Journal List > Korean J Radiol > v.18(6) > 1027395

Ahn, Lee, Chang, Lee, Kang, Yang, Yoon, Park, and Han: Prospective Validation of Intra- and Interobserver Reproducibility of a New Point Shear Wave Elastographic Technique for Assessing Liver Stiffness in Patients with Chronic Liver Disease

Abstract

Objective

To assess intra- and inter-observer reproducibility of a new point shear wave elastography technique (pSWE, S-Shearwave, Samsung Medison) and compare its accuracy in assessing liver stiffness (LS) with an established pSWE technique (Virtual Touch Quantification, VTQ).

Materials and Methods

Thirty-three patients were enrolled in this Institutional Review Board-approved prospective study. LS values were measured by VTQ on an Acuson S2000 system (Siemens Healthineer) and S-Shearwave on an RS-80A (Samsung Medison) in the same session, followed by two further S-Shearwave sessions for inter- and intra-observer variation at 8-hour intervals. The technical success rate (SR) and reliability of the measurements of both pSWE techniques were compared. The intra- and inter-observer reproducibility of S-Shearwave was determined by intraclass correlation coefficients (ICCs). LS values were measured by both methods of pSWE. The diagnostic performance in severe fibrosis (F ≥ 3) and cirrhosis (F = 4) was evaluated using the receiver operating characteristics curve analysis and the Obuchowski measure with the LS values of transient elastography as the referenced standard.

Results

The VTQ (100%, 33/33) and S-Shearwave (96.9%, 32/33) techniques did not display a significant difference in technical SR (p = 0.63) or reliability of LS measurements (96.9%, 32/33; 93.9%, 30/32, respectively, p = 0.61). The inter- and intra-observer agreement for LS measurements using the S-Shearwave technique was excellent (ICC = 0.98 and 0.99, respectively). The mean LS values of both pSWE techniques were not significantly different and exhibited a good correlation (r = 0.78). To detect F ≥ 3 and F = 4, VTQ and S-Shearwave showed comparable diagnostic accuracy as indicated by the following outcomes: areas under receiver operating characteristics curve (AUROC) = 0.87 (95% confidence intervals [CI] 0.70–0.96), 0.89 for VTQ (95% CI 0.74–0.97), respectively; and AUROC = 0.84 (95% CI 0.67–0.94), 0.94 (95% CI 0.80–0.99) for S-Shearwave (p > 0.48), respectively. The Obuchowski measures were similarly high for S-Shearwave and VTQ (0.94 vs. 0.95).

Conclusion

S-Shearwave shows excellent inter- and intra-observer agreement and diagnostic effectiveness comparable to VTQ in detecting LS.

INTRODUCTION

Cases of chronic liver diseases (CLD) caused by the hepatitis B or C viral infection are estimated to have reached approximately 280 million worldwide. The prevalence of nonalcoholic fatty liver disease is rapidly increasing; in particular, nonalcoholic steatohepatitis is estimated to affect 10–15% of the population in the United States of America (12). To assess the severity of fibrosis caused by various CLD, hepatologists can use either invasive (liver biopsy) or noninvasive techniques (3). Because a liver biopsy provides information regarding the fibrosis stage, necro-inflammation, and fatty infiltration and reveals specific markers in certain hepatic diseases, this morphologic examination is considered to be the “gold standard” method for the assessment of liver diseases (45). However, we must take into account that after a diagnostic liver biopsy, severe complications, including death, may occur in 1–5% of the cases (6). In addition, liver biopsy has limitations of sampling bias due to the uneven distribution of liver fibrosis and the small size of the specimen (approximately 1/50,000 of the total volume of the liver), and considerable inter- and intra-observer diagnostic discrepancies in the biopsy assessments of liver fibrosis (7).
For these reasons, there is a need for noninvasive methods to assess the degree of fibrosis in liver diseases, including serologic tests for several direct and indirect markers of liver fibrosis (8) and elastographic techniques such as transient elastography (TE) and an ultrasound (US)-based shear wave elastography (SWE) method (91011). Several published studies have reported that TE (FibroScan; Echosens, Paris, France) is a reliable diagnostic tool for the noninvasive evaluation of liver fibrosis (1213). In recent years, several US-based point shear wave elastography (pSWE) methods and two-dimensional (2D)-SWE using acoustic radiation force impulse quantification have become commercially available for the noninvasive assessment of liver fibrosis (101415). Shear wave-based elastographic methods can be implemented in standard US systems that are used for several other purposes (e.g., standard US examination, Doppler evaluation, contrast-enhanced US); therefore, these devices may be more cost effective for the simultaneous evaluation of chronic liver disease and surveillance of hepatocellular carcinoma (16). Among these techniques, the Virtual Touch Quantification (VTQ; Siemens AG, Erlangen, Germany), which is a type of pSWE technique, has been studied the most. More recently, 2D-SWE techniques have appeared on the market, and although they are promising and involve larger sample volumes than the pSWE techniques, there are several published studies regarding this technique (1517).
S-Shearwave elastography (S-Shearwave; Samsung Medison, Hongcheon, Korea) was recently developed and is based on the same physical principles as VTQ; therefore, it is expected to show promising results in measuring liver stiffness (LS) in hepatic fibrosis patients, similar to other pSWE techniques (1819). LS measurements using pSWE techniques such as VTQ and S-Shearwave require only a few minutes using conventional US probes. So, it can easily be performed during a regular liver US session (1819). However, the fibrosis cutoff values for US elastographic techniques are manufacturer dependent because of the variability in velocity measurements (9). So, depending on the US equipment used, its levels of technical success and reliable measurement of tissue stiffness and reproducibility of LS measurements for assessing LS must be determined before its clinical adoption for liver US examination (2021). However, until now, there has not been any studies that validate this new pSWE (S-Shearwave) and compare the performance of S-Shearwave with other previously introduced SWE techniques.
Therefore, the aims of this study were to estimate the validity of a new pSWE (S-Shearwave) technique by evaluating the reproducibility of measurements, and to compare the performance of S-Shearwave to that of VTQ considering the LS values measured by TE as the referenced standard.

