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11/29/2023

Ultrastructure of DCT
• Similar to PCT
– Lateral cell
interdigitations
– Large numbers
of mitochondria

• BUT lacks a
brush border
• Na+/K+ ATPase
in basolateral
membrane
• Drives
exchange of
Na+ and K+
or H+ at the
apical
surface

46

Juxtaglomerular apparatus
• Specialization of the
glomerular afferent
arteriole and DCT of
the same nephron
• Regulation of
systemic blood
pressure via reninangiotensinaldosterone system
(RAAS)
• Composed of:

DCT comes in close proximity to
glomerulus. DCT cells become
modified to macula densa
Juxtaglomerular cells of the
afferent arteriole

– (1) juxtaglomerular
cells of the afferent
arteriole
– (2) macula densa of
DCT
– (3) extraglomerular
mesangial cells

Lacis cells

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Juxtaglomerular apparatus (JGA)
• Macula densa are
darker staining, taller
epithelial cells of the
DCT located adjacent to
vascular pole of
glomerulus
• Juxtaglomerular cells
are modified smooth
muscle cells of afferent
arteriole just before
entering glomerulus
• Extraglomerular
mesangial cells lie
between afferent and
efferent arterioles and
macula densa

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Renin-Angiotensin-Aldosterone System
•

JGA acts as both baroreceptor and
chemoreceptor
– Macula densa detects decreased sodium
concentration of fluid in DCT – indicates
decreased glomerular filtration rate (GFR)
– Juxtaglomerular cells detect decreased
blood pressure in afferent arteriole

 secretion of renin from juxtaglomerular cells
• Renin (enzyme) converts angiotensinogen
to angiotensin I in blood
• Angiotensin converting enzyme (ACE) in the
lung converts angiotensin I to angiotensin II
• Angiotensin II raises BP by: (1) peripheral
vasoconstriction, (2) promoting release of
aldosterone, (3) promoting Na+ (and water)
reabsorption in DCT
expands plasma volume & increases BP

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Macula densa role: baroreceptor, will recognize pressure and also osmoreceptor

Renal medulla
• Consists of closely
packed tubules of two
types:
• (1) the loop of Henle and
• (2) the collecting
tubules and ducts
• Also contains the vasa
recta (capillary network
around loop of Henle)
• Collecting ducts empty at
the papilla into the pelvicalyceal system

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Loop of Henle
• Limbs of loops of
Henle are
closely
associated with
the capillary
loops of the
vasa recta in the
medulla
• vasa recta
recovers water
from medullary
interstitium and
carries it to
general
circulation
maintains high
ion

55

Medulla
• Thin limbs lined by a simple
squamous epithelium
– Similar to capillaries, but no
erythrocytes in lumen

• Thick limbs lined by a low
cuboidal epithelium
• Collecting tubules lined by
low cuboidal epithelium
similar to thick ascending
limb
• Collecting ducts lined by
cuboidal to columnar
epithelium
– Large diameter

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Collecting tubules and ducts
• Collecting tubules (connecting
segment) join distal convoluted tubule
to collecting duct
– Several collecting tubules empty into
each collecting duct

• Collecting ducts are long straight
tubules that connect nephron to renal
papilla
– Collecting ducts descend through
cortex in parallel bundles known as
medullary rays
– Ducts progressively merge in medulla
to form ducts of Bellini, which drain
urine from papilla into pelvis
• Renal pelvis lined by transitional
epithelium (extension of ureter)

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Renal Papilla

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Urine Concentration
• Epithelial cells of collecting tubules and ducts have tight
junctions to retain water
• Antidiuretic hormone (ADH, vasopressin) secreted by
pituitary gland in response to dehydration increases
water permeability in collecting tubules and ducts
– water flows into hyperosmolar medulla
– results in passive water reabsorption from filtrate  more
concentrated urine
– vasa recta returns water to circulation

• Hyperosmolarity of medulla produced by action of loop
of Henle and passive diffusion of urea into interstitium
from collecting duct
• Hyperosmolarity of medulla and ADH provide means of
making urine that is hyperosmotic to plasma, i.e.
conserving water

