MRI of the kidney—state of the art

Renal cell carcinomas account for 3% of all malignancies in adults. Almost 50% are detected incidentally. As many as 85% of suspicious renal lesions are malignant [10]. Features indicating potential malignancy of a renal lesion are size of the lesion, the presence of calcifications, the distribution of the calcifications within the lesion, wall thickness and the presence of septa in case of a cystic lesion (Fig. 1), inhomogeneity of the lesion, extension of the tumor beyond Gerota’s fascia, and last but not least, enhancement after contrast administration. Concerning calcifications in cystic lesions, recent research suggests that the importance of these calcifications as a determinant of malignancy is relatively low [11].

Duchene found in 186 renal tumors that all tumors greater than 7 cm (n = 48) were malignant. About 80% of tumors smaller than 3 cm were malignant [10]. The differential diagnosis of solid renal lesions smaller than 7 cm consists of oncocytoma, angiomyolipoma, hemangioma, leiomyoma, and focal xanthogranulomatous pyelonephritis. Of these lesions, only cysts and angiomyolipomas can often be positively identified as benign lesions.

Generally, MRI is performed only after a renal lesion has been detected by ultrasound or CT. CT may be followed by MRI if the enhancement at CT imaging is indeterminate (10–20 Hounsfield Units) [12] or in case of suspected pseudo-enhancement. At CT examination, simple cysts may show pseudo-enhancement after intravenous contrast administration, which is an increase in attenuation of more than 10 Hounsfield Units, not caused by administered contrast or by partial volume effect but by technical factors [13].

In recent years, interest in nephron-sparing surgery has been growing. At first, partial nephrectomy was mainly performed in case of a solitary kidney or diminished renal function, in order to preserve as much function as possible. Due to improving techniques and to increasing application of modern imaging modalities, the number of small, incidentally detected renal tumors is increasing [38]. This development has encouraged surgeons to use nephron-sparing surgery also for patients with normal renal function. The long-term follow-up data suggest that survival after partial nephrectomy of small renal cell carcinomas is comparable to total nephrectomy [39]. The ideal tumor for partial nephrectomy is smaller than 3 cm, is confined to the parenchyma of the kidney and has a peripheral location [40]. The presence of a pseudocapsule around a renal tumor is a sign of lack of perinephric fat invasion and therefore a favorable sign for partial nephrectomy [38, 41]. A pseudocapsule consists of compressed renal tissue and fibrous tissue. The sensitivity of CT in depicting a pseudocapsule is low (10–26%), whereas MRI shows a moderate to high sensitivity in depicting the pseudocapsule (54–93%) [41, 42]. On MRI, a pseudocapsule presents as a hypointense rim around the tumor on both T1-weighted and T2-weighted images, but can be best seen on the T2-weighted images and sometimes on gadolinium-enhanced GRE images [40].

Transitional cell carcinoma of the kidney is usually evaluated by intravenous urography, CT and endoscopy. However, MRI may play a role if CT and endoscopy are not feasible. CT may not be possible in case of poor renal function, and in case of ureteral obstruction, contrast excretion may be too limited to allow tumor detection. The ureter may not be accessible for endoscopy because of fibrosis and stricture of the ureter and ureter ostium. This may especially be the case in patients who have been treated for bladder cancer. These patients are at particularly increased risk for upper urinary tract transitional cell carcinoma [43]. Transitional cell carcinoma of the pyelum or ureter will generally show as an irregular mass projecting in the lumen. In the collecting system, transitional cell carcinoma is usually confined to the lumen (Fig. 4), but infiltrative growth into the renal parenchyma occurs and typically does not distort the renal contour. Chahal et al. applied MR urography (MRU) in 23 patients with high clinical suspicion of upper tract transitional carcinoma and hydronephrosis that could not be explained with other imaging modalities. MRU showed five renal pelvic transitional cell carcinomas and eight ureteral transitional cell carcinomas, confirmed by histology. In the remaining patients, no sign of transitional cell carcinoma was observed during 1-year follow-up [43]. Although these results are promising, the number of publications on MRI for transitional cell carcinoma is limited and more research is required to determine the value of MRI for the detection of transitional cell carcinoma.

