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26.07.2018 | Review

Review of the main surgical and angiographic-oriented classifications of the course of the internal carotid artery through a novel interactive 3D model

verfasst von: Marc Valera Melé, Anna Puigdellívol-Sánchez, Marija Mavar-Haramija, Juan A. Juanes-Méndez, Luis San Román, Matteo De Notaris, Giuseppe Catapano, Alberto Prats-Galino

Erschienen in: Neurosurgical Review | Ausgabe 2/2020

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Abstract

The course of the internal carotid artery (ICA) and its segment classifications were reviewed by means of a new and freely available 3D interactive model of the artery and the skull base, based on human neuroimages, that can be freely downloaded at the Public Repository of the University of Barcelona (http://diposit.ub.edu/dspace/handle/2445/112442) and runs under Acrobat Reader in Mac and Windows computers and Windows 10 tablets. The 3D-PDF allows zoom, rotation, selective visualization of structures, and a predefined sequence view. Illustrative images of the different classifications were obtained. Fischer (Zentralbl Neurochir 3:300–313, 1938) described five segments in the opposite direction to the blood flow. Gibo-Rothon (J Neurosurg 55:560–574, 1981) follow the blood flow, incorporated the cervical and petrous portions, and divided the subarachnoid course—supraclinoid—in ophthalmic, communicating, and choroidal segments, enhancing transcranial microscopic approaches. Bouthillier (Neurosurgery 38:425–433, 1996) divided the petrous portion describing the lacerum segment (exposed in transfacial procedures and exploration of Meckel’s cave) and added the clinoid segment between the proximal and distal dural rings, of interest in cavernous sinus surgery. The Kassam’s group (2014), with an endoscopic endonasal perspective, introduces the “paraclival segment,” including the “lacerum segment” and part of the intracavernous ICA, and details surgical landmarks to minimize the risk of injury. Other classifications are also analyzed. This review through an interactive 3D tool provides virtual views of the ICA and becomes an innovative perspective to the segment classifications and neuroanatomy of the ICA and surrounding structures.

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Abdulrauf SI, Ashour AM, Marvin E, Coppens J, Kang B, Hsieh TY, Nery B, Penanes JR, Alsahlawi AK, Moore S, Abou Al-Shaar H, Kemp J, Chawla K, Sujijantarat N, Najeeb A, Parkar N, Shetty V, Vafaie T, Antisdel J, Mikulec TA, Edgell R, Lebovitz J, Pierson M, Pires de Aguiar PH, Buchanan P, Di Cosola A, Stevens G (2016) Proposed clinical internal carotid artery classification system. J Craniovertebr Junction Spine 7:161–170 Erratum in J Craniovertebr Junction Spine (2016) 8:84CrossRef

Bouthillier A, van Loveren HR, Keller JT (1996) Segments of the internal carotid artery: a new classification. Neurosurgery 38:425–433PubMed

Choi HC, Park SE, Choi DS, Shin HS, Kim JE, Choi HY, Park MJ, Koh EH (2018) Ruptured extracranial carotid artery: endovascular treatment with covered stent graft. J Neuroradiol 45:217–223

D’Avella E, De Notaris M, Enseñat J, Berenguer J, Gragnaniello C, Mavar M, Ferrer E, Prats-Galino A (2015) The extended endoscopic endonasal transplanum transtuberculum approach to the anterior communicating artery complex: anatomical study. Acta Neurochir 157:1495–1503CrossRef

De Notaris M, Prats-Galino A, Cavallo LM, Esposito F, Iaconetta G, González JB, Montagnani S, Ferrer E, Cappabianca P (2010) Preliminary experience with a new three-dimensional computer-based model for the study and the analysis of skull base approaches. Childs Nerv Syst 26:621–626CrossRef

De Notaris M, Solari D, Cavallo LM, Enseñat J, Alobid I, Soria G, Gonzalez JB, Ferrer E, Prats-Galino A (2011) The use of a three-dimensional novel computer-based model for analysis of the endonasal endoscopic approach to the midline skull base. World Neurosurg 75:106–113CrossRef

De Notaris M, Palma K, Serra L, Enseñat J, Alobid I, Poblete J, González JB, Solari D, Ferrer E, Prats-Galino A (2014) A three-dimensional computer-based perspective of the skull base. World Neurosurg 82:S41–S48CrossRef

De Notaris M, Prats-Galino A, Enseñat J, Topczewski T, Ferrer E, Cavallo LM, Cappabianca P, Solari D (2014) Quantitative analysis of progressive removal of nasal structures during endoscopic suprasellar approach. Laryngoscope 124:2231–2237CrossRef

De Powell JJ, Froelich SC, Zimmer LA, Leach JL, Karkas A, Theodosopoulos PV, Keller JT (2014) Segments of the internal carotid artery during endoscopic transnasal and open cranial approaches: can a uniform nomenclature apply to both? World Neurosurg 82(6S):S66–S71

10.

