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Surgical and Radiologic Anatomy

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Open Access 01-12-2016 | Original Article

Morphometric study of the neural ossification centers of the atlas and axis in the human fetus

Authors: Mariusz Baumgart, Marcin Wiśniewski, Magdalena Grzonkowska, Bogdan Małkowski, Mateusz Badura, Michał Szpinda

Published in: Surgical and Radiologic Anatomy | Issue 10/2016

Abstract

Purposes

The knowledge of the developing cervical spine and its individual vertebrae, including their neural processes may be useful in the diagnostics of congenital vertebral malformations. This study was performed to quantitatively examine the neural ossification centers of the atlas and axis with respect to their linear, planar and volumetric parameters.

Methods

Using the methods of CT, digital-image analysis and statistics, the size of neural ossification centers in the atlas and axis in 55 spontaneously aborted human fetuses aged 17–30 weeks was studied.

Results

Without any male–female and right–left significant differences, the best fit growth dynamics for the neural ossification centers of the atlas and axis were, respectively, modelled by the following functions: for length: y = −13.461 + 6.140 × ln(age) ± 0.570 and y = −15.683 + 6.882 × ln(age) ± 0.503, for width: y = −4.006 + 1.930 × ln(age) ± 0.178 and y = −3.054 + 1.648 × ln(age) ± 0.178, for cross-sectional area: y = −7.362 + 0.780 × age ± 1.700 and y = −9.930 + 0.869 × age ± 1.911, and for volume: y = −6.417 + 0.836 × age ± 1.924 and y = −11.592 + 1.087 × age ± 2.509.

Conclusions

The size of neural ossification centers of the atlas and axis shows neither sexual nor bilateral differences. The neural ossification centers of the atlas and axis grow logarithmically in both length and width and linearly in both cross-sectional area and volume. The numerical data relating to the size of neural ossification centers of the atlas and axis derived from the CT and digital-image analysis are considered specific-age reference values of potential relevance in both the ultrasound monitoring and the early detection of spinal abnormalities relating to the neural processes of the first two cervical vertebrae in the fetus.

Bagnall KM, Harris PF, Jones PRM (1977) A radiographic study of the human fetal spine. 1. The development of the secondary cervical curvature. J Anat 123:777–782PubMedPubMedCentral

Bagnall KM, Harris PF, Jones PRM (1977) A radiographic study of the human fetal spine 2. The sequence of development of ossification centres in the vertebral column. J Anat 124:791–802PubMedPubMedCentral

Bagnall KM, Harris PF, Jones PRM (1979) A radiographic study of the human fetal spine 3. Longitudinal growth. J Anat 128:777–787PubMedPubMedCentral

Baumgart M, Szpinda M, Szpinda A (2013) New anatomical data on the growing C4 vertebra and its three ossification centers in human fetuses. Surg Radiol Anat 35:191–203CrossRefPubMed

Castellana C, Kósa F (2001) Estimation of fetal age from dimensions of atlas and axis ossification centers. Forensic Sci Int 117:31–43CrossRefPubMed

Chano T, Matsumoto K, Ishizawa M, Morimoto S, Hukuda S, Okabe H, Kato H, Fujino S (1996) Analysis of the presence of osteocalcin, S-100 protein, and proliferating cell nuclear antigen in cells of various types of osteosarcomas. Eur J Histochem 40:189–198PubMed

Currarino G, Rollins N, Diehl JT (1994) Congenital defects of the posterior arch of the atlas: a report of seven cases including an affected mother and son. Am J Neuroradiol 15:249–254PubMed

Duarte WR, Shibata T, Takenaga K, Takahashi E, Kubota K, Ohya K, Ishikawa I, Yamauchi M, Kasugai S (2003) S100A4: a novel negative regulator of mineralization and osteoblast differentiation. J Bone Miner Res 18:493–501CrossRefPubMed

Filly RA, Simpson GF, Linkowski G (1987) Fetal spine morphology and maturation during the second trimester. Sonographic evaluation. J Ultrasound Med 6:631–636PubMed

10.

Henderson P, Desai IP, Pettit K, Benke S, Brouha SS, Romine LE, Beeker K, Chuang NA, Yaszay B, Van Houten L, Pretorius DH (2016) Evaluation of fetal first and second cervical vertebrae: normal or abnormal? J Ultrasound Med 35:527–536CrossRefPubMed

11.

Junewick JJ, Chin MS, Meesa IR, Ghori S, Boynton SJ, Luttenton CR (2011) Ossification patterns of the atlas vertebra. Am J Roentgenol 197:1229–1234CrossRef

12.

Karwacki GM, Schneider JF (2012) Normal ossification patterns of atlas and axis: a CT study. Am J Neuroradiol 33:1882–1887CrossRefPubMed

13.

Kirmcher NA, Sarwar M (1977) Absent arch and hypoplastic pedicle: another confusing cervical spine anomaly. Am J Roentgenol 129:154–155CrossRef

14.

Lee HJ, Kim JT, Shin MH, Choi DY, Park YS, Hong JT (2015) The ossification pattern in paediatric occipito-cervical spine: is it possible to estimate real age? Clin Radiol 70:835–843CrossRefPubMed

15.

Lee HJ, Kim JT, Shin MH, Choi DY, Hong JT (2015) Quantification of pediatric cervical spine growth at the cranio-vertebral junction. J Korean Neurosurg Soc 57:276–282CrossRefPubMedPubMedCentral

16.

