Abstract
Background
The vidian canal (VC) is normally a reliable anatomical landmark for locating the petrous internal carotid artery (pICA). This study determined the influence of petroclival chondrosarcoma on the relationship between the VC and pICA.
Methods
Nine patients (3 males, 6 females; median age 49) with petroclival chondrosarcoma, and depiction of the pICA on contrast-enhanced CT, were retrospectively studied. CT-based measurements were performed by two observers, both in the presence of the petroclival chondrosarcoma (case) and on the contralateral control side. The antero-posterior (AP) and craniocaudal (CC) measurements from the posterior VC to the pICA, whether the pICA was in the trajectory of the VC, and the coronal relationship of the pICA anterior genu with the VC were recorded.
Results
Chondrosarcoma usually displaced the pICA anteriorly (8/9 cases) and superiorly (6/9 cases) relative to the normal side with mean AP and CC measurements of 3.9 mm v 7.2 mm (p = 0.054) and 4.4 mm v 1.4 mm (p = 0.061). The VC trajectory less frequently intersected the pICA cross-section in the presence of chondrosarcoma however it was in the line of the eroded dorsal VC in one case. The anterior genu of the pICA was displaced more laterally by chondrosarcoma but usually remained superior to the VC.
Conclusion
Petroclival chondrosarcoma variably influences the anatomical relationship between the VC and the pICA, hence requiring an individualised approach. The pICA is usually anterosuperiorly displaced, and the anterior genu remains superior to the VC, however it may be located in the line of the canal.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
Endoscopic endonasal approaches (EEA) offer a direct approach to the resection of petroclival lesions, without the need for brain retraction [9, 17, 25]. The surgical corridor requires the localisation and exposure of the petrous internal carotid artery (pICA) in order to safely remove tumour [13]. The relationship of anatomical landmarks with the adjacent pICA has been evaluated in studies of cadaveric, dry skull and histological specimens [3, 5, 7, 8, 12, 14, 15, 18, 19, 21, 22] as well as on computed tomography (CT) imaging [12, 15, 16, 23].
The vidian canal (VC) is widely accepted as being a reliable indicator of the pICA location in the coronal plane [3, 5, 7, 8, 12, 14, 15, 21, 23]. In normal subjects, the pICA courses anteromedially to the foramen lacerum where it curves superiorly at the anterior genu [5] to become the paraclival ICA. The VC runs posterolaterally from the pterygopalatine fossa to reach the anterolateral margin of the foramen lacerum where its posterior opening usually lies inferior to the pICA and inferolateral to its anterior genu [8, 12,13,14, 21, 23].
Chondrosarcomas of the skull base are indolent locally invasive neoplasms which represent 6% of all skull base tumours [4, 6] and typically originate from the cartilaginous elements of the petroclival synchondrosis [2]. Many centres advocate EEA as the initial surgical approach to these petroclival chondrosarcomas [24]. These tumours tend to displace neurovascular elements laterally and superiorly [17]; however there are no previous reports of the relationship of the VC with the pICA in petroclival chondrosarcomas. A variable pICA displacement or destruction of the posterior vidian canal would limit the use of the VC as a reliable anatomical landmark.
The objective of this CT-based study was to evaluate the location of the pICA and its anterior genu relative to the posterior opening of the vidian canal in the presence of petroclival chondrosarcoma and to compare with the contralateral normal side.
Methods
Patients
Patients were selected for this retrospective single centre case–control study following local institutional approval (NS024) and without the requirement for informed consent.
A search of our institution’s electronic operative records was performed to identify consecutive petroclival chondrosarcoma patients (between 1/1/2001 and 31/12/2019). Patients were excluded if there was no definitive histological confirmation, tumour extension across the midline clivus, previous surgery to the petroclival region, or if thin section contrast-enhanced CT imaging did not adequately depict the pICA. Minimum imaging quality criteria comprised slice collimation < 0.7 mm and either pICA Hounsfield unit (HU) > 100 or pICA HU of 50–100 with contemporary MRA for correlation. Data collection included demographic and clinical information (age, gender, tumour characteristics). Contemporary MRI studies were reviewed to assess tumour dimensions and staging. Data on surgical complications and patient outcomes was obtained from the electronic patient record.
