Applied Radiology

Editor-in-Chief

Professor of Radiology Gerald D. Dodd, Jr. Distinguished Chair Diagnostic Imaging Director of Academic DevelopmentUniversity of Texas M.D. Anderson Cancer Center Houston, TX

Contributing Editors

Janio Szklaruk, MD, PhD University of Texas M.D. Anderson Cancer Center, Houston, TX

Chaan S. Ng, MD University of Texas M.D. Anderson Cancer Center, Houston, TX

Eric Tamm, MD University of Texas M.D. Anderson Cancer Center, Houston, TX

Terry J. Cooper, MBA, MT (ASCP)

University of Texas M.D. Anderson Cancer Center, Houston, TX

Imaging and Clinical Staging of Biliary Tract Tumors with MSCT

Janio Szklaruk, MD, PhD and Paul M. Silverman, MD

Cholangiocarcinomas are malignant tumors of the biliary tract that represent <2% of all neoplasms. ¹ Biliary tract cancer is, however, the second most common primary hepatobiliary malignancy, following hepatocellular carcinoma. In the United States, an estimated 2000 to 3000 bile duct cancers are diagnosed annually with a 1.2/100,000 rate of occurrence. ¹ Cholangiocarcinoma is more common in males (1.5:1) with an average onset in the 5th decade. These tumors can be divided into intrahepatic (8% to 13%) and extrahepatic location (87% to 92%). ¹ Extrahepatic tumors are divided into proximal, middle, or distal ductal tumors. Tumors located at the confluence of the right and left hepatic ducts with the proximal common hepatic duct are termed Klatskin tumors (Table1). Increased incidence of cholangiocarcinoma occurs in patients with choledochal cysts, liver fluke ( Chlonorchis sesensis ) infestation, thorotrast exposure, and ulcerative colitis with and without primary sclerosing cholangitis. The latter is the most common predisposing factor although in most cases the etiology is indeterminate. The clinical manifestations of cholangiocarcinoma are secondary to bile duct obstruction and include jaundice, prutitus, clay-colored stools, weight loss, cola-colored urine, and pain. The staging of the disease uses TNM classification. The primary tumor is defined by confinement to the bile duct and by local invasion. The thin wall of the bile ducts predisposes to periductal invasion. Extension of tumor to the liver, pancreas, ampulla of Vater, duodenum, colon, omemtum, stomach, or gallbladder are common. Late in the disease, distant metastases in the liver, lung, and peritoneum may occur. Surgery is the only curative treatment modality. Tumors are considered unresectable if there are distant metastases, bilateral involvement of the secondary radicles of the biliary tree, main portal vein involvement, or portal vein involvement with lobar atrophy. The application of chemotherapy and radiotherapy are currently under clinical trials.

Imaging plays an essential role in the clinical management of bile duct cancers. The goal of imaging is to identify the cause of biliary obstruction. If it is secondary to a mass lesion, the mass must be localized and its local extent determined, including invasion of adjacent vascular structures and hepatic parenchyma. Imaging must also identify the presence of distant metastases.

CT

CT is the most common imaging modality for staging bile duct tumors. Helical CT or multislice CT (MSCT) with dynamic contrast enhancement provides high-detail images for the diagnosis and staging of biliary tract cancer. The normal intrahepatic bile ducts are barely visible with a diameter <2 mm. The normal extrahepatic bile duct and common bile duct are visible with a paper-thin wall. The CT findings of extrahepatic cholangiocarcinoma are: (1) an infiltrating stenotic lesion with focal or eccentric wall thickening (Figure 1); (2) a polypoid mass; or (3) a mucin-producing intraductal tumor. Dilatation of bile duct, an abrupt change in duct caliber, non-union of bile duct radicles, and lobar atrophy are indirect signs of bile duct cancer.

With conventional and single-slice helical CT, the detection rate for hilar cholangiocarcinoma is poor, with reported rates varying from 40% to 68%. ² Current biphasic and thin-section scanning techniques using MSCT has improved lesion detection to 82% to 100%. ³ Using the biphasic helical scanning, the density of these tumors during the early phase, as compared with the surrounding liver, is quite variable; the tumors are reportedly hyperdense in 30% to 100% of cases. Tumors were identified to be hyperdense in either or both phases in 81%-100% of cases. Multiphasic CT for the staging of hilar cholangiocarcinoma results in a high rate of accuracy in the diagnosis of advanced disease. However, the technique still needs improvement in predicting resectability, as its rate of accuracy varies from 50% to 60%. ³ CT tends to underestimates the extent of bile duct involvement, portal vein or hepatic artery involvement, and nodal metastasis and peritoneal metastases.

