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Magnetic Resonance Materials in Physics, Biology and Medicine

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16.09.2016 | Research Article

Comparison of T1-weighted 2D TSE, 3D SPGR, and two-point 3D Dixon MRI for automated segmentation of visceral adipose tissue at 3 Tesla

verfasst von: Faezeh Fallah, Jürgen Machann, Petros Martirosian, Fabian Bamberg, Fritz Schick, Bin Yang

Erschienen in: Magnetic Resonance Materials in Physics, Biology and Medicine | Ausgabe 2/2017

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Abstract

Objectives

To evaluate and compare conventional T1-weighted 2D turbo spin echo (TSE), T1-weighted 3D volumetric interpolated breath-hold examination (VIBE), and two-point 3D Dixon-VIBE sequences for automatic segmentation of visceral adipose tissue (VAT) volume at 3 Tesla by measuring and compensating for errors arising from intensity nonuniformity (INU) and partial volume effects (PVE).

Materials and methods

The body trunks of 28 volunteers with body mass index values ranging from 18 to 41.2 kg/m² (30.02 ± 6.63 kg/m²) were scanned at 3 Tesla using three imaging techniques. Automatic methods were applied to reduce INU and PVE and to segment VAT. The automatically segmented VAT volumes obtained from all acquisitions were then statistically and objectively evaluated against the manually segmented (reference) VAT volumes.

Results

Comparing the reference volumes with the VAT volumes automatically segmented over the uncorrected images showed that INU led to an average relative volume difference of −59.22 ± 11.59, 2.21 ± 47.04, and −43.05 ± 5.01 % for the TSE, VIBE, and Dixon images, respectively, while PVE led to average differences of −34.85 ± 19.85, −15.13 ± 11.04, and −33.79 ± 20.38 %. After signal correction, differences of −2.72 ± 6.60, 34.02 ± 36.99, and −2.23 ± 7.58 % were obtained between the reference and the automatically segmented volumes. A paired-sample two-tailed t test revealed no significant difference between the reference and automatically segmented VAT volumes of the corrected TSE (p = 0.614) and Dixon (p = 0.969) images, but showed a significant VAT overestimation using the corrected VIBE images.

Conclusion

Under similar imaging conditions and spatial resolution, automatically segmented VAT volumes obtained from the corrected TSE and Dixon images agreed with each other and with the reference volumes. These results demonstrate the efficacy of the signal correction methods and the similar accuracy of TSE and Dixon imaging for automatic volumetry of VAT at 3 Tesla.

Nakajima T, Fujioka S, Tokunaga K, Matsuzawa Y, Tarui S (1989) Correlation of intraabdominal fat accumulation and left ventricular performance in obesity. Am J Cardiol 64(5):369–373CrossRefPubMed

Despres JP (1998) The insulin resistance-dyslipidemic syndrome of visceral obesity: effect on patients risk. Obes Res 6(S1):8–17CrossRef

Thamer C, Machann J, Haap M, Stefan N, Heller E, Schnödt B et al (2004) Intrahepatic lipids are predicted by visceral adipose tissue mass in healthy subjects. Diabetes Care 27(11):2726–2729CrossRefPubMed

Machann J, Thamer C, Schnödt B, Stefan N, Stumvoll M, Häring HU et al (2005) Age and gender related effects on adipose tissue compartments of subjects with increased risk for type 2 diabetes: A whole body MRI/MRS study. Magn Reson Mater Phy 18(3):128–137CrossRef

Despres JP, Prudhomme D, Pouliot M, Tremblay A, Bouchard C (1991) Estimation of deep abdominal adipose-tissue accumulation from simple anthropometric measurements in men. Am J Clin Nutr 54(3):471–477PubMed

van der Kooy K, Seidell J (1993) Techniques for the measurement of visceral fat: a practical guide. Int J Obes Relat Metab Disord 17(4):187–196PubMed

