Keywords Abdomen - Gastrointestinal Tract - Point of care - Physics and Technology
Introduction
The prevalence of nonalcoholic fatty liver disease (NAFLD) in the general population
is 20–30% and may be up to 70% in the obese population and 90% in individuals with
diabetes mellitus [1 ]
[2 ]
[3 ]. Since epidemiological data show a further increase in the prevalence of obesity
and diabetes mellitus, the number of NAFLD patients is also expected to increase in
the forthcoming years [4 ]. NAFLD progresses to nonalcoholic steatohepatitis (NASH) in 25% of cases within
3 years, and NASH already accounts for 12% of all liver transplantations in Europe
[3 ]. Fibrosis, more than steatosis and inflammatory activity, is associated with portal
hypertension and subsequent adverse long-term outcomes, such as hepatocellular carcinoma
(HCC) in NAFLD [2 ]
[5 ]
[6 ]. Thus, reliable noninvasive techniques for the assessment of liver fibrosis risk
are of increasing clinical importance. Simple laboratory-based scores (such as the
FIB-4 score) can be used to identify patients at risk for fibrosis in low-prevalence
populations. However, a sequential algorithm of laboratory-based scores followed by
liver elastography techniques is suggested to identify patients with NAFLD-associated
fibrosis [7 ].
Liver biopsy is the gold standard for diagnosing and staging liver fibrosis and can
be performed via the transcutaneous or transjugular route [9, 8]. However, it is an
imperfect gold standard [8 ] and associated with periprocedural risks and costs. Ultrasound-based techniques
for estimating liver fibrosis offer the advantages of lower-cost, low-risk, quick,
and point-of-care assessment. Vibration-controlled transient elastography (VCTE) is
a well-validated method of assessing liver fibrosis [7 ]
[9 ]. However, it requires a dedicated device that cannot perform conventional ultrasound
needed in patients with chronic liver disease to screen for HCC and other liver-related
complications. In contrast, acoustic radiation force impulse (ARFI)-based techniques,
either point shear wave elastography (pSWE) or two-dimensional SWE, can be included
in regular modern ultrasound devices. The diagnostic accuracy and cutoffs for VCTE
for different fibrosis stages, portal hypertension, and esophageal varices have been
established in multiple liver disease etiologies, including NAFLD [6 ]
[7 ]. The use of VCTE in NAFLD has been recommended in national and international guidelines
[10 ]. However, VTCE also has relevant limitations: despite the introduction of the XL-probe,
failed and unreliable measurements in obese patients remain a problem [11 ] and measurements cannot be reliably performed in the presence of perihepatic ascites.
pSWE-Elast-PQ (EPQ) is the pSWE technique implemented in Philips ultrasound systems.
Its use for liver fibrosis assessment has been validated in various etiologies [12 ]
[13 ]. In contrast to VCTE, the region of interest (ROI) placement and, therefore, the
depth of measurement can be chosen on the B-mode ultrasound image, which allows for
more advantageous localization (e.g., avoiding larger blood vessels or other interfering
structures). Since abdominal ultrasound devices are needed to screen for liver-related
complications, pSWE is potentially more widely and readily available than VCTE. However,
reliable cutoffs for ruling in or ruling out significant fibrosis and advanced fibrosis
in patients with NAFLD have not yet been sufficiently established.
Therefore, we set up a prospective European multicenter study to assess the performance
of EPQ for ruling out significant fibrosis and ruling in advanced fibrosis in patients
with (suspected) NAFLD using VCTE as a reference standard, exploring factors, which
might influence liver stiffness as measured by EPQ and to provide a clinical algorithm
comprised of elastography and the laboratory-based noninvasive FIB-4 tests [14 ].
Patients and methods
Study centers and study population
Patients with suspected or diagnosed NAFLD were prospectively recruited at 4 European
centers. We included patients for whom the clinical diagnosis of NAFLD was made and
who underwent ultrasound evaluation and elastography to assess fibrosis and steatosis.
