Relationship between the anterior ethmoid artery and skull base in CT images and its significance in rhinosinusitis surgery

doi:10.16098/j.issn.0529-1356.2020.05.005

Abstract

Abstract:

Objective To investigate the anatomical relationship between the anterior ethmoid artery (AEA) and skull base and its significance in rhinosinusitis surgery. Methods A retrospective study was conducted in 52 patients with sinusitis from January 2017 to August 2017. All patients underwent CT scan and the images were reconstructed. The distance between AEA and the skull base was measured and AEAs were classified. The distance from the AEA to the frontal beak was measured and its relationship with the AEA suspension was studied. The prevalence of supraorbital ethmoid cell (SOEC) was recorded the relationship between SOEC and AEA suspension was analyzed by Chi-square test. The depth of lateral lamella of the cribriform plate was measured and the Keros classification was used to classify the sinuses. Spearman’s rank correlation coefficient was used to analyze the relationship between Keros classification and AEA suspension. Results The recognition rate of AEA in CT images was 100%. Type Ⅰ AEA was embedded in the skull, accounting for 42.3% (44/104). Type Ⅱ AEA protruded at the skull base, accounting for 18.3% (19/104). Type Ⅲ AEA was suspended in the ethmoid sinus, accounting for 39.4% (41/104), that is, the AEA suspension rate was 39.4%. The average distance to the skull base was （3.8 ± 1.5） mm. The average distance from AEA to beak was (14.1 ± 2.2) mm, and the difference of the distance in the AEA suspended and non-suspended groups was not statistically significant (t=0.740, P>0.05). In the Keros classification, type Ⅰ accounted for 51.9% (54/104), type Ⅱ for 37.5% (39/104), and type Ⅲ for 10.6% (11/104). The spearman correlation coefficient between Keros classification and AEA suspension was 0.505 (P<0.001), which meaned they were moderately positively related. The prevalence of SOEC was 17.3% (17/104). There was a statistically significant difference of AEA suspension rate between patients with SOEC and patients without SOEC(χ2=4.287, P<0.05). Conclusion When SOEC is present or the level of Keros classification is high, the suspension rate of AEA increased significantly. Preoperative CT imaging can identify the anatomy of the skull base, and clarify the positional relationship between AEA and the skull base, and then reduce the risk of AEA injury during surgery.

Key words: Anterior ethmoidal artery, Skull base, Rhinosinusitis, Supraorbital ethmoid cell, Keros classification, Anatomy, Human

CLC Number:

R762

SHI Mu-han WANG Min WU Yu-xiao LI Hui HUANG Shi-en Lü Zhi-gang. Relationship between the anterior ethmoid artery and skull base in CT images and its significance in rhinosinusitis surgery[J]. Acta Anatomica Sinica, 2020, 51(5): 664-669.