CT acquisition, processing and analyses
The high-resolution CT studies through the temporal bones were performed (Siemens Healthcare, Erlangen, Germany) with scan parameters shown in Table 1.
A neuro-radiologist and a neurosurgeon analysed the CT studies by consensus. Petroclival chondrosarcoma and contralateral normal sides were analysed in a random order.
Multiplanar reformats were performed on a high-resolution PACS workstation (Sectra workstation, Sectra AB, Sweden). The images underwent standardised magnification and standardised window width. The pICA was defined as the segment extending from the external orifice of the carotid canal to the petro-lingual ligament [10]. The VC was defined as the canal located in the pterygoid process of the sphenoid bone, extending from just anterior to the foramen lacerum to the pterygopalatine fossa. The posterior opening of the VC was defined as where it started to splay at its dorsal margin. Any bony attenuation by the tumour at this site was documented, and, in such cases, the posterior opening of the VC was then estimated by reproducing the contralateral normal anatomy.
Firstly, a standardised oblique sagittal reformat was performed in the line of the VC by aligning in the axial planes (Fig. 1) and the following was recorded (Table 2) (Figs. 1, 2):
-
(1)
Antero-posterior (AP) measurement between the VC and the pICA
-
(2)
Craniocaudal (CC) measurement between the VC and the pICA
-
(3)
Craniocaudal intersection.
Secondly, a coronal reformat was performed perpendicular to the craniocaudal angle of the VC but without coronal obliquity. This was used to evaluate the direct coronal relationship between the anterior genu of the pICA and the posterior opening of the vidian canal (Table 2) (Fig. 3). The anterior genu corresponds to the junction of the petrous (C2) and lacerum (C3) segments as defined by Bouthillier et al. [1]. When the position of the anterior genu was not well defined on coronal reformats, it was correlated with volume-rendered imaging (Fig. 4).
Any narrowing of the pICA by the petroclival chondrosarcoma was documented as mild (30–50% area narrowing) or marked (greater than 50% area narrowing) and > 2700 contact of the chondrosarcoma with the ICA was recorded.
Statistical analysis
Statistical analysis was performed using IBM SPSS (version 26) with a p value of < 0.05 being considered statistically significant.
Descriptive statistics summarised the patient demographics, previous surgery and tumour dimensions, Carlson staging and documented VC destruction, pICA narrowing by tumour, ICA contact with the tumour, craniocaudal intersection of the pICA in the trajectory of the VC and quadrant location of the anterior genu relative to the VC.
Continuous AP and CC measurements were compared between the chondrosarcoma and normal contralateral sides (paired t test if normally distributed and the Mann–Whitney test if not normally distributed).
The STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) reporting guideline was implemented. Source data is available on request from the lead author.
Results
Patient, imaging and tumour descriptive characteristics
Twenty-two patients were eligible for study inclusion but 13 were excluded (1 primarily sellar chondrosarcoma and 12 cases that failed to meet image quality criteria). In total, the images of 9 patients (3 males, 6 females; median age 48.0, age range 17–74) were analysed in this study (Table 3).
The long and short axial dimensions of the petroclival chondrosarcomas were 34.7 ± 12.5 mm and 22.6 ± 7.0 mm. Four tumours were Carlson stage 2 and 5 tumours were Carlson stage 3 [2]. There were 6 left-sided and 3-right sided lesions. There had been previous partial retro-sigmoid surgical resections in 2/9 patients and previous infra-labyrinthine and retro-sigmoid resections in one patient (Table 3). The presence of extra-osseous extension within posterior fossa, middle cranial fossa, parasellar and extracranial compartments is documented in Table 3.
There were 3/9 patients with mild pICA narrowing and 2/9 patients with moderate pICA narrowing by the chondrosarcoma. There was greater than 270 degrees ICA involvement in 3/9 patients (Table 3). The posterior opening of the VC was attenuated in one patient with a petroclival chondrosarcoma (Fig. 3). Data on the pre- and post-treatment patient Eastern Cooperative Oncology Group (ECOG) [20] performance status together with surgical complications and follow-up is tabulated (Table 4).