MATERIALS AND METHODS

Study Population

This prospective study was approved by our Institutional Review Board, and written informed consent was obtained from all patients. From July to September 2016, 33 patients who were referred to the Radiology department for US examination before locoregional treatment of suspected small malignant liver tumors. Among them, 30 patients were diagnosed with CLD based on laboratory tests or clinical findings (22) and 3 patients had no parenchymal liver disease. The most common etiology of CLD was chronic hepatitis B (23/33, 69.7%), followed by chronic hepatitis C (4/33, 12.1%) (Table 1).
Liver stiffness values obtained by TE were used for the assignment of hepatic fibrosis stage in accordance with the referenced values provided by a previous meta-analysis (1223). Detailed characteristics of the study population are provided in Table 1. To assess the technical success rate (SR) and reliable measurement of the two pSWE techniques, the results of all 33 patients were included. For the comparison of two pSWE techniques (VTQ vs. S-Shearwave), only patients who had reliable LS values in both examinations and TE were included (Fig. 1).

Virtual Touch Quantification and S-Shearwave Measurements

Virtual Touch Quantification was performed using the Siemens Acuson S2000 Virtual Touch US system (Siemens AG), and S-Shearwave was performed using the Samsung RS 80A US system (Samsung Medison). In general, at least 10 measurements should be obtained; although, some studies suggest that a smaller number of measurements may have similar accuracy (1316). Technical failures and unreliable results occur more frequently in patients with liver cirrhosis than in patients with a normal liver (13). Hence, 15 measurements were made with each instrument per patient. All patients fasted for at least 6 hours prior to the examination and were placed in the supine position with the right arm maximally abducted above the head to stretch the intercostal muscles. One attending radiologist, who was blinded to the TE results and had 6 years of experience in US elastography and 20 years of experience with liver USs, performed VTQ and S-Shearwave. The LS measurement was done using the intercostal approach by placing the region of interest in the right anterior segment of the liver. The focal liver lesions and vessels were carefully avoided and a measurement depth of 25–45 mm was maintained from the liver capsule (Fig. 2). While the LS values were being measured, patients were instructed to hold their breath for approximately 5–7 seconds (1624). After all 15 measurements were acquired, we removed the measurement with lower than 0.4 calculated reliability measurement index (RMI) in order to increase the reliability (20). RMI is an automatically calculated value in the S-Shearwave that is obtained by the weighted sum of the residual of the wave equation and the magnitude of the shear wave when performing each stiffness measurement (20). The median value of LS measurements was automatically calculated and expressed in kilopascals (kPa). To avoid potential bias, the summary of the serial measurements of each technique was not available to the operator until two examinations were completed (1624).
Additional sessions were done with S-Shearwave to evaluate intra- and inter-observer agreement. After the initial measurement of S-Shearwave, another session of measurements was performed by the same operator within 8 hours to evaluate the intra-observer reproducibility of the LS measurements using S-Shearwave. The LS measurements were repeated within 1 hour of the second measurement by one of three other radiologists with 1–5 years of clinical experience, who was blinded to the TE results and the results of the other exam. The mean, median, and standard deviation values of the LS measurements were provided in US units. The interquartile range (IQR) was calculated using statistical software.

Definition of Technical Failure and Reliable (or Unreliable) Measurement

Technical failure of SWE methods was defined as failure to acquire 10 valid measurements after at least 15 trials. The reliable measurement of LS was defined as a measurement in which the IQR/median LS of 15 measurements was less than 30% (13).
A reliable measurement of TE was defined as the median of 10 valid LS measurements with a SR (ratio of number of successful acquisitions to total number of acquisitions) greater than or equal to 60% and an IQR/median ratio (IQR = difference between 75th and 25th percentiles, essentially the range of the middle 50% of the data) of less than 30%, as described in detail previously (25). The TE measurement was defined as having failed if no valid measurement was obtained after at least 10 attempts.