References

［1］ Wormald PJ, Hoseman W, Callejas C, et al. The international frontal sinus anatomy classification (ifac) and classification of the extent of endoscopic frontal sinus surgery (EFSS)［J］. Int Forum Allergy Rhinol, 2016, 6(7):677-696.
［2］ Wang M, Yuan F, Qi WW, et al. Anatomy, classification of intersinus septal cell and its clinical significance in frontal sinus endoscopic surgery in Chinese subjects［J］. Chin Med J (Engl), 2012, 125(24):4470-4473.
［3］ Shi MH, Wang M, Li H, et al. The CT image features of ethmomaxillary sinus and their significance in endoscopic surgery［J］. Chinese Journal of Otorhinolaryngology Head and Neck Surgery，2019, 54(11): 813-818. (in Chinese)
史慕寒, 王旻, 李辉, 等. 筛上颌窦气房的CT影像特点及其在上颌窦手术中的意义［J］. 中华耳鼻咽喉头颈外科杂志, 2019, 54(11): 813-818.
［4］ Lannoy-Penisson L, Schultz P, Riehm S, et al. The anterior ethmoidal artery: radio-anatomical comparison and its application in endonasal surgery［J］. Acta Otolaryngol, 2007, 127(6):618-622
［5］ Keros P. On the practical value of differences in the level of the lamina cribrosa of the ethmoid［J］. Z Laryngol Rhinol Otol, 1962, 41:809-813.
［6］ Joshi AA, Shah KD, Bradoo RA. Radiological correlation between the anterior ethmoidal artery and the supraorbital ethmoid cell［J］. Indian J Otolaryngol Head Neck Surg,2010, 62(3):299-303.
［7］ Zhu L, Wu HB, Fang GL, et al. Value of three-dimensional interactive localization of the anterior ethmoidal canals in minimally invasive nasal surgery［J］. Chinese Journal of Minimally Invasive Surgery, 2009,9(12):1105-1107. (in Chinese)
朱丽, 邬海博, 房高丽, 等. 筛前动脉三维交互观察在鼻微创手术中的定位意义［J］. 中国微创外科杂志, 2009, 9(12):1105-1107.
［8］ Pan ZhY, Qian XJ, Zhai RY, et al. Anatomical study of the ethmoidal canal by multislice CT and its clinical significance［J］. Chinese Journal of Medical Imaging Technology, 2006, 22(8):1185-1188. (in Chinese)
潘振宇, 钱晓军, 翟仁友, 等. 筛动脉管的CT影像解剖学研究及其临床意义［J］. 中国医学影像技术, 2006, 22(8):1185-1188.
［9］ Ding J, Li GY, Zhang XP, et al. Initial evalution of anterior ethmoid artery by 320-row CT cerebral angiography: contrast study with DSA［J］. Chinese Journal of Clinicians(Electronic Edition), 2011,5(13):3746-3750. (in Chinese)
丁娟, 李国英, 张绪平, et al. 320排CT血管成像评价筛前动脉的初步探讨［J］.中华临床医师杂志(电子版),2011,5(13):3746-3750.
［10］ Simmen D, Raghavan U, Briner HR, et al. The surgeon’s view of the anterior ethmoid artery［J］. Clin Otolaryngol, 2006, 31(3): 187-191.
［11］ Erdogmus S, Govsa F. The anatomic landmarks of ethmoidal arteries for the surgical approaches［J］. J Craniofac Surg, 2006, 17(2):280-285.
［12］ Moon HJ, Kim HU, Lee JG, et al. Surgical anatomy of the anterior ethmoidal canal in ethmoid roof［J］. Laryngoscope, 2001, 111(5):900-904.
［13］ Mcdonald SE, Robinson PJ, Nunez DA. Radiological anatomy of the anterior ethmoidal artery for functional endoscopic sinus surgery［J］. J Laryngol Otol, 2008, 122(3):264-267.
［14］ Abdullah B, Lim EH, Mohamad H, et al. Anatomical variations of anterior ethmoidal artery at the ethmoidal roof and anterior skull base in Asians［J］. Surg Radiol Anat, 2019, 41(5):543-550.
［15］ Araujo Filho BC, Weber R, Pinheiro Neto CD, et al. Endoscopic anatomy of the anterior ethmoidal artery: a cadaveric dissection study［J］. Braz J Otorhinolaryngol, 2006, 72(3):303-308.
［16］ Zhang RX, Tian H, Ma YX. Computed tomography assessment of skull base height before endoscopic sinus surgery［J］. Journal of Otolaryngology and Ophthalmology of Shandong University, 2018, 32(5):75-77. (in Chinese)
张汝祥, 田昊, 马有祥. 鼻内镜鼻窦手术前筛窦颅底高度的CT评估价值［J］. 山东大学耳鼻喉眼学报, 2018, 32(5):75-77.
［17］ Skorek A, Tretiakow D, Szmuda T, et al. Is the Keros classification alone enough to identify patients with the‘dangerous ethmoid’? An anatomical study［J］. Acta Otolaryngol, 2017, 137(2):196-201.
［18］ Poteet PS, Cox MD, Wang RA, et al. Analysis of the relationship between the location of the anterior ethmoid artery and keros classification［J］. Otolaryngol Head Neck Surg, 2017, 157(2):320-324.
［19］ Yenigun A, Goktas SS, Dogan R, et al. A study of the anterior ethmoidal artery and a new classification of the ethmoid roof (Yenigun classification)［J］. Eur Arch Otorhinolaryngol, 2016, 273(11):3759-3764.
［20］ Jang DW, Lachanas VA, White LC, et al. Supraorbital ethmoid cell: a consistent landmark for endoscopic identification of the anterior ethmoidal artery［J］. Otolaryngol Head Neck Surg, 2014, 151(6):1073-1077.
［21］ Tran LV, Ngo NH, Psaltis AJ. A radiological study assessing the prevalence of frontal recess cells and the most common frontal sinus drainage pathways［J］. Am J Rhinol Allergy, 2019, 33(3): 323-330.
［22］ Li M, Sharbel DD, White B, et al. Reliability of the supraorbital ethmoid cell vs Keros classification in predicting the course of the anterior ethmoid artery［J］. Int Forum Allergy Rhinol, 2019, 9(7):821-824.

