Normal Development of Costal Element Ossification Centers of Sacral Vertebrae in the Fetal Spine: a Postmortem Magnetic Resonance Imaging Study

Overview

Journal Neuroradiology

Specialties Neurology
Radiology

Date 2019 Jan 5

PMID 30607474

Citations 3

Authors

Nan Jian

Nan Lin

Mi-Mi Tian

Shuai Zhang

Guan Li

Hui Zhao

Lian-Xiang Xiao

Wen-Jia Liang

Xiang-Tao Lin

Affiliations

Soon will be listed here.

Abstract

Purpose: This postmortem magnetic resonance imaging (MRI) study of the fetal spine aimed to describe the timing of appearance, shape, volume, and relative positions of the S1-S3 costal element ossification centers (CEOCs).

Methods: We obtained sagittal 3D dual-echo steady-state with water excitation T2 images of the entire spine in 71 fetuses (gestational ages (GAs), 17-42 weeks). Computed tomography and histological examinations were performed on two fetal specimens (GAs, 21 and 30 weeks) to validate the MR images. The presence/absence of each sacral CEOC was recorded according to the GA. CEOC volume was measured. We analyzed the CEOC position relative to the vertebral column and ilium.

Results: The S1, S2, and S3 CEOCs first appeared at 23, 22, and 29 weeks, respectively. The S1 and S2 CEOCs could be detected in all fetuses with GAs of ≥ 30 weeks and ≥ 35 weeks, respectively, while the S3 CEOCs were variably present until term. The percentages of detection of the S1 and S2 CEOCs were significantly greater than that of the S3 CEOCs at each GA. At S1 and S2, the CEOC volume increased exponentially with GA. The relative positions of the S1 and S2 CEOCs, but not the S3 CEOCs, significantly correlated with GA (P < 0.001).

Conclusion: We have described the timeline of appearance as well as the volume and position of the S1-S3 CEOCs in the fetal spine on postmortem MRI according to GA.

Citing Articles

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Yang W, Han D, Pan S, Zou S, Xie S, Ma Y Heliyon. 2024; 10(10):e31526.

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Fetal magnetic resonance imaging of lumbar spine development in vivo: a retrospective study.

Yin X, Zhao X, Lu L, Zhang L, Xing Q, Yuan R Childs Nerv Syst. 2022; 38(11):2113-2118.

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Use of magnetic resonance imaging in the diagnosis of fetal vertebral abnormalities in utero: a single-center retrospective cohort study.

Cai X, Chen X, Wei X, Liu W, Hou X, Gong T Quant Imaging Med Surg. 2022; 12(6):3391-3405.

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References

Aoyama H, Asamoto K . The developmental fate of the rostral/caudal half of a somite for vertebra and rib formation: experimental confirmation of the resegmentation theory using chick-quail chimeras. Mech Dev. 2000; 99(1-2):71-82. DOI: 10.1016/s0925-4773(00)00481-0. View

Guihard-Costa A, Menez F, Delezoide A . Organ weights in human fetuses after formalin fixation: standards by gestational age and body weight. Pediatr Dev Pathol. 2002; 5(6):559-78. DOI: 10.1007/s10024-002-0036-7. View

Francis C . Appearance of centers of ossification in the human pelvis before birth. Am J Roentgenol Radium Ther. 1951; 65(5):778-83. View

Widjaja E, Whitby E, Paley M, Griffiths P . Normal fetal lumbar spine on postmortem MR imaging. AJNR Am J Neuroradiol. 2006; 27(3):553-9. PMC: 7976966. View

ORAHILLY R, Muller F, Meyer D . The human vertebral column at the end of the embryonic period proper. 4. The sacrococcygeal region. J Anat. 1990; 168:95-111. PMC: 1256893. View