotericin B, and
toxicity through exposure to heavy metals.
Kidney injury in the setting of systemic disease with dysfunction
in other organs includes the cardiorenal, pulmonary renal, and
hepatorenal syndromes. Other syndromes that typically involve the
kidney include febrile illness, systemic infection with septic shock,
hemodynamic collapse due to cytokines, or capillary leak syndrome.
These syndromes as well as the endothelial origins of thrombotic
microangiopathies and hemolytic uremic syndrome are shown in
Fig. 308-4. Obstetric patients with abruptio placenta may develop bilateral cortical necrosis and as a consequence, anuria, and often irreversible renal failure. In addition, patients with atheroembolic syndrome
can present with AKI or chronic progressive damage following an aortic catheterization. If the blood vessels catheterized involve the aortic
arch, an encephalopathic syndrome that can mimic uremic encephalopathy may follow. As many as 70% of patients with COVID-19 who
required ventilators during the early phase of the pandemic developed
multiorgan failure, including AKI. AKI may also be a risk for chronic
kidney disease following a COVID-19 infection.
CHRONIC KIDNEY DISEASE AND THE
UREMIC SYNDROME
Chronic kidney disease (CKD), progressing over months to years, can
be the long-term result of any of the previously mentioned diseases.
If the time course is unknown, other ways to diagnose CKD versus
TABLE 308-2 Hereditary and Congenital Diseases
HEREDITARY
GLOMERULAR DISEASES:
NEPHROTIC SYNDROME
OR RENAL FAILURE
HEREDITARY TUBULAR
DISEASES APOL1 CILIOPATHIES CHANNELOPATHIES
CONGENITAL
ANOMALIES
Podocyte mutations;
basement membrane
mutations; hereditary
nephritis; X-linked and
somatic mutations;
COL4A5; Allport’s
syndrome with hematuria
neurosensory hearing
loss, conus lentus; Fabry’s
disease (X-linked alphagalactosidase deficiency)
Fanconi’s syndrome
with renal glycosuria,
proximal tubule RTA,
hypophosphatemia,
hypouricemia; distal RTA
with hearing loss, renal
calcification; nephrogenic
diabetes insipidus;
hyper- or hypotensive
disorders with hypo- or
hyperkalemia; metabolic
alkalosis or acidosis
Mutant allele in
African-American
population, leading to
susceptibility to further
injury in many other
disorders including
diabetes mellitus
Autosomal dominant
and recessive polycystic
kidney disease;
medullary cystic kidneys
(metabolic acidosis and
salt-wasting); other
phenotypes
Gitelman’s and Bartter’s
syndromes; disorders of
eNaC and proton pumps
Unilateral agenesis;
dysgenetic disease;
medullary sponge kidney
(hematuria, stones, or
infection); horseshoe
kidneys (proteinuria);
malposition; ureteropelvic
obstruction; cystoureteral
reflux (proteinuria)
2285Approach to the Patient with Renal Disease or Urinary Tract Disease CHAPTER 308
a more recent kidney disorder are useful, for example, the finding of
bilaterally small kidneys on a renal ultrasound. Kidneys by this method
are normally 10–12 cm in length. Small kidneys, <8 cm, are likely atrophic with irreversibly low function; but in some cases of CKD, such as
diabetes, the kidneys may be large despite kidney failure. Remarkably,
even atrophic kidneys may still produce renin to sustain blood pressure
and erythropoietin to minimize anemia; however, due to low calcitriol
in CKD, patients develop secondary hyperparathyroidism. The normal
parathyroid gland weighing 25 mg would be limited in raising PTH,
such that very elevated PTH likely is in favor of CKD. Thinning of the
renal cortex is also a sign of chronicity.
DM accounts for approximately 50% of CKD patients that progress
to end-stage renal disease (ESRD). Other important causes leading to
ESRD are IgA nephropathy, ischemic nephropathy without proteinuria
manifesting after age 50 years with hypertension, and signs of other
large-vessel disease, such as intermittent claudication from peripheral
vascular disease, stroke, and coronary artery disease. In contrast, renal
arterial disease due to fibromuscular dysplasia, seen predominantly in
white women in the fourth decade of life, does not progress to renal
failure and is a treatable form of hypertension. Other arterial diseases
include polyarteritis nodosum (PAN) and, in medium-sized vessels,
a Kawasaki-like illness affecting children, which has had a thirtyfold
increase since the onset of COVID-19 as part of the multisystem
inflammatory syndrome.