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Lower urinary tract
• Includes renal pelvis and
calyces, ureters, urinary
bladder, urethra
• Passage/storage of urine – NO
modification after leaving
kidney
• Ureter
– Muscular tubes carry urine
from kidney to bladder
– Lined by transitional epithelium
(AKA urothelium)
– Lamina propria underlies
epithelium
– 2-3 layers of smooth muscle
(may be difficult to distinguish
from each other)
– Outer layer is adventitia

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Urinary Bladder
•
•
•
•

Lined by transitional epithelium
Substantial elastic fibers in lamina propriasubmucosa
3 variably distinct layers of smooth muscle
Outer adventitia

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Urethra
• Passage from bladder
to external
• Short in females; long
penile urethra in males
• Transitional epithelium
near bladder 
stratified cuboidal or
pseudostratified
columnar  stratified
squamous at the
external orifice
• Paraurethral glands in
subepithelial stroma
produce mucoid
secretion

Can see change from transitional epithelium to cuboidal

At external opening → stratified squamous
Keeps area lubricated; is tougher epithelium
Near the opening → stratified cuboidal or
pseudostratified columnar
Near bladder is transitional epithelium

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Renal Disease
• Disease of the kidney are divided into those that affect four
basic anatomic components
–
–
–
–

Glomeruli
Tubules
Interstitium
Blood vessels

• Damage to one component often secondarily affects another
• All forms of chronic disease ultimately damage all four
anatomic components, culminating in end stage kidney
disease

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Clinical Manifestations of Renal Disease
• Azotemia refers to an elevation of blood urea nitrogen and
creatinine levels and is largely related to decreased
glomerular filtration rate (GFR)
– Prerenal azotemia refers to the occurrence of azotemia from
conditions that exert their effect prior to the formation of urine
and in the absence of parenchymal damage
• hypoperfusion of the kidneys which decreases GFR (e.g. shock)

– Postrenal azotemia refers to the occurrence of azotemia from
conditons that exert their effect after the formation of urine
• urine flow is obstructed below level of kidney (e.g. calculus)

• Uremia occurs when azotemia progresses and is
characterized not only by failure of renal excretory function
but also metabolic and endocrine alterations
– Uremic gastritis, peripheral neuropathy, pericarditis

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Uremia → seeing uric damage; ulceration on tongue; mineralization on lining of stomach; all
damage that excess uric acid can do
Most common is prerenal azotemia: can result from shock, hypotension;
Exam: absence of parenchymal damage in prerenal azotemia

Major Renal Syndromes
•

Acute nephritic syndrome

•

Nephrotic Syndrome

– glomerular syndrome; acute onset hematuria, mild to moderate proteinuria,
azotemia, edema, hypertension
– glomerular syndrome; severe proteinuria, hypoalbuminemia, severe edema,
hyperlipidemia, lipiduria

•

Asymptomatic hematuria or proteinuria

•

Rapidly progressive glomerulonephritis

•

Acute renal failure

– Manifestation of subtle or mild glomerular abnormalities
– loss of renal function in days or few weeks; microscopic hematuria and red blood
cells casts
– oligouria or anuria; recent azotemia; results from lesions to any of 4 anatomic
components of the kidney

•

Chronic renal failure

•

Urinary tract infection

•

Nephrolithiasis

– prolonged signs of uremia; end result of all chronic renal diseases
– bacteriuria and pyuria; pyelonephritis or cystitis
Nephritis of pelvic area

Gastric ulcers, hemorrhages Anemia due to lack
of erythropoietin

– stones; signs include renal colic, hematuria
In urethra, kidney, etc.