Currently at our institution, we use a biphasic scanning technique (the late arterial phase and the portal venous phase) following an intravenous (IV) injection of nonionic contrast material (150 to 180 mL) delivered by a power injector at a rate of 5 mL/sec (Szklaruk J, Silverman PM, Charnsangavej C. Imaging in the diagnosis, staging, treatment, and surveillance of biliary tumors. Unpublished data, 2003). The initial phase is scanned from the dome of the diaphragm inferiorly to the distal bile duct 30 seconds after the start of contrast injection. A breath hold of only 15 to 20 seconds is necessary to acquire images of this region at a slice thickness of 1 to 3 mm. This late arterial phase of imaging is utilized to maximize the enhancement of the tumor in the hilar region and to enhance visualization of its relationship to the hepatic artery. The second phase, or portal venous phase, is obtained after a pause of 7 to 10 seconds for breathing following the completion of the first phase. This phase emphasizes the relationship between the tumor and the portal vein and adjacent liver.

Applications of MSCT

The gold standard for biliary tree evaluation is direct but invasive contrast opacification of the biliary system using percutaneous cholangiography (PTC) or endoscopic retrograde cholangiopancreatography (ERCP). The complication rates for these procedures are 3.4% and 0.5% to 5%, respectively. ⁴ Magnetic resonance cholangiopancreatography (MRCP) has gained popularity as a noninvasive technique.

CT technology with three-dimensional (3D) reconstruction is evolving in its application in the evaluation of the biliary tree. CT cholangiography can provide images of the biliary tree using two techniques. In the first technique, the biliary tree is opacified by the oral or IV administration of a radiodense biliary contrast agent. Thin-section axial images are then reconstructed in the desired plane, typically a coronal or coronally obliqued plane, using a maximum intensity projection (MIP) algorithm. More recently, a technique has been developed that avoids the administration of a cholangiographic agent. In this technique, thin-section axial images acquired after the administration of conventional IV contrast are reconstructed in the desired plane using a minimum intensity projection (Min, Figures 2 and 3), or a volume-rendering (VR, Figure 4) technique. There is a good correlation between the images produced using these techniques and those generated by ERCP or PTC. An additional advantage of this second technique is that the axial source images can also be postprocessed to display arterial and venous anatomy in any desired plane (CT angiography/CT portography, Figure 5). Thus, the information that can be provided by a single multiphase, multislice CT examination can be used to provide a variety of perspectives (angiographic, cholangiographic, and morphologic) for aiding treatment planning.

For preoperative MSCT assessment of patients with bile duct tumors, we currently use a combination of thin axial-source images, acquired in multiple phases as outlined above, with several postprocessing techniques. Coronally oriented MIP images are generated of the arterial and portal venous structures (CT arteriography and CT portography, Figure 5). Oblique coronally oriented MIP (Figure 6) and Min images (Figures 3 and 4) are generated of the biliary tree and the pancreatic ducts. We currently also use a 3D volume postprocessing technique to estimate segmental volume in the assessment of the preoperative patient. Our experience with evaluating biliary tract cancer using this combination of techniques has had promising results.

In conclusion, the combination of axial and multiplanar reconstructed images from MSCT allows an improved sensitivity of detection, staging, and surgical planning of bile duct tumors.

References

1. Blumgart LH, Fong Y, Jarnagin WR. Hepatobiliary Cancer . Lewiston, NY: B.C. Decker; 2001.

2. Choi B, Lee JH, Han MC, et al. Hilar cholangiocarcinoma: Comparative study with sonography and CT. Radiology . 1989;172:689-692.

3. Tillich M, Milschinger HJ, Preisegger KH, et al. Multiphasic helical CT in diagnosis and staging of hilar cholangiocarcinoma. AJR Am J Roentgenol . 1998;171:651-658.

4. Loperfido S, Angelini G, Benedetti G, et al. Major early complications from diagnostic and therapeutic ERCP: A prospective multicenter study. Gastrointest Endosc. 1998;48:1-10.