Hereditary and congenital diseases of the kidney are shown in
Table 308-2. Autosomal dominant PCKD occurs in all ethnic populations. The patient may first show signs of cysts in late teenage years
with hypertension, urinary or cyst infection, or pain and bleeding. Kidney
stones may be seen. By the age of 30 years, individuals with the disorder
will have ultrasound-detectable cysts. The clinician should know that
• Increased right
atrial pressure
• > renal vein pressure
• Decreased GFR,
increased UP
• Decreased SV, CO BP
• Systemic vasodilation,
• Increased renal
vascular resistance
• Increased salt,
water retention
• Decreased GFR
Hepatorenal Syndrome Cardiorenal Syndrome
• Postcardiac, aortic cath
• Post-anticoagulation
• CNS encephalopathy
• Cholesterol microemboli to limbs
(blue toes, livido reticularis),
pancreas, retina
• Eosinophilia
Atheroembolic Syndrome
• Increased capillary leak of protein-rich fluid to ISF
• Dx: diffuse edema, shock, non-cardiogenic shock,
pulmonary edema
• Causes: sepsis, idiopathic, allergic, OHSS, poisonings,
toxins, IL-6, cytokines, burns
• Multi-organ failure, AKI
Capillary Leak Syndrome
• Low platelets, MAHA, schistocytes
• Low haptoglobin, high LDH
• Fibrin thrombi, endotheliosis, mesangiolysis
• HUS of childhood
• GI and bacterial toxins: Shigatoxin,
E. Coli O157:H7 (STEC)
• CNS involvement: TTP-ADAMTS13 antibodies
• Genetic: low complement C3, C4,Factors,H,I
• Antiphospholipid syndromes, ACL, anti-β2GP1
• Accelerated HBP, scleroderma
• Associated with SLE
• Pre-eclampsia
• Post-transplant syndromes
• Drugs: mitomycin, calcineurin inhibitors
Thrombotic Microangiopathies
• Long hx of aspirin, caffeine
acetaminophen, phenacetin,
or mixed APC
• Gastritis GI symptoms
• Chronic TIN
• Urothelial cancers
Analgesic Syndrome
• Goodpasture/antiGBM
• ANCA + vasculitis
• Other vasculitis
Cryoglobulinemia
SLE
IgA
Pulmonary Renal Syndrome Tumor Lysis Syndrome
• Increased SVR (SNS,
RAAS, ADH V1R)
Increased HR
• Decreased renal perfusion
pressure, RPF, GFR
• Increased Na and water
reabsorption, edema,
increased venous return
• Frank-Starling effects on CO
• Increased catabolic rate
• Encephalopathy, neuropathy
• Pericarditis
• Fluid overload, pulmonary edema, hypertension
• GI: dysgeusia, anorexia, weight loss, diarrhea
• Dry skin, pruritis
• Cell lysis-releases DNA
• 1 purine: 2 Phosphates
per dinucleotide
• Intratubular CaP
• Intratubular uric acid
obstruction
Uremic Syndrome
•
FIGURE 308-4 Categories of systemic or non-renal-based syndromes that involve the kidney and in advanced cases can cause the uremic syndrome requiring renal
replacement therapy. ACL, anticardiolipin antibodies; ADH V1R, antidiuretic hormone V1 receptor; anti-β2GP1, anti-beta-2-glycoprotein-1; APC, aspirin phenacetin caffeine;
BP, blood pressure; CaP, calcium phosphate crystals; CO, cardiac output; HUS, hemolytic uremic syndrome; IgA, immunoglobulin A; ISF, interstitial fluid; LDH, lactic
dehydrogenase; MAHA, microangiopathic hemolytic anemia; OHSS, ovarian hyperstimulation syndrome; RAAS, renin angiotensin aldosterone system; RPF, renal plasma
flow; SV, stroke volume; SNS, sympathetic nervous system; SVR systemic vascular resistance; TIN, tubulointerstitial nephritis; TTP, thrombotic thrombocytopenic purpura;
UP, urine protein.
2286 PART 9 Disorders of the Kidney and Urinary Tract
a diagnosis of PCKD requires multiple cysts in both kidneys. Cysts are
also found in the liver. The first manifestation of PCKD may be a cerebral hemorrhage, since berry aneurysms are present in a small subset
of patients with this disease, most commonly in the circle of Willis.
Hereditary nephritis with many variations includes the Alport
syndrome, involving a gene mutation (COL4A5, accounting for the
majority of cases) effecting the alpha 3 region of the noncollagenous
domain of type IV collagen in GBM. There is an X-linked pattern of
genetic transmission, where males may be most severely affected by
renal failure in middle age. The syndrome involves hematuria, neurosensory hearing loss, and ocular deformities of the lens. A predominant
symptom in hereditary nephritis is microscopic hematuria and the
pathologic correlate to this is thin basement membranes. It must be
distinguished from the less severe and more common related condition
known as thin basement membrane disease as a cause of hematuria.