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Glomerular Diseases

•Glomerular diseases are a
major problem in nephrology
•Chronic glomerulonephritis
(GN) is one of most common
causes of chronic kidney
disease
•Nephrin is the major
glycoprotein component of the
slit diaphragms and maintains
the glomerular barrier function

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Pathogenesis of Glomerular Diseases
• Primary glomerular diseases are those in which the kidney
is the only or predominant organ involved
• Secondary glomerular diseases are those in which glomeuli
are injured in the course of systemic diseases
• Immune mechanisms underlie most types of primary
glomerular diseases and many secondary glomerular
diseases
• Two forms of antibody-associated injury
– Injury resulting from deposition of soluble circulating antigenantibody complexes in glomerulus
– Injury by antibodies reacting in situ within the glomerulus, either
with intrinsic fixed glomerular antigens or with extrinsic
molecules planted within the glomerulus

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Nephritis caused by circulating immune complexes
• Complexes are formed in circulation and trapped in the
glomeruli where they activate complement and recruit
leukocytes
• Glomerular lesions usually consist of leukocyte infiltration
(exudation) into glomeruli and proliferation of endothelial,
mesangial, and parietal epithelial cells
• Electron microscopy reveals immune complexes as electrondense deposits or clumps that lie at one of three sites:
– in the mesangium,
– between endothelial cells and GBM (subendothelial)
– between outer surface of GBM and podocytes (subepithelial)

• Using fluorescent labeling with anti-Ig or anti-complement
antibodies, the immune complexes are seen as granular
deposits throughout the glomerulus

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Nephritis caused by in situ immune complexes
• Antibodies react directly with fixed or planted antigens in the
glomerulus
• Anti-GBM antibody glomerulonephritis
– Antibodies directed against fixed antigens of GBM
– Deposition of these antibodies creates a linear pattern of staining
when visualized with immunofluorescence compared to granular
pattern
– Basement membrane antigen responsible for classic anti-GBM
antibody GN is a component of the noncollagenous domain of the
alpha3 chain of collagen type IV
• Cross-react with basement membrane of alveoli resulting in
simultaneous lung and kidney lesions, aka Goodpasture syndrome

•

Antibodies also react in situ with “planted” nonglomerular antigens
that localize to GBM
– DNA (affinity for GBM), endostreptosin (Group A streptococci)
– Induce a granular pattern of immunofluorescence

• Localization of Ag-Ab complexes determines glomerular response
– Proximal zone versus distal zones of the GBM

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Mediators of Immune Injury
•
•

•

•
•

The principal pathway of antibody-mediated glomerular injury is
complement-leukocyte-mediated
Complement leads to generation of chemotactic agents and recruitment
of neutrophils and monocytes
– Release proteases, reactive oxygen species, arachidonic acid
Also, complement-dependent but not neutrophil-dependent injury due to
the effect of the membrane attack complex (C5-C9)
– Injury to epithelial cells
– Upregulates TGF-beta receptors on podocytes  synthesis of ECM 
altered GBM composition and thickening
Antibodies directed to glomerular cells may be directly cytotoxic
Other mediators
– Monocytes and macrophages
– Platelets which aggregate and release prostaglandins and growth factors
– Resident glomerular cells can be stimulated to secrete cytokines,
arachidonic metabolites, growth factors, NO, and endothelin
– Fibrin-related products cause leukocyte infiltration, and glomerular cell
proliferation

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Nephrotic Syndrome
• Initial event is derangement in capillary wall of glomeruli
resulting in increased permeability to plasma proteins
• A clinical complex that includes:
–
–
–
–
–

Massive proteinuria, e.g. 3.5gm or more daily
Hypoalbuminemia, with plasma levels less than 3gm/dL
Edema, progressing to anasarca (generalized edema)
Hyperlipidemia and lipiduria
AT ONSET, little or no azotemia, hematuria, or hypertension

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Nephrotic Syndrome
• Causes of nephrotic syndrome vary according to age
– In children, the cause is almost always a primary lesion of the
kidney, e.g. FSGS and minimal-change disease
– In adults, almost always due to renal manifestations of a
systemic disease, e.g. diabetes, amyloidosis, SLE

• Four primary glomerular lesions characteristically lead to
nephrotic syndrome:
•
•
•
•

MCD: Minimal change disease
FSGS: Focal and segmental glomerulosclerosis
Membranous Glomerulopathy
Membranoproliferative GN

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Minimal change disease (MCD)aka Lipoid Nephrosis
•Glomeruli appear normal by light
microscopy
•GBM appears normal by TEM
•Uniform and diffuse effacement
of foot processes of podocytes
•Cytoplasm of podocytes appears
flattened over the GBM