Vidian canal to pICA anatomical relationships on chondrosarcoma and contralateral control sides
The AP and CC measurements between the posterior opening of the VC and the pICA are shown in Table 4. The measurements were normally distributed as determined by the Shapiro Wilk test.
The AP measurement between the VC and the pICA was 3.9 ± 4.6 mm on the chondrosarcoma side and 7.2 ± 1.7 mm on the contralateral normal side. The pICA was located more anteriorly than the contralateral side in 8/9 of cases (Fig. 3) and more posteriorly in one case. The CC measurement between the VC and the pICA was 4.4 ± 3.7 mm on the chondrosarcoma side and 1.4 ± 0.8 mm on the contralateral side. The pICA was located more superiorly than the contralateral side in 6/9 of cases (Fig. 3), the same craniocaudal level in one case and more inferiorly in one case. The AP measurement differences were decreased on the chondrosarcoma side (p = 0.054) and CC measurement differences were increased on the chondrosarcoma side (p = 0.061) compared to the contralateral side.
The line extrapolated from the posterior opening of the VC in the trajectory of the canal less frequently intersected the pICA cross-section in the presence of chondrosarcoma (3/9 cases) than on the contralateral normal side (7/9 cases) (Table 5). The pICA cross-section was superior to this line in the remaining cases.
Whilst the anterior genu was consistently located in the superomedial quadrant of all contralateral normal petroclival regions (Table 4), there was a more variable coronal location relative to the posterior opening of the VC in the presence of a chondrosarcoma (superomedial n = 5, superolateral n = 3, centred on the canal n = 1 (Fig. 5)).
Discussion
This study indicates that the presence of a petroclival chondrosarcoma significantly and variably impacts on the anatomical relationship between the VC and the pICA. A petroclival chondrosarcoma most frequently displaces the pICA more superiorly and anteriorly relative to the posterior VC (Fig. 6). Whilst the pICA normally lies in the direct trajectory of the VC, a chondrosarcoma often displaces it superiorly relative to the line of the canal. In addition, the anterior genu of the artery pICA is expected to be superomedial to the dorsal VC; however a chondrosarcoma may displace it superolaterally. There may be rare occasions when the pICA is located directly in the line of the eroded posterior VC.
Injury to the pICA has a reported occurrence rate of 0.4–3.8% during traditional endoscopic endonasal approaches [13]. Endoscopic approaches to access the petroclival region in the coronal plane require fixed and consistent anatomical landmarks in order to locate the pICA [5,6,7,8,9,10,11, 14, 17]. The VC is the most established surgical marker to safely access the foramen lacerum [12, 23]. Drilling posteriorly along the medial and inferior aspect of the VC is described as a safe technique, since the posterior opening of the VC is reported to lie inferior to the anterior genu of the pICA. Alternative landmarks to localise the pICA have been evaluated such as the maxillary nerve [14], eustachian tube [22], vidian-eustachian junction [19], and the pterygo-clival ligament [18].
The presence of a petrous apex chondrosarcoma may potentially distort the pICA or erode the VC and impact on their expected spatial relationship. Whilst neuro-navigation may assist the surgeon during the surgical approach in the presence of distorted anatomy, movement of the pICA during the course of the dissection may lead to loss of accuracy. Whilst real-time intraoperative imaging such as Doppler ultrasonography [11] can help identify vital vascular structures, it is not a replacement for a clear understanding of the expected anatomical relationships along the coronal surgical trajectory. There have been few studies applying anatomical landmarks for the identification of the pICA and its anterior genu in the presence of central skull base tumours. Kassam et al.9 described the anatomical relationship in 25 surgical cases although the tumour characteristics were not described. Oakley et al. [19] successfully applied the vidian-eustachian junction to the location of the ICA in 9 patients with skull base tumours of which 3 were petroclival chondrosarcomas. Our results indicate that petroclival chondrosarcomas should be anticipated to displace the pICA superiorly from the trajectory of the VC, so maintaining its application as a safe landmark in almost all cases. However, in rare cases, the pICA may be displaced anteriorly in the line of the canal and so surgeons should be mindful of this potential hazard. The potential for destruction of the dorsal VC may also require the use of alternative anatomical landmarks to identify the pICA [18].