Certain congenital abnormalities of the kidney, such as horseshoe
and ectopic kidneys, also shown in Table 308-2, consist of low nephron
numbers that may result in secondary FSGS. The condition known as
ureteral reflux is an abnormality involving the functional insertion of
the ureter into the muscular bladder, which normally closes off the
ureter upon bladder contraction. In reflux disease the ureter cannot
prevent retrograde flux of urine during micturition. In children this
may cause hypertension and, in some cases, secondary FSGS. Surgical
correction of the abnormality may be curative, but the child may outgrow it in adulthood in any case.
The stages of CKD are listed in Table 308-3 and are important in
terms of planning for renal replacement therapy (dialysis and transplantation), and for assessing and slowing the rate of progression,
defined as the decline in GFR over time. In CKD, the estimated GFR
(eGFR) is determined by the current stable serum creatinine, entered
into one of several equations derived from clinical trial data that
compared the subject’s value to actual measurements of GFR. For
example, the Modification of Diet in Renal Disease (MDRD) study
used a radioisotope (I125iothalamate) clearance to measure true GFR.
The equation contains additional factors such as age and sex to derive
the current eGFR, corrected for 1.73 m2
body-surface area. This value
of eGFR is not a creatinine clearance, nor a measurement of GFR.
There has been debate about the inclusion of corrective factors that
would alter the result from that equation, based on the patient’s ethnicity and race. For example, it has been recommended in some centers to
multiply the eGFR value by a factor of 1.2 in black patients in order to
correct for the perceived underestimate of GFR using the MDRD equation. There is considerable objection to making this correction, which
may have the effect of introducing bias based on race. Because the corrected eGFR will give a higher value to the GFR, there could be delays
in discussion of renal replacement therapy and in initiation of treatment. Consequently, the correction has fallen out of favor. Recently an
alternative, the Chronic Kidney Disease Epidemiology Collaboration
(CKD-EPI), has been used that excludes race as a parameter. Another
method of calculating GFR uses cystatin-C.
In the course of CKD, the clinician must evaluate the patient for
symptoms and signs of worsening renal function. When the eGFR is
<15–20 mL/min, the patient should already have had conversations
about choices of eventual treatment and, if indicated, surgical preparation for peritoneal or hemodialysis. Attention should be given to the
sensitive topic of transition to a lifesaving but mechanical procedure. It
is also important to discuss transplantation and issues of timing. The
ethical standard is for separate clinicians to evaluate the recipient and
donor of a kidney transplant. Confidentiality and privacy are essential. Very importantly, access to transplantation has not been equally
offered to minority populations and it is incumbent on the clinician to
avoid bias by discussing the option with every patient.
Symptoms of CKD are often nonspecific and include fatigue,
weakness, loss of appetite and taste, weight loss, mood changes, and
metabolic encephalopathy that may involve cognitive changes such as
decline in executive function and the ability to calculate and remember. Other symptoms are peripheral and autonomic neuropathies and
sleep and movement disorders such as restless legs and asterixis or
myoclonus. Patients with AKD lose their ability to concentrate the
urine, and therefore have an obligate urine output of approximately
2 L. This results in nocturia, since the bladder fills during the night.
Ironically, the loss of nocturia may be sensed by the patient as an
improvement of symptoms but actually indicates worsening oliguria.
Pruritis commonly occurs. Clinical issues include changes in medications and doses. The full uremic syndrome is characterized by severe
hypertension, the above-mentioned encephalopathic manifestations,
GI bleeding, pericarditis, severe electrolyte disturbances, particularly hyperkalemia, and secondary hyperparathyroidism. Anemia is
frequently present and though it may be due to iron deficiency or
decreased erythropoietin, other causes of anemia should be investigated. Patients respond well to erythropoietic stimulating agents, with
the goal of therapy >10 g/dL but <12 g/dL. Notably, not all patients are
anemic. For example, some patients with urinary tract obstruction,
polycystic kidney disease, renal vascular disease, and renal cell carcinoma may in fact have erythrocytosis.
In nephrotic syndrome, heavy proteinuria may persist throughout
the course of CKD and carries a worse prognosis. In all kidney diseases, including the nephritic processes, renal disease may progress to
late stages even when the acute inflammation has subsided. However,
the underlying mechanisms of progressive renal failure involve inflammatory pathways (reflected in elevated levels of C-reactive protein and
erythrocyte sedimentation rate in CKD), emphasizing the importance
of managing risk factors for cardiovascular disease, such as hypertension, smoking, hyperlipidemias, diabetes, and obesity early in the
course of CKD.