Patients with viral liver disease (as assessed by HBsAg and HCVAb), alcohol intake,
hepatic malignancies, and heart failure were excluded.
Elastography protocol
We consecutively performed liver stiffness measurements (LSM) with pSWE and VTCE on
the same day in all included patients. For the pSWE, we used the EPQ module of the
Philips EPIQ 7 ultrasound system (Philips Medical System, The Netherlands) with a
C5–1 convex probe, and for VCTE, either the FibroScan 502 Touch or Mini 430 (Echosens,
Paris, FR) with the M- or XL-Probe, as suggested by the probe selection tool. Patients
fasted for at least four hours before the examination. As recommended, both measurements
were taken with the patient in a supine position, with the right arm abducted [9 ]. Both VCTE and EPQ examinations were performed via an intercostal space on the upper
right lobe of the liver. Measurements with EPQ and VCTE were performed following guideline
recommendations [7 ]. We considered VCTE and EPQ LSM with an IQR/median ratio ≤0.3 reliable and included
VCTE measures < 7.1 kPa irrespective of IQR/median [15 ]
[16 ].
Statistical analysis
The mode of display of the given variables and the statistical tests used are described
in the supplementary material.
Definition of significant and advanced fibrosis and cirrhosis
As VCTE was used as a diagnostic reference standard for risk assessment, published
cutoffs [17 ]
[18 ]
[19 ] were used to differentiate the ≥F2/significant fibrosis group, the ≥F3/advanced
fibrosis group, and the F4/cirrhosis group. These cutoffs were > 7 kPa for ≥F2/significant
fibrosis, ≥10 kPa for ≥F3/advanced fibrosis and ˃ 15 kPa for F4/cirrhosis. Using the
grouping described above, the area under the receiver operator characteristic curve
(AUROC) and the respective 95% CI for the ability of EPQ to determine the fibrosis
stage defined by VCTE were calculated. To establish cutoffs for the differentiation
between fibrosis stages, the Youden Index [20 ] was used to derive optimal cutoffs. With this method, the optimal cutoff is chosen
to maximize the sum of sensitivity (sens.) and specificity (spec.). Additional rule-in
and rule-out cutoffs were chosen to maximize sensitivity and specificity. For each
cutoff, the sensitivity, specificity, positive predictive value (PPV), negative predictive
value (NPV), as well as the false positives (FP) and false negatives (FN) for the
given population were derived. To further elucidate the fibrosis stage of patients
in whom significant fibrosis could not be ruled out and advanced fibrosis could not
be ruled in using EPQ, published cutoffs of the FIB-4 score were used [14 ]. To further elucidate the factors impacting the absolute difference between paired
measurements of VCTE and EPQ, we performed univariate linear modelling and multivariate
modelling comprising all univariately significant variables and another model of the
same kind exploring the impact of factors additional to VCTE-based liver stiffness
on EPQ-liver stiffness.
Results
In total, 353 concomitant, paired VCTE, and EPQ-based liver stiffness measurements
were obtained in the four participating centers. Of these, 21 (6.0%) were excluded,
as they did not fulfill the reliability criterion of IQR/median ≤0.3% for either VCTE
or EPQ (see Supplementary Table-ST1 ). Consequently, 332 (94.1%) patients were included in the analysis. Among these,
222 (66.9%) had no significant fibrosis (F0–1), 41 (12.4%) had significant fibrosis
(F2), 30 (9.0%) were diagnosed with advanced fibrosis (≥F3), and 39 (11.8%) were diagnosed
with cirrhosis (F4). A summary of the included patients, the calculated cutoffs, and
the resulting fibrosis staging is shown in [Fig. 1 ]A.
Fig. 1
A Study flow chat, showing the fibrosis staging by VCTE and EPQ, as well as resulting
cutoffs. B Reclassification of patients without rule-out of significant fibrosis and without
rule-in of advanced fibrosis, using the FIB-4 index.