TECHNICAL ISSUES

Multislice CT in 3D Imaging for Partial Nephrectomy

Chaan S. Ng, MD, Marc J. Fenstermacher, MD, and Paul M. Silverman, MD

Refinements in surgical technique have allowed for increased application by urologists of partial nephrectomy for small renal tumors. For the radiologist who has multislice CT (MSCT), it represents a challenge and opportunity to demonstrate its outstanding imaging capabilities in helping urologists assess and plan surgery. The rationale for pursuing partial, rather than total or radical, nephrectomies is the motivation to sacrifice as little normal renal tissue as possible in the process of removing the tumor, hence nephron-sparing surgery. The approach is further strengthened by emerging data that indicates that nephron-sparing surgery is as efficacious as total nephrectomy for renal tumors, with reported local recurrence rates of <2% and 5-year survivals of 87% to 90%, which are comparable with those from radical nephrectomy. ¹

The indications for nephron-sparing partial nephrectomy are evolving. At our institution, the current requirements are that the tumor is <4 cm in size and that it is located peripherally. Specific indications are absence of a contralateral kidney, renal insufficiency, and conditions in which patients are at an increased risk for bilateral renal tumors, such as in patients with von Hippel Lindau.

Surgical approaches to partial nephrectomy include open surgery, laparoscopic surgery, and hand-assisted laparoscopic surgery. The advantages of the laparoscopic approaches include a faster postoperative recovery for patients, with all the associated benefits.

Important determinants for the feasibility of and surgical approach for partial nephrectomy include the location of the tumor, in particular its relationship to the renal pelvic structures, specifically the renal artery(s) and vein(s), and the collecting system. Identification of accessory renal arteries is particularly important in assisting planning. Other aspects of preoperative staging also need to be addressed; for example, exclusion of renal vein thrombosis, and detection of adrenal masses, contralateral renal masses, and abnormally enlarged lymph nodes.

At our institution, MSCT evaluation of renal tumors with a view to partial nephrectomy involves a multiphasic protocol encompassing from above the kidneys superiorly to the proximal common iliac arteries inferiorly. Scans are undertaken using 5-mm collimation and 15-mm table speed (pitch 1.5, 120 kV, 370 mA, HS mode, LightSpeed scanner, GE Medical Systems, Milwaukee, WI). Data is reconstructed prospectively at 2.5-mm slice thickness, 1.5-mm intervals. The raw data prior to reconstruction is not saved due to archival constraints. Patients are given oral contrast 45 minutes prior to their scan. Precontrast images are obtained of the abdomen. We administer 150 mL of 300 mg/mL nonionic contrast at 5 mL/sec through a peripheral line, and scan at delays of 25 sec (arterial/early cortico-medullary phase), 100 sec (nephrographic phase), and 180 sec (excretory phase), utilizing breath-holds of approximately 12 to 15sec for each phase. If required, an evaluation of the chest and/or abdomen (and pelvis) can be undertaken in the interscan periods, with the abdomen (and pelvis) scan typically being interposed between the arterial and nephrographic phases of the renal scan. The latter are undertaken using the HQ mode of the GE LightSpeed scanner utilizing 7.5-mm collimation, table speed of 15 mm, 120 kV, and 220 mA.

The reconstructed 2.5-mm thick, 1.5-mm interval source images from each of the renal phases are transferred to a workstation (Vitrea2, Vital Images Inc., Minneapolis, MN, or General Electric Advantage Windows) for image processing. Image manipulation includes multiplanar orthogonal, oblique and/or curved reformations, MIP reconstruction, and 3D volume rendering. Although all phases of the study are potentially useful, the arterial phase images are particularly useful for determining the number and origin of the renal arteries, and evaluating the tumor in relation to the arteries, veins, and collecting system.

Variant or aberrant anatomy and relationship of the tumor to structures in the renal pelvis are vital in the evaluation for surgical and preoperative planning, particularly when considering laparoscopic approaches (Figure 1). Urologists find the presentation of 3D data, particularly surface-rendered presentations, extremely helpful in allowing them to plan their surgery, as it provides them with a realistic sense of what they are likely to see at surgery. ^2,3 It should noted however, that 3D manipulations can create artifacts, and careful review of the source images is advised in these circumstances.

With the increased incidence of renal tumor detection, particularly of small tumors detected incidentally in the course of other radiologic studies, including CT body screening, there is likely to be a concomitant increase in the demand for nephron-sparing surgery. With the addition of 3D techniques, MSCT is an important tool to assist urologists in their planning for partial nephrectomies.

References

1. Novick AC. Advances in the management of localized renal cell cancer. Can J Urol. 2000;7:960-966.

2. Sheth S, Scatarige JC, Horton KM, et al. Current concepts in the diagnosis and management of renal cell carcinoma: Role of multidetector CT and three-dimensional CT. RadioGraphics . 2001;21:S237-S254.

3. Urban BA, Ratner LE, Fishman EK. Three-dimensional volume-rendered CT angiography of the renal arteries and veins: Normal anatomy, variants, and clinical applications. RadioGraphics . 2001;21:373-386.