Some chronic renal syndromes may present with predominant
tubular dysfunction, including genetic diseases known as channelopathies. Examples are the depletion of electrolytes such as phosphorus
and potassium and proximal RTA due to Fanconi’s syndrome, mentioned above; hypokalemic alkalosis and volume depletion in Bartter’s
syndrome (mutations resulting in abnormal loop of Henle function);
and electrolyte losses in Gitelman’s, a defect in the thiazide-sensitive
sodium-chloride transporter. Gitelman’s also causes hypochloremic
hypokalemic metabolic alkalosis. Bartter’s and Gitelman’s can be distinguished by examining the urine for the usual solutes regulated by
these transporters. Thus, Bartter’s is associated with hypercalciuria
TABLE 308-3 Stages of Chronic Kidney Disease
STAGES OF CKD,
ABNORMALITY > 3 MONTHS RANGE OF eGFR CLINICAL FEATURES IMPORTANCE
1 >60 mL/min/1.73 m2 Abnormal urinalysis, abnormal
renal imaging
Risk of progression to later stages increases with increased proteinuria
and dependent on cause of disease
2 >60 mL/min/1.73 m2 Abnormal urinalysis, abnormal
renal imaging
Mild risk of progression to later stages increases with increased
proteinuria and dependent on cause of disease
3a 45–60 mL/min/1.73 m2 Cardiovascular disease or other
organ damage
Moderate risk of progression of disease. Pay attention to other vascular
risk factors, high BP, lipids, smoking, weight
3b 30–45 mL/min/1.73 m2 Proteinuria High risk of progression
4 15–30 mL/min/1.73 m2 High likelihood of progression to ESRD, need preparation and education
regarding choices for RRT including transplant and dialysis
5 <15 mL/min/1.73 m2 Highest risk of requiring RRT
2287Cell Biology and Physiology of the Kidney CHAPTER 309
and the inability to put out a concentrated urine, whereas Gitelman’s is
associated with hypocalciuria and preserved ability to concentrate the
urine. Fanconi’s syndrome results in hypokalemic acidosis and can be
distinguished from distal RTA, which does not associate with the loss
of glucose, amino acids, and phosphate in the urine.
Disorders involving the collecting duct and its transporters of
sodium, potassium, and acid base can result in syndromes that also
suggest certain diagnoses. For example, polyuria due to inappropriate free water losses and insensitive to ADH is characteristic of
nephrogenic diabetes insipidus and it is common to see simultaneous defects in potassium secretion and hydrogen ion secretion, with
hypertension suggesting blockade of one of the sodium regulators of
ENaC. These disorders are usually associated with hyporenin and/
or hypoaldosterone states, which include UTO, type 4 RTAs in DM,
amyloidosis, or Addison’s disease. In contrast, hypokalemic metabolic
alkalosis with volume expansion may suggest an adrenal adenoma,
unilateral renal artery stenosis, ACTH-secreting tumors, licorice abuse,
or potassium-sparing diuretics.
Renal Masses Patients with renal cell carcinoma may have been
diagnosed via an incidental finding in an abdominal imaging study, or
sometimes by a palpable mass best felt with the patient supine, usually
a thin patient but occasionally a very large protruding mass. Very large
masses or multiple masses that are easily palpable may represent cystic diseases of the kidney, including polycystic kidney disease (PKD)
or even a single cyst, versus a congenital ureteral pelvic obstruction.
Other times, a renal cell carcinoma can present as anemia, possibly
caused by hematuria, or as back pain associated with metastatic lytic
vertebral lesions. Metastases may involve the lungs and the bone marrow as well.
Imaging and Renal Biopsy Indications For hematuric syndromes, imaging may add valuable information, particularly in the
patient who has heavy bleeding or blood clots in the urine. Renal
pathology may be detected as an abdominal mass, as in the case of
renal cell carcinoma, chronic urinary tract obstruction, or cystic diseases of the kidney including polycystic kidney disease (PKD) and
simple cyst. If the patient has a known history of tubular sclerosis or the
finding of skin fibroadenoma, one might identify a renal mass found
on CT imaging as an angiomyolipoma.
The renal ultrasound is efficacious in determining the size and
symmetry of the kidneys and in excluding urinary obstruction. It is
helpful in detecting renal cysts or mass, but less useful in kidney stone
disease. Ultrasound is not as accurate a tool for angiomyolipomas.
The renal-limited noncontrast CT scan is the standard test for nephrolithiasis but carries the risk of accumulative radiation. MRI is often
useful in evaluating and following renal masses, including renal cell
carcinoma. The patient with renal disease may develop the complication of systemic sclerosis after receiving gadolinium; new contrast
media to replace it are emerging. CT iodinated contrast media remain a
problem, particularly in the patient with vascular disease of the kidney.
Radioisotope scanning is useful in demonstrating the percentage of
renal function coming from each kidney. Finally, in many of the diseases discussed above, diagnosis ultimately depends on renal biopsy
and pathologic evaluation.
■ FURTHER READING
Glassock RJ: Kidney biopsy is required for nephrotic syndrome with
PLA2R+ and normal kidney function: Commentary. Kidney360
1:894, 2020.
Harding K et al: Health disparities in kidney transplantation for
African Americans. Am J Nephrol 46:165, 2017.
