Prevalence of anatomical variations at the suboccipital (V3) segment of the vertebral artery: a systematic review

Vertebral artery (VA) injuries during surgical interventions around the atlantoaxial region constitute a potentially catastrophic complication that may result in permanent neurological deficit or even death [1, 2]. The rates of injury range from 1.7 to 9.0% [2‐4]. The segment of the VA located in the atlantoaxial region is the suboccipital (V3) segment. The V3 segment is the most anatomically complicated as the artery undergoes a series of bends to form proximal and distal loops while passing through the transverse foramen of the axis and atlas vertebrae. Although mild tortuosity is a variation in the course of the VA usually reported at the V1 and V2 segments. However, loop formation distinguishes the V3 segment from other segments of the artery. This feature of the V3 segment predisposes it to iatrogenic injury when performing skull base surgical procedures and instrumentation at the atlantoaxial region [5]. The V3 segment is subdivided into three portions for description: the vertical portion ascends through the transverse foramen of C2 and C1; the horizontal portion extends from the transverse foramen of C1 and courses in the VA groove on the upper surface of the posterior arch of the atlas; and an oblique portion extends from the groove to the point of penetration of the posterior atlanto-occipital membrane [6, 7]. The VA typically gives off muscular branches (also known as the suboccipital artery of Salmon) in the suboccipital region [8]. These small branches are not always present and are rarely seen on angiograms.

Apart from the aforementioned standard anatomical description, reports of variant vascular anatomy such as fenestration (FEN), persistent first intersegmental artery (FIA), hypoplasia, and incidence of the posterior inferior cerebellar artery (PICA) arising from the V3 segment also contribute to the complexity of this segment [9, 10]. A recent meta-analysis on the incidence of iatrogenic injury to the VA has revealed that patients with variant anatomy are more prone to iatrogenic injury [11]. This is because variant arteries are often situated in an unanticipated position. Therefore, the present study has been designed to review the available literature on the anatomic variations peculiar to this segment in different population groups and their incidences.

Adequate information about anatomical variation can influence the choice of procedure for the treatment of deformities and injuries at the CVJ. The V3 segment is susceptible to injury at the point of transition from V2 to V3, particularly within the C-2 groove when inserting a C1-2 transarticular screw or when placing C-2 pars screws [28, 29]. Authors have also identified potential sites of injury at different portions of the V3 segment in cadaveric samples [7]. The advent of computed tomography angiography (CTA), a unique non-invasive imaging modality, has improved the diagnosis and detection of vascular variation at the V3 segment. Its uniqueness lies in its ability to show details of vascular anatomy and its relationship with the atlas and the axis vertebrae. Recent advances in CTA have demonstrated that vascular structures can easily be depicted, which has caused some level of reduction in the use of invasive examinations such as digital subtraction angiography (DSA) [30]. According to some institutions, DSA remains the gold standard for assessing the vascular system. However, it is an invasive technique with potential hitches such as permanent neurological complications as a direct consequence of the procedure [30, 31]. In a recent meta-analysis comparing CTA with DSA, the latter technique was traditionally regarded as the gold standard for evaluating and treating vascular pathology. More recently, CTA has been viewed as a technique of choice. However, the most appropriate choice between these imaging techniques remains debatable [31]. For instance, the American Heart and Stroke Association lists DSA as a class I recommendation in their guidelines for managing aneurysmal subarachnoid hemorrhage. However, the American College of Radiology’s Appropriateness Criteria list CTA ahead of DSA but gives equal scores for both [32]. CTA is also occasionally used as a complementary imaging technique to conventional angiography for follow-up [33]. In addition, studies have shown that CTA allows reliable evaluation of intracranial arterial pathology, including aneurysms, stenosis, and occlusion [34]. Post-processed images in the 3D workstation of CTA and the raw images provide better details and opportunities for a detailed description of the presence of anatomical variation [18]. This is also confirmed in our review, as most of the studies evaluating anatomical variations at the suboccipital segment of the VA used CTA as the imaging modality (Table 1). However, CTA is not without its shortcomings. In addition to the high-cost implication, the use of ionizing radiation and iodinated contrast media has been associated with adverse events such as contrast allergy, nephrotoxic effects, neurological injury, and stroke, especially in patients with chronic kidney disease [17, 30, 35].

Embryologically, the VA develops from the fusion of six primitive cervical intersegmental arteries (CIAs). The seventh CIA persists to form the subclavian artery and the point of origin of the VA, while the first CIA is also referred to as the proatlantal artery [36]. As reported by Luh and co-authors, the horizontal portion of the V3 segment develops specifically from the anastomosis between the proatlantal artery and CIAs [37]. This theory suggests that the vertical portion of the V3 segment may have developed together with the V1 and V2 segments from the primitive CIAs. This is possible due to the dynamic and unique embryogenesis of the VA compared with any other arterial vessel [38].

