MDCT of blunt renal trauma: imaging findings and therapeutic implications

In case of blunt thoraco-abdominal trauma, a clear distinction must be made between haemodynamically unstable and haemodynamically stable or stabilised patients; indeed, the former must immediately undergo surgical exploration in order to try to improve their outcome, whereas the latter should undergo imaging studies in order to better assess the presence of visceral injuries and guide treatment. Although some controversies still exist, in haemodynamically stable (or stabilised) patients who have suffered blunt thoracic and/or abdominal trauma, absolute indications for imaging in the suspicion of renal injuries are gross haematuria, microscopic haematuria associated with hypotension, suspicion of major injuries to other viscera and trauma dynamics strongly associated with renal injury (i.e., rapid deceleration, fall from great height and direct contusion to the flank) [3, 5].

Several different imaging techniques have been considered as the initial imaging tool in the suspicion of renal injury in haemodynamically stable patients; nowadays, however, thanks to its wide availability, reproducibility, scan speed and high spatial resolution, contrast-enhanced multidetector computed tomography (MDCT) is considered the gold standard imaging modality in case of suspicion of renal injury and has completely replaced intravenous urography for this purpose [3, 5, 21‐24]. The great advantage of MDCT is its ability to assess, in an extremely rapid scanning time, the presence of lesions of the parenchyma, vessels and collecting system and of injuries to other abdominal organs.

Multidetector CT systems are nowadays ubiquitously available in trauma centres and represent the minimum requirement for emergency renal imaging. The availability of modern scanners with a high number of detector rows (16 or more) enables shortening acquisition times, therefore reducing the possibility of motion artefacts and increasing image quality.

A correct positioning of the patient on the CT table represents a fundamental prerequisite for performing high-quality MDCT studies. Whenever possible, the patient should lay supine on the table, with the arms bent over the head in order to prevent beam-hardening artefacts; if that position cannot be obtained, the patient’s arms should be placed flexed on a large pillow ventrally to the patient’s chest [25]. Moreover, all the medical devices that are not strictly necessary should be removed from the scan area.

The MDCT scanning protocol in the setting of suspected renal trauma should always be always tailored according to the clinical conditions of the patient. Most authors sustain that a non-enhanced acquisition should always be performed in order to detect intraparenchymal, subcapsular or perinephric haematomas, which will appear as slightly hyperattenuating areas or collections during this phase, whereas they might be barely recognisable on post-contrast images [26‐28]. According to our experience, however, the performance of native scans is not necessary in the setting of renal trauma for two reasons: first, the large majority of the above-mentioned lesions are clearly recognisable also on post-contrast images; second, those lesions that might eventually be missed (i.e., small intraparenchymal or subcapsular haematomas) do not have any therapeutic consequences. In any case, when acquiring post-contrast images using a dual-energy technique, virtual non-enhanced images may be retrospectively generated from post-contrast ones by means of commercially available software and show similar accuracy to true non-contrast ones for the detection of haematomas [29].

On the other hand, post-contrast acquisitions must always be performed in case of suspicion of renal injuries. About 1.7–1.5 ml/kg of 350–370 mgI/ml iodinated contrast material must be administered using a flow rate of at least 3.5 ml/s, followed by a 50-ml saline flush. Contrast-enhanced scans should be acquired cranio-caudally, with thin collimation (0.625 mm). Multi-planar reformats (MPR), maximum intensity projection (MIP) and volume-rendering (VR) reconstructions represent extremely useful tools for imaging interpretation. According to the wide variability of circulatory conditions in trauma patients, post-contrast scans should be always performed using a bolus-tracking technique. A late arterial/corticomedullary phase acquisition should be acquired with a 15-s delay from a 100-HU peak aortic enhancement when using a bolus-tracking technique or with a 30-s fixed delay after injection if bolus-tracking is not available; this phase is mandatory for recognising arterial vascular lesions (i.e., renal artery avulsion or thrombosis, pseudoaneurysms and artero-venous fistulae) and for detecting active arterial contrast material extravasation; moreover, it enables to accurately depict the arterial vascular anatomy and eventual variants. The portal-venous or nephrographic phase, acquired 70-80 s after the start of contrast material injection, represents the best phase for detecting parenchymal lesions (i.e., lacerations and segmental infarctions), venous vascular lesions (i.e., avulsion or thrombosis of the renal vein) and haematomas and should be always performed in case of suspicion of renal injury; moreover, it represents a useful aid for assessing the relevance of an active arterial contrast material extravasation and enables accurately ruling out injuries to other parenchymatous abdominal organs. The decision to acquire a delayed excretory scan is strictly dependent on the patient’s clinical conditions and the findings in the previous phases. The timing of the delayed acquisition depends on renal function and may vary from 5 to 15 or more minutes; 8 min may represent a good compromise in the majority of the cases. Delayed acquisitions are fundamental for the detection of collecting system injuries, by showing hyperdense urine extravasation, and may also help in the differential diagnosis between renal contusion and infarction [3].

MDCT can generate a wide spectrum of findings in renal trauma and the majority of these can be easily categorised into the above-mentioned five AAST grades; moreover, MDCT may also show some findings that are not mentioned in the AAST classification, the latter being based on the kidney appearance at surgery. The AAST classification must be kept in mind when reporting renal injuries, particularly because of its prognostic implications; in any case, subtle differences in AAST grade do often not have practical consequences for patient management. In the following paragraphs we will describe the possible MDCT findings in renal trauma grouped by their therapeutical management and not simply by the AAST grading scale.