Levey AS et al: Nomenclature for kidney function and disease: report
of Kidney Disease: Improving Global Outcomes (KDIGO) Consensus
Conference. Kidney Int 97:1117, 2020.
Reidy KJ et al: Genetic risk of APOL1 and kidney disease in children
and young adults of African ancestry. Curr Opin Pediatr 30:252,
2018.
Ronco C: Acute kidney injury biomarkers: Are we ready for the
biomarker curve? Cardiorenal Med 9:354, 2019.
Cell Biology and
Physiology of the Kidney
Alfred L. George, Jr., Eric G. Neilson
309
The kidney is one of the most highly differentiated organs in the body.
At the conclusion of embryologic development, nearly 30 different cell
types form a multitude of filtering capillaries and segmented nephrons
enveloped by a dynamic interstitium. This cellular diversity modulates
a variety of complex physiologic processes. Endocrine functions, the
regulation of blood pressure and intraglomerular hemodynamics,
solute and water transport, acid-base balance, and removal of drug
metabolites are all accomplished by intricate mechanisms of renal
response. This breadth of physiology hinges on the clever ingenuity of
nephron architecture that evolved as complex organisms came out of
water to live on land.
EMBRYOLOGIC DEVELOPMENT
Kidneys develop from intermediate mesoderm under the timed
or sequential control of a growing number of genes, described in
Fig. 309-1. The transcription of these genes is guided by morphogenic cues that invite two ureteric buds to each penetrate bilateral
metanephric blastema, where they induce primary mesenchymal cells
to form early nephrons. The two ureteric buds emerge from posterior
nephric ducts and mature into separate collecting systems that eventually form a renal pelvis and ureter. Induced mesenchyme undergoes mesenchymal epithelial transitions to form comma-shaped
bodies at the proximal end of each ureteric bud leading to the
formation of S-shaped nephrons that cleft and enjoin with penetrating endothelial cells derived from sprouting angioblasts. Under the
influence of vascular endothelial growth factor A (VEGF-A), these
penetrating cells form capillaries with surrounding mesangial cells
that differentiate into a glomerular filter for plasma water and solute.
The ureteric buds branch, and each branch produces a new set of
nephrons. The number of branching events ultimately determines
the total number of nephrons in each kidney. There are ~900,000
glomeruli in each kidney in normal-birth-weight adults and as few as
225,000 in low-birth-weight adults, with the latter producing numerous comorbid risks.
Glomeruli evolve as complex capillary filters with fenestrated endothelia under the guiding influence of VEGF-A and angiopoietin-1
secreted by adjacently developing podocytes. Epithelial podocytes
facing the urinary space envelop the exterior basement membrane supporting these emerging endothelial capillaries. Podocytes are partially
polarized and periodically slough into the urinary space by epithelialmesenchymal transition and, to a lesser extent, apoptosis, only to be
replenished by migrating parietal epithelia from Bowman capsule.
Impaired replenishment results in heavy proteinuria. Podocytes attach
to the basement membrane by special foot processes and share a slitpore membrane with their neighbor. The slit-pore membrane forms
a filter for plasma water and solute by the synthetic interaction of
nephrin, annexin-4, CD2AP, FAT, ZO-1, P-cadherin, podocin, TRPC6,
PLCE1, and Neph 1-3 proteins. Mutations in many of these proteins
also result in heavy proteinuria. The glomerular capillaries are embedded in a mesangial matrix shrouded by parietal and proximal tubular
epithelia forming Bowman capsule. Mesangial cells have an embryonic
lineage consistent with arteriolar or juxtaglomerular cells and contain
contractile actin-myosin fibers. These mesangial cells make contact
with glomerular capillary loops, and their local matrix holds them in
condensed arrangement.
Between nephrons lies the renal interstitium. This region forms a
functional space surrounding glomeruli and their downstream tubules,
which are home to resident and trafficking cells such as fibroblasts,
dendritic cells, occasional lymphocytes, and lipid-laden macrophages.
The cortical and medullary peritubular capillaries, which siphon off
2288 PART 9 Disorders of the Kidney and Urinary Tract
solute and water following tubular reclamation of glomerular filtrate,
are also part of the interstitial fabric as well as a web of connective
tissue that supports the kidney’s emblematic architecture of folding
tubules. The relational precision of these structures determines the
unique physiology of the kidney.
Each nephron is partitioned during embryologic development
into a proximal tubule, descending and ascending limbs of the loop
of Henle, distal tubule, and the collecting duct. These classic tubular
segments build from subsegments lined by highly unique epithelia
serving regional physiology. All nephrons have the same structural
components, but there are two types whose structures depend on
their location within the kidney. The majority of nephrons are
cortical, with glomeruli located in the mid-to-outer cortex. Fewer
nephrons are juxtamedullary, with glomeruli at the boundary of the
cortex and outer medulla. Cortical nephrons have short loops of
Henle, whereas juxtamedullary nephrons have long loops of Henle.