Oncocytomas are benign, most often asymptomatic renal tumors. They represent 2–12% of renal masses. On MRI, oncocytomas show variable low signal intensity on T1-weighted images (Fig. 5) and heterogeneous high signal intensity on T2-weighted images. In 33–54% a central scar with low signal intensity on both T1- and T2-weighted images is visible. After contrast enhancement a spoke-wheel-like pattern may be observed [44]. Both a central scar and spoke-wheel pattern, however, may also be seen in renal cell carcinomas [38, 45] and are therefore not specific for oncocytomas. Oncocytomas may show a pseudocapsule, consisting of compressed renal parenchyma and fibrous tissue. One should be aware that a pseudocapsule is not specific for oncocytoma, since renal cell carcinomas can also be surrounded by a pseudocapsule. Because the characteristics of oncocytomas show considerable overlap with the characteristics of renal cell carcinomas, the therapy for a suspected oncocytoma is usually surgical [38].

Angiomyolipomas are benign hamartomatous tumors, consisting of fat, smooth muscle and blood vessels. Angiomyolipomas are the only solid renal tumors that can be positively characterized using MRI [46]. Angiomyolipomas are identified by demonstrating macroscopic fat in the lesion (Fig. 6). The ability to differentiate angiomyolipomas is especially urgent in patients with tuberous sclerosis, since angiomyolipomas develop in about 80% of these patients, and at the same time these patients are at an increased risk of developing renal cell carcinomas. Macroscopic fat in a renal lesion can be detected by CT using density measurement and by MRI using fat-suppression techniques. On the opposed-phase gradient echo images, macroscopic fat is demonstrated by a hypointense rim surrounding the fat (India ink artifact) [46]. It must be noted that the India ink artifact also occurs at the interface between tumors that don’t contain fat and the surrounding perinephric fat, if the tumor extends into the perinephric fat.

If the amount of intralesional fat is small, the differentiation between angiomyolipoma and renal cell carcinoma may be difficult (Fig. 7). Kim et al. showed for CT that homogeneous enhancement and a prolonged enhancement pattern were significantly more prevalent in angiomyolipoma with minimal fat than in renal cell carcinoma [47]. Using both CT findings as a criterion for the differentiation of angiomyolipoma with minimal fat from renal cell carcinoma, they found a positive predictive value of 91% and a negative predictive value of 87%. It is likely that this is also the case in contrast-enhanced MRI, however this has not yet been proved.

It has been shown that clear cell carcinomas may show signal loss on opposed-phase images compared to in-phase images, due to intracellular lipid [21]. This loss of signal intensity should be distinguished from the signal loss at the interface of macroscopic fat and surrounding tissue in angomyolipomas on opposed-phase images, especially if the amount of macroscopic fat is small. If in doubt, the in-phase gradient echo images are often helpful because the fatty portion of angiomyolipomas will be hyperintense, whereas renal clear cell carcinomas are generally hypo- or isointense [6, 46]. Unfortunately, clear cell carcinomas are incidentally hyperintense on T1-weighted images [48]. In these cases spectral fat-suppression images should be used to prove the presence of macroscopic fat in the angiomyolipoma.

Attention should be paid to the possibility that carcinomas sometimes contain hemorrhage, causing high signal intensity on in-phase T1-weighted images. In these cases, opposed-phase images and spectral fat suppression will not show a drop in signal intensity.

Xanthogranulomatous pyelonephritis is a rare chronic pyelonephritis, which may result in severe renal impairment. It is most common in middle-aged women, but it may also occur in children. Often Proteus or E. coli species are involved and the pyelonephritis is often accompanied by calculi, most typically staghorn calculi. It may be accompanied by calyx obstruction and parenchymal abscesses. In xanthogranulomatous pyelonephritis, the affected renal parenchyma is replaced by lipid-laden macrophages, resulting in the typical yellow-gray appearance of the lesion at macroscopy. It may involve the whole kidney, or it may be focal. Especially when it is focal, xanthogranulomatous pyelonephritis may be mistaken for a renal carcinoma. On T1-weighted images, the solid component of the lesion may be isointense or hyperintense, which can be attributed to the fatty component. On T2-weighted images, the signal intensity of the solid component is isointense to slightly hypointense. The parenchymal cavities filled with fluid and pus show high signal intensity on T2-weighted images and low signal intensity in T1-weighted images, varying according to the protein concentration in the cavity [49, 50]. In xanthogranulomatous pyelonephritis, the perirenal fascia may be thickened and show enhancement after gadolinium administration [49]. The absence of hyperintense signal on T2-weighted images of the solid components may be helpful in the differentiation between xanthogranulomatous pyelonephritis and renal tumor [50].