The population defining characteristics for all patients, patients without significant
fibrosis, patients with significant and advanced fibrosis, and cirrhosis patients
are displayed in [Table 1 ] and the patient characteristics by center in Supplementary Table-ST2 . The patient populations were heterogeneous between centers, differing in age, sex
distribution, BMI, markers of disease severity, such as laboratory values and liver
stiffness, steatosis grade, and liver stiffness. The included patients were 59 [IQR:
16.5] years old and predominantly males. The median BMI was 29 [IQR: 7] kg/m2 and did not increase with the fibrosis stage. The blood work was mostly obtained
on the same day as the elastography [IQR: 1 day]. Platelet count, cholesterol, albumin,
and the CAP decreased, while the international normalized ratio (INR), alkaline phosphatase
(ALP), and aspartate aminotransferase (AST), gamma-glutamyltransferase (GGT), and
FIB-4 increased with each fibrosis stage. Liver stiffness as measured with EPQ significantly
increased with the fibrosis stage as defined by VCTE ([Table 1 ]).
Table 1 Patient characteristics.
All NAFLD
N= 332 (100%)
No/Mild Fibrosis F0/F1
N= 222 (66.9%)
Significant Fibrosis F2
N= 41 (12.3%)
Severe Fibrosis F3
N= 30 (9.0%)
Cirrhosis F4
N= 39 (11.7%)
P-value
P-values were calculated using the Kruskal-Wallis test comparing the values of patients
with no significant fibrosis, F2, F3, and F4. Significant p-values are bold.
Abbreviations
ALT: alanine aminotransferase; AST: aspartate aminotransferase; CAP: continuous attenuation
parameter; EPQ: Elast PQ;F0/1: fibrosis stage 0 or 1; F2: fibrosis stage 2; F3: fibrosis
stage 3; F4: fibrosis stage 4; GGT: gamma glutamyl transferase; INR: international
normalized ratio; IQR: interquartile range; IQR: interquartile range; kPa: kilopascal;
M: median; N: number; VCTE: vibration-controlled transient elastography
Age, years, median [IQR]
59.0 [16.5]
56.5 [19.0]
59.0 [12]
59.5 [16.0]
63.0 [10.5]
0.001
Sex, N (%)
Female
137 (41.3)
92 (41.4)
17 (41.5)
12 (40.0)
16 (41.0)
0.999
Male
195 (58.7)
130 (58.6)
24 (58.5)
18 (60.0)
23 (59.0)
Center, N (%)
Pavia
27 (8.1)
24 (10.8)
1 (2.4)
0 (0.0)
2 (5.1)
<0.001
Timișoara
57 (17.2)
39 (17.6)
6 (14.6)
8 (26.7)
4 (10.3)
Vienna
112 (33.7)
58 (26.1)
15 (36.6)
12 (40.0)
27 (69.2)
Zagreb
136 (41.0)
101 (45.5)
19 (46.3)
10 (33.3)
6 (15.4)
BMI, kg/m2 , median [IQR]
29.0 [7.1]
28.6 [6.3]
30.7 [10.9]
26.9 [6.0]
31.2 [8.9]
0.025
Platelets, G/L, mean (SD)
224 (75)
240 (70)
228 (64)
200 (62)
149 (72)
<0.001
INR, median [IQR]
1.0 [0.2]
1.0 [0.1]
1.0 [0.2]
1.1 [0.3]
1.0 [0.20]
<0.001
Bilirubin, mg/dL, median [IQR]
0.76 [0.42]
0.76 [0.37]
0.83 [0.49]
0.76 [0.25]
0.77 [0.54]
0.913
Albumin, g/dL, median [IQR]
41.9 [8.1]
43.1 [8.4]
40.5 [7.1]
40.75 [6.9]
39.2 [5.7]
0.027
AST, U/L, median [IQR]
30 [21]