Dolati P, Golby A, Eichberg D, Abolfotoh M, Dunn IF, Mukundan S, Hulou MM, Al-Mefty O (2015) Pre-operative image-based segmentation of the cranial nerves and blood vessels in microvascular decompression: can we prevent unnecessary explorations? Clin Neurol Neurosurg 139:159–165CrossRef

11.

Dolati P, Eichberg D, Golby A, Zamani A, Laws E (2016) Multimodal navigation in endoscopic transsphenoidal resection of pituitary tumors using image-based vascular and cranial nerve segmentation: a prospective validation study. World Neurosurg 95:406–413CrossRef

12.

Dusick JR, Esposito F, Malkasian D, Kelly DF (2007) Avoidance of carotid artery injuries in transsphenoidal surgery with the Doppler probe and micro-hook blades. Neurosurgery 60:322–328PubMed

13.

Fischer E (1938) Die lageabweichungen der vorderen hirnarterie im gefäbild. Zentralbl Neurochir 3:300–313

14.

Gao Z, Chi FI (2015) Anatomy relationship around internal carotid artery in the endoscopic surgery of nasopharynx: a study based on computed tomography angiography. J Neurol Surg B Skull Base 76:176–182CrossRef

15.

Gibo H, Lenkey C, Rhoton A Jr (1981) Microsurgical anatomy of the supraclinoid portion of the internal carotid artery. J Neurosurg 55:560–574CrossRef

16.

Glasscock ME III (1969) Middle fossa approach to the temporal bone. An otologic frontier. Arch Otolaryngol 90:15–27CrossRef

17.

Gorpe P, Auperin A, Honart JF, Ton Van J, El Bedoui S, Bidault F, Temam S, Kolb R, Qassemyar Q (2018) Revisiting vascular contraindicatios for transoral robotic surgery for oropharyngeal cancer. Laryngoscope Investig Otolaryngol 3:121–126CrossRef

18.

Harris FS, Rhoton AL (1976) Anatomy of the cavernous sinus. A microsurgical study. J Neurosurg 42:169–180CrossRef

19.

Kassam AB, Gardner P, Snyderman C, Mintz A, Carrau R (2005) Expanded endonasal approach: fully endoscopic, completely transnasal approach to the middle third of the clivus, petrous bone, middle cranial fossa and infratemporal fossa. Neurosurg Focus 19:E6PubMed

20.

Kassam AB, Vescan AD, Carrau RL, Prevedello DM, Gardner P, Mintz AH (2008) Expanded endonasal approach: vidian canal as a landmark to the petrous internal carotid artery. J Neurosurg 108:177–183CrossRef

21.

Kawase T, Shiobara R, Toya S (1991) Anterior transpetrosaltranstentorial approach for sphenopetroclival meningiomas: surgical method and results in 10 patients. Neurosurgery 28(6):869–875 discussion 875–876CrossRef

22.

Kim B (2010) Anatomy. Blood supply to the brain. In: Citow JS, Macdonald RL, Refai D (eds) Comprehensive neurosurgery board review, 2nd edn. Thieme, New York, pp 1–110

23.

Labib M, Prevedello D, Carrau R, Kerr E, Naudy C, Abou Al-Shaar H, Corsten M, Kassam A (2014) A road map to the internal carotid artery in expanded endoscopic endonasal approaches to the ventral cranial base. Neurosurgery 10:448–471PubMed

24.

Lasjaunias P, Berenstein A (1978) Arterial anatomy: introduction. In: Lasjaunias P, Berenstein A (eds) Surgical Neuroangiography: functional anatomy of craniofacial arteries. Springer-Verlag, Berlin, pp 1–32

25.

Louw L (2015) Different ophthalmic artery origins: embriology and clinical significance. Clin Anat 28:276–576CrossRef

26.

Marcati E, Andaluz N, Froelich SC, Zimmer LA, Leach JL, Fernández-Miranda JC, Kurbanov A, Keller JT (2017) Paratrigeminal, paraclival, precavernous, or all of the above? A circumferential anatomical study of the C3-C4 transitional segment of the internal carotid artery. Oper Neurosurg (Hagerstown). https://doi.org/10.1093/on/opx121

27.

Mavar-Haramija M, Prats-Galino A, Juanes-Méndez JA, Puigdellívol-Sánchez A, de Notaris M (2015) Interactive 3D-PDF presentations for the simulation and quantification of extended endoscopic endonasal surgical approaches. J Med Sys 39:127CrossRef

28.

Mujika KM, Méndez JAJ, de Miguel AF (2018) Advantages and disavantages in image processing with free software in radiology. J Med Sys 42:36CrossRef

29.