Measurement of renal perfusion may be a tool to assess the significance of renal artery stenosis and to assess ischemic nephropathy, and it may be used in renal transplant assessment. Several techniques have been studied to measure renal perfusion [1]. The maximum slope Gd-DTPA technique uses the maximum slope of the Gd-DTPA enhancement curve in relation to the maximum Gd-DTPA concentration in the aorta to calculate renal blood flow. The Gd-DTPA concentration in the aorta can be calculated using pre-contrast and post-contrast relaxation times measured in the aorta, assuming a linear relationship between gadolinium concentration and the inverse of the pre- and post-contrast T1 difference. Calibration of the signal intensity is performed using phantoms with increasing gadolinium concentration [67].

Furthermore, attempts have been made to assess renal perfusion by arterial spin labeling. To prevent leakage of the contrast medium into the extravascular space, albumin-bound contrast agent is used [68]. However, the different MRI renal perfusion techniques still need to be validated so more research is needed to assess the clinical usefulness.

The glomerular filtration rate (GFR) is a parameter that is used to assess renal function. The serum creatinine level is a rough indicator of the glomerular filtration rate, it is easy and cheap to obtain, but it provides no information about each individual kidney. For the measurement of the GFR by MRI, several techniques have been investigated. The first technique used MR spectroscopy to measure the T1 relaxation times of urine and serum samples taken at intervals after intravenous gadolinium administration. Calculation of the glomerular filtration rate was based on the linear relationship of 1/T1 to the serial dilution measurements of the serum and urine samples [69]. This technique still had the disadvantage of measuring the GFR of both kidneys together.

Another MR technique assessing each individual kidney was developed by calculating the extraction fraction (EF) of Gd-DTPA, which is the difference between renal arterial and renal venous Gd-DTPA concentration, normalized to the arterial Gd-DTPA concentration: \({\text{EF}} = {{\left( {{\text{Gd}}^{{{\text{art}}}} {\text{ - Gd}}^{{{\text{venous}}}} } \right)}} \mathord{\left/ {\vphantom {{{\left( {{\text{Gd}}^{{{\text{art}}}} {\text{ - Gd}}^{{{\text{venous}}}} } \right)}} {{\text{Gd}}^{{{\text{art}}}} }}} \right. \kern-\nulldelimiterspace} {{\text{Gd}}^{{{\text{art}}}} }.\) The gadolinium concentrations can be calculated after measurement of the T1 relaxation time of arterial and venous blood before and after intravenous gadolinium administration, using the formula \({\text{1}} \mathord{\left/ {\vphantom {{\text{1}} {{\text{T1}}^{{{\text{post}}}} }}} \right. \kern-\nulldelimiterspace} {{\text{T1}}^{{{\text{post}}}} } = {\text{1}} \mathord{\left/ {\vphantom {{\text{1}} {{\text{T1}}^{{{\text{pre}}}} }}} \right. \kern-\nulldelimiterspace} {{\text{T1}}^{{{\text{pre}}}} } + {\left[ {{\text{Gd}}} \right]} * R,\) where R is the relaxivity of gadolinium, and T1^pre and T1^post are the T1 relaxation times before and after intravenous gadolinium. The glomerular filtration rate can then be calculated according to the formula \({\text{GFR}} = {\text{EF}} * {\text{RBF}} * {\left( {{\text{1 - Hct}}} \right)},\)where RBF is renal blood flow, which can be measured by phase contrast flow quantification [3], and Hct is hematocrit [66].

An alternative MRI technique to measure glomerular filtration rate also uses contrast-enhanced dynamic MRI and is based on a the time-dependent concentrations of Gd-DTPA in the cortex and the medulla—a two compartment model [1]. The different techniques to measure glomerular filtration rate still need to be validated, and their role in clinical practice needs to be established.