Postobstructive diuresis

Urinary retention

Urinary retention is a common clinical condition addressed in both primary health care clinics and hospitals. It is traditionally classified as acute or chronic. Acute urinary retention (AUR) is a rapid-onset condition associated with suprapubic pain and the inability to urinate. Conversely, chronic urinary retention (CUR) has a gradual onset, with no associated pain and the ability to pass only small amounts of urine. These patients might also present with overflow urinary incontinence.² Chronic urinary retention is further classified into high- and low-pressure CUR. The presence or absence of intrinsic detrusor pressure is what differentiates them. High-pressure CUR results from an obstruction with the presence of detrusor muscle activity, while low-pressure CUR involves detrusor failure with low intravesical pressure.³ This distinction is important, as high detrusor pressure can lead to upper urinary tract damage and present with new-onset hypertension, peripheral edema, or renal dysfunction.⁵

The incidence of urinary retention is higher in men than in women and increases with age. It is estimated that 1 in 10 men between the ages of 70 and 79 and 3 in 10 men between the ages of 80 and 89 will have an episode of AUR within their lifespans.² Apart from age and sex, other risk factors associated with an increased risk of urinary retention include lower urinary tract symptoms, prostate disease, long-standing diabetes, recurrent catheterization, fecal impaction, and the use of anticholinergic medications.^5,6

After a thorough history taking and physical examination, the patient should be assessed for a palpable bladder and neurologic integrity, and a rectal examination should be performed to assess the prostate and rectal tone. Urinary retention can be confirmed with a postvoid bladder ultrasound or the placement of a urinary catheter demonstrating a large residual urine volume. There are currently no universally accepted diagnostic values for a normal postvoid residual volume, but it has been reported that AUR is associated with a residual urine volume of 500 to 600 mL, whereas CUR is associated with a volume of greater than 800 mL.^6,7 Commonly, patients with CUR present with 1.0 L to 1.5 L of retained urine, with some case reports noting volumes greater than 4 L.⁷

Bladder outlet obstruction (BOO)

Bladder outlet obstruction is the most common cause of urinary retention and a list of causes is outlined in Box 1.^2,8 In many cases this obstructive process is gradual and can evolve into CUR. As the BOO progresses, the detrusor pressure will also increase, resulting in high-pressure CUR. In severe cases, BOO can lead to vesicoureteral reflux and subsequent hydronephrosis. Prolonged high-pressure hydronephrosis can injure nephrons and result in renal dysfunction.⁹

Postobstructive diuresis

Postobstructive diuresis is a polyuric state in which copious amounts of salt and water are eliminated after the relief of a urinary tract obstruction. The incidence of POD is unclear but estimates suggest 0.5% to 52% of patients will experience POD after relief of obstruction.¹⁰ It generally occurs after relieving BOO, bilateral ureteric obstruction, or unilateral ureteric obstruction in a solitary kidney.¹¹ Diuresis is a normal physiologic response to help eliminate excess volume and solutes accumulated during the prolonged obstruction. In most patients, the diuresis will resolve once the kidneys normalize the volume and solute status and homeostasis is achieved. Some patients will continue to eliminate salt and water even after homeostasis has been reached, referred to as pathologic POD. These patients are at risk of severe dehydration, electrolyte imbalances, hypovolemic shock, and even death if fluid and electrolyte replacement is not initiated.⁹

Numerous mechanisms have been proposed to describe the pathophysiology of POD, which include a progressive reduction in the medullary concentration gradient secondary to vascular washout and down-regulation of sodium transporters in the thick ascending loop of Henle; reduction in glomerular filtration rate, which leads to ischemia and loss of juxtamedullary nephrons; and reduced response of the collecting duct to circulating antidiuretic hormone, leading to nephrogenic diabetes insipidus.^12–15 The most likely cause is a combination of all these mechanisms.

