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Comparison of IV Contrast-Enhanced Sonography and Histopathology of Pancreatic Cancer

¹ Department of Imaging Diagnosis, Ogaki Municipal Hospital, 4-86 Minaminhokawa, Ogaki, Gifu 503-8502, Japan.
² Department of Gastroenterology, Ogaki Municipal Hospital, 4-86 Minaminokawa, Ogaki, Gifu 503-8502, Japan.

Received October 11, 2004; accepted after revision November 23, 2004.

 
Address correspondence to T. Kumada.

Abstract

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OBJECTIVE. We compared contrast-enhanced sonography findings with pathologic findings in pancreatic cancer to evaluate the ability of contrast-enhanced sonography to depict the pathologic changes associated with pancreatic cancer.

SUBJECTS AND METHODS. Thirty-four patients with pancreatic cancer who underwent surgery were investigated. Sonography was performed with contrast material (Levovist) for all patients before surgery. Pathologic findings were evaluated on the basis of the resected cancer specimens. We compared contrast-enhanced sonography findings with pathologic findings.

RESULTS. All tumors that were hyperechoic on contrast-enhanced sonography were papillary adenocarcinoma, and all tumors that were hypoechoic on contrast-enhanced sonography were ductal adenocarcinoma. Among ductal adenocarcinomas, five (71.4%) of seven tumors for which the size of the hypoechoic area was unchanged on contrast-enhanced sonography had clear tumor margins with no infiltration or inflammation in the margin. In contrast, all tumors for which the size of the hypoechoic area was reduced on contrast-enhanced sonography had unclear tumor margins with infiltration of cancerous cells and inflammation. Nine (90%) of 10 tumors that showed partial contrast enhancement or a vascular shadow in a hypoechoic area had large or medium-sized vessels within a tumor at pathology. In contrast, only one (4.8%) of 21 tumors that did not show the vascular shadow in a hypoechoic area had no large or medium-sized vessels in a tumor.

CONCLUSION. Contrast-enhanced sonography well reflects the pathologic changes of pancreatic cancer and will provide useful information in a pretreatment evaluation. Further studies with a large number of patients will be required to confirm this finding.

Introduction

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Pancreatic cancer is one of the malignant tumors with few clinical symptoms in its early stage, so it is frequently first observed in an advanced state. Sonography is one of the diagnostic methods used for screening of pancreatic tumors. Development of sonographic techniques and devices contributed to the early detection of pancreatic tumors. Unenhanced sonography, however, cannot provide sufficient information about the characteristics of these tumors and is limited to the detection of the pancreatic tumor itself; the imaging diagnosis of pancreatic cancer has usually been based on the combination of other imaging findings such as endoscopic sonography, CT, and MRI [1].

Contrast-enhanced sonography with the arterial infusion of CO₂ microbubbles is the first technique of contrast-enhanced sonography [2]. Initially, CO₂ sonography was useful for the diagnosis of liver tumors such as hepatocellular carcinoma and focal nodular hyperplasia [3–6]. In addition, the use of CO₂ sonography for the differential diagnosis of pancreatic tumors has been reported [7, 8]. However, CO₂ sonography requires angiography, so patients must undergo an invasive examination.

Recently, IV sonographic contrast agents have been developed, and contrast-enhanced sonography with these agents has become available in clinical practice. Contrast-enhanced sonography using the harmonic gray-scale method with the IV injection of a contrast agent enables the visualization of intratumoral blood flow dynamics that equals that of CO₂ sonography. In addition, compared with CO₂ sonography, contrast-enhanced harmonic gray-scale sonography has that advantage that it can be performed noninvasively at the bedside. This method has been frequently used for the evaluation of hepatic tumor lesions [9], but recently its usefulness in the evaluation of pancreatic tumors has been reported [10–14].

In our study, we compared the imaging findings of pancreatic cancer on the arterial phase of contrast-enhanced sonography using the IV sonographic contrast agent Levovist (SH U 508A, Schering) with macroscopic and microscopic pathologic findings based on resected pancreatic cancer specimens from patients who underwent surgery.