Standard of Reference for Hepatic Fibrosis

Because TE is a validated method for the evaluation of liver fibrosis (1226), it was considered the reference method against which the performance of VTQ and S-Shearwave techniques was assessed. To discriminate between the various stages of fibrosis with TE, we used the latest published LS cutoffs as proposed in Chon et al.'s meta-analysis (12): 7.9 kPa for moderate fibrosis (F ≥ 2), 8.8 kPa for severe fibrosis (F ≥ 3), and 11.7 kPa for liver cirrhosis (F = 4).
Transient elastography was measured by a technologist who was blinded to both VTQ and S-Shearwave results. The median interval of TE for the two examinations was 20 days (range: 5–31 days). For each patient, 10 valid TE measurements were performed under fasting conditions. The patient was in the supine position, using the intercostal approach, with the right arm in maximal abduction, as described in detail previously study (27). A standard XLprobe was used. The median value was calculated and expressed in kPa (13).

Statistical Analysis

The χ2 analysis was used to determine whether the technical success and reliable measurements of the two pSWE methods were significantly different. The Wilcoxon signed-rank test was used to compare the LS measurements obtained by VTQ and S-Shearwave. The Spearman correlation coefficient was then obtained to determine the correlation between the two pSWE techniques (28). A Bland–Altman analysis was used to evaluate the agreement between the VTQ and S-Shearwave techniques (29). The agreement between the two methods was further investigated by calculating the intraclass correlation coefficient (ICC) from the mean VTQ and S-Shearwave LS measurements. The intraand inter-observer reproducibility of the LS measurements using S-Shearwave was evaluated by calculating the ICC in 28 patients who underwent two sessions of S-Shearwave. As in previous studies, an ICC greater than 0.75 was considered to be a good agreement (30). To estimate the magnitude of change in LS measurements that can confidently be detected in a single individual, a 95% limit of agreement between repeat S-Shearwave measurements was obtained and then followed by the Bland-Altman method. The estimate was expressed as a percentage of the mean (29).
The areas under receiver operating characteristic curve (AUROC) curves and their 95% confidence intervals (CIs) were built for VTQ and S-Shearwave with regard to the diagnosis of severe fibrosis (F ≥ 3) or liver cirrhosis (F = 4) (31). The optimal cutoff values were determined using the highest Youden Index. The results for sensitivity (Se) and specificity (Sp) were recorded. The DeLong test was used to compare AUROC curves. A 95% CI was calculated for each predictive test, and a p value less than 0.05 was considered statistically significant. Because the fibrosis staging system using TE is not a binary reference, the use of only a receiver operating characteristics curve analysis may have led to an overestimation of the diagnostic performance. Thus, the overall performance was obtained using the Obuchowski measure with a R package (32). All statistical analyses were performed using commercially available software programs (SPSS version 21, IBM Corp., Armonk, NY, USA; MedCalc, version 14, MedCalc Software, Mariakerke, Belgium) and a free software program (R version 3.4.1; R Package for Statistical Computing, www.r-project.org).

RESULTS

The presumed distribution of liver fibrosis calculated from TE examinations showed that liver cirrhosis (F4) was the most common fibrosis stage (13/33, 39.4%), followed by severe (F3) and moderate (F2) liver fibrosis (27.3% and 21.2%, respectively), and lastly, mild (F1) or no (F0) liver fibrosis (12.1%) (Table 1) (23).

Technical Success Rate and Reliable Measurements

Among the 33 patients who underwent pSWE imaging with both techniques, five patients were excluded due to lack of TE data within 3 months (n = 1), unreliable measurement of TE (n = 1), technical failuare on S-Shearwave measurement (n = 1), unreliable measurement of VTQ (n = 1) and unreliable measurement of S-Shearwave (n = 1). Indeed , two pateints show unreliable measurements for S-Shearwave but one patient was already excluded due to unreliable measurements for VTQ. Ultimately, 28 patients were included for cross validation of VTQ and S-Shearwave measures.
There were no technical failures with VTQ and one technical failure with S-Shearwave because of severe obesity (body mass index [BMI] = 39). There was no significant difference in the technical SRs of VTQ (100%, 33/33) and S-Shearwave (96.9%, 32/33) (p = 0.63). Approximately 3.1% (1/33) of the VTQ measurements were unreliable and 6.3% (2/32) of the S-Shearwave measurements were unreliable. There was no significant difference in the reliable measurement rate (p = 0.61). All three unreliable measurements were observed by the operator in patients with obesity (BMI = 36), with or without a subjective poor sonic window because of advanced liver cirrhosis. Among these, one patient also failed to demonstrate a reliable measurement with S-Shearwave. One patient, where a technical failure was experienced with S-Shearwave, showed a reliable measurement with VTQ.

Correlation of LS Values between VTQ and S-Shearwave

In the 28 patients who had reliable VTQ and S-Shearwave measures, the LS value for both exhibited a good, positive correlation (r = 0.78, p < 0.0001) (Fig. 3). Significant correlations among LS values by VTQ elastography and S-Shearwave were also obtained in various subgroups of the study's sample (Table 2). The mean LS values for S-Shearwave were not significantly different from those for VTQ: 1.88 ± 0.36 m/s vs. 2.01 ± 0.56 m/s, p = 0.25 (Table 3). The mean LS values assessed by S-Shearwave were not significantly different from those obtained by VTQ in hepatic fibrosis stages F ≤ 2 to F4 (Table 4).