Anatomical variations have been identified as a clinically significant risk factor for VA injury, especially during the posterior approach to the V3 segment [11, 39, 40]. In a recent multi-center study on the epidemiology of iatrogenic VA injury, the overall incidence of injury was reported as 0.08%, with posterior fixation surgery around C1-2 having the highest risk of injury (1.35%) [41]. Other previous studies have also reported that the incidence of iatrogenic injury may be as high as up to 8% in posterior fixation surgery [42], higher than 0.5% registered during anterior cervical spine surgery [11]. Iatrogenic injury during cervical spine surgery can cause catastrophic bleeding, permanent neurological deficits such as stroke, and even death [11, 41]. The most reported vascular variation at the suboccipital segment of the VA is FIA (Table 1, Fig. 2). An abnormal intradural course of the V3 segment of the VA through the spinal canal between the vertebral body of C2 and C1 has been previously defined with different terminologies such as; an “aberrant VA coursing intradurally at the C2 level” [20] and “FIA” [9, 10]. The latter is the most frequently used. The prevalence of this variation reported by individual authors ranges between 0.01 and 3.2% [9, 17, 26]. Similarly, the overall incidence was 1.8% in this review (197/10820) (Table 1).

Fenestration is the least reported variation in the V3 segment, 0.7% (72/10820) (Table 1, Fig. 3). FEN can be described as a luminal division of an artery with a common origin into two separate and parallel channels anywhere along its course, which rejoin distally [43]. A recent study proposed two terminologies for FEN at the suboccipital segment of the VA: a C2 segmental type of the VA associated with a normal VA or an aberrant VA with an intradural course at the C2 level associated with a normal VA [20]. However, the term “fenestration” was not acknowledged in the suggested names. In our own opinion, although fenestration sometimes coexists with FIA, it should be described separately for lucidity. The prevalence of FEN ranges from 0.01 to 1.3% [17, 18]. The incidence observed in the present review is within the range reported by previous studies. PICA is the principal branch of the VA, and it typically originates from the intracranial part of the vertebral artery (4^th segment). However, due to numerous embryonic vessels involved in forming the VA and its branches, PICA sometimes emerges from the V3 part (Fig. 4). We observed an incidence rate of 1.6% (175/10820) in the present review. An abnormal course of the VA or its PICA branch below the C1 arch may predispose the arteries to iatrogenic injuries during drilling, tapping, and insertion of lateral mass screws [26].

In this review, the highest incidence of variation was registered in the Asian population at 5.5% (374/6780) (Table 2). This is followed by a recent report from South Africa representing the African population [4.2% (23/554)] [44]. The incidences reported in the European [1.6% (41/2511)] and the American population [0.6% (6/975)] were similar, although slightly higher in the European population (Table 2). It should be noted that the reported incidence from this review is skewed since most available studies in the literature are from the Asian population, followed by the European population (Table 1). We found one study each representing the American and African populations [17, 44]. Although the theory is not well understood, authors have hypothesized genetic and environmental factors as the likely cause of differences in the incidence of VA variations [17, 21, 45]. A recent longitudinal study of the vertebrobasilar system focusing on Caucasian twins has suggested that the morphology of the vertebrobasilar arterial system is a function of genetic factors in combination with some environmental effects [46]. This important factor may have contributed to the regional differences, as reported in this review. However, the disparity in the incidence may also be due to underreporting from other population groups apart from the Asian population. It is important to note that the prevalence of variation in the included study is for the normal population without CVJ anomalies. The incidence of variation is usually higher in patients with congenital bone anomalies at the CVJ, such as atlantoaxial dislocation [25, 47].

In some instances, the morphology of the variant VA and osseous relationship at the CVJ is incompatible with screw placement. In the presence of FIA, insertion of a C1-2 transarticular screw may not be appropriate; C1 superior lateral mass may be the best alternative [48]. On the other hand, in the presence of FEN and PICA, a transarticular screw may be the best option, as placing a C-2 pars screw should be avoided [48]. Since most of this variation occurs unilaterally, preoperative imaging will be useful to determine the anomalous side. It has been suggested that it is preferable to commence dissection from the normal side during surgical intervention [5]. Vascular variation at the V3 segment can be present without any clinical symptoms and is sometimes symptomatic when it coexists with a disease condition. For instance, FIA has been associated with cervical cord myelopathy and other clinical presentations such as cervical pain, occipital neuralgia, and accessory nerve palsy [49]. Also, FEN has been associated with an aneurysm due to irregularities in the vascular walls of the fenestrated segment [50]. In addition to anatomical studies from different population groups, studies highlighting the incidence of iatrogenic injury from clinical series may give a better idea of the necessity of preoperative CTA in different population groups.

Because only a few of the included manuscripts presented data on morphometry, there was no sufficient data to perform a meta-analysis of pooled data. Regarding morphology, most of the studies were conducted in Asia. This may skew the result, and it may not be easy to generalize results beyond Asia. Hence, we grouped the included studies into Asian, European, American, and African and commented on the differences.

The authors summarize the incidence of vascular variation at the suboccipital segment of the VA in different population groups across the Asian, European, American, and African continents (Table 2). Although most available data are from the Asian population, other regions are also represented. This review will contribute to the knowledge of evidence-based anatomy. Regarding the low prevalence of variation at the V3 segment in most of the population groups except Asia as mapped out in this review, we do not recommend routine preoperative CTA before the surgical intervention or endovascular treatment of vascular pathologies. Alternatively, a non-contrast CT scan may be considered. While such scans do not demonstrate detailed vascular anatomy, they may suggest the typical and variable course of the VA. When an anatomical variation is suspected in the course of the VA, CTA may be required for clarification. However, when the prevalence is high in a population group such as the Asian, routine preoperative CTA should be considered to prevent iatrogenic injury. Awareness of the extent of possible anatomical variation will help interpret radiographs, which will enhance the identification of vascular pathologies and reduce the risk of iatrogenic injury.