Clinical Implications of Non-Steatotic Hepatic Fat Fractions on Quantitative Diffusion-Weighted Imaging of the Liver

Dijkstra, Hildebrand; Handayani, Astri; Kappert, Peter; Oudkerk, Matthijs; Sijens, Paul E.

doi:10.1371/journal.pone.0087926

Cited by 7 publications

(6 citation statements)

References 48 publications

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“…In contrast to a previously reported study in a fat-water mixed phantom (12), our simulations and in vivo observations suggested that underestimation of renal diffusion coefficients may be significant even at low fractions of the fat signal, and the rate of underestimation decreases until the curve nearly plateaus. Dijkstra et al showed that the correlation of pure-diffusivity and FRF is stronger using a log-linear compared to linear correlation (14), concordant with our observed correlation of this marker and Oil-Red-O. Taken together, these findings support a non-linear relationship between the FRF and pure-diffusivity (28).…”

Section: Discussionsupporting

confidence: 91%

“…The confounding effect of fat on hepatic DWI parameters has been suggested by several recent studies, demonstrating an inverse correlation of ADC and pure-diffusivity with fat content (13, 15), and its significance emphasized even in non-steatotic livers (14). In contrast to a previously reported study in a fat-water mixed phantom (12), our simulations and in vivo observations suggested that underestimation of renal diffusion coefficients may be significant even at low fractions of the fat signal, and the rate of underestimation decreases until the curve nearly plateaus.…”

Section: Discussionmentioning

confidence: 97%

“…However, recent studies on hepatic DWI identified fat as a potential third compartment with a significant confounding effect (12, 13), even in non-steatotic livers (14, 15). Similar outcomes were also observed in other organs (16, 17).…”

Section: Introductionmentioning

confidence: 99%

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Renal Adiposity Confounds Quantitative Assessment of Markers of Renal Diffusion With MRI

et al. 2017

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Objectives Recent studies have indicated that excessive fat may confound assessment of diffusion in organs with high fat content, such as the liver and breast. However, the extent of this effect in the kidney, which is not considered a major fat deposition site, remains unclear. This study tested the hypothesis that renal fat may impact DWI parameters, and proposes a three-compartment model (TCM) to circumvent this effect. Methods Using computer simulations, we investigated the effect of fat on assessment of apparent diffusion coefficient (ADC), intravoxel incoherent-motion (IVIM) and TCM-derived pure-diffusivity. We also investigated the influence of MR repetition (TR) and echo time (TE) on DWI parameters as a result of variation in the relative contribution of the fat signal. ADC, IVIM and TCM DWI parameters were calculated in domestic pigs fed a high-cholesterol (Obese) or normal diet (Lean), and correlated to renal histology. IVIM-derived pure diffusivity was also compared among fifteen essential hypertension (EH) patients classified by BMI (high vs. normal). Finally, pure diffusivity was calculated and compared in eight patients with atherosclerotic renal artery stenosis (ARAS) and five healthy subjects using IVIM and TCM. Results Simulations showed that unaccounted fat results in the underestimation of IVIM-derived pure-diffusivity. The underestimation increases as the fat fraction increases, with higher pace at lower fat contents. The underestimation was larger for shorter TR and longer TE values due to the enhancement of the relative contribution of the fat signal. Moreover, TCM, which incorporates highly diffusion-weighted images (b>2500s/mm2), could correct for fat-dependent underestimation. Animal studies in Lean and Obese confirmed lower ADC and IVIM pure-diffusivity in Obese vs. Lean pigs with otherwise healthy kidneys, while pure-diffusivity calculated using TCM were not different between the two groups. Similarly, EH patients with high BMI had lower ADC (1.9 vs. 2.1×10−3 mm2/s) and pure-diffusivity (1.7 vs. 1.9×10−3mm2/s) than those with normal BMI. Pure-diffusivity calculated using IVIM was not different between the ARAS and healthy subjects, but TCM revealed significantly lower diffusivity in ARAS. Conclusions Excessive renal fat may cause underestimation of renal ADC and IVIM-derived pure-diffusivity, which may hinder detection of renal pathology. Models accounting for fat contribution may help reduce the variability of diffusivity calculated using DWI.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionmentioning

confidence: 97%

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Renal Adiposity Confounds Quantitative Assessment of Markers of Renal Diffusion With MRI

et al. 2017

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“…However, when taking the minimal ADC value of the ROI, they observed significant differentiation between glioma grades by the ADC, which is in accordance with our results. In addition, other compounds, such as fatty acids and calcifications, potentially present in oligodendroglioma, can affect the minimal ADC of a tumor which can be avoided by a manually selected area of low diffusion with a circle ROI (17,18).…”