•Cells of PCT are laden with
protein droplets and lipids (lipoid
nephrosis)
•No hypertension and normal
renal function
•Steroid-responsive

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Focal and segmental
glomerulosclerosis
•Affects only some
glomeruli and initially the
juxtaglomerular glomeruli
(focal)
•Affects some tufts of the
glomerulus and not others
(segmental)
•Lesion is one of increased
mesangial matrix,
obliterated capillary
lumens, and deposits of
hyaline masses
(hyalinosis) and lipid
droplets
•Occasional glomeruli are
completely affected (global
sclerosis)
•Nonspecific trapping of
IgM and complement in
areas of hyalinosis

•Effacement of podocyte foot processes
seen on TEM
•Progresses to global sclerosis, tubular
atrophy and interstitial fibrosis
•Injury to podocytes is thought to represent
the initiating event of primary FSGS

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Membranous nephropathy
•Most common between 30 and 50 years of age
•Slowly progressive disease
•Characteristic light microscopic change is diffuse thickening
of GBM
•Caused by subepithelial deposits along the GBM separated
by spikelike protrusions of GBM matrix (spike and dome
pattern)
•As progresses, deposits get incorporated into GBM and
there is effacement of foot processes
•Granular deposits of Ig and complement along GBM with
immunofluorescent staining
•Form of chronic immune complex nephritis induced by
antibodies reacting to endogenous or planted glomerular
antigens, or DNA in SLE

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Membranoproliferative
Glomerulonephritis
•Manifested histologically
by alterations in GBM and
mesangium and by
proliferation of glomerular
cells
•Type I MPGN seems to
result from circulating
immune complexes
•Type II MPGN seems to
be linked to excessive
complement activation
•By light microscopy, both
types have large glomeruli
with accentuated lobular
appearance, porliferation of
mesangial and endothelial
cells, infiltrating leukocytes

•GBM is thickened, and capillary wall shows
double contour – caused by inclusion of
processes of glomerular or inflammatory cells

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•Type I MPGN characterized
by subendothelial electrondense deposits
•Immunofluorescent labeling
of C3 deposited in an irregular
granular pattern (immune
complex pathogenesis)
•Type II MPGN characterized
by lesions in the lamina densa
and subendothelial space of
the GBM, transforming these
into a ribbon-like electrondense structure dense deposit
disease
•C3 is present in irregular
deposits

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Nephritic Syndrome
• Clinical complex, usually of acute onset, characterized by
–
–
–
–

Hematuria, with dysmorphic RBCs and RBC casts in urine
Oliguria and azotemia
Hypertension
Proteinuria (but mild, i.e. not severe as in nephrotic syndrome)

• Glomerular lesions have in common (1) proliferation of cells
in glomeruli accomapnied by (2) leukocyte infiltration
• Inflammation cause injury to capillary wall allowing RBCs to
escape into urine
– Hemodynamic changes result in reduction of GFR

• Reduced GFR is manifest as oliguria, fluid retention, and
azotemia
• Reduced GRF leads to renin release, with fluid retention,
results in hypertension

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Acute Postinfectious
(Poststreptococcal) GN
• Classic case develops in children
1-4 weeks after recovery from
group A streptococcal infection
• Characteristic change is fairly
unifrom increased cellularity of
glomerular tufts that affects nearly
all glomeruli (diffuse) due to
proliferration of endothelial and
mesangial cells and infiltration of
neutrophils and monocytes
• Most often subepithelial deposits
of immune complexes, aka
subepithelial humps
• Granular deposits of IgG and
complement within capillary walls
and mesangium

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IgA Nephropathy (Berger Disease)
• Affects children and young adults and occurs as an
episode of gross hematuria within 1-2 days of
upper respiratory tract infection
• Hematuria lasts several days, then subsides, but
then recurs every few months
• One of the most common causes of recurrent
microscopic or gross hematuria and is the most
common glomerular disease revealed by renal
biopsy
• Pathogenic hallmark is deposition of IgA in
mesangium
• Characteristic immunofluorescent labeling of
mesangial deposition of IgA, with C3 and proteins

