Glomerular Filtration

The two most widely used biochemical tests of GFR are plasma creatinine and blood urea nitrogen (BUN). The normal plasma creatinine concentration is 50 to 120 μmol/l (0.6 to 1.4 mg/dl) in males and 40 to 100 μmol/l (0.5 to 1.1 mg/dl) in females. The normal BUN concentration is 3.2 to 7.7 mmol/l (9 to 22 mg/dl). Of the two, creatinine is the more reflective of the GFR. Creatinine is released from muscle at a relatively constant rate, is freely filtered at the glomerulus and, unlike urea, is not reabsorbed in the tubules. Creatinine concentration is relatively constant despite changes in diet and metabolic rate. As people age, there is a gradual reduction in the GFR, which is matched by a decline in muscle mass. Thus, creatinine concentration remains relatively constant. The relationship between the creatinine concentration and the GFR is not linear (Fig. 33-1); with normal renal function, a small rise in creatinine concentration signals a large deterioration in the GFR; with severe renal dysfunction, large changes in creatinine reflect small changes in the GFR.

Figure 33.1 The relationship between plasma creatinine concentration and creatinine clearance. This graph assumes that plasma creatinine concentration is stable.

A more accurate estimate of the GFR, which is independent of age, is creatinine clearance. The normal range for creatinine clearance is 120 ± 25 ml/min for men and 95 ± 20 ml/min for women.⁸ Creatinine clearance (C_Cr) can be calculated on the basis of the plasma (P_Cr) and urinary (U_Cr) concentrations of creatinine and the urine volume (V):

(33-1)

This requires 24-hour urine collection. A simpler method is to estimate creatinine clearance on the basis of the following empiric formula:

(33-2)

This formula assumes that a steady state exists; it cannot be applied to estimate the GFR during the development of acute renal failure.

Measurement (or estimation) of creatinine clearance is particularly important in the elderly and in patients with abnormal body mass indexes.

As with creatinine, BUN levels are inversely related to the GFR. However, BUN levels are also influenced by the rate of urea production and the degree of tubular reabsorption. Increased urea production, and therefore increased BUN levels, occur with a high-protein diet, gastrointestinal bleeding, and increased protein catabolism (e.g., treatment with corticosteroids). Increased tubular reabsorption of urea, and therefore increased BUN levels, occur when tubular flow is low, as occurs in renal hypoperfusion. Thus, a greater increase in BUN levels relative to creatinine levels also occurs with hypovolemia and heart failure. One advantage of measuring BUN levels rather than creatinine levels is that they increase within a few hours of a reduction in the GFR, whereas creatinine takes at least 8 hours to become significantly elevated.

Tubular Function

Tubular dysfunction results in the inability to generate appropriately concentrated urine in response to a physiologic stimulus. With prerenal azotemia, tubular function is intact. In this situation, high levels of aldosterone and antidiuretic hormone lead to maximal tubular reabsorption of sodium and the excretion of low-volume, hypertonic urine. Urine osmolarity is typically greater than 500 mOsm/l and urinary sodium concentration less than 20 mmol/l. An exception to these findings is seen in patients treated with diuretics and in the very elderly, who have a higher sodium concentration and a lower osmolarity. With acute tubular necrosis, there is loss of the normal hypertonicity of the medulla (see Chapter 1) and the inability to conserve sodium and excrete concentrated urine. In this circumstance, urine osmolarity is typically less than 400 mOsm/l, and urinary sodium concentration is greater than 20 mmol/l.

Urine Output

Oliguria (urine output <0.5 ml/kg/hr) is an important marker of renal hypoperfusion and evolving acute tubular necrosis. However, urine output must be interpreted with caution. With a normal diet, about 600 mOsm/day of solute waste products generated by metabolism must be excreted in the urine. With normal renal tubular function and maximal antidiuretic hormone stimulation, this requires a minimum of 500 ml/day of urine. In postoperative patients who have low dietary intake and high plasma levels of catecholamines, aldosterone, and antidiuretic hormone (see Chapter 32), oliguria may be a normal finding and not indicative of a reduced GFR or tubular dysfunction. Oliguria in association with normal plasma creatinine concentration and normal intravascular volume does not require treatment. However, oliguria in association with prerenal azotemia or acute tubular necrosis mandates a search for the cause of renal hypoperfusion, in particular, a careful assessment of intravascular volume status and cardiac function. Conversely, high urine output can occur despite intravascular volume depletion. Polyuria is common in the first few hours following cardiac surgery as a consequence of hypothermic cardiopulmonary bypass (CPB) and the administration of diuretics—particularly mannitol, which may be used in the CPB prime solution.