Inter- and Intra-Observer Reproducibility of S-Shearwave Measurements

The intra-observer reproducibility of S-Shearwave measurements was calculated by comparing the repeat LS values obtained from 28 patients. The ICC of 28 S-Shearwave measurements was 0.99 (95% CI 0.97–0.99), which indicates very good reproducibility. The 95% Bland-Altman limit of agreement for the repeat S-Shearwave measurements was -0.029 of the mean (Fig. 4A). With respect to inter-observer reproducibility of the S-Shearwave technique, ICC values were 0.98 (95% CI 0.95–0.99) which indicates very good reproducibility. The Bland-Altman limit of agreement for the repeat S-Shearwave measurements was −0.014 of the mean (Fig. 4B).

Performance of VTQ and S-Shearwave in Detecting Significant Fibrosis, (F ≥ 2), Severe Fibrosis (F ≥ 3) and Liver Cirrhosis (F = 4)

For LS cutoff values greater than 1.33 m/s, VTQ had 100% Se, 75.0% Sp, 88.86% positive predictive value (PPV), and 100% negative predictive value (NPV) (AUROC = 0.89, 95% CI 0.73–0.97, p < 0.0001) to differentiate between subjects with or without significant fibrosis (≥ F2). The S-Shearwave cutoff value discriminating between these two categories was greater than 1.54 m/s, with 88% Se, 87.5% Sp, 93.3% PPV, and 78.5% NPV (AUROC = 0.80, 95% CI 0.63–0.92, p = 0.002). The AUROCs of the two methods were not significantly different (p = 0.13) (Fig. 5A).
Both VTQ and S-Shearwave techniques were efficient in differentiating between mild and moderate fibrosis (F ≤ 2) from patients with severe fibrosis and cirrhosis (F ≥ 3), respectively (Fig. 5A). For LS cutoff values greater than 1.56 m/s, VTQ had 86.4% Se, 81.8% Sp, 90.36% PPV, and 92.3% NPV (AUROC = 0.87, 95% CI 0.70–0.96, p = 0.0001) to differentiate between subjects with or without severe liver cirrhosis. The S-Shearwave cutoff value discriminating between these two categories was greater than 1.67 m/s, with 86.4% Se, 80.8% Sp, 89.2% PPV, and 92.2% NPV (AUROC = 0.84, 95% CI 0.67–0.94, p = 0.009). The AUROCs of VTQ and S-Shearwave for predicting the presence of severe cirrhosis (F ≥ 3) was not significantly different (p = 0.51) (Fig. 5B).
For cirrhosis detection, VTQ had 100.0% Se, 82.4% Sp, 98.36% PPV, and 96.3% NPV (AUROC = 0.89, 95% CI 0.74–0.97, p = 0.0006) using a cutoff value of 1.72 m/s; and S-Shearwave had 100.0% Se, 82.3% Sp, 97.9% PPV, and 95.8% NPV (AUROC = 0.94, 95% CI 0.80–0.99, p = 0.007) when applying the cutoff value of greater than 1.75 m/s. The AUROCs of the two pSWEs for predicting the presence of liver cirrhosis (F = 4) were also not significantly different (p = 0.48) (Fig. 5C).
In both methods, the Obuchowski measures were similarly high (0.94 and 0.95 for S-Shearwave and VTQ, respectively).