There are critical differences in blood supply as well. The peritubular
capillaries surrounding cortical nephrons are shared among adjacent
nephrons. By contrast, juxtamedullary nephrons depend on individual capillaries called vasa recta that run alongside the long loops of
Henle. Cortical nephrons perform most of the glomerular filtration
because there are more of them and because their afferent arterioles
are larger than their respective efferent arterioles. The juxtamedullary
nephrons, with longer loops of Henle, create an osmotic gradient for
concentrating urine. How developmental instructions specify the
differentiation of all these unique epithelia among various tubular
segments is still unknown.
DETERMINANTS AND REGULATION OF
GLOMERULAR FILTRATION
Renal blood flow normally drains ~20% of the cardiac output, or
1000 mL/min. Blood reaches each nephron through the afferent arteriole leading into a glomerular capillary where ultrafiltration forms
the tubular fluid. The distal ends of the glomerular capillaries coalesce
to form an efferent arteriole leading to the first segment of a second
capillary network (cortical peritubular capillaries or medullary vasa
recta) surrounding the tubules (Fig. 309-2A). Thus, nephrons have two
capillary beds arranged in a series separated by the efferent arteriole
that regulates the hydrostatic pressure in both capillary beds. The distal
capillaries empty into small venous branches that coalesce into larger
veins to eventually form the renal vein.
The hydrostatic pressure gradient across the glomerular capillary
wall is the primary driving force for glomerular filtration. Oncotic
pressure within the capillary lumen, determined by the concentration
of unfiltered plasma proteins, partially offsets the hydrostatic pressure
gradient and opposes filtration. As the oncotic pressure rises along
the length of the glomerular capillary, the driving force for filtration
falls to zero en route to the efferent arteriole. Approximately 20% of
the renal plasma flow is filtered into Bowman space, and the ratio of
glomerular filtration rate (GFR) to renal plasma flow determines the
filtration fraction. Several factors, mostly hemodynamic, contribute to
the regulation of filtration under physiologic conditions.
Although glomerular filtration is affected by renal artery pressure,
this relationship is not linear across the range of physiologic blood
pressures due to autoregulation of GFR. Autoregulation of glomerular
filtration is the result of three major factors that modulate either afferent or efferent arteriolar tone; these include an autonomous vasoreactive (myogenic) reflex in the afferent arteriole, tubuloglomerular
feedback (TGF), and angiotensin II–mediated vasoconstriction of the
efferent arteriole. The myogenic reflex is a first line of defense against
fluctuations in renal blood flow. Acute changes in renal perfusion pressure evoke reflex constriction or dilatation of the afferent arteriole in
response to rising or falling pressure, respectively. This phenomenon
helps protect the glomerular capillary from sudden changes in systolic
pressure.
TGF changes the rate of filtration and tubular flow by reflex vasoconstriction or dilatation of the afferent arteriole. TGF is mediated
by specialized cells in the thick ascending limb of the loop of Henle
called the macula densa that act as sensors of solute concentration
and tubular fluid flow rate. With high tubular flow rates, a proxy for
an inappropriately high filtration rate, greater solute delivery to the
macula densa (Fig. 309-2B) evokes vasoconstriction of the afferent
arteriole causing GFR to return toward normal. One component of
the soluble signal from the macula densa is adenosine triphosphate
(ATP) released by the cells during increased NaCl reabsorption. ATP
is metabolized in the extracellular space to generate adenosine, a potent
vasoconstrictor of the afferent arteriole. During conditions associated
with a fall in filtration rate, a lower rate of solute delivery to the macula
densa attenuates TGF, allowing afferent arteriolar dilatation and restoring GFR to normal levels. Angiotensin II and reactive oxygen species
enhance TGF, whereas nitric oxide (NO) blunts TGF. A distinct feedback mechanism may exist between the connecting tubule and GFR
in which high Na+ delivery evokes afferent arteriolar dilation possibly
mediated by prostaglandins.
The third component underlying autoregulation of GFR involves
angiotensin II. During states of reduced renal blood flow, renin is
released from granular cells within the wall of the afferent arteriole
near the macula densa in a region called the juxtaglomerular apparatus
(Fig. 309-2B). Renin, a proteolytic enzyme, catalyzes the conversion of
angiotensinogen to angiotensin I, which is subsequently converted to
angiotensin II by angiotensin-converting enzyme (ACE) (Fig. 309-2C).
Angiotensin II evokes vasoconstriction of the efferent arteriole, and
the resulting increased glomerular hydrostatic pressure elevates GFR
to normal levels.
