ORIGINAL PAPER
Pneumatization of the sphenoid sinus, dorsum sellae and posterior clinoid processes in computed tomography
Submission date: 2018-06-13
Acceptance date: 2018-07-11
Publication date: 2018-07-18
Pol J Radiol, 2018; 83: 366-371
KEYWORDS
posterior clinoid processdorsum sellaesphenoid sinus pneumatizationComputed Tomography (CT)sphenoid sinuspneumatisationcomputed tomography
TOPICS
ABSTRACT
Purpose:
Assessment of sphenoid sinus (SS), posterior clinoid process (PCP), and dorsum sellae (DS) pneumatisation is significant when planning surgical approaches both to intra- and extrasellar pathologies. The authors analysed pneumatisation of the SS, with particular attention paid to pneumatisation of the PCP and DS.
Material and methods:
The study was based on 100 computed tomography angiography examinations. SS, PCP, and DS pneumatisation grades were assessed using the classification system proposed by Hardy. The analyses were conducted in sagittal planes: midline plane (MP), sagittal posterior clinoid plane right (SPCP-R), and sagittal posterior clinoid plane left (SPCP-L). The occurrence of the highest pneumatisation grade (IVB according to Hardy), which encompasses DS and PCP, prompted the authors to conduct a further analysis in the coronal plane. In this way, seven DS and PCP pneumatisation symmetry types were identified.
Results:
In the MP and SPCP-R, the most frequent pneumatisation grade was grade III (41% and 38%, respectively). In the SPCP-L, grade IVA prevailed (41%). Grade IVB was found in 12% of the SPCP-R images, 10% of the SPCP-L images, and in 12% of the MP images. Consistent pneumatisation grades in all analysed planes were found for 64% of cases. This was usually grade III noted in 28% of cases.
Conclusions:
SS pneumatisation is characterised by considerable individual variability. There are a number of SS pneumatisation classification systems, but the system proposed by Hardy is the most useful for assessment of DS and PCP pneumatisation. Grade III of SS pneumatisation is the most common. Pneumatisation encompassing DS and PCP was found in 10-12% of cases.
Assessment of sphenoid sinus (SS), posterior clinoid process (PCP), and dorsum sellae (DS) pneumatisation is significant when planning surgical approaches both to intra- and extrasellar pathologies. The authors analysed pneumatisation of the SS, with particular attention paid to pneumatisation of the PCP and DS.
Material and methods:
The study was based on 100 computed tomography angiography examinations. SS, PCP, and DS pneumatisation grades were assessed using the classification system proposed by Hardy. The analyses were conducted in sagittal planes: midline plane (MP), sagittal posterior clinoid plane right (SPCP-R), and sagittal posterior clinoid plane left (SPCP-L). The occurrence of the highest pneumatisation grade (IVB according to Hardy), which encompasses DS and PCP, prompted the authors to conduct a further analysis in the coronal plane. In this way, seven DS and PCP pneumatisation symmetry types were identified.
Results:
In the MP and SPCP-R, the most frequent pneumatisation grade was grade III (41% and 38%, respectively). In the SPCP-L, grade IVA prevailed (41%). Grade IVB was found in 12% of the SPCP-R images, 10% of the SPCP-L images, and in 12% of the MP images. Consistent pneumatisation grades in all analysed planes were found for 64% of cases. This was usually grade III noted in 28% of cases.
Conclusions:
SS pneumatisation is characterised by considerable individual variability. There are a number of SS pneumatisation classification systems, but the system proposed by Hardy is the most useful for assessment of DS and PCP pneumatisation. Grade III of SS pneumatisation is the most common. Pneumatisation encompassing DS and PCP was found in 10-12% of cases.
REFERENCES (21)
1.
Cakur B, Sümbüllü MA, Yılmaz AB. A retrospective analysis of sphenoid sinus hypoplasia and agenesis using dental volumetric CT in Turkish individuals. Diagn Interv Radiol 2011; 17: 205-208.
2.
Cheng Y, Chen Y, Zhou Z, et al. Anatomical study of posterior clinoid process (PCP) and its clinical meanings. J Craniofac Surg 2015; 26: 537-540.
3.
