Background
The Atlas, located at the cranio-cervical junction, is a ring-shaped vertebra. Normally, the vertebral artery glides easily with neck movements as it lies in the groove at the supero-lateral aspect of the C1 dorsal arch. The relationship of the VA to the dorsal arch of C1 has been well described. Cacciola, Ebraheim, and others have studied the course of the artery and the parameters relevant during surgery in the region [
1‐
8]. Cacciola, et al. injected colored silicone into the arteries and veins of ten cadaveric specimen; and the microsurgical anatomy of the VAs were evaluated along its course from the C3 transverse process to its entrance into the vertebral foramen at the occipito-atlantal (C0-C1) level with particularly close inspection of the relationship to the C2 vertebra [
1]. The authors concluded that the intimate relationship makes the VA susceptible to injury during the surgical procedures in the region [
1]. The multiple loops of the artery provide VA extra length which is probably essential to avoid any stretch during neck movements [
1].
Certain anomalies of the Atlas vertebra may have clinical significance for surgery, chiropractic and other manual therapies [
9‐
14]. Arcuate foramen have been shown to be commonly found anomalies with highly variable shapes and sizes [
1‐
8,
15,
16]. A bony bridge is formed by ossification in the oblique part of the atlanto-occipital membrane above the passage of VA [
15]. There are several names used for the bony bridge, among them: posterior ponticle, posticus ponticus, ponticulus posticus, kimmerle anomaly or arcuate foramen [
15]. Of grave concern is whether the posterolateral bony bridge could involve VA compression and/or fixation (tethering). Cushing et al. reported that presence of arcuate foramen caused increased incidence of VA dissection because of tethering as it passed through the osseous bridges of arcuate foramina [
9]. The number of patients treated with C1 lateral mass screws through the posterior arch has dramatically increased recently, therefore it is important to recognize the presence of arcuate foramen before performing the Goel procedure for placement of the screws [
15‐
19].
A meta-analysis, by Elliot and Tanweer, demonstrated that arcuate foramen anomalies are not rare [
15]. Their report described a systematic review of radiographic, cadaveric, and surgical data. They reported overall prevalence of arcuate foramina was 16.7 %; with 18.8 % in cadaver studies, 17.2 % in computed tomography studies, and 16.6 % in x-ray studies. Standard radiographs cannot demonstrate bilateral versus unilateral arcuate foramina. Elliot and Tanweer reported complete foramen in 9.3 % of patients and a partial or incomplete foramen in 8.7 %. In 5.4 % of cases, complete foramina were present bilaterally. In 7.6 % of cases, it was unilateral. They found no difference in prevalence between males and females [
15].
Measurements of arcuate foramina are of interest because of the highly variable nature of the anomalies and their clinical implications. The arcuate foramina may possibly compress the VA. In a study by Krishnamurthy et al., 1044 complete undamaged dry human atlas vertebrae were examined [
13]. These researchers found the trait was present in 13.8 % of their samples. They measured the mean length of the arcuate foramen at 7.16 mm on the left side and 9.99 mm on the right side in bilateral positive samples. It was 8.14 mm and 9.26 mm respectively in unilateral positive samples. They reported mean vertical height of arcuate foramen was 6.57 mm on the left side and 6.52 mm on the right side in bilateral positive samples. It was 4.91 mm and 5.38 mm respectively in unilateral positive samples. Besides genetic factors, the researchers discuss that mechanical external factors, such as carrying heavy objects on the head, could also play a role in the development of bridges [
13]. It has been suggested that healthcare providers, including neurologists, neurosurgeons, and the medical community, in general, should have knowledge about the present variation and should try to look for it when dealing with the patients complaining of symptoms of vertebrobasilar insufficiency like headache, vertigo, and shoulder and arm pain [
9‐
13,
14,
20‐
22].
This report describes an unusual finding during anatomy course instruction with cadavers provided by the Life University, College of Chiropractic. Anatomists generally recognized that skillful prosection leads to better visualization, demonstration and description for student learning [
23,
24]. Anatomical descriptions of location, relation to neighboring structures, size and shape are often supported by drawings, but not often by photographic or radiographic images [
23]. An increase in the use of computers for teaching anatomy has been reported [
24]. Our study provided photography and x-rays of this clinically important anomaly for use in teaching. This report will discuss the anomalies of arcuate foramen found and clinical significance for surgery, as well as chiropractic and other manual therapies.
Results
Among the 40 cadavers, only one (Specimen A) showed the presence of almost symmetrical bilateral dorsal bony bridges and lateral osseo-fibrous rings. In this specimen, VAs were found passing through the lateral foramina but deep to the dorsal bony bridge, as shown in Fig.