Pax2
Gdnf/Ret
Lhx1
Cited1
Six1
Itga8/Itgb1
Fgfr2
Hoxa11/Hoxd11
Foxd1
Slit2/Robo2
Wt1
Brn1
DII1
Jag1
Lhx1
Wnt4
Emx2
Fgf8
Notch2
Notch1
Lgr5
Nephrogenesis
Hnf1b
VEGF-A/Kdr (Flk-1) Tcf21
Foxc2
Lmx1b
Itga3/Itgb1 Pdgfb/Pdgfbr
Cxcr4/Cxcl12
Nphs1
Nck1/Nck2
Cd36
CD2AP
Neph1
Nphs2
Lamb2
Mature
glomerulus
Capillary
loop
Comma-shape S-shape
Pretubular
aggregation
Ureteric bud induction
and condensation
FIGURE 309-1 Genes controlling renal nephrogenesis. A growing number of genes have been identified at various stages of glomerulotubular development in the
mammalian kidney. The genes listed have been tested in various genetically modified mice, and their location corresponds to the classical stages of kidney development
postulated by Saxen in 1987.
2289Cell Biology and Physiology of the Kidney CHAPTER 309
MECHANISMS OF RENAL TUBULAR
TRANSPORT
The renal tubules are composed of highly differentiated epithelia that
vary in morphology and function along the nephron (Fig. 309-3). The
cells lining the various tubular segments form monolayers connected
to one another by a specialized region of the adjacent lateral membranes called the tight junction. Tight junctions form an occlusive barrier that separates the lumen of the tubule from the interstitial spaces
surrounding the tubule and also apportions the cell membrane into
discrete domains: the apical membrane facing the tubular lumen and
the basolateral membrane facing the interstitium. This regionalization
allows cells to allocate membrane proteins and lipids asymmetrically.
Owing to this feature, renal epithelial cells are said to be polarized.
The asymmetric assignment of membrane proteins, especially proteins
mediating transport processes, provides the machinery for directional
movement of fluid and solutes by the nephron.
■ EPITHELIAL SOLUTE TRANSPORT
There are two types of epithelial transport. Movement of fluid and
solutes sequentially across the apical and basolateral cell membranes
(or vice versa) mediated by transporters, channels, or pumps is called
cellular transport. By contrast, movement of fluid and solutes through
the narrow passageway between adjacent cells is called paracellular
transport. Paracellular transport occurs through tight junctions, indicating that they are not completely “tight” or occlusive. Indeed, some
epithelial cell layers allow rather robust paracellular transport to occur
(leaky epithelia), whereas other epithelia have more restrictive tight
junctions (tight epithelia). In addition, because the ability of ions to
flow through the paracellular pathway determines the electrical resistance across the epithelial monolayer, leaky and tight epithelia are also
referred to as low- or high-resistance epithelia, respectively. The proximal tubule contains leaky epithelia, whereas distal nephron segments,
such as the collecting duct, contain tight epithelia. Leaky epithelia are
most well suited for bulk fluid reabsorption, whereas tight epithelia
allow for more refined control and regulation of transport.
■ MEMBRANE TRANSPORT
Cell membranes are composed of hydrophobic lipids that repel water
and aqueous solutes. The movement of solutes and water across cell
membranes is made possible by discrete classes of integral membrane
proteins, including channels, pumps, and transporters. These different
mechanisms mediate specific types of transport activities, including
Renin
ACE
ACE2
C
Angiotensinogen
Asp-Arg-Val-Tyr-IIe-His-Pro-Phe-His-Leu - Val-IIe-His
Angiotensin I
Asp-Arg-Val-Tyr-IIe-His-Pro-Phe - His-Leu
Angiotensin II
Asp-Arg-Val-Tyr-IIe-His-Pro-Phe
Angiotensin (I-VII)
Asp-Arg-Val-Tyr-IIe-His-Pro
Collecting
duct
B
A
Peritubular
capillaries
Distal
convoluted
tubule
Macula
densa
Renin-secreting
granular cells
Peritubular
venules
Proximal
convoluted tubule
Proximal
tubule
Bowman
capsule
Efferent
arteriole
Efferent
arteriole
Afferent
arteriole
Afferent
arteriole
Glomerulus
Glomerulus
Proximal
tubule
Thick
ascending
limb
Thick
ascending
limb
Collec
duc
Distal
convolute
tubule
Peritubular
venules
man
sule
riole
Proximal
tubule
Thic
ascend
limb
la
a
nt
le
nt
le
FIGURE 309-2 Renal microcirculation and the renin-angiotensin system. A. Diagram illustrating relationships of the nephron with glomerular and peritubular capillaries.
B. Expanded view of the glomerulus with its juxtaglomerular apparatus including the macula densa and adjacent afferent arteriole. C. Proteolytic processing steps in the
generation of angiotensins.
2290 PART 9 Disorders of the Kidney and Urinary Tract
active transport (pumps), passive transport (channels), facilitated diffusion (transporters), and secondary active transport (cotransporters).