PRACTICAL ISSUES

Pitfalls in the Diagnosis of Pancreatic Cancer by CT

Eric Tamm, MD and Paul M. Silverman, MD

Because of its poor prognosis, pancreatic cancer remains the fifth leading cause of cancer death in the Western hemisphere. ¹ Surgical resection remains the only option for cure. However, nearly 60% of patients have advanced disease at the time of diagnosis. Accurate staging by CT may mean the difference between unnecessary surgery and the possibility for cure.

Optimal technique is essential. When multislice CT (MSCT) is used at our institution, dual-phase imaging technique is utilized. Patients are injected with 150 mL of nonionic intravenous (IV) contrast at a rate of 5 mL/sec. Imaging during the first phase, the pancreatic parenchymal phase, begins 25 seconds after the start of IV contrast injection. Imaging begins at the level of the diaphragm and extends through the pancreas to the horizontal portion of the duodenum at 2.5-mm slice thickness at a table speed of 7.5 mm/sec, reconstructed to 1.25-mm slice thickness. Imaging of the pancreas therefore occurs at 35 to 45 seconds after the start of injection of IV contrast. This first phase is utilized to evaluate for the primary tumor, detection of vascular variants, and for involvement of vasculature.

During the second phase (the portal venous phase [PVP]) imaging begins 55 seconds after beginning IV contrast injection at the level of the diaphragm through to the horizontal portion of the duodenum at 5-mm slice thickness, table speed of 15-mm/sec, reconstructed to 2.5-mm slice thickness. This second phase is utilized to evaluate for possible liver metastases and to offer a second opportunity to evaluate the portal venous system for local tumor involvement.

The first possible pitfall is the result of poor technique. Low injection rates of contrast or poor timing of image acquisition can result in poor differentiation between the tumor and normal pancreatic parenchyma, which results in failure to diagnose pancreatic cancer.

Another potential pitfall occurs when CT is performed too soon after other diagnostic procedures (Figures 1 and 2). Often, CT examinations are performed following ERCP. In patients who complain of upper abdominal pain, the first diagnostic procedure is typically an abdominal ultrasound. When such a study reveals a dilated common bile duct and no evidence of cholecystitis, ERCP is often utilized next. When ERCP shows possible malignant narrowing of the common bile duct, brushings are obtained and, typically, a stent is placed. CT may follow shortly. However, postprocedure inflammatory changes from pancreatitis and artifacts directly related to a stent can result in either a misdiagnosis of cancer or a failure to detect malignancy. These inflammatory changes can also infiltrate the fat surrounding the superior mesenteric artery as well as the common hepatic artery resulting in a misdiagnosis of tumor involvement. Therefore, caution should be exercised when interpreting such CT studies. Follow-up examinations, allowing for resolution of possible inflammatory changes, would be advised. Similar difficulties are encountered when CT follows immediately after an endoscopic ultrasound (EUS)-guided, fine-needle aspiration (FNA).

Signs that are useful for diagnosing pancreatic cancer include dilatation of the pancreatic duct with abrupt change in caliber, the presence of a hypodense mass, focal enlargement of the pancreas, soft-tissue changes surrounding vasculature, and mass effect upon vasculature, as well as signs of spread of disease, including adenopathy, peritoneal disease, and metastatic disease to the liver and lungs. The presence of multiple signs increases the probability of diagnosis of pancreatic cancer.

Hypodense changes from focal chronic pancreatitis can mimic pancreatic cancer closely ² ; chronic pancreatitis can also be associated with stricture of the pancreatic duct, distortion of the contour of the pancreas, and thrombosis of the splenic vein. Therefore, the presence of pancreatic cancer must be determined by biopsy, which is typically obtained with endoscopic ultrasound guidance. The greater sensitivity of EUS and the high specificity of EUS-guided FNA, ^3,4 also allows for the evaluation of cases that are negative on CT.

In summary, MSCT can provide a comprehensive evaluation for pancreatic cancer. Furthermore, optimal technique and knowledge of the patient's clinical history, including the nature of prior work-up, is essential in avoiding diagnostic pitfalls. Biopsy is required to confirm the diagnosis of pancreatic cancer. In the case of negative EUS, negative biopsy, and negative MSCT, close follow-up by CT and EUS may be necessary to prove the absence of cancer.

References

1. Jemal A, Thomas A, Murray T, Thun M. Cancer statistics, 2002. CA Cancer J Clin. 2002;52:23-47.

2. Kim T, Murakami T, Takamura M, et al. Pancreatic mass due to chronic pancreatitis: Correlation of CT and MR imaging features with pathologic findings. AJR Am J Roentgenol. 2001;177:367-371.