[1]	YIN Shi-qin YANG Si-yi WANG Rui-han YOU Gui-xuan YANG Ying-qiu ZHANG Lei. Distal tibiofibular syndesmosis fibular notch typing and its clinical significance based on CT [J]. Acta Anatomica Sinica, 2024, 55(1): 82-87.
[2]	YANG Yang SHI Jun LI Kun MA Yuan ZHANG Shao-jie HOU Er-fei WANG Chao-qun CHEN Jie WANG Xing LI Zhi-jun. Finite element analysis of cervical intervertebral discs after removing different ranges of uncinate processes [J]. Acta Anatomica Sinica, 2024, 55(1): 88-97.
[3]	YUAN Shuo ZHAO An-quan HUANG Qi-ri-mai-la-tu WU Hai-he XU Yong-sheng QI Yan-song BAO Hu-ri-cha. Association between posterior tibial slope and tibial torsion angle and recurrent patellar dislocation based on the full-length CT of the lower limbs [J]. Acta Anatomica Sinica, 2023, 54(6): 703-709.
[4]	ZHOU Chun-hui XIE Sheng-qiang WANG Jiang-ting LAN Xiao-juan ZHANG Jian-ning ZHAO Hu-lin . Application of multimodal electromagnetic navigation in endoscopic endonasal skull base anatomical measurement of fresh cadavers [J]. Acta Anatomica Sinica, 2023, 54(5): 560-566.
[5]	LIU Yan-jing SHI Yong-hong . Automatic extraction of point cloud on cartilage surface of intraoperative knee using FPFH-PointNet [J]. Acta Anatomica Sinica, 2023, 54(5): 553-559.
[6]	ZHU Qiu-liang YU Xiang-ping MA Jun CHEN Yun-yun LIN Fang RUAN Wen-bin . Adjustment of X-ray angle intraoperation based on the anatomic shape of femoral neck section [J]. Acta Anatomica Sinica, 2023, 54(5): 586-592.
[7]	LIU Hai-lan MEI Yi-xuan ZHANG Yi LIU Cheng LIU Shu-wei. Classification and clinical significance of the branching patterns of the right pulmonary arteries based on the intravital CT data [J]. Acta Anatomica Sinica, 2023, 54(4): 453-459.
[8]	YAO Xiao-xiao LIU Xiao-li LI Ru-hua LI Chang-sheng REN Chuan-gen CHEN Cheng-chun . Susceptibility weighted imaging of superficial cerebellar veins [J]. Acta Anatomica Sinica, 2023, 54(4): 465-472.
[9]	CHENG Zhi-han RAN Zhi-yu LING Liang-you HE Jia-ning. Sex differences in the morphology of the distal humerus in Ming and Qing Dynasties population in North China [J]. Acta Anatomica Sinica, 2023, 54(3): 328-334.
[10]	LI Yun-qing. Trends in neuroanatomical research [J]. Acta Anatomica Sinica, 2023, 54(3): 368-373.
[11]	WANG Jian-wei LIU Huai-cun CHENG Quan-cheng DING Hui-ru SUN Yan-rong GU Pei-liang LUAN Ying-jie ZHANG Jun-wei ZHANG Wei-guang. Brain removal through a posterior incision on the scalp of both ears [J]. Acta Anatomica Sinica, 2023, 54(1): 123-125.
[12]	ZHANG Lei YANG Si-yi ZHANG Xiao-hong CAO Xing-wang XIA Zhang-rong ZHOU Xin. Anatomical characteristics and clinical significance of the syndesmosis based on MRI [J]. Acta Anatomica Sinica, 2022, 53(5): 628-632.
[13]	WANG Jian-wei XU Jing-yong WEI Jun-min ZHANG Wei-guang. Clinical anatomy of cast specimens of the pancreatic duct [J]. Acta Anatomica Sinica, 2022, 53(5): 633-636.
[14]	RUAN Cai-lian GUO Hong-tao HUI Xue-feng WANG Lu ZHU Hui ZHAO Lin LIU Bo-feng LI Xiao-ji. Morphological analysis of thoracic pedicle of 12-15-year-old idiopathic scoliosis and normal spine in northern Shaanxi province [J]. Acta Anatomica Sinica, 2022, 53(2): 225-237.
[15]	SONG Hui-fang TAN Jia-yin LIU Yang ZHANG Wei-guo GUO Rui. Hypoxic pretreatment enhancing the angiogenesis of aged human bone marrow mesenchymal stem cells through hypoxia inducible factor-1α [J]. Acta Anatomica Sinica, 2022, 53(1): 35-41.