Normal Ossification Patterns of Atlas and Axis: A CT Study

Discussion

Our study shows that there is a general caudal to cranial gradient in the growth of ossification centers and closure of synchondroses in the atlas and axis. Closure of the horizontally oriented medial synchondroses began at the base of the dens at the SDS and ended at the AAA. On the other hand, the vertically oriented lateral neurocentral synchondrosis fused at an age similar to the SDS, which is in line with postmortem radiologic evaluation,^2,6 but slightly later compared with a pediatric population examined by MR imaging, in which these closed at approximately 7 years.¹⁰ This is possibly because MR imaging was used instead of CT, which delivers a lower anatomic resolution and has an inherent weakness in depicting bone structure.

Considering the AAA, we demonstrate a larger variability in ossification patterns compared with data in the literature.^8,11⇓–13 The prevalence of an anterior midline synchondrosis has been estimated to be as low as 20%,⁸ but the presence of bipartite or multiple OCs and, hence, an anterior midline synchondrosis was identified in our study in 102 patients (34%). It has been postulated that the OC in the anterior arch of atlas develop through intramembranous perichondral ossification, probably as a result of the forces applied by the anterior longitudinal ligament.¹⁴ Because ossification centers require a blood supply, the number of developing OCs may be also determined by the vascularization pattern. On the other hand, the variable number of ossification centers seemed to affect neither the closure time of synchondroses nor the general shape of AAA. If no ossification centers develop within the AAA, osseous extensions spread ventrally directly from the lateral masses. This pattern was identified in 38 patients (16.5%) in our series, much higher in comparison with the literature (0.7%).⁸ Nevertheless, no persistent ventral cleft was found after the estimated closure age of 12 years, possibly because of the low incidence of these gaps, which was found to be as low as 0.1% in an autopsy study.¹⁵ Moreover, our study shows that 80% of the patients had a complete ossification pattern after the age of 12 years, which was higher than in the literature, in which a median age between 7 and 8.5 years has been described.^7,8 Persistent gaps at the posterior arch were found in approximately 4% in the same autopsy study,¹⁵ while, in our study, only minimal slits could be found.

Last, congenital defects, though some may assume bizarre forms, are usually easy to differentiate from acute injury on the basis of their sclerotic margins. Furthermore, our study also confirms that, in all cases, these osseous gaps are actually unossified fibrous tissue bridges; therefore, stability is not an issue.¹⁶

Ossification of the axis has been described in numerous publications.^5,6,17 Unresolved and controversially discussed are the origin of the odontoid process and the etiology of an os odontoideum, both topics being beyond the scope of this article.^18⇓–20 Furthermore, ossification patterns of the ADS and the tip of the dens have not been analyzed in similar studies.⁸ Most relevant in clinical practice are the appearance and closure of synchondroses in the central axis column and the ossification evolution of the axial tip. The SDS, located below the superior articular facets of the axis, is the preferred plane of fracture in children.^21,22 At a histologic level, a chondroid matrix can be identified, which represents the remnant of an intervertebral disk blastema.²³ Consequently, healing within this physis and focal osseous bridging may provide stability at the expense of growth potential, though longitudinal growth of C2 occurs mainly at the ADS level and only marginally at the SDS level.

Both the SDS and ADS show a similar central ossification spot at the beginning of the ossification process on both coronal and sagittal views (Figs 9 and 11). Analogous to the SDS, one can postulate that the ADS also represents a small residual disk blastema, which will be eventually completely resorbed and assimilated into the CHT. One can also postulate that the ADS is a further line of weakness within the axis. Although dens fractures in children preferentially occur through the physis of the SDS, traumatic forces applied at the upper part of the dens could result in injuries of the ADS. Dislocations at that level in early childhood may explain why a large ossiculum terminale or even an os odontoideum may develop from the CHT, in which the arterial supply through the apical ligament is preserved. Furthermore, associated dens hypoplasia, in which arterial supply and, hence, consecutive growth are disturbed, may occur at the same time, as has been previously described in the literature.^24,25

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Fig 11.

Sagittal view of ossification development of the axis. Children are of the following ages: (A) 30 days, (B) 3 months, (C) 3 years, (D) 5 years, (E) 6.5 years, (F) 8 years, (G) 13 years, and (H) 16 years.

The last part of the axis to ossify is the CHT, and its ossification pattern was most variable. ADS and CHT were completely ossified in over 80% of children at the approximate age of 10.5 years, which was slightly higher than that reported in the literature, with a median age of 8.2 years.⁸ Multiple ossification centers within the CHT and an asymmetric appearance may sometimes mimic osseous posttraumatic fragments, but a distinction can be made when considering the smooth surrounding cartilaginous envelope covering the OC itself, the surface of which was in regular continuity with the dens below (Fig 12). A completely separate ossification can grow quite large and may not fuse with the ADS and OCs of the dens, leading to a persistent ossiculum terminale (Fig 13). This is generally of little clinical significance, as it lies above the transverse ligament and its position does not change during movements at the CVJ.^14,19

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Fig 12.

Rare posterior ossification of the CHT resembled a dislocated fragment.

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Fig 13.

Large ossiculum terminale in an 8-year-old child and incomplete ossification of the ADS.

The current study has several shortcomings. There was no analysis of variation by sex or race. As a retrospective study, technical parameters were not homogeneous in all examinations and, especially, triplanar reconstructions were available in only 50% of cases, while biplanar reconstructions were retrieved in 17%. Assessment of synchondroses and OCs in the axial plane only (33%) may have led to incorrect classification. From a study design point of view, a longitudinal approach would have been ideal, but in our cross-sectional approach, we did not actually see the ossification progress or synchondroses close. Furthermore, the degree of maturation was subjective, and neither inter- nor intraobservation analysis was attempted. Finally, as the real progress of ossification could not be directly determined, we arbitrarily defined the “normal” closure age to correspond to the age category in which more than 80% of the patients showed definitive closure.