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Rapidly Progressive (Crescentic) GN
• RPGN is a clinical syndrome and not a
specific form of GN
• Characterized clinically by rapid and
progressive loss of renal function with
features of nephritic syndrome, severe
oliguria, and if untreated, death from renal
failure
• Regardless of cause, histologic picture is
characterized by crescents
– Produced by proliferation of parietal
epithelial cells of Bowman’s capsule
and by infiltration of monocytes and
macrophages
• Three types of RPGN

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Rapidly Progressive (Crescentic) GN
• RPGN is a clinical syndrome and not a
specific form of GN
• Characterized clinically by rapid and
progressive loss of renal function with
features of nephritic syndrome, severe
oliguria, and if untreated, death from renal
failure
• Regardless of cause, histologic picture is
characterized by crescents
– Produced by proliferation of parietal
epithelial cells of Bowman’s capsule
and by infiltration of monocytes and
macrophages
• Three types of RPGN

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• Pauci-Immune (Type III) Crescentic GN
– Defined by lack of anti-GBM antibodies
or significant immune complex deposition
detectable by immunofluorescence
– Anti-neutrophil cytoplasmic antibodies in
serum
– No deposits detectable by EM or by
immunofluorescence

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• Anti-Glomerular Basement Membrane Antibody (Type I)
Crescentic GN
– Characterized by linear deposits of IgG and C3
along the GBM
– Antibodies to collagen type IV antigen endogenous
to GBM
– Anti-GBM antibodies also bind to pulmonary alveolar
capillary basement membranes, aka Goodpasture
syndrome
– Kidneys are enlarged and pale, often with petechiae
hemorrhages on cortical surface
– Glomeruli show segmental necrosis and GBM
breaks Will be picture on this in exam

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PAS stain

Goodpasture syndrome

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• Immune Complex-Mediated (Type II) Crescentic GN
– Complications of any immune complex nephritides,
including Poststreptococcal GN, SLE, and IgA
Glomelur nephritis
nephropathy
– Severe glomerular injury with segmental necrosis and
GBM breaks
– Immunofluorescence reveals granular (“lumpy bumpy”)
pattern of the GBM and/or mesangium for Ig and/or
complement

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• Pauci-Immune (Type III) Crescentic GN
– Defined by lack of anti-GBM antibodies
or significant immune complex deposition
detectable by immunofluorescence
– Anti-neutrophil cytoplasmic antibodies in
serum
– No deposits detectable by EM or by
Electron micrography
immunofluorescence

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Chronic Glomerulonephritis

Chronic renal failure.

• Important cause of end-stage kidney disease presenting as
chronic renal failure
• At the time of diagnosis, glomerular changes so advanced
that it is difficult to discern the nature of the original lesion
• Kidneys are symmetrically contracted and surfaces are red
brown and diffusely granular
• Common features histologically are advanced scarring of
glomeruli to point of complete sclerosis
– Obliteration of glomeruli

• Marked interstitial fibrosis associated with atrophy and loss of
tubules
• Hypertension leads to thickening of walls of small muscular
arteries Basement membrane irregular or expanded by collagen deposition. Also blood vessels
• Lymphocytic infiltrates in fibrous interstitium

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Obsolete glomeruli
Fibrosis

Expande
d
inflamma
tory cells

Collagen and inflammatory cells
interstitial this is interstitial
nephritis

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Diseases Affecting Tubules and Interstitium
•

•

•

•
•

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Diseases characterized by one of the following:
1. Inflammatory involvement of the tubules and interstitium
2. Ischemic or toxic tubular injury leading to acute tubular
necrosis and acute renal failure
Tubulointerstitial nephritis (TIN) refers to group of
inflammatory diseases of the kidneys that primarily involve
the interstitium and tubules
In most cases of TIN caused by bacterial infection, the renal
pelvis is prominantly involved, hence, pyelonephritis, (from
Common cause is over consuming Tylenol or ibuprofen
pyelo, “pelvis”)
Interstitial nephritis is a term reserved for cases of TIN that
are nonbacterial in origin
Two routes by which bacteria reach the kidney
Pyelonephritis affects the pelvic region.