DISCUSSION

In our prospective study, both the VTQ and S-Shearwave techniques provided excellent levels of technical success and reliable measurement, and there was no significant difference between them. Unreliable measurements were recorded in two patients with the S-Shearwave technique; one owing to obesity and the other due to a poor sonic window. That result corresponded with previous studies reporting less than 3% measurement failure with SWE (2325). In addition, the mean LS measurements obtained by VTQ (2.01 ± 0.56 m/s) and S-Shearwave (1.98 ± 0.66 m/s) did not reveal any significant difference (p = 0.25) and showed good correlation (r = 0.78). Considering that both pSWE techniques are based on similar physical principles of developing shear waves and measurement of shear wave propagation, these results were expected (33, 34). Our results demonstrating reliable SWE measurements (VTQ: 96.9%, 32/33 and S-Shearwave: 93.7%, 30/32) are well correlated with those of Yoo et al. (35), who compared ElastPQ and VTQ in 85 patients (95.3% vs. 97.5%). Furthermore, the S-Shearwave technique showed similar accuracy compared to VTQ in the diagnosis of severe fibrosis (F ≥ 3, AUROC 0.84 and 0.87, respectively) and cirrhosis (F = 4, AUROC 0.94 and 0.89, respectively) using the LS values of TE as a standard of reference for liver fibrosis.
To our knowledge, many studies have already investigated the reproducibility of US elastography with respect to both intra- and inter-observer variability (363738). In our study, the reproducibility of the S-Shearwave results was excellent for both intra-observer (ICC = 0.99) and inter-observer (ICC = 0.98) variability. Our results are similar to the intra-observer reproducibility of another pSWE LS measurement (ICC = 0.99) (35) and were slightly better than the intra-observer reproducibility of VTQ reported in a previous study (ICC = 0.945) (39). Moreover, in our study, even though the two operators had different levels of experience in US elastography, the S-Shearwave method showed an excellent ICC in inter-observer reproducibility. This result is different from that of a previous study which showed that operator experience is related to the intra-observer variability of SWE (40). This discrepancy could be attributed to the S-SWE technique of automatically measuring RMI. Initial studies in both phantom and in vivo studies showed that RMI values are strongly correlated with reproducible measurements (20), and therefore, we may assume that RMI filtered out unreliable measurements and resulted in an improvement of inter-observer agreement in the LS measurement of S-Shearwave.
The diagnosis and stage of liver fibrosis, with the exception of early compensated liver cirrhosis, are important in treatment decisions and surveillance of patients with chronic liver disease (14). In daily practice, more than one SWE method can be used for the longitudinal assessment of liver fibrosis during the management of chronic liver disease over time. Therefore, for the longitudinal assessment or monitoring of liver fibrosis, the interchangeability of LS measurements by different SWE techniques may be of significant value. According to our results, although both VTQ and S-Shearwave exhibited similar values of the LS measurements, accuracy in diagnosing significant fibrosis and liver cirrhosis, and similar cutoff values for the fibrosis stages provided by the meta-analysis of LS measurements (14), these techniques cannot be used interchangeably because of the different cutoff values. Given the small number of patients included in the study's sample (28 patients), further research with a larger sample size is warranted.
Several noninvasive imaging methods, either US- or MR-based SWE techniques, have been evaluated to date for the assessment of LS and are showing good diagnostic accuracy for stage F ≥ 2 fibrosis and excellent diagnostic accuracy for liver cirrhosis (41). In the literature, most studies have been performed using TE followed by pSWE, 2D SWE, and MR elastography (MRE), and to date, comparable results have been reported for the assessment of liver fibrosis by these imaging methods (354142). Thus far, only TE has been accepted as a noninvasive test for the assessment of liver fibrosis in the European and American guidelines for the management of patients with chronic hepatitis C virus infection (4344) and the WHO guidelines for the prevention, care, and treatment of persons with chronic hepatitis B virus infection (45). However, point and 2D SWE can provide the advantage of being integrated into conventional US systems, thus enabling hepatocellular carcinoma surveillance with the same machine. Such is not possible with TE (41). Several papers have suggested an additional diagnostic benefit when elastography is used with conventional ultrasonography, as this enables the early identification of patients with compensated liver cirrhosis that would not be detectable by conventional ultrasonography (no liver cirrhosis signs) or laboratory values (no thrombocytopenia) (41464748). Since 2D SWE methods allow detailed monitoring of shear waves over a large area of liver parenchyma, they provide an advantage over both TE and pSWE (21). However, minimizing probe pressure when imaging superficial tissues is required to avoid artifacts near the surface (21). The MRE technique also provides quantitative maps of tissue stiffness over large regions of the liver. Furthermore, it is much less operator dependent and less affected by obesity or ascites (49), all of which may limit the application of pSWE. However, pSWE seems to be more time efficient and easy to access in daily practice than the MRE is and has comparably good performance in most patients (46).
The current study has several limitations. Since there was no pathological staging of liver fibrosis, we could not evaluate the diagnostic performance of the S-Shearwave technique in the staging of liver fibrosis using pathologic results. However, it should be mentioned that a liver biopsy for fibrosis staging is not completely reliable due to the significant sampling error and interobserver variability and has a potential for complications (67). In addition, we included only a small number of patients (28) so further prospective studies with a larger number of patients, including healthy volunteers, are needed to determined cutoff values for the liver fibrosis stages. Additionally, we used the LS cut off values for the staging of liver fibrosis that have been proposed for patients with chronic hepatitis B even though we included heterogeneous epidemiology of liver disease (12). However, a large percentage (69.7%, 23/33) of the patients in this study had chronic hepatitis B. Finally, although there are other clinically available SWE techniques such as 2D SWE, we merely compared two commercially available pSWE techniques.
In conclusion, the S-Shearwave method provided a high technical SR and reliable LS measurements as well as a diagnostic performance comparable to VTQ for fibrosis staging, while proving high intra-and inter-observer reproducibility.

Figures and Tables

Fig. 1

Flow diagram of study population.

*One population with unreliable measurements for S-Shearwave also had unreliable measurements for VTQ. LS = liver stiffness, S-Shearwave = S-Shearwave elastography, TE = transient elastography, VTQ = virtual touch quantification
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Fig. 2

LS measurement by two pSWE techniques, VTQ (A) and S-Shearwave (B).

For both measurements, operator sited predefined measurement box in liver. pSWE = point shear wave elastography
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Fig. 3

Correlation between VTQ and S-Shearwave in same individuals.