Shah RV, Murthy VL, Abbasi SA, Blankstein R, Kwong RY, Goldfine AB et al (2014) Visceral adiposity and the risk of metabolic syndrome across body mass index. J Am Coll Cardiol Cardiovasc Imaging 7(12):1221–1235CrossRef

Sadananthan SA, Prakash B, Leow MKS, Khoo CM, Chou H, Venkataraman K et al (2015) Automated segmentation of visceral and subcutaneous (deep and superficial) adipose tissues in normal and overweight men. J Magn Reson Imaging 41(4):924–934CrossRefPubMed

Glover GH (1991) Multipoint dixon technique for water and fat proton and susceptibility imaging. J Magn Reson Imaging 1(5):521–530CrossRefPubMed

10.

Würslin C, Machann J, Rempp H, Claussen C, Yang B, Schick F (2010) Topography mapping of whole body adipose tissue using a fully automated and standardized procedure. J Magn Reson Imaging 31(2):430–439CrossRefPubMed

11.

Machann J, Thamer C, Schnödt B, Haap M, Haring HU, Claussen CD et al (2005) Standardized assessment of whole body adipose tissue topography by MRI. J Magn Reson Imaging 21(4):455–462CrossRefPubMed

12.

Joshi AA, Hu HH, Leahy RM, Goran MI, Nayak KS (2013) Automatic intra-subject registration-based segmentation of abdominal fat from water-fat MRI. J Magn Reson Imaging 37(2):423–430CrossRefPubMed

13.

Thoermer G, Bertram HH, Garnov N, Peter V, Schuetz T, Shang E et al (2013) Software for automated MRI-based quantification of abdominal fat and preliminary evaluation in morbidly obese patients. J Magn Reson Imaging 37(5):1144–1150CrossRef

14.

Wald D, Teucher B, Dinkel J, Kaaks R, Delorme S, Boeing H et al (2012) Automatic quantification of subcutaneous and visceral adipose tissue from whole-body magnetic resonance images suitable for large cohort studies. J Magn Reson Imaging 36(6):1421–1434CrossRefPubMed

15.

Addeman BT, Kutty S, Perkins TG, Soliman AS, Wiens CN, McCurdy CM et al (2015) Validation of volumetric and single-slice MRI adipose analysis using a novel fully automated segmentation method. J Magn Reson Imaging 41(1):233–241CrossRefPubMed

16.

Berglund J, Ahlström H, Kullberg J (2012) Model-based mapping of fat unsaturation and chain length by chemical shift imaging-phantom validation and in vivo feasibility. Magn Reson Med 68(6):1815–1827CrossRefPubMed

17.

Müller HP, Raudies F, Unrath A, Neumann H, Ludolph AC, Kassubek J (2011) Quantification of human body fat tissue percentage by MRI. NMR Biomed 24(1):17–24CrossRefPubMed

18.

Bernstein M, Zhou KK, Zhou X (2004) Handbook of MRI pulse sequences. Elsevier Academic Press, Oxford

19.

Boyle GE, Ahern M, Cooke J, Sheehy NP, Meaney JF (2006) An interactive taxonomy of MR imaging sequences. RadioGraphics 26(6):e24;quiz e24

20.

Lu W, Lu Y (2010) Message passing for in-vivo field map estimation in MRI. In: 7th IEEE international symposium on biomedical imaging: from nano to macro (ISBI2010), Rotterdam

21.

Hernando D, Kellman P, Haldar J, Liang Z (2010) Robust water-fat separation in the presence of large field inhomogeneities using a graph cut algorithm. Magn Reson Med 63(1):79–90PubMedPubMedCentral

22.

Ladefoged CN, Hansen AE, Keller SH, Holm S, Law I, Beyer T et al (2014) Impact of incorrect tissue classification in Dixon-based MR-AC: fat-water tissue inversion. EJNMMI Phys 1(1):1–9CrossRef

23.