Subjects and Methods

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Patients
One hundred three patients with pancreatic disease underwent contrast-enhanced sonography in our hospital between September 1999 and October 2002. Among them, 40 patients underwent surgery for pancreatic tumors, and 34 patients were diagnosed with pancreatic cancer pathologically on the basis of a resected specimen. They consisted of 21 men and 13 women with a mean age of 66.6 ± 9.3 years (age range, 43–80 years). All patients also underwent contrast-enhanced dynamic helical CT before treatment. We compared contrast-enhanced sonography findings with pathologic findings of these 34 patients.

The entire study was approved by the hospital ethics committee and was performed in accordance with the Declaration of Helsinki [15]. Written informed consent was obtained from all patients before the study.

Imaging Procedures
Contrast-enhanced broadband harmonic gray-scale sonography was performed on all patients. A Sonoline Elegra system (Siemens Medical Solutions) was used, and images were obtained with a 3.5-MHz convex probe. The pancreas was scanned with tissue harmonic gray-scale imaging (transmit, 2.8 MHz; and receive, 5.6 MHz) before injection of the contrast agent. After the IV bolus injection of 300 mg/mL concentration of a galactose–palmitic acid contrast agent (Levovist), the pancreas was scanned using contrast-enhanced broadband harmonic gray-scale sonography (transmit, 2.8 MHz; and receive, 5.6 MHz) at a frame rate of 0.5–7 frames per second; we usually set 0.5–1 frame per second. The transmitted acoustic power was 100%, and the mechanical index values were between 1.7 and 1.9, which depended on the focus point. The focus position was just below the bottom of the lesion. Seven milliliters of contrast agent—air-filled microbubble suspension of galactose (99.9%) stabilized with 0.1% palmitic acid—was injected at 2.0 mL/sec via a 20-gauge cannula placed in an antecubital vein. Ten milliliters of physiologic saline was injected immediately after a bolus injection of the contrast agent. The patients gently inspired and then held their breath for about 50 sec (10–60 sec after contrast agent injection) while the enhancement of the lesion was examined (observation of the arterial phase). The full examinations were recorded on magnetooptical disks and S-VHS (super VHS) videotape.

Contrast-enhanced sonograms were evaluated by two of the authors independently. If there was a discrepancy between them, they reached agreement by consensus.

Histopathologic Evaluations
Resected specimens from all patients were explored both macroscopically and microscopically. Specimens were stained with H and E, and the entire specimen was explored. Pathologic evaluations were made independently by two authors (one pathologist and one gastroenterologist who is a pancreatic specialist) who were unaware of the contrast-enhanced sonography findings. If a discrepancy in classification existed between them, they reached agreement by consensus. Pathologic evaluation included measuring the size of the tumor (maximal diameter) and the blood vessels within it macroscopically, histologic classification of tumor differentiation, and microscopic evaluation of the infiltration of cancerous cells in the border of the tumor.

Based on the results of both evaluations, contrast-enhanced sonography images were compared with histopathologic findings from the resected specimens.

View larger version (8K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1 —Drawing shows patterns of changes on contrast-enhanced sonography. From top to bottom in far right column: complete hypoechoic response with hyperechoic spot (n = 1), complete hypoechoic response with no hyperechoic spot (n = 6), marginal isoechoic response with hyperechoic spot (n = 9), marginal isoechoic response with no hyperechoic spot (n = 15), and hyperechoic response (n =3) (bottom row).

Results

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Tumor size was 24.9 ± 8.1 mm in diameter on unenhanced sonography. According to the histologic classification, 31 patients had ductal adenocarcinoma (well-differentiated type in 11, moderately differentiated type in 18, and poorly differentiated type in two), and the other three had papillary adenocarcinoma.