Linear correlation analysis of LS values seen with VTQ and S-Shearwave in same individuals indicates significant correlation between two techniques.
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Fig. 4

Bland–Altman plot showing inter- (A) and intraobserver agreement (B) in S-Shearwave measurement.

X-axis shows means of repeated LS measurements, and y-axis displays difference between repeat S-Shearwave LS measurements. Red line = mean difference, green line = 95% limit of agreement
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Fig. 5

Comparison of ROC curves for VTQ and S-Shearwave for different fibrosis thresholds.

(A) F0–1 vs. F2–4, (B) F0–F2 vs. F3–F4, (C) F0–F3 vs. F4. In parentheses, 95% CI are shown. p values of differences between AUROCs are given. AUROC = areas under receiver operating characteristics curve, CI = confidence intervals, ROC = receiver operating characteristics
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Table 1

Patients' Characteristics and Presumed Staging of Estimated Hepatic Fibrosis Based on TE Meta-Analysis Values from Previous Study

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Characteristics No. Patients (%)
Sex
 Male 24 (72.3)
 Female 9 (27.7)
Age 64 (26–83)
BMI (kg/m2) 26.3 (17.8–40.8)
Etiology of chronic liver disease
 Chronic hepatitis B 23 (69.7)
 Chronic hepatitis C 4 (12.1)
 Alcoholic liver disease 1 (3.0)
 Unknown* 2 (6.1)
 None 3 (9.1)
Liver fibrosis stage
 F ≤ 1 4 (12.1)
 F2 7 (21.2)
 F3 9 (27.3)
 F4 13 (39.4)

Age and BMI are presented as median values and range intervals. *Idiopathic origin chronic liver disease diagnosed with clinical or laboratory, Without evidence of chronic liver disease both serology and image. Cut-offs used in classification of liver fibrosis was F ≥ 2 (7.9 kPa), F ≥ 3 (8.8 kPa), and F = 4 (11.7 kPa) (12). BMI = body mass index, kPa = kilopascals, TE = transient elastography

Table 2

Correlations between Estimated LS Values Assessed by VTQ and by S-Shearwave in Subgroups of Subjects

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Subgroup of Subjects Correlation VTQ and S-Shearwave Values*
All r = 0.78, p < 0.0001
 F ≤ 2 r = 0.82, p < 0.0001
 F3 r = 0.78, p < 0.0001
 F4 r = 0.73, p < 0.0001

Cut-offs used in classification of liver fibrosis was F ≥ 2 (7.9 kPa), F ≥ 3 (8.8 kPa), and F = 4 (11.7 kPa) according to transient elastography (12). *Spearman r correlation coefficient. LS = liver stiffness, S-Shearwave = S-Shearwave elastography, VTQ = Virtual Touch Quantification

Table 3

Mean, Median, and Median/IQR Values of Two SWE Methods Compared by Wilcoxon Signed-Rank Test

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VTQ S-Shearwave P
Mean 2.01 ± 0.56 1.88 ± 0.36 0.25
Median 1.98 ± 0.66 1.88 ± 0.42 0.51
IQR/median 0.23 ± 0.06 0.25 ± 0.04 0.18

IQR = interquartile range, SWE = shear wave elastography

Table 4

Comparison between Estimaged Mean LS Values Obtained by Means of VTQ and by S-Shearwave in Subgroups of Patients

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Subgroup of Subjects Mean VTQ Value Mean S-Shearwave Value P
F ≤ 2 1.16 ± 0.15 1.14 ± 0.12 0.06
F3 1.68 ± 0.75 1.65 ± 0.61 0.18
F4 2.15 ± 0.83 2.17 ± 0.06 0.09

Cut-offs used in classification of liver fibrosis was F ≥ 2 (7.9 kPa), F ≥ 3 (8.8 kPa), and F = 4 (11.7 kPa) according to transient elastography (12).

Notes

This study was supported by Samsung Medison (Hongcheon, Korea).