1, and at higher magnification of the right side in Fig.
2. The detailed dissection showed only the sub-occipital nerve (C1 dorsal ramus) along with accompanying branch of the VA emerging through the oval opening between the dorsal and lateral arches (Figs.
1 and
2). VAs were found passing deep to the oval opening on both sides, they course from lateral to medial, toward the dural sheath at the C0-C1 level on their way to the cranial cavity. The opening on the left side measured 14 mm in length and 7.5 mm in height, and on the right measured 13 mm in length and 5 mm in height. Structurally, the dorsal aspect of lateral foramina, which made the lateral borders of each dorsally faced oval opening, were osseo-fibrous i.e., they were not totally ossified. This border extended infero-laterally from the dorsolateral aspect of the C1 superior articular process to the dorsal root of the C1 transverse process. The oval windows’ medial borders were bony. These bony bridges originated from the dorsal aspect of the C1 superior articular process and fused to the C1 dorsal arch (Figs.
1 and
2). The bony bridges were the same length on both sides, but twice as thick (5 mm) on the right side as the left side (2.5 mm). As a result, the dorsal opening on the right side (5 mm) was narrower than the left side (7.5 mm). Figure
3 demonstrates the anatomical relationship with dimension measurements of the dorsal and lateral foramina.
The photographic image of Specimen A showed the VAs were intimately attached to the ossified bridges as they passed deep to the lateral and medial borders of the oval opening on both sides. Branches of VAs along with sub-occipital nerves emerged through the oval openings (Figs.
1 and
2). For comparison, the normal membranes were demonstrated in Specimens B and C, except for a partial superior ossification of the inferior oblique part of the atlanto-occipital membrane (Specimen B is shown in Fig.
4, Specimen C is not shown).
The frontal radiographic image corresponded to an AP open mouth projection (Fig.
5). Radiographic findings included bilateral lateral ponticle formations which consist of ossification in the oblique part of the atlanto-occipital membrane passing laterally from the supero-lateral aspect of the atlas lateral mass to the transverse process. This appeared as a thicker ossific band on the right with a thinner, and possibly incomplete, ossific band on the left. The lateral image revealed arcuate foramen with complete ossification of the oblique portion of the atlanto-occipital membrane bridging the posterior lateral mass and the C1 dorsal arch bilaterally (Fig.
6).
Discussion
Specimen A showed a unique type of variation of the arcuate foramen anomaly related to the passage of the VA in the sub-occipital region. First, the VA passed from lateral to medial deep through a tunnel behind the oval windows bilaterally. Then, as it passed through the tunnel, the VA gave rise to branches which accompanied the sub-occipital nerve as it emerged dorsally through the oval window to supply the sub-occipital muscles. For comparison, the literature has provided other descriptions of VA passing through the arcuate foramina as well as a description of the normal course and position of VAs in the neck and sub-occipital region [
1‐
8]. The two VAs, as commonly described, were found to originate from the first part of the subclavian artery and then ascend through the transverse foramina of six cervical vertebrae (C6 to C1). In the sub-occipital region, they were found to wind posterior to the atlanto-occipital joint, laying on the groove located on the superior and lateral aspect of the dorsal arch of the atlas on their way to the cranium through the atlanto-occipital membrane then through the dorsolateral aspect of the spinal dural sheath at C0-C1 level and foramen magnum. Specimen B and C demonstrated similar partial ossification of the superior aspect of the membrane. (Fig.
4 Specimen B, Specimen C is not shown)
The height and the length of the dorsal arcuate foramen in Specimen A were similar to previous studies. In our study, Specimen A measurements of the dorsal arcuate foramen included Length (14 mm Left, 13 mm Right) and Height (7.5 mm Left, 5 mm Right). In comparison, Krishnamurthy et al. found a Mean Vertical Height of 6.57 mm Left (range = 5.24 to 7.36 mm) and 6.52 mm Right (range = 6 - 6.90 mm). Krishnamurthy et al. also reported Mean Length was 7.16 mm Left (range = 5.28 - 9.56 mm) and 9.99 mm Right (range = 9.35 - 10.4 mm) [
13]. Specimen A has longer length measurements because of the finding of the double foramina, similar to Tubbs et al. [
5]. Tubbs et al. found both lateral and dorsal complete arcuate foramina of which the dorsal arch measured 12 mm in length. For surgeons, there is a discussion in the literature concerning surgical screw placement in the C1 lateral mass through the dorsal arch in the presence of arcuate foramen [
15‐
19]. Of specific concern is how the false appearance of a widened dorsolateral arch would impact surgical decision for screw placement. We found the thickness of the dorsolateral aspect of the atlas arch in our specimen measured 6 mm on each side. Lee et al. reported that they found a measurement greater than 5 mm in only 13.7 % of their specimens with the average measurement only 4.13 mm. [
19]. The significance of the measurement for surgical consideration is that 5 mm is the minimum requirement to safely pass a 3.5 mm screw via the C1 dorsolateral arch without injuring the VA, C2 dorsal root ganglion, C1 and C2 spinal nerves during surgical fixation of C1-C2 vertebrae (Figs.