Active transport requires metabolic energy generated by the hydrolysis
of ATP. Active transport pumps are ion-translocating ATPases, including the ubiquitous Na+/K+-ATPase, the H+-ATPases, and Ca2+-ATPases.
Active transport creates asymmetric ion concentrations across a cell
membrane and can move ions against a chemical gradient. The potential energy stored in a concentration gradient of an ion such as Na+
can be used to drive transport through other mechanisms (secondary
active transport). The movement of solutes through a membrane
protein by simple diffusion is called passive transport. This activity is
mediated by channels created by selectively permeable membrane proteins, and it allows solute or water to move across a membrane driven
by favorable concentration gradients or electrochemical potential. Facilitated diffusion is a specialized type of passive transport mediated by
simple transporters called carriers or uniporters. For example, hexose
transporters such as GLUT2 mediate glucose transport by tubular cells.
These transporters are driven by the concentration gradient for glucose that is highest in extracellular fluids and lowest in the cytoplasm
due to rapid metabolism. Many other transporters operate by translocating two or more ions/solutes in concert either in the same direction
(symporters or cotransporters) or in opposite directions (antiporters or
exchangers) across the cell membrane. The movement of two or more
ions/solutes may produce no net change in the balance of electrostatic
charges across the membrane (electroneutral), or a transport event may
alter the balance of charges (electrogenic). Several inherited disorders
of renal tubular solute and water transport occur as a consequence of
mutations in genes encoding a variety of channels, transporter proteins, and their regulators (Table 309-1).
SEGMENTAL NEPHRON FUNCTIONS
Each anatomic segment of the nephron has unique characteristics
and specialized functions enabling selective transport of solutes and
water (Fig. 309-3A). Through sequential events of reabsorption and
secretion along the nephron, tubular fluid is progressively conditioned
into urine. Knowledge of the major tubular mechanisms responsible
for solute and water transport is critical for understanding hormonal
regulation of kidney function and the pharmacologic manipulation of
renal excretion.
PROXIMAL TUBULE
The proximal tubule is responsible for reabsorbing ~60% of filtered
NaCl and water, as well as ~90% of filtered bicarbonate and most critical nutrients such as glucose and amino acids. The proximal tubule
uses both cellular and paracellular transport mechanisms. The apical
membrane of proximal tubular cells has an expanded surface area
available for reabsorption created by a dense array of microvilli called
the brush border, and leaky tight junctions enable high-capacity fluid
reabsorption.
Solute and water pass through these tight junctions to enter the
lateral intercellular space where absorption by the peritubular capillaries occurs. Bulk fluid reabsorption by the proximal tubule is
driven by high oncotic pressure and low hydrostatic pressure within
the peritubular capillaries. Cellular transport of most solutes by the
proximal tubule is coupled to the Na+ concentration gradient established by the activity of a basolateral Na+/K+-ATPase (Fig. 309-3B).
This active transport mechanism maintains a steep Na+ gradient by
keeping intracellular Na+ concentrations low. Solute reabsorption from
the tubular lumen is coupled to the Na+ gradient by Na+-dependent
Distal
convoluted
Proximal tubule
tubule
Thick ascending
limb
Cortical
collecting
duct
Connecting
tubule SGLT2
inhibitors
Loop of Henle:
MEDULLA
A
CORTEX
Thin descending
limb
Thin ascending
limb Inner medullary
collecting duct
Macula densa
Bowman
capsule
Vein
Artery
PROXIMAL TUBULE
Lumen Interstitium
HPO4 + H
H2PO4
HCO3 + H
H2CO3 H2CO3
H2O + CO2 CO2
Na
H
Na
H
H
Cl
Formate
3Na
2K
H2O
NH4
Formic
acid
carbonic
anhydrase
carbonic
anhydrase
NH3
H2O, solutes
Na
Na
Na
Amino
acids
Amino
acids
Na
HCO3
Cl
K
3Na
2K
Glucose
Phosphate
Glucose
Apical Basolateral
B
FIGURE 309-3 Transport activities of the major nephron segments. Representative cells from five major tubular segments are illustrated with the lumen side (apical
membrane) facing left and interstitial side (basolateral membrane) facing right. A. Overview of entire nephron. B. Proximal tubular cells. C. Typical cell in the thick ascending
limb of the loop of Henle. D. Distal convoluted tubular cell. E. Cortical collecting duct cells. F. Typical cell in the inner medullary collecting duct. The major membrane
transporters, channels, and pumps are drawn with arrows indicating the direction of solute or water movement. For some events, the stoichiometry of transport is indicated
by numerals preceding the solute. Targets for major diuretic agents are labeled. The actions of hormones are illustrated by arrows with plus signs for stimulatory effects
and lines with perpendicular ends for inhibitory events. The dashed line indicates water impermeability of cell membranes in the thick ascending limb and distal convoluted
tubule.
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