Review
Copyright ©The Author(s) 2023.
World J Gastroenterol. May 7, 2023; 29(17): 2534-2550
Published online May 7, 2023. doi: 10.3748/wjg.v29.i17.2534
Table 1 Characteristics of imaging techniques for hepatic steatosis evaluation
Techniques
Clinical characteristics
Limitations
CAPLow cost; High availability; Time-savingHigh measurement failure rate
Allows simultaneous evaluation of steatosis and fibrosisMeasurement without B-mode ultrasound image
Moderate to high diagnostic accuracy for detecting and grading steatosisThe cutoff value for diagnosing steatosis is poorly standardized
Moderate to high repeatability and reproducibility
Well validated
ATI, ATT and UGAPOutperform or have comparable diagnostic accuracy compared with CAPThe measurement may be influenced by liver fibrosis
High repeatability and reproducibilityFairly small number of studies
Strong correlation with liver histology or MRI-PDFF
Low measurement failure rate
Measured on B-mode ultrasound images
Att. PLUSMeasurement is obtained at the same time as the sound speed measurementFairly small number of studies
Comparable diagnostic accuracy with CAPNo study comparing this technique with liver histology or MRI-PDFF
TAI and TSIHigh diagnostic accuracy for detecting and grading steatosisFairly small number of studies
Strong correlation with MRI-PDFF
High repeatability and reproducibility
BSCUses a reference phantom to reduce sources of variability due to ultrasound systems or operatorsFairly small number of studies
High diagnostic accuracy for detecting and grading steatosis
Strong correlation with liver histology or MRI-PDFF
High repeatability and reproducibility
UDFFIs a combination of both attenuation coefficient and backscatter coefficientFairly small number of studies
UDFF approximates MRI-PDFF
ASQ and NLVModerate to high diagnostic accuracy for detecting and grading steatosisWeak correlation with liver histology
Strong correlation with CAPThe correlation with MR-based techniques is controversial
The influence of fibrosis on measurement is controversial
Fairly small number of studies
SSModerate to high diagnostic accuracy for detecting and grading steatosisFairly small number of studies
Strong correlation with CAP
MRS and MRI-PDFFHigh diagnostic accuracy for detecting and grading steatosisHigh cost; low availability
Considered as the reference standardTime-consuming
CAP: Controlled attenuation parameter; ATI: Attenuation imaging; ATT: Attenuation measurement function; UGAP: Ultrasound-guided attenuation parameter; Att. PLUS: Attenuation plane-wave ultrasound; TAI: Tissue attenuation imaging; TSI: Tissue scatter distribution imaging; BSC: Backscatter coefficient; UDFF: Ultrasound-derived fat fraction; ASQ: Acoustic structure quantification; NLV: Normalized local variance; SS: Speed of sound; MRS: Magnetic resonance spectroscopy; MRI-PDFF: Magnetic resonance imaging-proton density fat fraction.
Table 2 Summary of studies using ultrasound methods to evaluate hepatic steatosis
Ref.
No.
Method
Reference standard
Grade of steatosis
Optimal cutoff value
AUROC
Bae et al[59], 2019 108ATILB≥ S10.640.84
≥ S20.700.89
≥ S30.750.93
Bae et al[60], 2022 120ATILB≥ S10.660.91
≥ S20.660.91
Tada et al[62], 2019 148ATILB≥ S10.660.85
≥ S20.670.91
≥ S30.680.91
Tada et al[63], 2020 119ATIMRI-PDFF≥ S10.630.81
≥ S20.730.87
≥ S30.750.94
Jeon et al[61], 2019 87ATIMRI-PDFF≥ S10.590.76
Ferraioli et al[65], 2019 129ATIMRI-PDFF≥ S10.630.91
≥ S20.720.95
Ferraioli et al[66], 2021 72ATI-GENMRI-PDFF≥ S10.620.92
ATI-PENMRI-PDFF≥ S10.690.90
Sugimoto et al[67], 2021 111ATILB≥ S10.670.88
≥ S20.720.86
≥ S30.860.79
Hsu et al[70], 2021 28ATILB≥ S10.690.97
≥ S20.780.99
≥ S30.820.97
Kwon et al[57], 2021 100ATIMRI-PDFF≥ S10.620.91
≥ S20.720.94
Jang et al[58], 2022 57ATILB≥ S10.620.81
Koizumi et al[73], 2019 89ATTLB≥ S10.680.74
≥ S20.720.80
≥ S30.780.96
Tamaki et al[54], 2018 351ATTLB≥ S10.630.79
≥ S20.690.87
≥ S30.850.96
Fujiwara et al[75], 2018 163UGAPLB≥ S10.530.90
≥ S20.600.95
≥ S30.650.96
Imajo et al[76], 2022 1010UGAPMRI-PDFF≥ S10.650.91
≥ S20.710.91
≥ S30.770.89