Oliguria is usually present with prerenal azotemia in the early period of acute tubular necrosis. If tubular necrosis is severe, anuria develops because of a low or absent GFR and tubular obstruction (see Chapter 1). If the GFR is then partially or fully restored, polyuria often develops due to the inability to concentrate urine.

Renal Imaging

Ultrasound scanning of the kidneys and renal tract is the most useful imaging technique in patients with acute renal dysfunction, and it can be performed at the bedside. Ultrasonography can identify obstruction in the upper or lower urinary tract and can confirm the presence and size of each kidney. Small (or large polycystic) kidneys indicate chronic renal disease. Doppler flow imaging may suggest the presence of atherosclerotic renal artery stenosis or, occasionally, renal vein thrombosis.

Intravenous pyelography and contrast-enhanced computed tomography should be avoided if possible because of the risk for contrast nephropathy, unless it is likely to change the management of the patient (e.g., renal artery stenting following aortic dissection).

Definition

Various definitions of renal dysfunction are used; they are based on the plasma creatinine concentration, the percentage of rise in creatinine concentration, or the need for renal replacement therapy. Recently, the RIFLE (risk, injury, failure, loss, and end-stage kidney disease) classification has been proposed by the Acute Dialysis Quality Initiative Workgroup as a consensus definition of acute renal failure in critically ill patients.⁹ Renal dysfunction is divided into three categories (risk, injury, failure) on the basis of plasma creatinine concentration and urine output. In addition, there are two levels of outcome (loss, end-stage kidney disease), determined by the persistence of renal failure at 4 weeks or 3 months (Table 33-1). The RIFLE classification has recently been evaluated in cardiac surgery patients and has been shown to be an independent predictor of mortality: patients categorized as having risk, injury, or failure postoperatively had 90-day mortality rates of 8%, 22%, and 33%, respectively.¹⁰

Table 33-1 RIFLE Classification of Renal Dysfunction and Failure

GFR, glomerular filtration rate

From Bellomo R, Ronco C, Kellum JA, et al: Acute renal failure—definition, outcome measures, animal models, fluid therapy and i nformation technology needs: the Second International Consensus Conference of the Acute Dialysis Quality Initiative (ADQI) Group. Crit Care 8:R204-R212, 2004.

Risk Factors for Acute Renal Failure Following Cardiac Surgery

The causes of renal failure following cardiac surgery are multifactorial. Renal hypoperfusion may occur because of periods of hypovolemia, hypotension, or low cardiac output. Nonpulsatile CPB leads to reduced renal blood flow.^11,12 Renal function may be adversely affected by the systemic inflammatory response to surgery and CPB and by free plasma hemoglobin generated by bypass-induced trauma to red blood cells. Atheroembolism may occur due to aortic manipulations such as cross-clamping, cannulation, and the use of an intraaortic balloon pump. Nephrotoxic drugs—in particular radiocontrast agents used for coronary angiography—may be administered during the perioperative period.

The risk factors for renal failure requiring renal replacement therapy following cardiac surgery are listed in Table 33-2. Of these, preexisting renal dysfunction is by far the most important; it is a major predictor of postoperative mortality.¹³

Table 33-2 Factors That are Independently Associated with the Need for Postoperative Renal Replacement Therapy Following Cardiac Surgery

From Bove T, Calabro MG, Landoni G, et al: The incidence and risk of acute renal failure after cardiac surgery. J Cardiothorac Vasc Anesth 18:442-445, 2004.

Causes of chronic renal dysfunction include hypertension, diabetes, connective tissue disease, chronic use of nonsteroidal antiinflammatory drugs, glomerulonephritis, and polycystic kidney disease. Chronic renal dysfunction is very common in patients presenting for cardiac surgery. In one large series, 51% of patients had mild renal dysfunction (GFR 60 to 90 ml/min); 24% had moderate renal dysfunction (GFR 30 to 59 ml/min); 2% had severe renal dysfunction (GFR <30 ml/min); and 1.5% were dialysis dependent.¹³

Physiologic Consequences of Renal Failure

Monitoring Renal Function

In all patients with acute renal dysfunction, a urinary catheter should be inserted. Fluid input and output should be recorded hourly. Acid-base, sodium, potassium, creatinine, BUN, and hemoglobin levels should be measured at least daily. Potassium should be measured much more frequently (e.g., every 1 to 4 hours) in acutely oliguric patients. Measurements of urinary sodium concentration and osmolarity are also useful. Careful monitoring of cardiorespiratory function is indicated. Intraabdominal pressure monitoring may also be indicated.

Preventing Further Renal Injury