27 [18]
29 [34]
38 [35]
45 [22]
<0.001
ALT, U/L, median [IQR]
35 [38]
35 [39]
32 [33]
44 [38]
33 [22]
0.275
GGT, U/L, median [IQR]
50 [74]
40 [60]
64 [68]
73 [60]
112 [193]
<0.001
FIB-4, points, median [IQR]
1.33 [1.12]
1.17 [0.75]
1.36 [1.05]
1.81 [1.68]
3.62 [3.27]
<0.001
VCTE, kPa, median [IQR]
6 [4.33]
5 [1.8]
8.4 [1.3]
12.7 [3.1]
22.8 [16.0]
<0.001
VCTE IQR/median, %, median [IQR]
15.0 [10.0]
15.0 [10.0]
16.0 [11.0]
14.5 [7.2]
17.5 [11.6]
0.284
CAP, dB/m, median [IQR]
298 [78]
298 [73]
305 [89]
299 [70]
272 [122]
0.42
CAP IQR, dB/m, median [IQR]
29 [20]
30 [19]
29 [10]
30 [12]
30 [34]
0.855
EPQ, kPa, median [IQR]
5.2 [2.8]
4.6 [1.5]
7.0 [3.1]
9.4 [4.3]
13.6 [9.2]
<0.001
EPQ IQR, kPa, median [IQR]
1.23 [0.02]
1.24 [0.51]
1.53 [0.33]
1.77 [0.42]
2.13 [0.68]
<0.001
EPQ IQR/median, %, median [IQR]
22.9 [10.4]
22.0 [10.0]
24.6 [9.6]
25.0 [12.6]
26.0 [7.3]
0.033
The correlation between reliable measurements of VCTE and EPQ was high, with a Pearson’s
R = 0.87 (95% CI: 0.83–0.89, p < 0.0001). This is shown in a scatterplot of the reliable
measurements of VCTE and EPQ in [Fig. 2 ].
Fig. 2 Pearson correlation of reliable liver stiffness measurements by VCTE and EPQ, with
CI 95% shown, on a log-10 scale.
The concordance between VCTE and EPQ was high, as shown by Lin's CCC = 0.792 (95%
CI: 0.623–0.889). To display the effect of increasing liver stiffness on the concordance
of the two compared methods, a Bland-Altmann-Leh plot is provided in [Fig. 3 ]. It shows that the numeric difference between absolute liver stiffness as measured
by VCTE and EPQ increased with increasing liver stiffness leading to a converse monotonous
decrease in the Pearson’s correlation coefficient ([Fig. 4 ]). Multivariate analysis to predict the absolute difference in liver stiffness as
measured by EPQ and VCTE revealed that higher VCTE, EPQ-based liver stiffness, BMI
and EPQ IQR are associated with a larger absolute difference in measured liver stiffness
(compare Supplementary Table-ST3 ). A second analysis aimed at factors that might impact EPQ-based liver stiffness,
in addition to VCTE-based liver stiffness, showed an association of VCTE IQR and probe
with EPQ-based liver stiffness (see Supplementary Table-ST4 ).
Fig. 3 Bland-Altman-Leh plot comparing the difference between VCTE and EPQ measurements for
a given mean of a measurement with lines of average difference and two 95% CI lines,
with the Lin’s concordance coefficient shown on a pseudo-log10 scale.
Fig. 4 Correlation of VCTE with EPQ at different VCTE liver stiffnesses. The figure shows
the Pearson correlation coefficient of the LSM by VCTE and EPQ (y-axis) at the liver
stiffness as determined by VCTE +/- 10 kPa (x-axis). This does not indicate the correlation
at this point but illustrates how increasing liver stiffness affects the correlation.