Kuroda et al[79], 2021 202UGAPLB≥ S10.490.89
≥ S20.650.91
≥ S30.690.92
Tada et al[80], 2019 126UGAPMRI-PDFF≥ S10.600.92
≥ S20.690.87
≥ S30.690,89
Jeon et al[83], 2021 120TAIMRI-PDFF≥ S10.880.86
TSIMRI-PDFF≥ S191.20.96
Rónaszéki et al[84], 2022 110TAIMRI-PDFF≥ S10.590.92
TSIMRI-PDFF≥ S199.70.91
Şendur et al[85], 2023 80TAIMRI-PDFF≥ S10.750.95
≥ S20.860.97
≥ S30.960.97
TSIMRI-PDFF≥ S192.440.96
≥ S296.640.91
≥ S399.450.94
Lin et al[91], 2015 204BSCMRI-PDFF≥ S10.00380.98
Dillman et al[94], 2022 56UDFFMRI-PDFF≥ S15%0.90
Labyed et al[37], 2020 101UDFFLB≥ S18.1%0.94
≥ S215.9%0.88
≥ S316.1%0.83
AUROC: Area under the receiver operating characteristic curve; LB: Liver biopsy; MRI-PDFF: Magnetic resonance imaging-proton density fat fraction; ATI: Attenuation imaging; ATT: Attenuation measurement function; UGAP: Ultrasound-guided attenuation parameter; TAI: Tissue attenuation imaging; TSI: Tissue scatter distribution imaging; BSC: Backscatter coefficient; UDFF: Ultrasound-derived fat fraction.
Table 3 Summary of techniques for liver fat quantification and their mechanisms
Technique
Mechanism for liver fat quantification
Principle of the techniques
CAPSpectral based technique (AC)CAP measures the attenuation of or reduction in the amplitude of the ultrasound waves on their way through the liver
ATISpectral based technique (AC)ATI quantifies the degree of the ultrasound beam attenuation. The attenuation of the ultrasound beam is calculated by analyzing echo signals received by the transducer
ATTSpectral based technique (AC)Two ultrasonic waves of different frequencies (F0, F1; F0 < F1) are transmitted to the same beamline and the received signal is obtained. ATT estimates the attenuation coefficient it by calculating the slope of the received signal ratio (F0/F1)
UGAP Spectral based technique (AC)UGAP compares the measured liver signal and the referential signal (measured on the reference phantom with known attenuation and backscatter coefficients)
Att. PLUSSpectral based technique (AC)Att. PLUS measures the decrease in amplitude of ultrasound waves as they propagate throughout the tissue
TAISpectral based technique (AC)TAI is determined based on the attenuation properties of different frequency components in the tissue, and the spectrum of radiofrequency signals provides a downshift of the center frequency according to depth. The TAI parameter indicates the slope of the ultrasound center frequency downshift
BSCSpectral based technique (BSC)BSC measures the ultrasound energy returned from the tissue
UDFFSpectral based technique (BSC)UDFF is obtained by combining both AC and BSC and the result is presented as the percentage of hepatic steatosis. Reference phantom data is integrated into the ultrasound system and fixed-acquisition region of interest is applied
TSIEnvelope Statistic based techniqueThe TSI is based on the shape parameter of the Nakagami distribution which reflects the local concentration and arrangement of ultrasound scatterers
ASQEnvelope Statistic based techniqueASQ measures the FD ratio, which is based on the difference between theoretical and real echo amplitude distributions
NLVEnvelope Statistic based techniqueNLV parameter was derived from ASQ, which analyzed ultrasound amplitudes sampled from gray-scale ultrasound images
SSEnvelope Statistic based techniqueSS calculates the speed of sound through the liver
SSp.PLUSEnvelope Statistic based techniqueSSp.PLUS is a novel technique that allows quantification of the intrahepatic speed of sound which is correlated with the liver fat content
AC: Attenuation coefficient; BSC: Backscatter coefficient; CAP: Controlled attenuation parameter; ATI: Attenuation imaging; ATT: Attenuation measurement function; UGAP: Ultrasound-guided attenuation parameter; Att.PLUS: Attenuation plane-wave ultrasound; TAI: Tissue attenuation imaging; UDFF: Ultrasound-derived fat fraction; TSI: Tissue scatter distribution imaging; ASQ: Acoustic structure quantification; NLV: Normalized local variance; SS: Speed of sound; SSp.PLUS: Sound speed plane-wave ultrasound; FD: Focal disturbance.