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Acute Pyelonephritis
• Common suppurative inflammation of the kidney and renal
pelvis caused by bacterial infection
– Enteric gram-negative rods, e.g. E. coli
• Great majority associated with infection of the lower urinary
tract (cystitis, prostatitis, urethritis)
• Discrete, yellowish, raised abscesses are grossly visible on
renal surface
• Characteristic histologic feature is suppurative necrosis or
abscess formation within the renal parenchyma
• Large masses of intratubular neutrophils give rise to
characteristic white cell casts

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Bilaterallly, lesions, white raised lesions, pyogenic. Multifocal and disseminated diffusely

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Chronic Pyelonephritis and Reflux Nephropathy
•

•

•
•

•

Characterized by interstitial
inflammation and uneven scarring of
the renal parenchyma
Hallmark is scarring involving the
pelvis or calyces, leading to papillary
blunting and marked deformity of
pelvicalyceal system
Can be divided into two forms
Chronic Obstructive Pyelonephritis
– Recurrent infections superimposed
on diffuse or localized obstructive
lesions
Chronic Reflux-Associated
Pyelonephritis
– Rresults from superimposition of
UTI on congenital vesicourteral
reflux and intrarenal influx

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Drug-Induced Interstitial Nephritis
• Drugs have emerged as an important cause of renal injury
• Two forms of TIN caused by drugs are recognized
Analgesic Nephropathy
•Consumption of large quantities of non-steriodal anti-inflammatory drugs
•Development of chronic interstitial nephritis associated with renal papillary
necrosis and progressive renal dysfunction
•Aspirin and acetominophen are principal drugs involved
•Papillary necrosis is the initial event, and the interstitial nephritis is secondary
•Pathognomonic gross features of papillary necrosis is sharply defined graywhite to yellow-brown necrosis of the apical two-thirds of the renal pyramids;
one or several papillae may be affected
•Histologic findings consist of coagulative necrosis with a surrounding
neutrophilic infiltrate and basement membrane thickening of blood vessels
•Aspirin, phenylbutazone (horses) inhibit prostaglandin synthesis which
predisposes the pyramid to ischemia by reducing the vasodilatory state of
venous tone of the medulla normally under prostaglandins

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Pyramidal necrosis caused by analgesics (black necrotic regions)

Acute Drug-Induced Interstitial
Nephritis
•Adverse reaction to any of a large
number of drugs
•Most often occurs with synthetic
penicillins (methicillin, ampicillin),
other synthetic antibiotics
(rifampin), diuretics (thiazides),
NSAIDs, cimetidine
•Immune mechanism of
hypersensitivity is suspected as
clinical signs include fever,
eosinophilia and rash
•Lesion is in the interstitium, which shows edema and infiltration of
lymphocytes and macrophages, also eosinophils and neutrophils (often in
large numbers)

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Acute Tubular Necrosis (ATN)
• ATN is characterized by damage to tubular epithelial cells
and acute suppression of renal function
• Most common cause of acute renal failure
– Urine flow falls to less than 400 mL per day

• ATN is a reversible renal lesion
– Can be due to trauma, acute pancreatitis, septicemia

• ATN associated with shock is called ischemic ATN due to
hypoperfusion of organs, and resultant hypotension
• Nephrotoxic ATN is caused by heavy metals, organic
solvents, or drugs that exert toxic effect on tubular epithelium
• Morphologically characterized by necrosis of tubular
segments (especially PCT), proteinaceous casts in distal
tubules and interstitial edema

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• Ischemic ATN is characterized by necrosis of short segments
of the renal tubules, particularly the PCT and ascending limb
• Histologically a variety of tubular injuries seen, e.g.
attentuation of PCT brush border, vacuolation of cells,
detachment of cells, proteinaceous casts in distal tubules and
collecting ducts
– Tamm-Horsfall protein normally secreted with hemoglobin,
myoglobin and plasma proteins
– Mild interstitial infiltrate of mixed inflammatory cells

• Toxic ATN is characterized by more prominnent necrosis in
proximal tubules and sparing of basement membranes
• Tubular epithelium can regenerate if organs can be
maintained and basement membrane damage is minimized
– Regeneration begins about one week after injury

