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Abstract
BACKGROUND AND PURPOSE: On the basis of a single multidynamic multiecho sequence acquisition, SyMRI generates a variety of quantitative image data that can characterize tissue-specific properties. The aim of this retrospective study was to evaluate the feasibility of SyMRI for the qualitative and quantitative assessment of fetal brain maturation.
MATERIALS AND METHODS: In 52 fetuses, multidynamic multiecho sequence acquisitions were available. SyMRI was used to perform multidynamic multiecho–based postprocessing. Fetal brain maturity was scored qualitatively on the basis of SyMRI-generated MR imaging data. The results were compared with conventionally acquired T1-weighted/T2-weighted contrasts as a standard of reference. Myelin-related changes in T1-/T2-relaxation time/relaxation rate, proton density, and MR imaging signal intensity of the developing fetal brain stem were measured. A Pearson correlation analysis was used to detect correlations between the following: 1) the gestational age at MR imaging and the fetal brain maturity score, and 2) the gestational age at MR imaging and the quantitative measurements.
RESULTS: SyMRI provided images of sufficient quality in 12/52 (23.08%) (range, 23 + 6–34 + 0) fetal multidynamic multiecho sequence acquisitions. The fetal brain maturity score positively correlated with gestational age at MR imaging (SyMRI: r = 0.915, P < .001/standard of reference: r = 0.966, P < .001). Myelination-related changes in the T2 relaxation time/T2 relaxation rate of the medulla oblongata significantly correlated with gestational age at MR imaging (T2-relaxation time: r = –0.739, P = .006/T2-relaxation rate: r = 0.790, P = .002).
CONCLUSIONS: Fetal motion limits the applicability of multidynamic multiecho–based postprocessing. However, SyMRI-generated image data of sufficient quality enable the qualitative assessment of maturity-related changes of the fetal brain. In addition, quantitative T2 relaxation time/T2 relaxation rate mapping characterizes myelin-related changes of the brain stem prenatally. This approach, if successful, opens novel possibilities for the evaluation of structural and biochemical aspects of fetal brain maturation.
ABBREVIATIONS:
- GA
- gestational age
- MDME
- multidynamic multiecho
- PD
- proton density
- R1
- T1-relaxation rate
- R2
- T2-relaxation rate
- SI
- signal intensity
- T1R
- T1-relaxation time
- T2R
- T2-relaxation time
Footnotes
Disclosures: Gudrun Mayr-Geisl—UNRELATED: Employment: Medical University of Vienna, Department of Neurosurgery, Comments: University Assistant. Mariana C. Diogo—RELATED: Grant: Austrian Science Fund*; Support for Travel to Meetings for the Study or Other Purposes: Austrian Science Fund*; UNRELATED: Employment: Hospital Garcia de Orta, in the meantime, Comments: working as a neuroradiologist. Gregor Kasprian—UNRELATED: Employment: Medical University of Vienna, Comments: employed as Faculty; Grants/Grants Pending: Austrian Science Fund, Comments: I 3925-B27. *Money paid to the institution.
Paper previously presented at: Annual Meeting of the European Congress of Radiology, March 3–7, 2021; Virtual.
- © 2021 by American Journal of Neuroradiology
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