Whilst the main focus has been on cadaveric studies, these anatomical relationships have also been investigated on computed tomography in normal subjects [16, 23]. Our findings on the contralateral normal petroclival regions are consistent with those of Vescan et al. [23] who found the anterior genu of the pICA to be superomedial to the VC in all cases. Mason et al. [16] studied the vertical relationship of the pICA with the VC and demonstrated 34% of cases to terminate at the level of the canal when extrapolated posteriorly in the line of the palate. Whilst this conflicts with our finding of 7/9 cases intersecting the pICA in the craniocaudal axis, it should be noted that our study mimicked the surgical approach in the trajectory of the VC.
This study has limitations due to its retrospective design. In particular, the majority of eligible chondrosarcoma cases were excluded due to the absence of adequate contrast-enhanced thin section CT imaging. In addition, whilst stringent inclusion criteria for the depiction of the contrast-enhanced ICA were applied, formal CTA studies would be optimal for this analysis.
Conclusion
Whilst the VC is normally a reliable indicator of the pICA location, conventional landmarks appear less reliable in the presence of petroclival chondrosarcoma. The pICA is usually superiorly displaced, and its anterior genu remains superior to the VC; however, rarely, the use of this anatomical landmark is precluded by anterior displacement of the pICA in the line of the VC. The inconsistent relationship between the VC and the pICA supports an individualised approach to determine anatomy of the VC and the pICA in the setting of a petroclival chondrosarcoma.
References
Bouthillier A, van Loveren HR, Keller JT (1996) Segments of the internal carotid artery: a new classification. Neurosurgery 38:425–432
Carlson ML, O’Connell BP, Breen JT et al (2016) Petroclival chondrosarcoma: a multicenter review of 55 cases and new staging system. Otol Neurotol 37:940–950
Cebula H, Kurbanov A, Zimmer LA et al (2014) Endoscopic, endonasal variability in the anatomy of the internal carotid artery. World Neurosurg 82:e759–e764
Cianfriglia F, Pompili A, Occhipinti E (1978) Intracranial malignant cartilaginous tumours. Report of two cases and review of literature. Acta Neurochir 45:163–175
DePowell JJ, Froelich SC, Zimmer LA et al (2014) Segments of the internal carotid artery during endoscopic transnasal and open cranial approaches: can a uniform nomenclature apply to both? World Neurosurg 82(6 Suppl):S66–S71
Dorfman HD, Czerniak B (1995) Bone cancers. Cancer 75:203–210
Elhadi AM, Zaidi HA, Yagmurlu K et al (2016) Infraorbital nerve: a surgically relevant landmark for the pterygopalatine fossa, cavernous sinus, and anterolateral skull base in endoscopic transmaxillary approaches. J Neurosurg 125:1460–1468
Fortes FS, Pinheiro-Neto CD, Carrau RL, Brito RV, Prevedello DM, Sennes LU (2012) Endonasal endoscopic exposure of the internal carotid artery: an anatomical study. Laryngoscope 122:445–451
Frank G, Sciarretta V, Calbucci F, Farneti G, Mazzatenta D, Pasquini E (2006) The endoscopic transnasal transsphenoidal approach for the treatment of cranial base chordomas and chondrosarcomas. Neurosurgery 59(1 Suppl 1):ONS50–ONS57
Gibo H, Lenkey C, Rhoton AL Jr (1981) Microsurgical anatomy of the supraclinoid portion of the internal carotid artery. J Neurosurg 55:560–574
Giurintano JP, Gurrola J, Theodosopoulos PV, El-Sayed IH (2021) Use of ultrasound for navigating the internal carotid artery in revision endoscopic endonasal skull base surgery. Cureus 13:e13547
Kassam A, Vescan AD, Carrau RL et al (2008) Expanded endonasal approach: vidian canal as a landmark to the petrous internal carotid artery. J Neurosurg 108:177–183
Labib MA, Prevedello DM, Carrau R et al (2014) A road map to the internal carotid artery in expanded endoscopic endonasal approaches to the ventral cranial base. Neurosurgery 10(Suppl 3):448–471