Section: Discussionmentioning

confidence: 99%

Inter-observer reproducibility of quantitative dynamic susceptibility contrast and diffusion MRI parameters in histogram analysis of gliomas

et al. 2019

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Background Dynamic-susceptibility contrast and diffusion-weighted imaging are promising techniques in diagnosing glioma grade. Purpose To compare the inter-observer reproducibility of multiple dynamic-susceptibility contrast and diffusion-weighted imaging parameters and to assess their potential in differentiating low- and high-grade gliomas. Material and Methods Thirty patients (16 men; mean age = 40.6 years) with low-grade (n = 13) and high-grade (n = 17) gliomas and known pathology, scanned with dynamic-susceptibility contrast and diffusion-weighted imaging were included retrospectively between March 2006 and March 2014. Three observers used three different methods to define the regions of interest: (i) circles at maximum perfusion and minimum apparent diffusion coefficient; (ii) freeform 2D encompassing the tumor at largest cross-section only; (iii) freeform 3D on all cross-sections. The dynamic-susceptibility contrast curve was analyzed voxelwise: maximum contrast enhancement; time-to-peak; wash-in rate; wash-out rate; and relative cerebral blood volume. The mean was calculated for all regions of interest. For 2D and 3D methods, histogram analysis yielded additional statistics: the minimum and maximum 5% and 10% pixel values of the tumor (min5%, min10%, max5%, max10%). Intraclass correlations coefficients (ICC) were calculated between observers. Low- and high-grade tumors were compared with independent t-tests or Mann–Whitney tests. Results ICCs were highest for 3D freeform (ICC = 0.836–0.986) followed by 2D freeform (ICC = 0.854–0.974) and circular regions of interest (0.141–0.641). High ICC and significant discrimination between low- and high-grade gliomas was found for the following optimized parameters: apparent diffusion coefficient ( P < 0.001; ICC = 0.641; mean; circle); time-to-peak ( P = 0.015; ICC = 0.986; mean; 3D); wash-in rate ( P = 0.004; ICC = 0.826; min10%; 3D); wash-out rate ( P < 0.001; ICC = 0.860; min10%; 2D); and relative cerebral blood volume ( P ≤ 0.001; ICC = 0.961; mean; 3D). Conclusion Dynamic-susceptibility contrast perfusion parameters relative cerebral blood volume and time-to-peak yielded high inter-observer reproducibility and significant glioma grade differentiation for the means of 2D and 3D freeform regions of interest. Choosing a freeform 2D method optimizes observer agreement and differentiation in clinical practice, while a freeform 3D method provides no additional benefit.

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“…We reviewed the published results on IVIM-derived PF of steatotic livers. Most of papers reported elevated PF (9), a small portion of papers(17) reported PF similar to normal liver which also indicate PF was artificially elevated since steatotic livers should have reduced true PF.…”

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confidence: 99%

Mutual constraining of slow component and fast component measures: some observations in liver IVIM imaging

Wáng¹

2021

Quant Imaging Med Surg

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Clinical Implications of Non-Steatotic Hepatic Fat Fractions on Quantitative Diffusion-Weighted Imaging of the Liver

Cited by 7 publications

References 48 publications

Renal Adiposity Confounds Quantitative Assessment of Markers of Renal Diffusion With MRI

Renal Adiposity Confounds Quantitative Assessment of Markers of Renal Diffusion With MRI

Inter-observer reproducibility of quantitative dynamic susceptibility contrast and diffusion MRI parameters in histogram analysis of gliomas

Mutual constraining of slow component and fast component measures: some observations in liver IVIM imaging

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