The aim of this study was to evaluate the tissue stiffness of solid pancreatic lesions by using acoustic radiation force impulse (ARFI) elastography to differentiate benign from malignant pancreatic lesions.
ARFI elastography was performed in 26 patients who had 27 focal solid pancreatic lesions, including 8 benign lesions (mass-forming pancreatitis, 5; autoimmune pancreatitis, 3) and 19 malignant lesions (pancreatic adenocarcinoma, 16; metastasis from colorectal cancer, 2; malignant neuroendocrine tumor, 1). On the elastographic images of virtual touch tissue imaging (VTI), the echogenicity of the mass was categorized on a 5-grade scale. On the elastographic image of virtual touch tissue quantification (VTQ), the shear wave velocities (SWVs) of the lesion and surrounding parenchyma were measured.
On the VTI images, the mean echogenicity score of the malignant lesions (3.7±1.0) was higher than that of the benign lesions (3.1±0.4; P=0.023). On the VTQ images, there were no statistical differences in the mean SWV between the benign (2.4±1.1 m/sec) and malignant (3.3±1.0 m/sec) lesions (P=0.101). However, the mean SWV difference values between the lesion and background parenchyma of the malignant lesions (1.5±0.8 m/sec) were higher than those of the benign lesions (0.4±0.3 m/sec; P=0.011).
ARFI elastography can determine the relative stiffness between a lesion and the background pancreatic parenchyma using VTI and VTQ, which is helpful in the differentiation between benign and malignant solid pancreatic lesions.
Ultrasonography (US) is a useful imaging modality for detection of focal pancreatic lesions. To characterize the lesions and determine malignancy, however, its role is limited; differentiation between pancreatic cancer and mass-forming pancreatitis is challenging in many cases encountered in daily practice [
Elastography is a method for visualizing the elastic properties of tissue using ultrasound. This technology is divided into strain elastography to visualize the tissue deformation induced by external compression and shear wave elastography, which estimates the shear wave velocity generated using an acoustic push pulse [
Recently, acoustic radiation force impulse (ARFI) elastography has emerged as a new method for measuring the stiffness of deep tissue, making transcutaneous elastography of the pancreas more feasible as a result. Pancreatic applications of US elastography are relatively recent because of the difficulty in pressing the pancreas, which is located deep in the body. Endoscopic ultrasound (EUS) elastography is rather widely used for diagnostic purposes, and its effectiveness has been well documented [
Pancreatic ductal adenocarcinoma is a firm mass, owing to the presence of fibrosis and a marked desmoplastic reaction [
Permission from the Institutional Review Board (IRB) at our institution was granted to perform this review and analysis. The IRB waived the requirement for informed consent for this retrospective study. We retrospectively identified a total of 29 patients with focal solid pancreatic lesions who underwent ARFI elastography, with the diagnosis confirmed by histopathologic examinations after surgical resection or US-guided biopsy between May 2010 and March 2013 by searching the medical databases. Three patients were excluded from the study due to technical failure from the patient’s inability to hold his or her breath properly.
Thus, our study population consisted of a total 26 patients (16 males, 10 females). There were 27 lesions included in this study because one patient with mass-forming pancreatitis had two lesions. The pancreatic lesions included 8 benign lesions (mass-forming pancreatitis, 5; autoimmune pancreatitis, 3) and 19 malignant lesions (pancreatic adenocarcinoma, 16; metastasis from colorectal cancer, 2; malignant neuroendocrine tumor, 1). The mean age of the benign group and malignant group was 62 years (range, 51 to 81 years) and 57 years (range, 37 to 75 years), respectively.
All of the patients underwent conventional abdominal US and ARFI scans, and a radiologist (JHC) with 17 years' experience of abdominal US conducted all of the examinations. Siemens Acuson S2000 CDFI (Siemens, Mountain View, CA, USA) and ARFI imaging technology using a 4C1 convex array probe with a frequency of 2.0-4.0 MHz were used in this study. Two kinds of ARFI elastography imaging studies, virtual touch tissue imaging (VTI) and virtual touch tissue quantification (VTQ), were performed and analyzed to assess the qualitative and quantitative lesion stiffness. When ARFI scanning was performed, the patient was asked to stop breathing for a moment for accurate and reproducible estimation.
A VTI image visualizes the relative stiffness in the selected region of interest (ROI) with a gray-scale map. It uses a dual imaging screen with the left screen showing the B-mode image and the right screen showing the elastographic image. Tissue softness is portrayed by high echogenicity and hardness by low echogenicity [
The VTQ image measures the shear wave velocity (m/sec) of the lesion by placing the ROI within the lesion tissues. The stiffer the tissue, the faster the shear waves propagate. Thus it provides numerical measurements about tissue elasticity properties [
The statistical analysis was performed using SPSS ver. 12.0 (SPSS Inc., Chicago, IL, USA). The mean sizes of the benign and malignant lesions were compared with each other with the use of a t-test. Comparisons of the mean echogenicity score in the VTI image, mean shear wave velocitie (SWV, m/sec) of the lesion and surrounding parenchyma, mean SWV difference value (=mean SWV of the lesion-parenchymal mean SWV, m/sec) in the VTQ image between benign and malignant lesions were performed by a Mann-Whitney U-test. Differences were considered significant at P<0.05. Correlations between the SWV and lesion size were tested using Spearman’s correlation coefficient.
The mean maximum diameter of the benign group and malignant group was 2.5 cm (range, 1.1 to 10.3 cm) and 2.9 cm (range, 1.2 to 7.4 cm), respectively. There was no significant difference in the mean maximum diameter between the benign and malignant liver lesions (P=0.303).
