True partial diphallia with associated penoscrotal transposition of two hemi-scrotums.

Diphallia or duplication of penis is extremely rare condition with a reported incidence of 1 in 5-6 million live births. Approximately around 100 cases of diphallia have been described in literature, each case have a unique presentation from associated anomalies. Clinically these patients can be classified into complete (true diphallia) or partial duplication. In true diphallia, each penis has 2 corpora cavernosa and 1 corpus spongiosum. If the duplicate penis is smaller or rudimentary with complete structure, it is described as true partial diphallia. The term bifid phallus is used if there is only one corpus cavernosum in each penis. Due to low incidence and varied presentation, not much is known about the underlying pathophysiology, management options, and outcomes. Here, we report a case of partial diphallia with associated penoscrotal transposition of 2 hemi-scrotums.

US artifacts.

Image artifacts are commonly encountered in clinical ultrasonography (US) and may be a source of confusion for the interpreting physician. Some artifacts may be avoidable and arise secondary to improper scanning technique. Other artifacts are generated by the physical limitations of the modality. US artifacts can be understood with a basic appreciation of the physical properties of the ultrasound beam, the propagation of sound in matter, and the assumptions of image processing. US artifacts arise secondary to errors inherent to the ultrasound beam characteristics, the presence of multiple echo paths, velocity errors, and attenuation errors. The beam width, side lobe, reverberation, comet tail, ring-down, mirror image, speed displacement, refraction, attenuation, shadowing, and increased through-transmission artifacts are encountered routinely in clinical practice. Recognition of these artifacts is important because they may be clues to tissue composition and aid in diagnosis. The ability to recognize and remedy potentially correctable US artifacts is important for image quality improvement and optimal patient care.

Multidetector CT arteriography with volumetric three-dimensional rendering to evaluate patients with metastatic colorectal disease for placement of a floxuridine infusion pump.

OBJECTIVE: We sought to evaluate the usefulness of multidetector CT (MDCT) arteriography with volumetric three-dimensional (3D) rendering to depict the hepatic vascular anatomy. Our study population was patients who had undergone arterial mapping in preparation for placement of a hepatic arterial floxuridine infusion pump for treatment of metastatic hepatic colorectal carcinoma. MATERIALS AND METHODS: We retrospectively reviewed the medical records of 26 patients with hepatic colorectal metastases who had been scheduled for implantation of a hepatic artery pump. Before surgery, all patients underwent MDCT arteriography with volumetric 3D rendering of the hepatic vessels. The axial and 3D arteriograms were evaluated for their usefulness in depicting hepatic arterial anatomy. Subsequently, three patients also underwent catheter angiography. Twenty-two of the 26 patients imaged had a hepatic artery floxuridine infusion pump implanted. Results of the CT arteriography were correlated with findings at surgery or on catheter angiography if surgery was not performed. RESULTS: MDCT arteriography correctly revealed hepatic arterial anatomy in all 25 patients with angiographic or surgical confirmation. One patient with aberrant hepatic arterial anatomy did not have angiographic or surgical confirmation. Classic hepatic arterial anatomy was identified in 16 (64%) of 25 patients. The following hepatic arterial variants were found in one patient each: the common hepatic artery arising directly from the aorta; a replaced left hepatic artery; an accessory right hepatic artery; a replaced left hepatic artery and accessory right hepatic artery; a replaced right hepatic artery; a right hepatic arterial branch arising early (before the origin of the gastroduodenal artery); and replaced right and left hepatic arteries. Three patients were not suitable candidates for placement of a hepatic artery floxuridine pump. The patient who had no angiographic or surgical confirmation was also not considered a good surgical candidate because of replaced right and left hepatic arteries. Two patients (8%) had an accessory left hepatic artery. CONCLUSION: MDCT arteriography with volumetric 3D rendering is an accurate, noninvasive method of depicting hepatic arterial anatomy and, therefore, of selecting patients with colorectal metastatic disease who could benefit from hepatic artery pump implantation. Catheter angiography provides no additional information, and we have eliminated it as a routine preoperative imaging examination.

Hemodynamic characterization of focal nodular hyperplasia using three-dimensional volume-rendered multidetector CT angiography.

OBJECTIVE: The goal of this study was to show the ability of three-dimensional multidetector CT angiography to display the angioarchitecture of focal nodular hyperplasia. CONCLUSION: CT angiography with volume rendering shows the anomalous feeding artery and hepatic draining veins that are characteristic of focal nodular hyperplasia. These features may be helpful in distinguishing focal nodular hyperplasia from other lesions.

Three-dimensional multislice helical computed tomography with the volume rendering technique in the detection of vascular complications after liver transplantation.

BACKGROUND: Hepatic artery stenosis and thrombosis are common complications in liver transplant patients. Digital subtraction angiography (DSA) has served as the gold standard to make this diagnosis. More recently, three-dimensional helical computed tomographic arteriography (3D CTA) with maximum intensity projection and shaded surface display techniques has been compared with DSA. The purpose of this study was to determine whether 3D CTA with the volume rendering technique is a useful and accurate tool in the detection of vascular complications after liver transplantation. METHODS: Thirty-five consecutive liver transplant patients underwent 3D CTA with volume rendering technique. The standard of reference was DSA for 20 patients and imaging and clinical follow-up for 15 patients. Two blinded reviewers evaluated the axial and 3D CTA images in consensus. RESULTS: 3D CTA with volume rendering technique detected 10 hepatic artery stenoses, six hepatic artery thromboses, two hepatic artery pseudoaneurysms, two splenic artery aneurysms, two portal vein stenoses, and four redundant hepatic arteries. In one case computed tomography (CT) detected a moderate hepatic artery stenosis, while conventional angiography showed a normal artery. The sensitivity of CT for detecting vascular lesions was 100%, specificity was 89% (8 of 9), accuracy was 95% (19 of 20), positive predictive value was 92% (11 of 12), and negative predictive value was 100% (8 of 8). CONCLUSIONS: 3D CTA is a useful and accurate noninvasive technique for detection of vascular complications in liver transplant patients.