Urinary Obstruction and Stasis PDF

Summary

This document covers urinary tract obstruction and stasis, discussing mechanisms, pathophysiology, and different types of obstructions. It details the hemodynamic changes seen in both unilateral and bilateral ureteral occlusion, including the triphasic pattern observed in animal experiments. The document also includes sections on pathologic changes, gross and microscopic findings related to obstruction, and the post-obstructive diuresis process. The etiologies of hydronephrosis during pregnancy and benign pelvic abnormalities, such as tubo-ovarian abscesses, are also explored, with a focus on the clinical implications of these conditions.

Full Transcript

URINARY OBSTRUCTION AND STASIS

UĞUR BOYLU, M.D.
Professor of Urology
Istinye University, Faculty of Medicine, Department of Urology
Liv Hospital Ulus, Istanbul
Obstruction of the urinary tract

Obstruction of the urinary tract can occur during
fetal development, childhood, or adulthood.

The point of obstruction:
– Proximal -> calyces
– Distal -> urethral meatus.

lead to à permanent renal damage à limiting
the excretion of metabolic wastes à altering
water and electrolyte balance.
Definitions

Hydronephrosis:
- Is the dilation of the renal pelvis or calyces.
- Associated with obstruction.
- may be present in the absence of
obstruction.
Obstructive uropathy:
- The functional or anatomic obstruction of
urinary flow at any level of the urinary tract.
- The obstruction causes:
functional or anatomic renal damage.
GLOBAL RENAL FUNCTIONAL CHANGES
Glomerular Filtration, Renal Blood Flow, Collecting System
Pressure

Functional changes associated with obstructive
nephropathy.
- Renal hemodynamic variables
- Glomerular filtration.

influenced by:
- The extent and severity of obstruction
- Unilateral or bilateral
- Persists or has been relieved.
Factors influencing GFR

Factors influencing GFR are expressed in the
following equation:
GFR = Kf (PGC −PT −πGC)
Kf: glomerular ultrafiltration coefficient
PGC: glomerular capillary pressure
Influenced by:
- Renal plasma flow (RPF)
- The resistances of the afferent and efferent
arterioles.
The hydraulic pressure of fluid in the tubule
(PT)
oncotic pressure (π) of the proteins
Renal plasma flow (RPF)

RPF depends upon:
- The renal perfusion pressure
- Intrarenal resistance to flow is mediated by the
resistances in the afferent and efferent
arterioles.

RPF = aortic pressure − renal venous pressure
renal vascular resistance

Obstruction can transiently or permanently alter
GFR and some or all of the determinants of
GFR.
Unilateral? Bilateral

Unilateral and bilateral ureteral obstructions
differ in
– the patterns of hemodynamic
– ureteral pressure changes
– distribution of renal blood flow.
Hemodynamic Changes with
Unilateral Ureteral Occlusion
Animal experiments have demonstrated a triphasic
pattern of RBF and ureteral pressure changes in
UUO

first 1 to 2 hours
-RBF increases
-high PT and collecting system pressure
second phase lasting 3 to 4 hours
-pressure parameters remain elevated
-RBF begins to decline.
third phase beginning about 5 hours after
obstruction
-a further decline in RBF
-decrease in PT and collecting system pressure.
 In phase I, renal blood flow and ureteral pressure rise together.
In phase II, the left renal blood flow begins to decline and ureteral pressure remains elevated
and, in fact, continues to rise.
In phase III, the left renal blood flow and ureteral pressure decline together.
Hemodynamic Changes with
Bilateral Ureteral Occlusion
A modest increase in RBF with BUO that lasts
approximately 90 minutes followed by a
prolonged and profound decrease in RBF that is
greater than found with UUO.

– The intrarenal distribution of blood flow is quite different with
BUO than with models of UUO.

– Thus the shift seen with UUO of blood flow from outer to inner
cortex is the opposite of that with BUO.
Hemodynamic Changes with
Bilateral Ureteral Occlusion
Ureteral pressure is higher with BUO than
with UUO.

In both cases ureteral and tubular pressures
are increased for the first 4 to 5 hours.
– The ureteral pressure remains elevated for at least 24 hours with
BUO
– The ureteral pressure begins to decline and approaches
preocclusion pressures by 24 hours with UUO.

Ureteral pressure is higher with BUO than
with UUO.
In summary,
Both UUO and BUO involve increases in renal vascular
resistances and increases in ureteral pressures. The timing
and regulation of these changes differ

With UUO, early renal vasodilation primarily mediated by
prostaglandins and NO is followed by prolonged
vasoconstriction and normalization of intratubular-ureteral
pressure as the contralateral kidney contributes to fluid
balance.