References

1. Barrera F, George J. The role of diet and nutritional intervention for the management of patients with NAFLD. Clin Liver Dis. 2014; 18:91–112.
2. Ferraioli G, Parekh P, Levitov AB, Filice C. Shear wave elastography for evaluation of liver fibrosis. J Ultrasound Med. 2014; 33:197–203.
3. Patel K, Bedossa P, Castera L. Diagnosis of liver fibrosis: present and future. Semin Liver Dis. 2015; 35:166–183.
4. Grant A, Neuberger J. Guidelines on the use of liver biopsy in clinical practice. British Society of Gastroenterology. Gut. 1999; 45:Suppl 4. IV1–IV11.
5. Rockey DC, Caldwell SH, Goodman ZD, Nelson RC, Smith AD. American Association for the Study of Liver Diseases. Liver biopsy. Hepatology. 2009; 49:1017–1044.
6. Piccinino F, Sagnelli E, Pasquale G, Giusti G. Complications following percutaneous liver biopsy. A multicentre retrospective study on 68,276 biopsies. J Hepatol. 1986; 2:165–1736.
7. The French METAVIR Cooperative Study Group. Intraobserver and interobserver variations in liver biopsy interpretation in patients with chronic hepatitis C. The French METAVIR Cooperative Study Group. Hepatology. 1994; 20(1 Pt 1):15–20.
8. Guha IN, Parkes J, Roderick P, Chattopadhyay D, Cross R, Harris S, et al. Noninvasive markers of fibrosis in nonalcoholic fatty liver disease: Validating the European Liver Fibrosis Panel and exploring simple markers. Hepatology. 2008; 47:455–460.
9. Srinivasa Babu A, Wells ML, Teytelboym OM, Mackey JE, Miller FH, Yeh BM, et al. Elastography in chronic liver disease: modalities, techniques, limitations, and future directions. Radiographics. 2016; 36:1987–2006.
10. Jeong WK, Lim HK, Lee HK, Jo JM, Kim Y. Principles and clinical application of ultrasound elastography for diffuse liver disease. Ultrasonography. 2014; 33:149–160.
11. Yu JH, Lee JI. Current role of transient elastography in the management of chronic hepatitis B patients. Ultrasonography. 2017; 36:86–94.
12. Chon YE, Choi EH, Song KJ, Park JY, Kim DY, Han KH, et al. Performance of transient elastography for the staging of liver fibrosis in patients with chronic hepatitis B: a meta-analysis. PLoS One. 2012; 7:e44930.
13. Castéra L, Foucher J, Bernard PH, Carvalho F, Allaix D, Merrouche W, et al. Pitfalls of liver stiffness measurement: a 5-year prospective study of 13,369 examinations. Hepatology. 2010; 51:828–835.
14. Friedrich-Rust M, Nierhoff J, Lupsor M, Sporea I, Fierbinteanu-Braticevici C, Strobel D, et al. Performance of Acoustic Radiation Force Impulse imaging for the staging of liver fibrosis: a pooled meta-analysis. J Viral Hepat. 2012; 19:e212–e219.
15. Ferraioli G, Tinelli C, Dal Bello B, Zicchetti M, Filice G, Filice C. Liver Fibrosis Study Group. Accuracy of real-time shear wave elastography for assessing liver fibrosis in chronic hepatitis C: a pilot study. Hepatology. 2012; 56:2125–2133.
16. Ferraioli G, Filice C, Castera L, Choi BI, Sporea I, Wilson SR, et al. WFUMB guidelines and recommendations for clinical use of ultrasound elastography: Part 3: liver. Ultrasound Med Biol. 2015; 41:1161–1179.
17. Bavu E, Gennisson JL, Couade M, Bercoff J, Mallet V, Fink M, et al. Noninvasive in vivo liver fibrosis evaluation using supersonic shear imaging: a clinical study on 113 hepatitis C virus patients. Ultrasound Med Biol. 2011; 37:1361–1373.
18. Ling W, Lu Q, Quan J, Ma L, Luo Y. Assessment of impact factors on shear wave based liver stiffness measurement. Eur J Radiol. 2013; 82:335–341.
19. Ma JJ, Ding H, Mao F, Sun HC, Xu C, Wang WP. Assessment of liver fibrosis with elastography point quantification technique in chronic hepatitis B virus patients: a comparison with liver pathological results. J Gastroenterol Hepatol. 2014; 29:814–819.
20. Choi KW, Kong DG, Hah ZG, Lee HK. A reliability index of shear wave speed measurement for shear wave elastography. Taipei. IEEE;2015. p. 1–4.
21. Bamber J, Cosgrove D, Dietrich CF, Fromageau J, Bojunga J, Calliada F, et al. EFSUMB guidelines and recommendations on the clinical use of ultrasound elastography. Part 1: basic principles and technology. Ultraschall Med. 2013; 34:169–184.
22. Musana KA, Yale SH, Abdulkarim AS. Tests of liver injury. Clin Med Res. 2004; 2:129–131.
23. Tsochatzis EA, Gurusamy KS, Ntaoula S, Cholongitas E, Davidson BR, Burroughs AK. Elastography for the diagnosis of severity of fibrosis in chronic liver disease: a meta-analysis of diagnostic accuracy. J Hepatol. 2011; 54:650–659.
24. Shiina T, Nightingale KR, Palmeri ML, Hall TJ, Bamber JC, Barr RG, et al. WFUMB guidelines and recommendations for clinical use of ultrasound elastography: Part 1: basic principles and terminology. Ultrasound Med Biol. 2015; 41:1126–1147.
25. Sporea I, Raţiu I, Bota S, Sirli R, Jurchiş A. Are different cut-off values of liver stiffness assessed by transient elastography according to the etiology of liver cirrhosis for predicting significant esophageal varices? Med Ultrason. 2013; 15:111–115.