To assess the accuracy of EPQ for fibrosis risk assessment in NAFLD, we calculated
the AUROC values for the detection of significant fibrosis and advanced fibrosis,
as well as respective rule-in and rule-out cutoffs. EPQ can identify significant fibrosis
with an AUROC of 0.94 (95% CI: 0.910–0.969,). The optimal (Youden) cutoff was determined
at ≥6.5 kPa (≥1.47 m/s; sens.: 80%, spec.: 95%), the specific rule-in cutoff at ≥6.8
kPa (≥1.51 m/s; sens.: 77%, spec.: 97%), and the sensitive rule-out cutoff at <6 kPa
(<1.41 m/s; sens.: 86%, spec.: 89%). The AUROC for advanced fibrosis was 0.949 (95%
CI: 0.919–0.979). The optimal cutoff was ≥6.9 kPa (≥1.52 m/s; sens.: 88%, spec.: 89%),
while the respective rule-in and rule-out cutoffs were ≥10.9 kPa (≥1.91 m/s; sens.:
61%, spec.: 99%) and <7 kPa (<1.53 m/s; sens.: 86%, spec.: 90%). EPQ detected cirrhosis
with an AUROC of 0.949 (95% CI: 0.91–0.989). The optimal rule-in and rule-out cutoffs
were ≥ 10.4 kPa (≥1.86 m/s; sens.: 87%, spec.: 94%), ≥15.6 kPa (≥2.28 m/s; sens.: 36%, spec.:
99%), and <8 kPa (<1.63 m/s; sens.: 90%, spec.: 90%), respectively. These cutoffs
and the corresponding measures are summarized in [Table 2 ].
Table 2 Elast-PQ cutoffs.
Stage
Cutoff
AUROC
EPQ cutoff,
stiffness (kPa)
EPQ cutoff,
shear wave (m/s)
Sensitivity, %
Specificity, %
PPV, %
NPV, %
FP, N
FN, N
EPQ cutoffs for the diagnosis of significant fibrosis (≥F2), advanced fibrosis (≥F3),
and cirrhosis (F4). Abbreviations: AUROC: area under the receiver operator characteristics; F2: fibrosis stage 2; F3:
fibrosis stage 3; F4: fibrosis stage 4; FN: false negative; FP: false positive; kPa:
kilopascal; NPV: negative predictive value; PPV: positive predictive value
≥F2
Youden
0.940
(95%CI:
0.910–0.969, Power: 1)
≥6.5
≥1.47
80
95
90
91
10
21
Rule-in
≥6.8
≥1.51
77
97
92
89
7
25
Rule-out
<6.0
<1.41
86
89
80
92
24
16
≥F3
Youden
0.949
(95%CI:
0.919–0.979, Power: 1)
≥6.9
≥1.52
88
89
69
97
28
8
Rule-in
≥10.9
≥1.91
60
99
93
96
3
27
Rule-out
<7.0
<1.53
86
90
71
96
25
9
F4
Youden
0.949
(95%CI:
0.91–0.989, Power: 1)
≥10.4
≥1.86
87
94
65
98
18
5
Rule-in
≥15.6
≥2.28
36
99
93
92
1
25
Rule-out
<8
<1.63
90
90
54
99
30
4
Using the established EPQ cutoffs, we could not rule-out significant fibrosis and
could not rule-in advanced fibrosis in some patients. Here we applied a FIB-4 cutoff
of ˂ 1.45 to rule-out significant fibrosis and a cutoff of 3.45 to rule in advanced
fibrosis [14 ].The FIB-4 (available in 69/73, 94.5%) allowed a further stratification of patients
in the EPQ gray zone, since significant fibrosis could be ruled out in 32 (46.4%)
patients, and advanced fibrosis could be ruled in in 8 (11.6%). Finally, after considering
EPQ and FIB-4 results, only 33 (9.9%) patients remained in the indeterminate "gray
zone" (Fig-1B).
Discussion
While different noninvasive tools for the diagnosis and staging of NAFLD are available,
ultrasound-based methods are a very attractive screening option since the first suspicion
of NAFLD is often based on detecting a hyperechogenic liver texture on abdominal ultrasound.