Details of the Contrast-Enhancement Pattern
Details of the contrast-enhancement pattern are shown in Figure 1. In 31 (91.2%) of 34 patients, contrast enhancement was less marked in comparison with surrounding parenchyma of pancreas, and these were classified as hypoechoic. In the other three patients, contrast enhancement was distinctly strong in comparison with surrounding parenchyma, and these were classified as hyperechoic. The patients with a hypoechoic response were further subclassified as follows: no change was observed in the size of hypoechoic area before and after contrast enhancement (complete hypoechoic response), or tumor was depicted as a smaller hypoechoic area in comparison with the tumor before contrast enhancement (marginal isoechoic response). Seven patients had a complete hypoechoic response, and 24 had a marginal isoechoic response. In addition, in patients having a hypoechoic response, 10 tumors showed spotty or linear enhancement in the hypoechoic area and were classified as hyperechoic response–hyperechoic spot (+), whereas the other 21 tumors without the hyperechoic spot were classified as hypoechoic response–hyperechoic spot (–). One patient with a complete hypoechoic response and nine patients with marginal isoechoic responses were hyperechoic spot (+) and the remaining were hyperechoic spot (–).

View larger version (104K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2A —54-year-old man with hyperechoic response and 29 x 29 mm tumor of pancreatic head. Sonograms obtained before (A) and 18 (B), 46 (C), and 60 (D) sec after injection of contrast agent. Tumor (arrowheads, A) is gradually stained on contrast-enhanced sonography and becomes slightly hyperechoic compared with surrounding tissue.

View larger version (111K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2B —54-year-old man with hyperechoic response and 29 x 29 mm tumor of pancreatic head. Sonograms obtained before (A) and 18 (B), 46 (C), and 60 (D) sec after injection of contrast agent. Tumor (arrowheads, A) is gradually stained on contrast-enhanced sonography and becomes slightly hyperechoic compared with surrounding tissue.

View larger version (108K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2C —54-year-old man with hyperechoic response and 29 x 29 mm tumor of pancreatic head. Sonograms obtained before (A) and 18 (B), 46 (C), and 60 (D) sec after injection of contrast agent. Tumor (arrowheads, A) is gradually stained on contrast-enhanced sonography and becomes slightly hyperechoic compared with surrounding tissue.

View larger version (116K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2D —54-year-old man with hyperechoic response and 29 x 29 mm tumor of pancreatic head. Sonograms obtained before (A) and 18 (B), 46 (C), and 60 (D) sec after injection of contrast agent. Tumor (arrowheads, A) is gradually stained on contrast-enhanced sonography and becomes slightly hyperechoic compared with surrounding tissue.

View larger version (148K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2E —54-year-old man with hyperechoic response and 29 x 29 mm tumor of pancreatic head. Histopathologic image shows papillary adenocarcinoma with septa and vessel. (H and E, x100)

Table 1 shows the tumor size in patients with a complete hypoechoic response and in those with a marginal isoechoic response. On unenhanced sonography, the maximal tumor size in patients with a marginal isoechoic response was 24.7 ± 5.8 mm, which was significantly larger than that in patients with a complete hypoechoic response (19.2 ± 4.4 mm, p = 0.0353). In contrast, the maximal tumor size on contrast-enhanced sonography was similar in both groups (18.7 ± 4.5 mm in patients with a complete hypoechoic response and 16.4 ± 4.9 mm in those with a marginal isoechoic response, p = 0.2970). In pathologic evaluation of the resected specimens, the maximal tumor size was 18.5 ± 5.1 mm in patients with a complete hypoechoic response and 25.3 ± 6.9 mm in those with a marginal isoechoic response. The size of the tumor at pathology in patients with a marginal hypoechoic response was similar to that on unenhanced sonography and was significantly larger than that in patients with a complete hypoechoic response (p = 0.0229). In patients with a complete hypoechoic response, well-differentiated tubular adenocarcinoma was observed in four (57.1%) of seven patients, moderately differentiated in two (28.6%) of seven patients, and poorly differentiated in one (14.3%) of seven patients. In patients with a marginal isoechoic response, well-differentiated carcinoma was observed in seven (29.2%) of 24 patients, moderately differentiated in 16 (66.7%) of 24 patients, and poorly differentiated in one (4.2%) of 24 patients. A trend was seen to lower differentiation of tumors in patients with a marginal isoechoic response, but the difference was not statistically significant (p = 0.371).