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Diseases Involving Blood Vessels
• Systemic vascular diseases also involve renal blood vessels
Benign Nephrosclerosis
•Renal changes in benign hypertension
and is associated with hyaline
arteriosclerosis
•Kidneys are symmetrically atrophic, with
a surface of diffuse granularity
•Basic microscopic anatomic change is
hyaline thickening of the walls of small
arteries and arterioles, aka hyaline
arteriolosclerosis, at expense of vessel
lumen  ischemia
Arcuate artery

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• Malignant Hypertension and Malignant Nephrosclerosis
–
–
–
–
–

Kidneys may be normal in size or slightly smaller
Small pinpoint petechial hemorrhages on cortical surface
Damage to small vessels manifests as fibrinoid necrosis
Vessel walls have a granular eosinophilic appearance
Larger vessels have an onion-skin appearance due to
proliferation of intimal cells, aka hyperplastic arteriolosclerosis

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Cystic Diseases of the Kidney
• Group of heterogeneous diseases including hereditary,
developmental but not hereditary, and acquired
• Reasonably common and present diagnostic challenges
• Some are major causes of chronic renal failure
• Can be confused with malignant tumors
• Emerging theme in the study of hereditary cystic diseases is that
the underlying defect is in the cilia-centrosome complex of tubular
epithelial cells, which may interfere with fluid balance or cellular
maturation
• Simple Cysts
– generally innocuous lesions occurring as multiple or single cystic
spaces that vary in diameter, are translucent, lined by a gray
glistening smooth membrane, and filled with clear fluid
– Microscopically membranes are single layer of cuboidal epithelium
which may be atrophic
– Cysts are usually confined to cortex
– Importance of cysts lies in their differentiation from kidney tumors

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Autosomal Dominant (Adult) Polycystic Kidney Disease
• Characterized by multiple expanding cysts of both kidneys that
ultimately destroy the parenchyma
• Autosomal dominant disease caused by mutations in the genes
encoding polycystin-1 or -2
• Accounts for ~ 10% of cases of chronic renal failure in adults
• Kidneys are very large and palpable abdominally
• Grossly, kidneys seems to be replaced by numerous, variablysized cysts with no intervening parenchyma
– Cysts are thin-walled and can contain fluid that may be clear, turbid or
hemorrhagic

• Microscopically, reveals narrow bands of normal parenchyma
between cysts
• Cysts may arise at any level of the nephron, and are lined by a
cuboidal to flattened or atrophic epithelium
• Pressure of expanding cysts causes ischemic atrophy of
intervening renal parenchyma
• One-third of patients have liver (biliary) cysts (asymptomatic)

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• Autosomal Recessive (Childhood) Polycystic Kidney Disease
– Caused by mutations in the gene encoding fibrocystin
– Strongly associated with liver abnormalities
– Numerous small cysts in the cortex and medulla giving the
kidney a sponge-like appearance

• Medullary Cystic Disease
– Nephronophthisis-medullary cystic disease complex usually
begins in childhood
– Being recognized as a cause of chronic renal failure in children
and young adults
– Associated with mutations in several genes that encode
epithelial proteins called nephrocystins
– Small contracted kidneys with numerous small cysts lined by
flattened or cuboidal epithelium

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Urinary Outflow Obstruction
Renal Stones
• Urolithiasis refers to calculus (stone) formation at any level in
the urinary collecting system, but most often in kidney
• Common sites are renal pelvis and calyces and the bladder
• The most important cause of stone formation is increased
urine concentration of stone’s constituents in excess of their
solubility in urine
• Prevalence of different types of stones varies
– Calcium oxalate and/or calcium phosphate comprise 80% of all
stones in humans
– Other types, e.g. struvite (Mg, NH3, Ca, Po4), uric acid,
cysteine

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Hydronephrosis
• Dilation of renal pelvis and
calyces, accompanied by
atrophy of the parenchyma
• Caused by obstruction to
the outflow of urine
anywhere from urethra to
renal pelvis
• Congenital – atresia of
urethra, valve formations
in ureter or urethra, renal
artery compressing on
ureter, kinking of ureter
• Acquired – foreign bodies
(calculi), tumors,
inflammation, neurogenic,
pregnancy

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