Anatomy of endoscopic endonasal intraorbital surgery

doi:10.16098/j.issn.0529-1356.2020.05.014

Abstract

Abstract:

Objective To identify the anatomic landmarks of endoscopic endonasal intraorbital approach, and to present two illustrative cases. Methods Three silicon-injected adult cadaveric heads (6 sides) were dissected, using the endosopic surgical instruments to perform the endoscopic endonasal intraorbital approach and the Karl Storz Image1 system to record the entire process. Results Important landmarks, such as the medial orbital wall, part of the inferior orbital floor, periorbita in the deep layer, and intraorbital fat in the superficial layer could be identified using this approach. Furthermore, medial rectus muscle, superior oblique muscle and inferior rectus muscle could also be recognized. Following dissecting the space between the medial rectus muscle and the inferior rectus muscle, the intraconal space could be accessed. After removing the intraconal fat, important vessels and nerves were identified, including the ophthalmic artery and its inferior medial muscular trunk, the optic nerve, and the branches of oculomotor nerve. One case was metallic intraorbital intraconal foreign body and the other one was cavernous hemangioma in the orbital apex involving the pterygopalatine fossa and infratemporal fossa. These two surgeries were both successfully performed, and the aims of the operation were all achieved. Both patients recovered well, and no postoperative complications ccurred. Conclusion An understanding of the landmarks of the intraorbital structures is paramount for surgically dealing with diseases located within or adjacent to this region. The endoscopic endonasal intraorbital approach is safe, effective and minimally invasive for appropriately selected cases.

Key words: Intraorbital structure, Transnasal, Rhino-orbital surgery, Foreign body, Cavernous hemangioma, Endoscopy, Anatomy, Human

CLC Number:

R765.6

LIU Jian-feng ZHAO Jian-hui ZHAO Yu WANG Yi-bei CHEN Zhong-yan HAN Jun YANG Da-zhang. Anatomy of endoscopic endonasal intraorbital surgery[J]. Acta Anatomica Sinica, 2020, 51(5): 719-725.

References

［1］ Castelnuovo P, Turri-Zanoni M, Battaglia P, et al. Endoscopic Endonasal Management of Orbital Pathologies［J］. Neurosurg Clin N Am, 2015,26(3):463-472.
［2］ Kenyon B, Antisdel JL. Anatomic evaluation of endoscopic transnasal transorbital approach to the lateral orbital apex［J］. Am J Rhinol Allergy, 2014,28(1):82-85.
［3］ Abuzayed B, Tanriover N, Gazioglu N, et al. Endoscopic endonasal approach to the orbital apex and medial orbital wall: anatomic study and clinical applications［J］. J Craniofac Surg, 2009,20(5):1594-1600.
［4］ Dallan Ⅰ, Castelnuovo P, de Notaris M, et al. Endoscopic endonasal anatomy of superior orbital fissure and orbital apex regions: critical considerations for clinical applications［J］. Eur Arch Otorhinolaryngol, 2013,270(5):1643-1649.
［5］ Bleier BS, Healy DY Jr, Chhabra N, et al. Compartmental endoscopic surgical anatomy of the medial intraconal orbital space［J］. Int Forum Allergy Rhinol, 2014,4(7):587-591.
［6］ Lenzi R, Bleier BS, Felisati G, et al. Purely endoscopic trans-nasal management of orbital intraconal cavernous haemangiomas: a systematic review of the literature［J］. Eur Arch Otorhinolaryngol, 2016,273(9):2319-2322.
［7］ Dallan Ⅰ, Castelnuovo P, Turri-Zanoni M, et al. Transorbital endoscopic assisted management of intraorbital lesions: lessons learned from our first 9 cases［J］. Rhinology, 2016,54(3):247-253.
［8］ De Rosa A, Pineda J, Cavallo LM, et al. Endoscopic endo-and extra-orbital corridors for spheno-orbital region: anatomic study with illustrative case［J］. Acta Neurochir (Wien), 2019,161(8):1633-1646.
［9］ Almeida JP, Ruiz-Trevio AS, Shetty SR, et al. Transorbital endoscopic approach for exposure of the sylvian fissure, middle cerebral artery and crural cistern: an anatomical study［J］. Acta Neurochir (Wien), 2017,159(10):1893-1907.
［10］ Locatelli D, Pozzi F, Turri-Zanoni M, et al. Transorbital endoscopic approaches to the skull base: current concepts and future perspectives［J］. J Neurosurg Sci, 2016,60(4):514-525.
［11］ Lee JY, Ramakrishnan VR, Chiu AG, et al. Endoscopic endonasal surgical resection of tumors of the medial orbital apex and wall［J］. Clin Neurol Neurosurg, 2012,114(1):93-98.
［12］ Düz B, Secer HI, Gonul E. Endoscopic approaches to the orbit: a cadaveric study［J］. Minim Invasive Neurosurg, 2009,52(3):107-113.
［13］ Maroon JC, Kennerdell JS. Surgical approaches to the orbit. Indications and techniques［J］. J Neurosurg,1984,60(6):1226-1235.
［14］ Escobar Montatixe D, VillacampaAubá JM, Sánchez Bá, et al. Transnasal, transethmoidal endoscopic removal of a foreign body in the medial extraconal orbital space［J］. Case Rep Otolaryngol, 2016,2016:1981456.
［15］ Marchioni D, Bertossi D, Soloperto D, et al. Traumatic intraconal foreign body: report of an injury corrected with combined surgical and endoscopic treatment［J］. OperNeurosurg (Hagerstown), 2016,12(1):14-18.
［16］ El Rassi E, Adappa ND, Battaglia P, et al. Development of the international orbital cavernous hemangioma exclusively endonasal resection (CHEER) staging system［J］. Int Forum Allergy Rhinol, 2019,9(7):804-812.
［17］ Bleier BS, Castelnuovo P, Battaglia P, et al. Endoscopic endonasal orbital cavernous hemangioma resection: global experience in techniques and outcomes［J］. Int Forum Allergy Rhinol, 2016,6(2):156-161.

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