Grande FD, Santini F, Herzka DA, Aro MR, Dean CW, Gold GE et al (2014) Fat-suppression techniques for 3 T MR imaging of the musculoskeletal system. Radiographics 34(1):217–233CrossRefPubMedPubMedCentral

24.

Sharma SD, Artz NS, Hernando D, Horng DE, Reeder SB (2015) Improving chemical shift encoded water–fat separation using object-based information of the magnetic field inhomogeneity. Magn Reson Med 73(2):597–604CrossRefPubMed

25.

Soliman AS, Yuan J, Vigen KK, White JA, Peters TM, McKenzie CA (2014) Max-IDEAL: a max-flow based approach for IDEAL water/fat separation. Magn Reson Med 72(2):510–521CrossRefPubMed

26.

Fallah F, Würslin C, Schick F, Yang B (2015) RF and coil inhomogeneity correction in 2D leg images: a new method comparing with LEMS. In: Proceedings of the 23rd scientific meeting, International Society for Magnetic Resonance in medicine, Toronto, p 1176

27.

Würslin C, Springer F, Yang B, Schick F (2011) Compensation of RF field and receiver coil induced inhomogeneity effects in abdominal MR images by a priori knowledge on the human adipose tissue distribution. J Magn Reson Imaging 34(3):716–726CrossRefPubMed

28.

Tustison NJ, Avants BB, Cook PA, Zheng Y, Egan A, Yushkevich PA et al (2010) N4ITK: improved N3 bias correction. IEEE Trans Med Imag 29(6):1310–1320CrossRef

29.

Laidlaw DH, Fleischer KW, Barr AH (1998) Partial-volume Bayesian classification of material mixtures in MR volume data using voxel histograms. IEEE Trans Med Imag 17(1):74–86CrossRef

30.

Banerjee S, Mukherjee DP, Majumdar DD (1999) Fuzzy c-means approach to tissue classification in multimodal medical imaging. Inf Sci 115(14):261–279CrossRef

31.

Ruan S, Jaggi C, Xue J, Fadili J, Bloyet D (2000) Brain tissue classification of magnetic resonance images using partial volume modeling. IEEE Trans Med Imag 19(12):1179–1187CrossRef

32.

Shattuck DW, Sandor-Leahy SR, Schaper KA, Rottenberg DA, Leahy RM (2001) Magnetic resonance image tissue classification using a partial volume model. Neuroimage 13(5):856–876CrossRefPubMed

33.

Monziols M, Collewet G, Mariette F, Kouba M, Davenel A (2005) Muscle and fat quantification in MRI gradient echo images using a partial volume detection method. Application to the characterization of pig belly tissue. Magn Reson Imaging 23(6):745–755CrossRefPubMed

34.

Salvado O, Hillenbrand CM, Wilson DL (2006) Partial volume reduction by interpolation with reverse diffusion. Int J Biomed Imaging 2006:1–13CrossRef

35.

Donnelly LF, O’Brien KJ, Dardzinski BJ, Poe SA, Bean JA, Holland SK et al (2003) Using a phantom to compare MR techniques for determining the ratio of intraabdominal to subcutaneous adipose tissue. Am J Roentgenol 180(4):993–998CrossRef

36.

Alabousi A, Al-Attar S, Joy TR, Hegele RA, McKenzie CA (2011) Evaluation of adipose tissue volume quantification with IDEAL fat–water separation. J Magn Reson Imaging 34(2):474–479CrossRefPubMed

37.

Griswold MA, Jakob PM, Heidemann RM, Nittka M, Jellus V, Wang J et al (2002) Generalized autocalibrating partially parallel acquisitions (GRAPPA). Magn Reson Med 47(6):1202–1210CrossRefPubMed

38.

Wolf I, Vetter M, Wegner I, Böttger T, Nolden M, Schöbinger M et al (2005) The medical imaging interaction toolkit. Med Image Anal 9(6):594–604CrossRefPubMed

39.