26. Adebajo CO, Talwalkar JA, Poterucha JJ, Kim WR, Charlton MR. Ultrasound-based transient elastography for the detection of hepatic fibrosis in patients with recurrent hepatitis C virus after liver transplantation: a systematic review and meta-analysis. Liver Transpl. 2012; 18:323–331.
27. Bota S, Sporea I, Sirli R, Popescu A, Gradinaru-Tascau O. How useful are ARFI elastography cut-off values proposed by meta-analysis for predicting the significant fibrosis and compensated liver cirrhosis? Med Ultrason. 2015; 17:200–205.
28. Zou KH, Tuncali K, Silverman SG. Correlation and simple linear regression. Radiology. 2003; 227:617–622.
29. Bland JM, Altman DG. Statistical methods for assessing agreement between two methods of clinical measurement. Lancet. 1986; 1:307–310.
30. Kim SY, Lee SS, Byun JH, Park SH, Kim JK, Park B, et al. Malignant hepatic tumors: short-term reproducibility of apparent diffusion coefficients with breath-hold and respiratory-triggered diffusion-weighted MR imaging. Radiology. 2010; 255:815–823.
31. Hanley JA, McNeil BJ. A method of comparing the areas under receiver operating characteristic curves derived from the same cases. Radiology. 1983; 148:839–843.
32. Obuchowski NA. Estimating and comparing diagnostic tests’ accuracy when the gold standard is not binary. Acad Radiol. 2005; 12:1198–1204.
33. Hollerieth K, Gaßmann B, Wagenpfeil S, Moog P, Vo-Cong MT, Heemann U, et al. Preclinical evaluation of acoustic radiation force impulse measurements in regions of heterogeneous elasticity. Ultrasonography. 2016; 35:345–352.
34. Youk JH, Gweon HM, Son EJ. Shear-wave elastography in breast ultrasonography: the state of the art. Ultrasonography. 2017; [Epub]. DOI: 10.14366/usg.17024.
35. Yoo H, Lee JM, Yoon JH, Lee DH, Chang W, Han JK. Prospective comparison of liver stiffness measurements between two point shear wave elastography methods: virtual touch quantification and elastography point quantification. Korean J Radiol. 2016; 17:750–757.
36. Bota S, Sporea I, Sirli R, Popescu A, Danila M, Costachescu D. Intra- and interoperator reproducibility of acoustic radiation force impulse (ARFI) elastography-preliminary results. Ultrasound Med Bio. 2012; 38:1103–1108.
37. Ferraioli G, Tinelli C, Zicchetti M, Above E, Poma G, Di Gregorio M, et al. Reproducibility of real-time shear wave elastography in the evaluation of liver elasticity. Eur J Radiol. 2012; 81:3102–3106.
38. Ferraioli G, Tinelli C, Lissandrin R, Zicchetti M, Dal Bello B, Filice G, et al. Point shear wave elastography method for assessing liver stiffness. World J Gastroenterol. 2014; 20:4787–4796.
39. Kircheis G, Sagir A, Vogt C, Vom Dahl S, Kubitz R, Häussinger D. Evaluation of acoustic radiation force impulse imaging for determination of liver stiffness using transient elastography as a reference. World J Gastroenterol. 2012; 18:1077–1084.
40. Mun HS, Choi SH, Kook SH, Choi Y, Jeong WK, Kim Y. Validation of intra- and interobserver reproducibility of shearwave elastography: Phantom study. Ultrasonics. 2013; 53:1039–1043.
41. Friedrich-Rust M, Poynard T, Castera L. Critical comparison of elastography methods to assess chronic liver disease. Nat Rev Gastroenterol Hepatol. 2016; 13:402–411.
42. Sporea I, Bota S, Grădinaru-Taşcău O, Sirli R, Popescu A. Comparative study between two point shear wave elastographic techniques: acoustic radiation force impulse (ARFI) elastography and ElastPQ. Med Ultrason. 2014; 16:309–314.
43. European Association for Study of Liver. Asociacion Latinoamericana para el Estudio del Higado. EASL-ALEH Clinical Practice Guidelines: non-invasive tests for evaluation of liver disease severity and prognosis. J Hepatol. 2015; 63:237–264.
44. AASLD/IDSA HCV Guidance Panel. Hepatitis C guidance: AASLD-IDSA recommendations for testing, managing, and treating adults infected with hepatitis C virus. Hepatology. 2015; 62:932–954.
45. WHO Guidelines Approved by the Guidelines Review Committee. Guidelines for the prevention, care and treatment of persons with chronic hepatitis B infection. Geneva: World Health Organization;2015.
46. Cosgrove D, Piscaglia F, Bamber J, Bojunga J, Correas JM, Gilja OH, et al. EFSUMB guidelines and recommendations on the clinical use of ultrasound elastography. Part 2: clinical applications. Ultraschall Med. 2013; 34:238–253.
47. Kim G, Kim MY, Baik SK. Transient elastography versus hepatic venous pressure gradient for diagnosing portal hypertension: a systematic review and meta-analysis. Clin Mol Hepatol. 2017; 23:34–41.
48. Park SH, Kim SY, Suh CH, Lee SS, Kim KW, Lee SJ, et al. What we need to know when performing and interpreting US elastography. Clin Mol Hepatol. 2016; 22:406–414.
49. Yoon JH, Lee JM, Joo I, Lee ES, Sohn JY, Jang SK, et al. Hepatic fibrosis: prospective comparison of MR elastography and US shear-wave elastography for evaluation. Radiology. 2014; 273:772–782.
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