With BUO, little early vasodilation is seen, and
vasoconstriction is more profound. When the obstruction is
released, the postobstructive diuresis is much greater with
BUO because volume expansion, urea and other osmolytes,
and secreted ANP contribute to a profound diuresis and
natriuresis.
PATHOLOGIC CHANGES OF
OBSTRUCTION
These may be affected by:
-the presence of infection
-duration of obstruction
-intra versus extrarenal localization of the renal
pelvis.
Gross Pathologic Findings
at 42 hours after obstruction :
Dilation of the pelvis and ureter
blunting of the papillary tips
the weight of this renal unit heavier.
at 7 days.
Pelviureteric dilation
weight further increased
parenchyma became edematous
at 12 days
The cortex remained slightly enlarged
increased calyceal dilatation
at 21 and 28 days
the external renal dimensions of both kidneys were similar.
the cortex and medullary tissue diffusely thinned.
At 6 weeks
The totally obstructed kidneys à enlarged, had a cystic appearance,
and weighed less than the contralateral renal unit
The partially obstructed kidneys à no gross differences in appearance
Microscopic Pathologic Findings
Widespread glomerular collapse and
tubular atrophy, interstitial fibrosis, and
proliferation of connective tissue in the
collecting system were reported at 5 to 6
weeks after obstruction
This is believed to be a result of interplay of
several cellular and molecular mechanisms
that collectively lead to the subtle
development of tubular atrophy, macrophage
infiltration/proliferation in the renal interstitial
tissue, interstitial fibrosis and progressive
loss of nephrons
Electron Microscopic Pathologic
Findings
Including:
-tubular atrophy
-glomerular collapse
-renal pelvic smooth muscle atrophy
at 5 to 6 weeks after obstruction
other changes including:
-a cell-poor stroma composed of elastic and
collagen fibers in the renal interstitium
-obstructed portions of the collecting system.
Post obstructive Diuresis
Mechanisms
Following the relief of urinary tract obstruction,
post- obstructive diuresis—a period of significant
polyuria— may ensue.
Urine outputs of 200 mL/hr or greater may be
encountered.
Postobstructive diuresis occurs primarily with BUO
and is usually self-limiting.
– mainly after relief of BUO or obstruction of a solitary kidney
– rarely occur when there is a normal, contralateral kidney
Post obstructive Diuresis

Downregulation of sodium transporters
The increased ANP induce a saline diuresis
other natriuretic peptides, such as the
Dendroaspis natriuretic peptide, may play a
role.
poor responsiveness of the collecting duct to
antidiuretic hormone (ADH).
due to a downregulation of aquaporin water
channels in this segment of the nephron and
perhaps in the proximal tubule
SELECTED EXTRINSIC CAUSES OF
URETERAL OBSTRUCTION

Retroperitoneal Fibrosis

uncommon
a fibrotic and inflammatory mass envelops and
potentially obstructs retroperitoneal structures
including either or both ureters.
Pelvic Lipomatosis
Rare
benign condition
marked by exuberant pelvic overgrowth of
nonmalignant but infiltrative adipose
tissue, usually in the abdominal and
pelvic cavities.
Occur in perivesical and perirectal spaces
The etiology and incidence are unknown.
Obesity play a role
radiographic improvement and worsening in
response to weight loss and gain,
respectively.
Obstetric and Gynecologic

Pregnancy
Hydronephrosis develops commonly during
pregnancy
occurrence varying between 43% and 100%.
Approximately one third of patients may
have persistent hydronephrosis during the
first postpartum week, but it resolves in the
majority within 6 weeks
 Two etiologies for hydronephrosis of
pregnancy:
- hormonal
- mechanical.
nonmechanical mechanism.
Progesterone promote ureteral dilatation and
subsequent development of hydronephrosis
mechanical etiology
after the 20th week of gestation, a time when
the uterus is large enough to compress the
ureters extrinsically
Benign Pelvic Abnormalities
Tubo-ovarian Abscess.
Tubo-ovarian abscess, occurring in approximately 15% of those
afflicted with PID, may cause extrinsic ureteral obstruction, lead to
anuria
Ureteral obstruction may resolve with:
- antibiotic therapy
- transvaginal drainage of the abscess.
- open surgical or laparoscopic intervention
- Placement of an internalized ureteral stent or percutaneous nephrostomy
Endometriosis.
Defined as the presence of functional endometrial
tissue in an ectopic site.
potential for malignant transformation
10% to 20% of women of reproductive age
peak incidence in the mid-20s
Vascular Causes of Ureteral
Obstruction
Arterial Causes of Obstruction
Abdominal Aortic Aneurysm.
Clinical signs and symptoms of ureteral obstruction may be the initial
manifestation of an abdominal aortic aneurysm (AAA)
due to a mass effect or localized inflammation
CT scanning
Ureteral findings vary.
- pushed laterally on both sides
- one side may deviate laterally while the opposite side is drawn medially
within the perianeurysmal inflammation
- both may be medially deviated.
lateral deviation of the ureter with AAA - not associated with obstruction
The medial deviation of the ureter associated with the desmoplastic
reaction of inflammatory aneurysms (IAAA), however, carries a more
significant risk of ureteral obstruction. Placement of internalized ureteral
stents
open surgery or an endovascular approach warrant close monitoring for
recurrent or de novo ureteral obstruction