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Correspondence  |   January 2011
It Is Time to Abandon Atlanto-Axial Joint Injections: Do No Harm!
Author Affiliations & Notes
  • Sukdeb Datta, M.D.
    *
  • *Vanderbilt University Medical Center, Nashville, Tennessee.
Article Information
Correspondence
Correspondence   |   January 2011
It Is Time to Abandon Atlanto-Axial Joint Injections: Do No Harm!
Anesthesiology 1 2011, Vol.114, 222-224. doi:10.1097/ALN.0b013e3182016667
Anesthesiology 1 2011, Vol.114, 222-224. doi:10.1097/ALN.0b013e3182016667
To the Editor:
We applaud Edlow et al  .1 for publishing the case report of posterior circulation stroke after C1-C2 intraarticular facet steroid injection with evidence of diffuse microvascular injury. The same mechanism involved with cervical transforaminal epidural injections may be implicated in this case with vertebral artery penetration and embolic phenomenon, as the authors described. Complications at this level are not only related to vertebral artery penetration and similar to transforaminal epidural injections, but they also encompass additional complications related to facet joint injections with penetration into the subarachnoid space, nerve roots, and spinal cord.
Considering the devastating nature of the complication presented, we would like to highlight a few more aspects pertinent to C1-C2 intraarticular injections, based on some anatomic observations and also related to the procedure performed, as described in the case report.
Anatomic Perspectives
We would like to comment first on the nomenclature of the joint as described in the article (C1-C2 intraarticular injection). Although the joint is between C1 and C2, most of the literature describes it as the lateral atlanto-axial (AA) joint rather than C1-C2 zygapophysial or facet joint. Zygapophysial joints are described from C2-C3 and below. Anatomic variations in morphology of C2 and the course of the vertebral artery are well recognized in the literature. Madawi et al  .2 found that the course of vertebral artery at C2 lateral mass was asymmetric in 52% of specimens. In a study of 98 dry C2 vertebra, Igarashi et al  .3 reported that 41% of specimens had asymmetric pedicles and approximately 20% of specimens were not suitable for screw fixation because the pedicle size was smaller than the diameter of a 3.5-mm screw. Computed tomography studies done by Noguiera-Barbosa and Defino4 in 2005 demonstrated vertebral artery grooves in 30%. Approximately 12% of patients were considered at risk with unilateral anatomic variation, and another 6% were not suitable for screw fixation because of bilateral variation. In 2010, a three-dimensional CISS magnetic resonance imaging study5 demonstrated that 40% of patients had significant anatomic variations on at least one side, prohibiting the insertion of transarticular screws. In another recent report, comprehensive computed tomography evaluation showed that the AA joint demonstrated larger variability in general, particularly in the sagittal plane.6 There were several contributing sources to this variability. First, these joints were inherently less conforming because of their biconcave anatomy. There were also more deviations from the neutral position (because the head was turned or tilted to the left or the right), which influenced their resting relationships. Most noteworthy is that the understanding of variations of the vertebral artery and its branches is essential before performing any intervention in the AA joint area. As the artery exits the foramen transverserium of C2, it is no longer dorsally covered by bone, as it is in the subaxial plane. It first takes a lateral course, enters the foramen transverserium of the atlas, and then bends posteromedially dorsal to the lateral mass of the atlas. The posterior ponticulus may appear falsely as a widened C1 arch. Another important variation is a persistent first intersegmental artery where the vertebral artery travels between the atlas and the axis in the space normally occupied only by the C2 nerve root. This may be seen in up to 4%. A fenestrated segment of the vertebral artery is a rare but described entity, and a takeoff of the posteroinferior cerebellar artery in the region of the atlas or the axis may also occur.7 
Procedural Considerations
Based on the autopsy report, it appears that the needle never entered the joint space, as demonstrated by the hemorrhage overlying the AA joint and intact cervical dura. Second, it is not clear from the case report whether an anterolateral, lateral, or posterior approach was employed while performing the AA intraarticular injection. Based on our interpretation of the provided images, we assume that a nonstandard anterolateral or lateral approach was used for the injection. Unpredictable anatomic variance between the vertebral artery and the bony structures suggests that no reliable placement of a needle may be expected to be completely safe, and transarterial or intraarterial injections are always a potential disastrous complication. Even without any anatomic variations, as described in the previous section, the vertebral artery runs on the lateral third of the AA joint dorsally, although its precise location is variable, and passes superiorly into the foramen magnum medially at the level of the atlas. The technique of injection of the AA joint is approaching the AA from the medial aspect because the artery is located laterally. The lateral entry directly targets the vertebral artery along with the lack of live fluoroscopy. We also question the use of 2 ml triamcinolone solution (40 mg/ml). Triamcinolone is a particulate steroid, and such a high dose of steroid has no proven effectiveness. The literature is very sparse on facet joint injections and almost nonexistent in the case of AA injections. With the added risk of intraarticular injection with potential entry into the spinal canal, the indications for these injections are minimal, and medical necessity weighing risk-benefit ratio is highly in favor of not performing the procedure. If an AA intraarticular injection is to be performed, it should only be performed in a prone position with the midline or a medial placement of the needle with injection of preservative-free lidocaine and nonparticulate betamethasone. Disastrous complications, as highlighted by the case, specifically above C2-C3, may not be prevented with live fluoroscopy, digital subtraction, blunt needles, and injection of nonparticulate steroid.
In summary, the danger lies not only in transforaminal cervical epidural injections but also in intraarticular injections and poorly performed ligament or trigger point injections of the AA joint or the C2-C3 area. No such complications have been reported with medial branch blocks with local anesthetic with or without nonparticulate betamethasone and radiofrequency neurotomy. However, penetration into the spinal canal and damage to the nerve roots and spinal cord is always a possibility with medial branch blocks, and radiofrequency neurotomy in the cervical spine and care is advocated when using any technique in the region. Finally, the effectiveness of radiofrequency neurotomy and medial branch blocks has been illustrated in the cervical spine.8,9 No such evidence exists for intraarticular AA joint injections, and the best course of action may be to abandon the practice.
*Vanderbilt University Medical Center, Nashville, Tennessee.
References
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Madawi AA, Casey AT, Solanki GA, et al: Radiological and anatomical evaluation of the atlantoaxial transarticular screw fixation technique: Case report and review of the literature. J Neurosurg 1997; 86:961–8Madawi, AA Casey, AT Solanki, GA et al.,
Igarashi T, Kikuchi S, Sato K, et al. Anatomic study of the axis for surgical planning of transarticular screw fixation. Clin Orthop Relat Res 2003; 408:162–6Igarashi, T Kikuchi, S Sato, K et al.,
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