3. Harewood GC, Wiersema MJ. Endosonography-guided fine needle aspiration biopsy in the evaluation of pancreatic masses. Am J Gastroenterol . 2002;97:1386-1391.

4. Shin HJ, Lahoti S, Sneige N. Endoscopic ultrasound-guided fine-needle aspiration in 179 cases: The M.D. Anderson Cancer Center experience. Cancer . 2002;96:174-180.

MEDICAL ECONOMICS

The Privacy Act and Its Impact on Patient Care

Terry J. Cooper, MBA, MT (ASCP)

Well, it seems that this HIPAA thing is not going away anytime soon. So, just like everything else in life, those of us in health care will have to adapt to the changes required to be in compliance with the HIPAA Privacy Rule by April 14, 2003. ¹ The American public continues to express their concerns about protecting their identifiable health information, also known as protected health information (PHI). The Health Privacy Project, at Georgetown University's Institute for Health Care Research and Policy, cited the following data ² :

* 1 of 5 American adults believes that a healthcare provider, insurance plan, government agency, or employer has improperly disclosed personal medical information. ³

* 74 % of the respondents said the privacy of their personal health information is very important. ⁴

* 75% of people are concerned about health Web sites sharing information without their permission. ⁵

The purpose and intent of the HIPAA is to protect the right of individuals to keep information about themselves from being disclosed. The HIPAA Privacy Rule is designed to safeguard records that hold personal health information. Paper records, electronic records, and oral communication are covered. Oral communication runs the gamut from paging patients, to whispering in corridors and elevators, and talking on cell phones. Confidential information is not necessarily relegated to a patient's name. ⁶ In fact, it includes information related to a person's past, present, or future physical or mental health condition and anything associated with healthcare services or treatment.

The Privacy Rule can be summed up as:

* Creating limits on the uses and disclosure of PHI;

* Giving patients new rights to access their medical records and to know who else has accessed them;

* Restricting most disclosure of PHI to the minimum needed for the intended purpose (minimum necessary guidelines);

* Creating new criminal and civil sanctions for improper use or disclosure of PHI; and

* Establishing new requirements for access to records by researchers and others. ⁷

While these rights are available to all patients, healthcare providers should review any requests carefully. The provider must weigh a patient's request against prudent patient care to prevent disruption of that care. Providers should explain to patients that excessive restrictions could impede timely care.

So, in general, what does the HIPAA Privacy Rule require the average healthcare provider to do? For the average provider, the Privacy Rule requires activities, such as:

* Notifying patients about their privacy rights and how their information can be used;

* Adopting and implementing privacy procedures for its practice, hospital, or plan;

* Training employees so that they understand the privacy procedures;

* Designating an individual to be responsible for seeing that the privacy procedures are adopted and followed; and

* Securing patient records containing individually identifiable health information so that they are not readily available to those who do not need them. ¹

Responsible healthcare providers and businesses already take many of the kinds of steps required by the Privacy Rule to protect patients' privacy. To ease the burden of complying with the new requirements, the Privacy Rule gives needed flexibility for providers to create their own privacy procedures, tailored to fit their size and needs. The scalability of the Privacy Rule provides a more efficient and appropriate means of safeguarding protected health information than would any single standard.

For example, the training requirement may be satisfied by a small physician's practice when each new member of the workforce is provided with a copy of its privacy policies and documentation is obtained that new members have reviewed the policies. In contrast, a large health organization may provide training through live instruction, video presentations, or interactive software programs.

Under HIPAA, a provider must issue a written Notice of Privacy Practices (NPP) to patients outlining its privacy practices and patients' rights. Anyone can request the NPP, although first-time patients must receive theirs at the time of initial contact where PHI is exchanged. In cases of phone communications, the NPP should be sent out via mail within 24 hours (preferably) or given to patients upon arrival for their first visit or treatment. If the provider has a Web site, the NPP should be posted and be downloadable. Regardless of whether the Notice is mailed or electronically downloaded, a good faith effort must be made to acquire a written acknowledgement from the patient. ¹

HIPAA is not another Y2K event, but an evolving piece of legislation. The Department of Health and Human Services has the authority to modify the privacy standards, as the Secretary may deem appropriate. However, a standard can be modified only once in a 12-month period. For those in healthcare, the HIPAA Privacy Rule uses the term reasonable several times throughout the regulation. Our approach to the Privacy Rule must be reasonable, not to over self-regulate your practices to the point of impeding quality care.