Indications and Contraindications

More than 85% to 90% of urinary calculi are radiopaque. Plain radiography, which is also referred to as KUB (radiograph of the kidney, ureter, and bladder), is used commonly in the evaluation or follow-up of radiopaque calcium calculi. KUB can also be used in evaluating the position of urinary stents. For pregnant women, even though most standard abdominal radiographs are not likely to pose serious risks to the fetus, KUB should be used only when the benefits outweigh the risk of harm. Every potential childbearing female patient should be screened for possible pregnancy before the examination.

Techniques

Overlying bowel gas and fecal material may obscure the urinary calculi. However, bowel preparation is not needed. Tomography of the kidneys is often more helpful in revealing small renal calculi than plain KUB. Less opaque or nonopaque urinary calculi such as uric acid or cystine stones may not be visible on KUB or even on tomography. However, on noncontrast CT these calculi are visible as high attenuation and thus can be easily depicted. Bladder or urethral calculi can be seen on KUB, but small calculi in urethral diverticula may only be seen on CT.

Indications and Contraindications

IVU has been used as the primary imaging modality for various urologic abnormalities because it is inexpensive and widely available. IVU is limited, however, in depicting small renal masses or radiolucent stones. Common indications include hematuria workup, stone disease, urinary tract obstruction, and renal mass, as well as upper urinary tract abnormalities such as stricture, inflammation, fistula, and urothelial tumors. It is also used to assess the integrity of the upper urinary tract following urologic surgery or stent placement. Recently, IVU has been replaced by CTU in many of these conditions. Common contraindications to IVU include allergic reaction to iodinated contrast media and renal insufficiency. Patients with a history of severe iodinated contrast reaction, including respiratory distress, should be evaluated with other imaging modalities such as US or MRI. In patients with a history of minor reaction, iodinated contrast media can be used with steroid premedication.

Contrast-induced nephropathy (CIN) may occur following intravenous administration of iodinated contrast media for urographic or CT examinations. It is defined as an increase of serum creatinine value greater than 25% to 50% from baseline or an absolute increase in serum creatinine of 0.5 to 1.0 mg/dL following intravenous contrast administration. The prevalence is dose related and, although controversial, nonionic contrast material is associated with lower prevalence of CIN compared with ionic contrast material. Preexisting renal insufficiency, diabetes, dehydration, cardiovascular disease, advanced age, multiple myeloma, and nephrotoxic drugs are known risk factors for developing CIN. Although the serum creatinine level gives only a crude estimate of renal function, most institutions use this value as a reference. The threshold value for the use of iodinated contrast media varies from institution to institution, but the majority adopt a threshold value of 1.5 mg/dL for selecting high-risk patients for CIN. Prophylactic measures for high-risk patients include adequate hydration and use of a minimum required dose of nonionic contrast media. Oral N -acetylcysteine and sodium bicarbonate infusion can be used, but their effects have not been investigated fully.

A bowel preparation with a mild oral laxative can be used before IVU. Stimulating a bowel movement can reduce gas and fecal material in the colon and may improve visualization of the kidneys and ureters.

Techniques

Intravenous iodinated contrast material is given most commonly by hand injection. The dose of contrast depends on the patient size and radiologist’s or institution’s preference. Typically, a total volume of 50 to 100 mL of contrast medium is administered. Timed, sequential films are obtained before and after contrast administration. Nephrotomography increases sensitivity for depicting renal calculi or masses. Prone, upright, or oblique images can be added for suspicious renal and ureteral lesions. Postvoid bladder imaging is helpful in evaluating bladder contractility, postvoid residual, and urethral diverticula.

Indications and Contraindications

Voiding cystourethrography is commonly used for the evaluation of vesicoureteral reflux but can also be helpful in evaluating various bladder and urethral abnormalities. This study should be avoided in patients with acute or active urinary tract infection. Although intravesical contrast is normally not absorbed into the bloodstream, sporadic cases of anaphylactic reaction during VCUG or RGP have been reported.

Techniques

Diluted iodinated contrast material is given through a transurethral Foley catheter to fill the bladder. Spot radiographs of the bladder and kidneys are obtained after fully filling the bladder and during micturition.

Indications and Contraindications

RGP is often indicated for patients with nonvisualization on the IVU or a suspicious filling defect or obstructing lesion in the upper urinary tract on IVU or CT. It can also be used when IVU or CT cannot be performed due to the patient’s impaired renal function. Although RGP may accurately demonstrate urothelial details, it is more invasive and requires catheterization and sedation or anesthesia.

Indications and Contraindications

US is commonly used as a screening modality for urinary tract obstruction or renal masses and can be used in pregnant patients owing to a lack of ionizing radiation and wide availability. US can depict hydronephrosis easily and can differentiate solid from cystic renal masses. Despite its high sensitivity in depicting hydronephrosis, the ureters are difficult to image on US and the evaluation of stone disease or obstructing lesion can be limited. Because of this limitation, it has been suggested that US should be used in combination with KUB for the evaluation of obstructing stone disease and with IVU for hematuria workup when CT cannot be used.