It is difficult to predict which patients will develop POD after the release of urinary tract obstruction. A recent article by Hamdi et al identified the initial presence of a high serum creatinine level, a high sodium bicarbonate level, and urinary retention as independent risk factors for developing POD after decompressing an obstructed urinary tract.¹⁶ Further, there are very few clinical markers that help predict which individuals with physiologic POD will progress to pathologic POD. There is no correlation between initial creatinine values, urea values, electrolyte values, creatinine clearance, or presence of hypertension with the severity of diuresis.^17,18 However, some studies have found that the presence of renal insufficiency, heart failure or evidence of volume overload, dizziness, and central nervous system depression are risk factors for developing substantial POD.^14,19

Postobstructive diuresis is a clinical diagnosis based on urine output after decompressing an obstructed bladder or ureter. Urine production exceeding 200 mL per hour for 2 consecutive hours or producing greater than 3 L of urine in 24 hours is diagnostic of POD (level III evidence).^14,19 Physiologic POD is self-limiting and generally lasts 24 hours. Pathologic POD generally lasts longer than 48 hours and can be exacerbated with excessive intravenous fluid replacement.¹⁴

The treatment of urinary retention begins with immediate catheter placement to decompress the bladder. It was once thought that decompression of the bladder should be performed gradually with periodic clamping to prevent hematuria, hypotension, and POD. However, a recent review by Nyman et al revealed that there is no evidence linking these complications with quick, complete bladder emptying, and the authors conclude that this is a safe and effective method of bladder decompression (level I evidence).^10,20 A list of general urinary catheter complications is outlined in Box 2.²¹

Patients with decompressed urinary obstruction (BOO, bilateral ureteric obstruction, or unilateral ureteric obstruction of a solitary kidney) need to be monitored closely for POD and might have to be admitted for a 24-hour observation period. These individuals should have their urine output recorded every 2 hours and vital signs checked every 6 to 8 hours. Further, their serum electrolyte (especially potassium), magnesium, phosphate, urea, and creatinine levels should be checked every 12 to 24 hours and corrected if necessary.¹⁴ These patients should be allowed free access to oral hydration and can be discharged after 24 hours if POD is not confirmed.¹² A follow-up visit with a urologist should be arranged for a later date for further management of their obstructive uropathy.

If the patient’s urine output exceeds 200 mL per hour for 2 consecutive hours, or is greater than 3 L over 24 hours, then this is diagnostic of physiologic POD and requires closer monitoring for conversion to pathologic POD. These individuals should continue to have their urinary outputs recorded, should be weighed daily, and should have their serum electrolyte, magnesium, phosphate, urea, and creatinine levels monitored every 12 hours or more frequently as necessary (level III evidence).^9,12,14 A urine sample should be collected for urinary sodium and potassium levels and urine osmolality to determine if it is a salt or urea type of diuresis.⁹ Urea diuresis is generally self-limiting, whereas salt diuresis can convert to pathologic POD and requires careful monitoring of serum electrolyte levels and hydration status. Spot urine sodium levels greater than 40 mEq/L suggest renal tubular injury and if prolonged can lead to pathologic POD.¹⁴

A simple method to estimate urine osmolality, if an automated method is not available, is to assess the urine specific gravity. A specific gravity of 1.010 is iso-osmotic with serum osmolality, indicating that the kidneys do not need to concentrate the urine. This is consistent with physiologic POD and is generally self-limiting. A specific gravity of 1.020 demonstrates that the kidneys are concentrating the urine and POD has resolved or has nearly resolved. However, a specific gravity of 1.000 is hypo-osmotic with serum osmolality, indicating the kidneys’ inability to concentrate the urine. This is consistent with pathologic salt-wasting POD and should alert the health care team to monitor the patient closely (level III evidence).¹⁴

Fluid balance should be closely monitored and a negative balance should be targeted in these patients. It is recommended to replace 75% of the previous 1-hour urinary output (level III evidence).⁹ Excessive fluid should be avoided as it can prolong or exacerbate the diuresis. Individuals without cognitive impairment should continue to take hydration orally. However, cognitively impaired patients should receive 0.45% normal saline intravenously. In physiologic POD, when the patient reaches a euvolemic state, the diuresis should resolve and this will be evident by a 24-hour urine production of less than 3 L.¹⁹

If pathologic POD ensues, then polyuria will continue even after a euvolemic state has been reached. These patients are at risk of hypovolemia and can become hemodynamically unstable. Prolonged polyuria also places the patient at risk of electrolyte and acid-base disturbances (Box 3).^9,14,18 Patients with pathologic POD require strict monitoring of vital signs, fluid status, and serum electrolyte levels, and benefit from the involvement of a nephrologist. Regardless of cognitive function, all patients with pathologic POD require intravenous fluid replacement run at a negative balance. The type and amount of fluid should be tailored to the patient’s needs based on his or her serum and urinary electrolyte levels and clinical hydration status.