Nathal E, Castillo G (2012) Surgical treatment of paraclinoid aneurysms. In: Quiñones-Hinojosa A (ed) Schmidek and sweet operative neurosurgical techniques: indications, methods and results, 6th edn. Elsevier, Philadelphia, pp 855–871CrossRef

30.

Phelps A, Naeger DM, Marcovici P (2012) Embedding 3D radiology models in portable document format. AJR Am J Roentgenol 199:1342–1344CrossRef

31.

Prasad SC, Thada N, Pallavi, Prasad KC (2011) Paragangliomas of the head&neck: the KMC experience. Indian J Otolaryngol Head Neck Surg 63:62–73CrossRef

32.

Prats-Galino A, Mavar M, Reina MA, Puigdellívol-Sánchez A, San-Molina J, De Andrés JA (2014) Three-dimensional interactive model of lumbar spinal structures. Anaesthesia 69:521CrossRef

33.

Prats-Galino A, Reina MA, Mavar Haramija M, Juanes Méndez JA, De Andrés JA (2015) 3D interactive model of lumbar spinal structures of anesthetic interest. Clin Anat 28:205–212CrossRef

34.

Rhoton AL (2002) The supratentorial arteries. Neurosurgery 51:53–120

35.

Sorensen MS, Dobrzeniecki AB, Larsen P, Frisch T, Sporring J, Darvann TA (2002) The visible ear: a digital image library of the temporal bone. ORL J Otorhinolaryngol Relat Spec 64:378–381CrossRef

36.

Spiessberger A, Baumann F, Kothbauer KF, Aref M, Marbacher S, Fandino J, Nevzati E (2019) Bony dehiscence of the horizontal petrous internal carotid artery canal: an anatomic study with surgical implications. World Neurosurg:S1878–S8750

37.

Sun X, Uan B, Truong HQ, Borghei-Razavi H, Snyderman CH, Fernández-Miranda JC (2018) A comparative analysis of endoscopic-assisted transoral and transnasal approaches to parapharyngeal space: a cadaveric study. J Neurol Surg B Skull Base 79:229–240CrossRef

38.

Tauber M, Van Loveren HR, Jallo G, Romano A, Keller JT (1999) The enigmatic foramen lacerum. Neurosurgery 44:386–391CrossRef

39.

Tubbs RS, Hansasuta A, Loukas M, Louis RG Jr, Shoja MM, Salter EG, Oakes WJ (2007) Branches of the petrous and cavernous segments of the internal carotid artery. Clin Anat 20:596–601CrossRef

40.

Üstün ME, Büyükmumcu M, Seker M, Karabulut AK, Uysal II, Ziylan T (2004) Possibility of middle meningeal artery-to-petrous internal carotid artery bypass: an anatomic study. Skull Base 14:153–156CrossRef

41.

Valera-Melé M, Puigdellívol-Sánchez A, Mavar-Haramija M, Juanes-Méndez J, San-Román L, De Notaris M, Prats-Galino A (2018) A novel and freely available interactive 3D model of the internal carotid artery. J Med Sys 42:72CrossRef

42.

Van Loveren HR, Keller JT, El-Kalliny M, Scodary DJ, Tew JM (1991) The Dolenc technique for cavernous sinus exploration (cadaveric prosection). J Neurosurg 74:837–844CrossRef

43.

Vijaywarqiya M, Deopujari R, Athavale SA (2017) Anatomical study of petrous and cavernous parts of internal carotid artery. Anat Cell Biol 50:163–170CrossRef

44.

Wang S, Quin Y, Xiao D, Wu Z, Wei L (2018) Imaging evaluation of the location and fenestration of sellar floor during endonasal transsphenoidal surgery in patients with pituitary adenomas. World Neurosurg. https://doi.org/10.1016/j.wneu.2018.04.178

45.

Wikimedia Commons. Gray H (1918) Anatomy of the Human Body, 20^th ed. Philadelphia and New York:Lea&Febiger. (https://upload.wikimedia.org/wikipedia/commons/9/9c/Gray513.png). [Accessed June 1th, 2017]

Titel: Review of the main surgical and angiographic-oriented classifications of the course of the internal carotid artery through a novel interactive 3D model
verfasst von: Marc Valera Melé
Anna Puigdellívol-Sánchez
Marija Mavar-Haramija
Juan A. Juanes-Méndez
Luis San Román
Matteo De Notaris
Giuseppe Catapano
Alberto Prats-Galino
Publikationsdatum: 26.07.2018
Verlag: Springer Berlin Heidelberg
Erschienen in: Neurosurgical Review / Ausgabe 2/2020
Print ISSN: 0344-5607
Elektronische ISSN: 1437-2320
DOI: https://doi.org/10.1007/s10143-018-1012-7

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