Subsequent pSWE of the liver – readily available in mid-and high-end ultrasound devices
– could represent a valuable one-stop assessment for diagnosing hepatic steatosis
and further risk stratification according to fibrosis grade. It is crucial to identify
significant liver fibrosis and cirrhosis as early as possible to initiate effective
measures to prevent disease progression and HCC screening. Furthermore, pSWE may allow
for noninvasive, longitudinal monitoring of the effects of lifestyle modification
and potential future medical therapies for NASH in the academic and routine clinical
setting.
As of today, among all the available pSWE techniques, only Virtual Touch Quantification
(VTQ) has been extensively evaluated for use in NAFLD/NASH: A 2015 ARFI meta-analysis
[23 ] reported only moderate sensitivity (80.2%) and specificity (85.2%). pSWE is not
recommended as an endpoint in patients with NAFLD by the 2017 update to the EFSUMB
guidelines [9 ], while the 2018 update to the WFUMB guidelines on the use of liver shear wave elastography
recommends SWE – a term that includes VCTE, pSWE, and two-dimensional SWE – for liver
stiffness measurements in NAFLD, in particular, to rule-out advanced fibrosis and
to select patients for further investigation [7 ]. A more recent meta-analysis (2020) on pSWE (VTQ) including 1,147 patients reported
a better diagnostic value of VTQ for significant fibrosis (≥F2; AUROC: 0.89; sens.:
85%, spec.: 83%) and for cirrhosis (F4; AUROC: 0.94; sens.: 90%, spec.: 95%) in NAFLD
patients [24 ].
EPQ has previously been evaluated for use in other etiologies [13 ] but only in a small group of NAFLD/NASH patients against liver biopsy [21 ]. VCTE was found to be superior to EPQ for fibrosis screening, indicating a diagnostic
performance for EPQ for significant fibrosis (≥F2) with an AUROC: 0.74 (sens.: 78.1%,
spec.: 61.4%) and for cirrhosis (F4) with an AUROC: 0.72 (sens.: 66.7%, spec: 93.2%).
However, this study included only a very limited number of patients with F0 and F4
fibrosis, which might have impacted this study's ability to assess the "true" diagnostic
accuracy in NAFLD fibrosis staging. Furthermore, the authors state that the histology
specimens, on average, did not fulfill recommended standards, introducing potential
sampling bias [21 ]. Therefore, although we applied liver stiffness measurement by VCTE instead of liver
biopsy as a diagnostic gold standard, our study provides important results regarding
the concordance of EPQ and VCTE in a large cohort of prospectively recruited NAFLD
patients from four European centers. While the largest group of patients was classified
as having no significant fibrosis, the significant and advanced fibrosis and cirrhosis
groups were sufficiently powered, thereby reflecting the clinical spectrum of NAFLD
seen at specialized centers.
Furthermore, VCTE is known to sometimes fail in patients with a higher BMI. Because
obese patients in whom VCTE failed or delivered unreliable results, despite using
the XL-probe, were excluded from the analysis, the present study cannot provide information
on the accuracy of EPQ in patients in the higher BMI range.
We found a high correlation between VCTE and EPQ (Pearson's correlation coefficient:
0.87) as well as a high concordance (CCC: 0.792). Therefore, EPQ can correctly identify
significant and advanced fibrosis and cirrhosis, as expressed by respective AUROCs
of ≥F2: 0.940, ≥F3: 0.949, and F4: 0.949. Optimal Youden's index-derived cutoffs for
stages of fibrosis were defined at ≥6.5 kPa (≥1.47 m/s) for significant fibrosis (≥F2),
at ≥6.9 kPa (≥1.52 m/s) for advanced fibrosis (≥F3), and at >10.4 kPa (>1.86 m/s)
for cirrhosis (F4). To further increase clinical applicability, we also provide specific
rule-in and specific rule-out cutoffs for the clinically relevant NAFLD-fibrosis stages.