Liu J, Pinheiro-Neto CD, Fernandez-Miranda JC et al (2014) Eustachian tube and internal carotid artery in skull base surgery: an anatomical study. Laryngoscope 124:2655–2664
Mason E, Gurrola J II, Reyes C, Brown JJ, Figueroa R, Solares CA (2014) Analysis of the petrous portion of the internal carotid artery: landmarks for an endoscopic endonasal approach. Laryngoscope 124:1988–1994
Mason EC, Hudgins PA, Pradilla G, Oyesiku NM, Solares CA (2018) Radiographic analysis of the vidian canal and its utility in petrous internal carotid artery localization. Oper Neurosurg (Hagerstown) 15:577–583
Mesquita Filho PM, Ditzel Filho LFS, Prevedello DM et al (2014) Endoscopic endonasal surgical management of chondrosarcomas with cerebellopontine angle extension. Neurosurg Focus 37:E13
Meybodi AT, Little AS, Vigo V, Arnau A, Kakaizada S, Lawton MT (2019) The pterygoclival ligament: a novel landmark for localization of the internal carotid artery during the endoscopic endonasal approach. J Neurosurg 130:1699–1709
Oakley GM, Ebenezer J, Hamizan A et al. (2018) Finding the petroclival carotid artery: the vidian–eustachian junction as a reliable landmark J Neurol Surg B 79:361–366
Oken M, Creech R, Tormey D et al (1982) Toxicity and response criteria of the Eastern Cooperative Oncology Group. Am J Clin Oncol 5:649–655
Osawa S, Rhoton AL Jr, Seker A, Shimizu S, Fujii K, Kassam AB (2009) Microsurgical and endoscopic anatomy of the vidian canal. Neurosurgery 64(5 Suppl 2):385–412
Ozturk K, Snyderman CH, Gardner PA, Fernandez-Miranda JC (2012) The anatomical relationship between the eustachian tube and petrous internal carotid artery. Laryngoscope 122:2658–2662
Vascan AD, Snyderman CH, Carrau RL, Mintz A, Gardner P, Branstetter B, Kassam AB, Vidian Canal (2007) Analysis and relationship to the internal carotid artery. Laryngoscope 117:1338–1342
VazGuimaraes F, Fernandez-Miranda JC, Koutourousiou M, Hamilton RL, Wang EW, Snyderman CH, Gardner PA (2017) Endoscopic endonasal surgery for cranial base chondrosarcomas. Oper Neurosurg (Hagerstown) 13:421–434
Zanation AM, Snyderman CH, Carrau RL, Gardner PA, Prevedello DM, Kassam AB (2009) Endoscopic endonasal surgery for petrous apex lesions. Laryngoscope 119:19–25
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Ethics approval
All procedures performed in studies involving human participants were in accordance with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. Institutional approval (NS024) was obtained without the requirement for patient informed consent.
Conflict of interest
This research was funded in whole, or in part, by the Wellcome Trust [203148/Z/16/Z]. For the purpose of open access, the author has applied a CC BY public copyright licence to any Author Accepted Manuscript version arising from this submission. Authors acknowledge funding support from Wellcome/Engineering and Physical Sciences Research Council Centre for Medical Engineering at King’s College London (WT 203148/Z/16/Z); National Institute for Health Research Biomedical Research Centre at Guy’s & St Thomas’ Hospitals and King’s College London; Cancer Research UK National Cancer Imaging Translational Accelerator (A27066); the UK Research & Innovation London Medical Imaging and Artificial Intelligence Centre.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
This article is part of the Topical Collection on Neurosurgical Anatomy
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Connor, S.E.J., Thomas, N.W.M. & Shapey, J. Localisation of the petrous internal carotid artery relative to the vidian canal on computed tomography: a case–control study evaluating the impact of petroclival chondrosarcoma. Acta Neurochir 164, 1939–1948 (2022). https://doi.org/10.1007/s00701-022-05254-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00701-022-05254-2