Fernandez-Miranda JC, Gardner PA, Rastelli MM Jr, et al. Endoscopic endonasal transcavernous posterior clinoidectomy with interdural pituitary transposition. J Neurosurg 2014; 121: 91-99.
4.
Youssef AS, van Loveren HR. Posterior clinoidectomy: dural tailoring technique and clinical application. Skull Base 2009; 19: 183-191.
5.
Congdon ED. The distribution and mode of origin of septa and walls of the sphenoid sinus. Anat Rec 1920; 18: 97-123.
6.
Hamid O, El Fiky L, Hassan O, et al. Anatomic variations of the sphenoid sinus and their impact on trans-sphenoid pituitary surgery. Skull Base 2008; 18: 9-15.
7.
Tang CT, Baidya NB, Tseng KY, et al. Posterior clinoid process as a landmarker in current endoscopic-assisted neurosurgical approaches. Formosan Journal of Surgery 2012; 45: 45-50.
8.
Tjahjadi M, Kivelev J, Serrone JC, et al. Factors determining surgical approaches to basilar bifurcation aneurysms and its surgical outcomes. Neurosurgery 2016; 78: 181-191.
9.
Silva D, Attia M, Kandasamy J, et al. Endoscopic endonasal posterior clinoidectomy. Surg Neurol Int 2012; 3: 64.
10.
Hardy J. Surgery of the pituitary gland, using the open trans-sphenoidal approach. Comparative study of 2 technical methods. Ann Chir 1967; 21: 1011-1022.
11.
Štoković N, Trkulja V, Dumić-Čule I, et al. Sphenoid sinus types, dimensions and relationship with surrounding structures. Ann Anat 2016; 203: 69-76.
12.
Lu Y, Pan J, Qi S, et al. Pneumatization of the sphenoid sinus in Chinese: the differences from Caucasian and its application in the extended transsphenoidal approach. J Anat 2011; 219: 132-142.
13.
Charsoula A, Nalmpantidou C, Torounidis I, et al. Age-related CT appearance of sphenoid sinus in infants and children. ECR Poster 2011; No. C-1443; doi: 10.1594/ecr2011/C-1443.
14.
Budu V, Mogoantă CA, Fănuţă B, et al. The anatomical relations of the sphenoid sinus and their implications in sphenoid endoscopic surgery. Rom J Morphol Embryol 2013; 54: 13-16.
15.
Anik I, Anik Y, Koc K, et al. Agenesis of sphenoid sinuses. Clin Anat 2005; 18: 217-219.
16.
Wiebracht ND, Zimmer LA. Complex anatomy of the sphenoid sinus: a radiographic study and literature review. J Neurol Surg B Skull Base 2014; 75: 378-382.
17.
Teatini G, Simonetti G, Salvolini U, et al. Computed tomography of the ethmoid labyrinth and adjacent structures. Ann Otol Rhinol Laryngol 1987; 96 (3 Pt 1): 239-250.
18.
ELKammash TH, Enaba MM, Awadalla AM. Variability in sphenoid sinus pneumatization and its impact upon reduction of complications following sellar region surgeries. The Egyptian Journal of Radiology and Nuclear Medicine 2014; 45: 705-714.
19.
Güldner C, Pistorius SM, Diogo I, et al. Analysis of pneumatization and neurovascular structures of the sphenoid sinus using cone-beam tomography (CBT). Acta Radiol 2012; 53: 214-219.
20.
Tomovic S, Esmaeili A, Chan NJ, et al. High-resolution computed tomography analysis of variations of the sphenoid sinus. J Neurol Surg B Skull Base 2013; 74: 82-90.
21.
Idowu OE, Balogun BO, Okoli CA. Dimensions, septation, and pattern of pneumatization of the sphenoidal sinus. Folia Morphol (Warsz) 2009; 68: 228-232.
Share
RELATED ARTICLE
We process personal data collected when visiting the website. The function of obtaining information about users and their behavior is carried out by voluntarily entered information in forms and saving cookies in end devices. Data, including cookies, are used to provide services, improve the user experience and to analyze the traffic in accordance with the Privacy policy. Data are also collected and processed by Google Analytics tool (more).
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
You can change cookies settings in your browser. Restricted use of cookies in the browser configuration may affect some functionalities of the website.