Kass M, Witkin A, Terzopoulos D (1988) Snakes: active contour models. Int J Comput Vis 1(4):321–331CrossRef

40.

Xu C, Prince JL (1997) Gradient vector flow: a new external force for snakes. In: 10th IEEE conference on computer vision and pattern recognition (CVPR1997), San Juan

41.

Heimann T, Münzing S, Meinzer HP, Wolf I (2007) A shape-guided deformable model with evolutionary algorithm initialization for 3D soft tissue segmentation. In: Proceedings of the 20th international conference on information processing in medical imaging (IPMI2007), Kerkrade

42.

Barron A, Rissanen J, Yu B (1998) The minimum description length principle in coding and modeling. IEEE Trans Inf Theory 44(6):2743–2760CrossRef

43.

Heimann T, Wolf I, Meinzer HP (2007) Automatic generation of 3D statistical shape models with optimal landmark distributions. Methods Inf Med 46:275–281PubMed

44.

Ma J (2008) Dixon techniques for water and fat imaging. J Magn Reson Imaging 28(3):543–558CrossRefPubMed

45.

Bamberg F, Kauczor HU, Weckbach S, Schlett CL, Forsting M, Susanne CL, Greiser KH, Weber MA et al (2015) Whole-body MR imaging in the German National Cohort: rationale, design, and technical background. Radiology 277(1):206–220CrossRefPubMed

46.

Holle R, Happich M, Löwel H, Wichmann HE (2005) KORA-A research platform for population based health research. Gesundheitswesen 67:19–25CrossRef

47.

Hardy PA, Henkelman RM, Bishop JE, Poon ECS, Plewes DB (1992) Why fat is bright in RARE and fast spin-echo imaging. J Magn Reson Imaging 2(5):533–540CrossRefPubMed

48.

Stokes AM, Feng Y, Mitropoulos T, Warren WS (2013) Enhanced refocusing of fat signals using optimized multipulse echo sequences. Magn Reson Med 69(4):1044–1055CrossRefPubMed

49.

Vovk U, Pernus F, Likar B (2007) A review of methods for correction of intensity inhomogeneity in MRI. IEEE Trans Med Imaging 26(3):405–421CrossRefPubMed

50.

Zhou A, Murillo H, Peng Q (2011) Impact of partial volume effects on visceral adipose tissue quantification using MRI. J Magn Reson Imaging 34(6):1452–1457CrossRefPubMed

51.

Bauer JD, Noël PJ, Vollhardt C, Much D, Degirmenci S, Brunner S, Rummeny EJ, Hauner H (2015) Accuracy and reproducibility of adipose tissue measurements in young infants by whole body magnetic resonance imaging. PLoS One 10(2):1–12CrossRef

52.

Leinhard OD, Johansson A, Rydell J, Smedby O, Nystrom F, Lundberg P et al (2008) Quantitative abdominal fat estimation using MRI. In: 19th IEEE international conference on pattern recognition (ICPR2008), Tampa

Titel: Comparison of T1-weighted 2D TSE, 3D SPGR, and two-point 3D Dixon MRI for automated segmentation of visceral adipose tissue at 3 Tesla
verfasst von: Faezeh Fallah
Jürgen Machann
Petros Martirosian
Fabian Bamberg
Fritz Schick
Bin Yang
Publikationsdatum: 16.09.2016
Verlag: Springer Berlin Heidelberg
Erschienen in: Magnetic Resonance Materials in Physics, Biology and Medicine / Ausgabe 2/2017
Print ISSN: 0968-5243
Elektronische ISSN: 1352-8661
DOI: https://doi.org/10.1007/s10334-016-0588-6

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Comparison of T1-weighted 2D TSE, 3D SPGR, and two-point 3D Dixon MRI for automated segmentation of visceral adipose tissue at 3 Tesla

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Materials and methods

Results

Conclusion

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Conclusion

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