Evaluation of the margin portion of the tumor revealed that clear margin type was found in five (71.4%) of seven patients having a complete hypoechoic response (Fig. 3A, 3B, 3C, 3D, 3E), whereas all the patients with a marginal isoechoic response were the unclear margin type (Fig. 4A, 4B, 4C, 4D, 4E), showing a distinct and significant difference between a complete hypoechoic response and a marginal isoechoic response (p < 0.0001, Table 2). In patients with an unclear margin type, a mixture of cancerous cells and inflammatory cells was observed in the marginal portion of the tumor that corresponded to the peripheral area of enhancement on contrast-enhanced sonography. In patients with a marginal isoechoic response, the size of the tumor evaluated pathologically based on a resected specimen was similar to that measured on unenhanced sonography (p = 0.2307) and was significantly larger than the size measured on contrast-enhanced sonography (p < 0.0001, Table 1).

View larger version (128K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3A —70-year-old man with complete hypoechoic response and 8 x 7 mm tumor of pancreatic head. Sonograms obtained before (A) and 12 (B), 16 (C), and 30 (D) sec after injection of contrast agent. Tumor is clearly depicted on contrast-enhanced sonography as hypoechoic tumor with high contrast, but reduction of hypoechoic area is not observed (arrowheads, A and D).

View larger version (135K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3B —70-year-old man with complete hypoechoic response and 8 x 7 mm tumor of pancreatic head. Sonograms obtained before (A) and 12 (B), 16 (C), and 30 (D) sec after injection of contrast agent. Tumor is clearly depicted on contrast-enhanced sonography as hypoechoic tumor with high contrast, but reduction of hypoechoic area is not observed (arrowheads, A and D).

View larger version (128K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3C —70-year-old man with complete hypoechoic response and 8 x 7 mm tumor of pancreatic head. Sonograms obtained before (A) and 12 (B), 16 (C), and 30 (D) sec after injection of contrast agent. Tumor is clearly depicted on contrast-enhanced sonography as hypoechoic tumor with high contrast, but reduction of hypoechoic area is not observed (arrowheads, A and D).

View larger version (130K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3D —70-year-old man with complete hypoechoic response and 8 x 7 mm tumor of pancreatic head. Sonograms obtained before (A) and 12 (B), 16 (C), and 30 (D) sec after injection of contrast agent. Tumor is clearly depicted on contrast-enhanced sonography as hypoechoic tumor with high contrast, but reduction of hypoechoic area is not observed (arrowheads, A and D).

View larger version (180K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3E —70-year-old man with complete hypoechoic response and 8 x 7 mm tumor of pancreatic head. Histopathologic image shows well-differentiated ductal adenocarcinoma with distinct margin (arrowheads). Infiltration of cancerous cells is not observed around margin. (H and E, x40)

View larger version (77K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4A —56-year-old man with marginal isoechoic response and 18 x 18 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 25 (C), and 45 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement on contrast-enhanced sonography, and hypoechoic area is reduced (arrowheads, A and D).

View larger version (100K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4B —56-year-old man with marginal isoechoic response and 18 x 18 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 25 (C), and 45 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement on contrast-enhanced sonography, and hypoechoic area is reduced (arrowheads, A and D).

View larger version (108K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4C —56-year-old man with marginal isoechoic response and 18 x 18 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 25 (C), and 45 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement on contrast-enhanced sonography, and hypoechoic area is reduced (arrowheads, A and D).

View larger version (113K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4D —56-year-old man with marginal isoechoic response and 18 x 18 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 25 (C), and 45 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement on contrast-enhanced sonography, and hypoechoic area is reduced (arrowheads, A and D).