On the VTI images, the mean echogenicity score of the malignant lesions (3.7±1.0) appeared higher compared with that of the benign lesions (3.1±0.4; P=0.023) (
The mean ARFI value of the extra-lesional pancreatic parenchyma was 1.78 m/sec. The malignant group (1.55±0.6 m/sec) showed a higher ARFI value than the benign groups (2.11±0.8 m/sec), although the difference was not statistically significant (
Regarding the transcutaneous or EUS elastography in the assessment of focal pancreatic lesions, some earlier studies analyzing elastographic patterns were rather inconclusive due to the subjectivity of the interpretation of the color map and a lack of reliability and consistency [
Several studies on transcutaneous elastography of the pancreas have been published in the recent literature but with limited validity. Uchida et al. [
ARFI is a kind of shearwave elastography. It provides information about tissue stiffness by focusing high-intensity acoustic pulses on a target area using a conventional ultrasound probe to propagate shear waves and detect the tissue's response by using a tracking pulse emitted by numerous transmission channels [
According to earlier studies investigating the role of ARFI, the mean ARFI value for normal pancreatic parenchyma was approximately 1.28 to 1.40 m/sec [
In the present study, the relative stiffness of a lesion to the adjacent parenchyma was significantly higher in the malignant group than in the benign group on both VTI and VTQ images. The stiffness of extra-lesional pancreatic parenchyma was also higher in the benign group than the malignant group. This means that fibrosis and calcification that developed not only in the lesion but also in the surrounding parenchyma in the benign group resulted in higher stiffness than would be found in normal parenchyma, making the difference in stiffness between the lesion and surrounding parenchyma insignificant. Based on the results of the present study, because both pancreatic adenocarcinoma and mass-forming chronic pancreatitis are characterized by hardness, the relative stiffness of a lesion to its adjacent parenchyma can be expected to provide more accurate information than the absolute ARFI value of a lesion.
This study has several limitations. First of all, a smaller number of subjects with benign lesions, that is, mass-forming pancreatitis, than those with pancreatic adenocarcinoma made it difficult to generalize the results of the study. Further research needs to include a larger number of patients with benign lesions. Regarding the technical limitations, ARFI is a static image that is sensitive to motion during measurement; thus it is not effective in examining patients with a lesion near a large blood vessel and those who have difficulty sustaining a breath hold. Five-time sampling would not be enoughfor obtaining conclusive results.
In conclusion, ARFI elastography identified relative stiffness values between the lesion and background pancreatic parenchyma using VTI and VTQ, which could be helpful in differentiating malignant tumors from benign inflammatory lesions, although there was a considerable degree of overlap between the ARFI values of the benign and malignant lesions.
No potential conflict of interest relevant to this article was reported
This study was supported in part by the Research Fund of the Korean Society of Ultrasound in Medicine.
A. On a VTI image, a score 2 lesion appears to have a light gray color. B. On a VTI image, a score 3 lesion has a gray color. C. On a VTI image, a score 4 lesion appears to have a patchy black color. D. On a VTI image, a score 5 lesion appears dark black.
The mean echogenicity score for the benign group and malignant group were 3.1±0.4 and 3.7±1.0, respectively (P=0.023).
A. On a conventional B-mode image, the lesion appears as a hypoechoic mass (left image). On a virtual touch tissue imaging elastographic image, the lesion shows a stiffness similar to the surrounding pancreatic parenchyma (echogenicity score, 3) (right image). The shear wave velocity of the lesion and surrounding pancreatic parenchyma was 2.08 m/sec and 2.02 m/sec, respectively. B. Axial computed tomography scan shows an ill-defined hypodense mass in the pancreatic head region.
A. On a conventional B-mode image, the lesion appears as an illdefined hypoechoic mass (left image). On a virtual touch tissue imaging elastographic image, the lesion appears to be stiffer than the surrounding pancreatic parenchyma (echogenicity score, 4; right image). The shear wave velocity of the lesion and surrounding pancreatic parenchyma was 4.85 m/sec and 2.23 m/sec, respectively. B, C. Axial computed tomography scans show an ill-defined hypodense mass in the pancreatic body, distal p-duct dilatation, and parenchymal atrophy, suggesting pancreatic cancer.
A. The mean shear wave velocity (SWV; m/sec) for the benign group and malignant group were 2.4±1.1 and 3.3±1.0, respectively (P=0.101). B. The mean shear wave velocity difference value (SWV of lesion-SWV of normal parenchyma) for the benign group and malignant group were 0.4±0.3 and 1.5±0.8, respectively (P=0.011).
Comparison of the acoustic radiation force impulse values in the benign and malignant groups
Variable | Benign | Malignant | P-value |
---|---|---|---|
Mean echogenicity score | 3.1±0.4 (2–4) | 3.7±1.0 (2–5) | 0.023 |
Mean SWV of the mass (m/sec) | 2.4±1.1 (0.9–3.7) | 3.3±1.0 (1.3–4.8) | 0.101 |
Parenchymal mean SWV (m/sec) | 2.11±0.8 (1.2–3.4) | 1.55±0.6 (0.9–3.8) | 0.121 |
Mean SWV difference value |
0.4±0.3 (0.1–1.6) | 1.5±0.8 (0.3–3.4) | 0.011 |
SWV, shear wave velocity.
Mean SWV difference value (m/sec)=mean SWV of the mass (m/sec)-parenchymal mean SWV (m/sec).