1,
2 and
3).
There are clinical risks to consider with manual therapies with regard to whether arcuate foramina compresses the VA as it passes beneath the bony bridge which could lead to neurological conditions e.g. Vertebro Basilar Arterial Insufficiency (VBAI) [
3,
25]. Mitchell and Vanitha concluded that VAs are in danger of compressive pressure resulting in stenosis from hyperextension of the head or manual pressure on the region, especially in the presence of arcuate foramen, during cervical manual manipulation [
8,
25]. However Haynes, in 2005, found there was no risk of stenosis using a Doppler examination [
26]. In 2001, Cushing et al. reported clinical findings that arcuate foramen caused increased incidence of VA dissection due to tethering within the arcuate foramina following traumatic events, especially with neck rotation [
9]. Clinical assessment of classic signs and symptoms of VBAI should be evaluated in pre-screening procedures prior to manipulative therapies [
20‐
22].
Our specimen showed the VAs have intimately adhered to the lateral and dorsal bridges as they passed through but were not compressed. In consideration of the risk of tethering and screw placement, it is important to include advanced imaging when the arcuate foramen is found on x-ray, especially in trauma cases. In 2014, Todd et al. reported on adverse events related to chiropractic care for children and infants but did not include arcuate foramen as an underlying pathology or increased risk for performing manual cervical manipulations [
27].
In our radiographic study, we found that the arcuate foramen appeared as a ring-like structure on the lateral cervical view. However, when correlated with the true anatomical structure on the cadaveric specimen, it is not a simple ring-like foramen but it is instead an actual tunnel transmitting the vertebral vessels along with first cervical spinal nerve. No stenosis was found along the course of VAs on either side. Therefore, in such a variation of the anomaly, the vertebral artery is in a protected position rather than at risk of any physical pressures. The lateral ponticle has been reported as anatomically visible on 3 % of cervical radiographs and was present on this specimen, which identified the location of the artery on its course in a posterior - medial direction. According to Yocham and Rowe, no clinical relevance has been found to the radiographic finding of lateral ponticle [
28].
Conclusion
Arcuate foramina have been shown to be commonly found highly variable anomalies, even in the same individual with a bilateral condition. It is possible for the VAs to be compressed by the arcuate foramina. However, based on our findings, the presence of such hard bridges over the VA may provide protection from compressive forces. Since the presence of these bridges may increase the incidence of VA dissection, it is therefore clinically significant for manual therapists and chiropractors. Pre-screening clinical assessment of classic signs and symptoms of VBAI is very important. For cervical manual manipulative therapy, evaluation for the presence of partial or complete arcuate foramen is recommended with radiographic imaging. In trauma cases, advanced imaging is highly recommended. For surgical cases, since arcuate foramen is not a rare anomaly, careful evaluation of dorsal-lateral arch thickness is necessary for reducing the risk of VA, C2 dorsal root ganglion, C1 and C2 spinal nerve injuries from screw placement.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
SA carried out the prosection of cadavers for anatomy instruction and photography, conceived the study and participated in preparation of the manuscript. KH carried out the literature review and retrieval, participated in design of the study and in preparation of the manuscript. RBF provided radiographic expertise and written description of the radiographic images. SD participated in the study design, review of the literature and critical revision of the manuscript. All authors read and approved the final manuscript.
SA has a Ph.D. degree in anatomy and teaches all anatomy courses, including Central Nervous System and Peripheral Nervous System, at the college. He has been published in refereed journals and has presented at many neuroscience conferences. He recently presented a report at a chiropractic conference. KH has a Doctor of Chiropractic degree and has been involved in chiropractic research since 1989. She has many refereed publications in clinical research including practice–based research, case reports and a randomized clinical trial. She has presented various research reports at many chiropractic conferences. She has taught research methods and design for 12 years. RBF has a Doctor of Chiropractic degree and a Diplomate Certificate in Radiology. He teaches advanced radiology courses at the college. He has presented radiographic research reports at many chiropractic conferences and has several refereed publications. SD has a PhD. degree in anatomy and teaches histology as well as anatomy and osteology labs at the college.