Lustrin ES, Karakas SP, Ortiz AO, Cinnamon J, Castillo M, Vaheesan K, Brown JH, Diamond AS, Black K, Singh S (2003) Pediatric cervical spine: normal anatomy, variants, and trauma. Radiographics 23:539–560CrossRefPubMed

17.

Mace SE, Holliday R (1986) Congenital absence of the C1 vertebral arch. Am J Emerg Med 4:326–329CrossRefPubMed

18.

Mac Rae DL (1953) Bony abnormalities in the region of the foramen magnum: correlation of the anatomic and neurologic findings. Acta Radiol 40:335–354CrossRef

19.

Mac Rae DL (1960) The significance of abnormalities of the cervical spine. Am J Roentgenol 84:3–21

20.

Mahony BS, Callen PW, Filly RA (1985) The distal femoral epiphyseal ossification center in the assessment of third-trimester menstrual age: sonographic identification and measurement. Radiology 155:201–204CrossRefPubMed

21.

Mãrginean OM, Mîndrilã I, Damian CM, Mãrginean CM, Melinte PR, Cãpitãnescu B (2011) Contributions on the morphometric study of the newborn and fetus spine. Rev Rom Anat Funct Clin Macro Microsc Antropol 10:423–428

22.

Patankar T, Krishnan A, Patkar D, Armao D, Mukherji SK (2000) Diastematomyelia and epidermoid cyst in the hemicord. Am J Roentgenol 174:1793–1794CrossRef

23.

Piatt JH Jr, Grissom LE (2011) Developmental anatomy of the atlas and axis in childhood by computed tomography. J Neurosurg Pediatr 8:235–243CrossRefPubMed

24.

Schulze PJ, Buurman R (1980) Absence of the posterior arch of the atlas. Am Roentgenol 134:178–180CrossRef

25.

Skórzewska A, Grzymisławska M, Bruska M, Łupicka J, Woźniak W (2013) Ossification of the vertebral column in human foetuses: histological and computed tomography studies. Folia Morphol 72:230–238CrossRef

26.

Szpinda M, Baumgart M, Szpinda A, Woźniak A, Mila-Kierzenkowska C (2013) Cross-sectional study of the neural ossification centers of vertebrae C1–S5 in the human fetus. Surg Radiol Anat 35:701–711CrossRefPubMedPubMedCentral

27.

Szpinda M, Baumgart M, Szpinda A, Woźniak A, Mila-Kierzenkowska C (2015) Cross-sectional study of C1–S5 vertebral bodies in human fetuses. Arch Med Sci 11:174–189CrossRefPubMed

28.

Szpinda M, Baumgart M, Szpinda A, Woźniak A, Mila-Kierzenkowska C, Dombek M, Kosiński A, Grzybiak M (2013) Morphometric study of the T6 vertebra and its three ossification centers in the human fetus. Surg Radiol Anat 35:901–916CrossRefPubMedPubMedCentral

29.

Szpinda M, Baumgart M, Szpinda A, Woźniak A, Mila-Kierzenkowska C (2013) New patterns of the growing L3 vertebra and its 3 ossification centers in human fetuses—a CT, digital, and statistical study. Med Sci Monit Basic Res 19:169–180CrossRefPubMedPubMedCentral

30.

Szpinda M, Baumgart M, Szpinda A, Woźniak A, Małkowski B, Wiśniewski M, Mila-Kierzenkowska C, Króliczewski D (2013) Cross-sectional study of the ossification center of the C1–S5 vertebral bodies. Surg Radiol Anat 35:395–402CrossRefPubMed

31.

Vignolo M, Ginocchio G, Parodi A, Torrisi C, Pistorio A, Venturini PL, Aicardi G, de Biasto P (2005) Fetal spine ossification: the gender and individual differences illustrated by ultrasonography. Ultrasound Med Biol 31:733–738CrossRefPubMed

32.

Waterham HR, Koster J, Mooyer P, van Noort G, Kelley RI, Wilcox WR, Wanders RJA, Hennekam RCM, Oosterwijk JC (2003) Autosomal recessive HEM/Greenberg skeletal dysplasia is caused by 3β-hydroxysterol-reductase deficiency due to mutations in the lamin B receptor gene. Am J Hum Genet 72:1013–1017CrossRefPubMedPubMedCentral

33.

Werner H, Dos Santos JRL, Fontes R, Daltro P, Gasparetto E, Marchiori E, Campbell S (2010) Additive manufacturing models of fetuses built from three-dimensional ultrasound, magnetic resonance imaging and computed tomography scan data. Ultrasound Obstet Gynecol 36:355–361CrossRefPubMed

34.

Wysocki J, Bubrowski M, Szymański I (2003) Anomalie rozwojowe okolicy szczytowo-potylicznej i ich znaczenie dla zaburzeń słuchu i równowagi. Otolaryngology 2:65–71 (in Polish)

Title: Morphometric study of the neural ossification centers of the atlas and axis in the human fetus
Authors: Mariusz Baumgart
Marcin Wiśniewski
Magdalena Grzonkowska
Bogdan Małkowski
Mateusz Badura
Michał Szpinda
Publication date: 01-12-2016
Publisher: Springer Paris
Published in: Surgical and Radiologic Anatomy / Issue 10/2016
Print ISSN: 0930-1038
Electronic ISSN: 1279-8517
DOI: https://doi.org/10.1007/s00276-016-1681-2

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

Morphometric study of the neural ossification centers of the atlas and axis in the human fetus

Abstract

Purposes

Methods

Results

Conclusions

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

Abstract

Purposes

Methods

Results

Conclusions

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