Indications and Contraindications

Noncontrast CT (NCT) has been commonly used in evaluating patients with acute flank pain in the United States. NCT has been reported to be superior to IVU, with reported sensitivities ranging from 94% to 99% compared with that of IVU ranging from 63% to 75%. NCT has also been reported to be cost effective in evaluating patients with acute flank pain. Owing to recent technical advances, the total scan time is less than 5 minutes and multiplanar reconstruction can be generated ( Fig. 2-1 ). Compared with KUB, the radiation dose of NCT examination is higher. The mean effective dose of single abdominopelvic CT is typically more than 10 times that of KUB. However, when compared with standard IVU, CT can be performed with similar or reduced radiation.

Noncontrast CT in a patient with right flank pain. A 3-mm calculus (arrows) is seen in the right upper ureter. Transaxial images through the right renal hilum (A) and lower kidney (B). C, Coronal reconstructed image. Note mildly dilated right renal pelvis (asterisk) .

(See Video 2-8 on DVD for CT scan demonstrating an obstructing stone. )

Indications and Contraindications

With recent technical advances of multidetector CT, CTU has become the major diagnostic imaging tool for urinary tract abnormalities and has rapidly replaced IVU in many instances. The most common indications for CTU include hematuria workup ( Fig. 2-2 ) and postoperative follow-up for patients with urothelial carcinoma; however, it can be used for most IVU indications. CTU is commonly used to evaluate the ureters and lower urinary tract for injury or obstruction. It has been reported to be superior to IVU in determining the cause of hematuria and in depicting nephrolithiasis and renal masses. Although IVU has been most commonly used for evaluating urothelial tumors, the role of CTU is increasing. Reported accuracies for CTU in depicting urothelial tumors range from 89% to 94%. Because iodinated contrast material is used as for IVU, CTU is contraindicated in patients with a history of severe iodinated contrast allergy or severe renal impairment.

Normal CT urography in a patient with hematuria. Transaxial (A) and coronal (B) reformatted excretory phase images obtained 10 minutes after contrast administration. C, Three-dimensional volume-rendered image. D, Plain radiograph obtained 20 minutes after contrast administration.

(See Video 2-9 on DVD for CT urogram demonstrating a three-dimensional rotating image. )

Techniques

CTU techniques are still being developed and refined and the detailed protocols are different from institution to institution. Typically, a total of two or three abdominopelvic acquisitions are obtained before and after contrast administration, which includes an unenhanced scan, an early nephrographic phase scan (70 to 120 seconds following contrast administration), and an excretory phase scan (3 to 15 minutes following contrast administration). Renal parenchymal lesions such as cysts or tumors are best seen on nephrographic phase images and renal collecting systems, ureters, and bladder can be best evaluated on excretory phase images. The acquisition of thin-slice CT scans of an optimally distended urinary tract obtained during the excretory phase of enhancement is essential for CTU (see Fig. 2-2 ). Additional delayed imaging may be required in patients with urinary tract obstruction as well as those with urinary tract injury or suspicious fistula following pelvic surgery.

Because the use of CTU is increasing, the radiation dose to patients is of growing concern. The mean effective dose of a typical CTU examination is more than 2 times that of a single-acquisition abdominopelvic CT. Because of this higher radiation dose, precautions should be taken when imaging children or young patients. In this case, the examination should be avoided when possible and low-dose techniques can be applied.

Indications and Contraindications

Although the spatial resolution of MRI is inferior to that of CT, it can be used in patients with iodinated contrast allergy or renal impairment, or in children or pregnant women. MRI can be helpful in staging renal tumors and in characterizing cystic renal masses. MRI is limited, however, in evaluating urinary calculi. Although small caliceal abnormalities or urothelial tumors may be difficult to depict on MRU, recent advances in techniques seem to be promising. MRU can be used as an alternative to CTU when CTU is contraindicated ( Fig. 2-3 ).

Normal MR urography. A and B, Consecutive coronal, 10-minute–delayed, contrast-enhanced, three-dimensional spoiled, gradient-recalled echo sequence images. C, Three-dimensional volume-rendered image of the urinary tract.

(See Video 2-10 on DVD for CT urogram demonstrating construction of three-dimensional images. )

Whereas iodinated contrast medium is used for CT, gadolinium chelates are used for MRI. Recently, exposure to gadolinium in patients with renal failure and those maintained on dialysis has been linked with the development of nephrogenic systemic fibrosis. This disease may involve the skin, skeletal muscles, heart, lungs, and other organs, and can be fatal. The majority of affected patients are on dialysis or have stage 4 or 5 chronic renal disease. Because of the risks for this devastating disease, it is recommended that all patients scheduled for MRI should be screened for a history of renal disease or dialysis. In patients with severe renal disease or renal failure, the estimated glomerular filtration rate should be obtained before the MRI examination. Gadolinium contrast agents should be avoided in patients with estimated glomerular filtration rate equal to or less than 30 mL/min/1.73 m ² or those already on dialysis.

Techniques

In addition to the common sequences of noncontrast T1- and T2-weighted imaging of the abdomen and pelvis, typical MRU protocol includes noncontrast coronal heavily T2-weighted hydrographic sequences and contrast-enhanced coronal and/or axial T1-weighted, three-dimensional-spoiled, gradient-recalled echo sequences in nephrographic and excretory phase (see Fig. 2-3 ). Commonly, 10 to 20 mg of furosemide is given intravenously to achieve maximal distention of the urinary tract.