View larger version (186K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4E —56-year-old man with marginal isoechoic response and 18 x 18 mm tumor of pancreatic head. Histopathologic image shows moderately differentiated ductal adenocarcinoma. Margin of tumor is indistinct, with marked infiltration of cancerous cells (arrowheads). (H and E, x200)

In the evaluation of blood vessels in the tumor in 31 ductal cell carcinomas, vessels of 0.1–0.5 mm in diameter were macroscopically confirmed in a tumor in 10 patients, and these tumors were classified as a tumor positive for blood vessels. In contrast, no vessels were observed macroscopically in a tumor in the other 21 patients, and their tumors were classified as negative for blood vessels. Among 31 patients with a hypoechoic response, a tumor positive for blood vessels was observed in nine (90.0%) of 10 patients who were hyperechoic spot (+) on contrast-enhanced sonography (Fig. 5A, 5B, 5C, 5D, 5E), whereas it was observed in only one (4.8%) of 21 patients who were hyperechoic spot (–) (p < 0.0001, Table 3).

View larger version (95K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5A —67-year-old man with marginal isoechoic response and positive hyperechoic spots in 29 x 24 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 18 (C), and 25 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement and reduction of hypoechoic area on contrast-enhanced sonography (arrowheads, A and D). Blood vessels developing in tumor are also depicted (arrowhead, C).

View larger version (95K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5B —67-year-old man with marginal isoechoic response and positive hyperechoic spots in 29 x 24 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 18 (C), and 25 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement and reduction of hypoechoic area on contrast-enhanced sonography (arrowheads, A and D). Blood vessels developing in tumor are also depicted (arrowhead, C).

View larger version (95K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5C —67-year-old man with marginal isoechoic response and positive hyperechoic spots in 29 x 24 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 18 (C), and 25 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement and reduction of hypoechoic area on contrast-enhanced sonography (arrowheads, A and D). Blood vessels developing in tumor are also depicted (arrowhead, C).

View larger version (93K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5D —67-year-old man with marginal isoechoic response and positive hyperechoic spots in 29 x 24 mm tumor of pancreatic head. Sonograms obtained before (A) and 15 (B), 18 (C), and 25 (D) sec after injection of contrast agent. Peripheral region of tumor shows mild heterogeneous enhancement and reduction of hypoechoic area on contrast-enhanced sonography (arrowheads, A and D). Blood vessels developing in tumor are also depicted (arrowhead, C).

View larger version (168K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5E —67-year-old man with marginal isoechoic response and positive hyperechoic spots in 29 x 24 mm tumor of pancreatic head. Histopathologic image shows moderately differentiated ductal adenocarcinoma; margin of tumor is indistinct, with marked infiltration of cancerous cells (arrowheads). Dilated vessels are observed on enlarged image (arrow). (H and E, x40)

Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Several studies have evaluated the vascularity of pancreatic mass lesions with various imaging techniques such as contrast-enhanced CT [16–20], Doppler sonography [21], endoscopic Doppler sonography [22, 23], and CO₂ sonography [7, 8]. These articles mainly focused on the differential diagnosis, based on tumor vascularity, of pancreatic tumors, including ductal adenocarcinoma, papillary adenocarcinoma, endocrine tumor, and benign nodule, that develop during the course of chronic pancreatitis. Four recent studies evaluated the vascularity of pancreatic tumors using sonography enhanced with the contrast agent Levovist [24–27]. In three of these reports, the vascularity of pancreatic tumors on contrast-enhanced sonography was compared with that on enhanced CT [24–26]. The study by Takeda et al. [27] attempted to compare contrast-enhanced sonography findings with pathologic findings, but in most cases pathologic findings were based on the samples of sonographically guided fine-needle aspiration biopsy.

In our study, we focused on pancreatic cancer and compared contrast-enhanced sonography findings with histopathologic findings based on resected specimens in all patients, with which we could perform pathologic analyses of the entire tumor, including tumor margins. All ductal adenocarcinomas were hypoechoic in comparison with the surrounding pancreatic parenchyma on contrast-enhanced sonography, indicating hypovascularity, whereas papillary adenocarcinomas showed hypervascularity. Contrast-enhanced dynamic CT also showed the enhancement of a tumor in all three patients with papillary adenocarcinoma, and no enhancement in all patients with ductal adenocarcinoma. Thus, contrast-enhanced sonography corresponded well with the dynamic CT findings of hypervascularity and hypovascularity, and these findings indicate that two histologic types of pancreatic cancer (i.e., ductal and papillary adenocarcinoma) can be distinguished by contrast-enhanced sonography findings.