The subsequent use of the FIB-4 score on the 69/73 patients in the EPQ gray zone,
where the FIB-4 was available, could rule-out significant fibrosis in 32 (9.6%) patients
and rule-in advanced fibrosis in 8 (2.4%), finally leaving only 33 (9.9%) patients
with an indeterminate fibrosis stage. This algorithm combining noninvasive EPQ liver
stiffness measurement and broadly available blood tests of fibrosis is a valuable
tool for noninvasive fibrosis risk discrimination.
In concordance with previous studies [27, 26], we noted an increase in the discrepancy
in numerical values between VCTE and EPQ above 20–25 kPa. To explore the factors impacting
the discrepancy between VCTE and EPQ, we performed a regression modeling of factors
that may impact the absolute difference between VCTE and EPQ. Next to higher VCTE-LSM
values, higher BMI and higher IQR of EPQ were significantly associated with a discrepancy
between VCTE-LSM vs. EPQ-LSM in multivariate analysis. Still, liver stiffness values
above 20 kPa would indicate advanced chronic liver disease (ACLD) using both VCTE
and EPQ, and the divergence above this range does not question the ability to detect
ACLD. However, since EPQ may not be in concordance with VCTE within high stiffness
ranges, useful cutoffs or relevant delta/changes in EPQ stiffness to monitor improvement
or worsening of liver cirrhosis/portal hypertension remain to be explored. Importantly,
EPQ was still useful for assessing the fibrosis risk in NAFLD and predicting clinical
outcomes [22 ]
[25 ]
[26 ]. Importantly, our cohort was acquired at tertiary centers, as evident from the high
proportion of patients with advanced fibrosis and cirrhosis. Therefore, the cutoffs
derived here might not be directly applicable to the primary care setting.
VCTE has been found to have lower sensitivity and specificity in NAFLD-associated
fibrosis for distinguishing lower fibrosis stages [27 ]. Subsequently, using VCTE as a reference standard for fibrosis staging may have
led to overly optimistic results since VCTE and EPQ are based on the same diagnostic
principle (i.e., elastography), which may indicate a higher concordance as compared
to using liver biopsy as a reference. Furthermore, fibrosis staging by VCTE is not
regarded as the gold standard, and thus, the comparator of VCTE-based LSM represents
a limitation of this study. However, by using VCTE as a reference standard, we ensured
that the results of EPQ-based LSM could be assessed in the context of VCTE as the
currently most widely used liver stiffness measurement technique. In addition, this
strategy also allowed us to recruit a larger number of NAFLD patients.
Ultimately, the EPQ cutoffs identified in our study only suggest the risk of having
the respective NAFLD-associated fibrosis stages. However, a previous study using histopathological
evaluation of liver biopsy – as the (imperfect) diagnostic gold standard – reported
similar cutoff values for fibrosis staging as in our study [21 ], which suggests the validity of our EPQ NAFLD fibrosis stage cutoffs. Importantly,
in our diagnostic algorithm, we specifically focused on the clinically relevant questions
of ruling out significant fibrosis and ruling in advanced fibrosis/ cirrhosis.
Future studies on the utility of EPQ to assess the risk of compensated advanced chronic
liver disease (cACLD) – validated by the diagnostic gold standards, i.e., varices
detection by endoscopy, HVPG ≥6 mmHg, or liver biopsy showing F3/F4 fibrosis – are
desirable.
In conclusion, this prospective, multinational study showed an excellent diagnostic
accuracy of EPQ-pSWE liver stiffness measurements for assessing fibrosis risk in a
large cohort of NAFLD patients. We found a divergence between absolute values of VCTE
and EPQ, which monotonously increases above 20 kPa, but does not impact the ability
of EPQ to stratify NAFLD fibrosis risk. Importantly, we provide optimized EPQ cutoffs
to rule-in and rule-out significant fibrosis, advanced fibrosis, and cirrhosis in
patients with NAFLD in daily clinical practice.