In the case of ductal pancreatic cancer, two distinct patterns of enhancement were observed on contrast-enhanced sonography in comparison with unenhanced sonography: pancreatic tumors with a constant size of the hypoechoic area (complete hypoechoic response) and tumors with a reduced size of the hypoechoic area (marginal isoechoic response). This reduction in tumor size represents the isoechoic enhancement of peritumoral regions. We previously examined the pattern of enhancement of pancreatic cancer on CO₂ sonography but did not find as distinct a difference in enhancement patterns as that on contrast-enhanced sonography [28]. This difference in the enhancement pattern between CO₂ sonography and contrast-enhanced sonography may be caused by the difference in bubble size between the two contrast agents. The size of CO₂ microbubbles is about 30 µm, whereas that of Levovist microbubbles is about 1.3 µm. It is therefore presumed that the latter more easily reach the site where infiltration of cancer cells or inflammation is observed in the marginal portion and, as a result, the peripheral portion of the tumor is contrast-enhanced and the hypoechoic area is apparently reduced in size.

In a recent study, Ozawa et al. [25] also reported the isoechoic enhancement of the peripheral region of pancreatic cancer. Those authors speculated that the presence of secondary changes of the pancreatic parenchyma, such as inflammation and subsequent fibrosis, was associated with pancreatic cancer causing marginal isoechoic enhancement, but they did not state this theory as a conclusion because of the scarcity of resected samples. Our analyses clearly showed the pathologic findings of this isoechoic enhancement, which consisted of a mixture of cancerous and inflammatory cells. Importantly, this area contains the cancerous cells and should be regarded as part of the cancer, not as marginal pancreatic parenchyma. The size of a tumor on a resected specimen was similar to that on unenhanced sonography and larger than that on contrast-enhanced sonography. Thus, unenhanced sonography better reflected the actual tumor size. Pancreatic cancer tends to infiltrate in the early stage, and capsular infiltration is observed even in tumors of 20 mm or less. Contrast-enhanced sonography findings can indicate the infiltration of pancreatic cancer and can provide useful pretreatment information, especially as a preoperative evaluation in patients who are candidates for surgery.

The presence of hyperechoic spots in a hypoechoic area of the pancreatic tumor on contrast-enhanced sonography has been reported by other investigators [25–27]. Pathologically, hyperechoic spots correspond to large or medium-sized muscular arteries (0.1–0.5 mm in diameter) involved in the tumor. Park et al. [29] suggested that hypervascularity in pancreatic cancer that was evaluated on arterial phase helical CT was characterized by a large feeding artery. They reported that large and medium-sized arteries were found in the pancreatic cancer on microscopic examination, which is consistent with our results. In our previous study of CO₂ sonography, hyperechoic spots were depicted in two (6.9%) of 29 patients with ductal adenocarcinoma [28]; this rate is lower than that in patients with ductal adenocarcinoma with positive hyperechoic spots (10/31 patients, 32.3%). This difference is also caused by the difference in the size of microbubbles between CO₂ and Levovist. As well as the evaluation of tumor margins, contrast-enhanced sonography using Levovist has an advantage over CO₂ sonography in evaluating these tumor blood vessels because of its smaller bubble size.

In conclusion, pancreatic cancer that was more hyperechoic than the surrounding pancreatic parenchyma on contrast-enhanced sonography was considered to be papillary adenocarcinoma. In ductal adenocarcinoma, the tumor was more hypoechoic than the surrounding pancreatic parenchyma on contrast-enhanced sonography. Tumors that showed reduced tumor size on contrast-enhanced sonography had indistinct tumor margins with infiltrative invasion of cancerous cells and inflammation. Most ductal adenocarcinomas in which a hyperechoic spot was depicted on contrast-enhanced sonography had feeding arteries of 0.1–0.5 mm in diameter in the tumor. Thus, our study showed the ability of contrast-enhanced sonography to depict the details of pathologic changes associated with pancreatic cancer. Contrast-enhanced sonography can provide useful information on pancreatic cancer in a pretreatment evaluation. However, further studies with a larger number of patients will be required to confirm our findings.

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