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Outcomes of Endoscopic Endonasal Surgery for Tuberculum Sellae and Planum Sphenoidale Meningiomas: A Retrospective Study

Published online by Cambridge University Press:  10 September 2024

Lynn Abigail Schroeder
Affiliation:
Department of Clinical Neurosciences, Cumming School of Medicine, University of Calgary, Calgary, AB, Canada
Yves Pieter Starreveld*
Affiliation:
Department of Clinical Neurosciences, Cumming School of Medicine, University of Calgary, Calgary, AB, Canada
*
Corresponding author: Yves Pieter Starreveld; Email: [email protected]
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Abstract

Background:

To evaluate clinical outcomes and volumetric changes following endoscopic endonasal approach (EEA) for tuberculum sellae (TS) and planum sphenoidale (PS) meningiomas. Key objectives included evaluating pre- and postoperative tumor volumes, visual assessments and EEA-related complications.

Methods:

A single-center retrospective study was conducted at Foothills Medical Centre, University of Calgary, Canada, from 2009 to 2022 including 24 patients meeting inclusion criteria for midline skull base tumors, confirmed as WHO Grade I or II meningiomas with optic canal extension.

Results:

EEA achieved gross total resection in 87.5% of cases, with a mean tumor volume reduction of 92.24%. Postoperatively, 91.67% exhibited visual improvement or stability. Cerebrospinal fluid leaks occurred in 12.5% of cases, necessitating revision surgery in one case. Persistent postoperative endocrine dysfunction affected 4.17%. Preoperative tumor volume did not demonstrate a correlation with complications.

Conclusions:

This study delivers reproducible data for pre- and postoperative tumor volume following the EEA after TS or PS meningiomas. The EEA demonstrated favorable radiographic and clinical outcomes in TS and PS meningiomas, achieving gross total resection with minimal morbidity.

Résumé

RÉSUMÉ

Résultats cliniques de la chirurgie endoscopique endonasale pour les méningiomes du tubercule de la selle et du planum sphénoïdal : une étude rétrospective.

Contexte :

Évaluer les résultats cliniques et les changements volumétriques après une chirurgie endoscopique endonasale (CEE) pour les méningiomes du tubercule de la selle (TS) et du planum sphénoïdal (PS). Les objectifs clés de cette étude comprenaient l’évaluation des volumes tumoraux pré et postopératoires, des évaluations visuelles de même que des complications liées à la CEE.

Méthodes :

Il s’agit d’une étude rétrospective monocentrique menée au Foothills Medical Centre de l’Université de Calgary (Canada) de 2009 à 2022. Cette étude incluait 24 patients répondant à des critères d’inclusion pour des tumeurs de la ligne médiane de la base du crâne. On a aussi confirmé que ces tumeurs étaient des méningiomes de grade I ou II selon l’OMS et qu’elles comportaient une extension du canal optique.

Résultats :

La CEE a permis une résection totale brute dans 87,5 % des cas ainsi qu’une réduction moyenne du volume tumoral de 92,24 %. En contexte postopératoire, 91,67 % des patients ont donné à voir une amélioration ou une stabilité de leurs capacités visuelles. Des fuites de liquide céphalorachidien (LCR) sont survenues dans 12,5 % des cas, ce qui a nécessité une reprise chirurgicale dans un cas. Un dysfonctionnement endocrinien postopératoire persistant a par ailleurs été observé dans 4,17 % des cas. Enfin, le volume tumoral préopératoire n’a pas montré de corrélation avec les complications subséquentes.

Conclusions :

Cette étude a fourni des données reproductibles sur le volume tumoral pré et postopératoire après une CEE pour des méningiomes du TS ou du PS. La CEE a aussi révélé des résultats radiographiques et cliniques favorables dans le cas des méningiomes du TS et du PS, permettant ainsi une résection totale brute avec une morbidité minimale.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Canadian Neurological Sciences Federation

Highlights

  • High gross total resection rate for tuberculum sellae and planum sphenoidale – meningiomas using the endoscopic endonasal approach.

  • In total, 91.67% of patients experienced improved or stable vision postoperatively, demonstrating significant visual outcomes.

  • Minimal morbidity with only 12.5% cerebrospinal fluid leak rate, effectively managed with advanced reconstruction techniques.

Introduction

Tuberculum sellae (TS) and planum sphenoidale (PS) meningiomas, constituting 10%–15% of all intracranial tumors, are challenging neurosurgeons due to their intricate anatomical location within the skull base. Reference Arai, Sato and Okuda1Reference Chi and McDermott3 Surgical decompression is the therapy of choice for symptomatic patients with the aim of addressing optic pathway decompression and preserving vital blood vessels. Reference Fernandez-Miranda, Pinheiro-Nieto, Gardner and Snyderman4,Reference Taha, Erkmen, Dunn, Pravdenkova and Al-Mefty5 According to Magill et al., an increased tumor size in meningiomas, irrespective of their location, is associated with atypical meningioma (WHO Grade II) and male sex. Reference Magill, Young, Chae, Aghi, Theodosopoulos and McDermott6 TS and PS meningiomas are particularly notorious for inducing visual impairment often leading to a chiasmal syndrome in patients. Reference Uede, Ohtaki, Nonaka, Tanabe and Hashi7Reference Sade and Lee9 Surgical intervention for these meningiomas encompasses both transcranial approaches (TCA) and endoscopic endonasal approaches (EEAs). The latter, evolving from its initial use for pituitary adenomas, has progressively extended its purview to include TS and PS meningiomas over the last two decades. Reference Jimenez, Harrison Snyder and Rabinovich10Reference Kassam, Snyderman, Mintz, Gardner and Carrau15 The EEA offering access between the olfactory groove and the odontoid process, demonstrates potential superiority in visual outcomes and overall complication rates. Reference Prevedello, Doglietto, Jane, Jagannathan, Han and Laws16,Reference Solares, Ong and Snyderman17 While EEA is associated with a higher incidence of cerebrospinal fluid (CSF) leaks compared to TCA, recent studies indicate a decreasing trend, with approximately 4% of EEA-treated patients experiencing CSF leaks. Consequently, EEA has emerged as an effective treatment option. Reference Jimenez, Harrison Snyder and Rabinovich10,Reference Jho and Ha14,Reference de Divitiis, Cavallo, Esposito, Stella and Messina18Reference Zhang, Ding and Liu25 Gross total resection (GTR) of the TS or PS tumor is described in 56%–100% of EEA studies. Reference Lopez, Suarez, Costales, Rodrigo, Suarez and Llorente26 Better rates of resection, postoperative visual improvement and preservation of olfaction emerge as potential benefits of EEA for TS or PS meningiomas. Reference Ottenhausen, Banu and Placantonakis27 This study is dedicated to assessing clinical outcomes in TS and PS meningiomas after the EEA, with a specific emphasis on reproducible pre- and postoperative tumor volume measurements, visual assessments and EEA-related complications. The primary focus is on demonstrating the validity of EEA as an effective approach for skull base surgeons in TS and PS meningiomas, underscored by an exhaustive single-center analysis conducted at our institution.

Methods

A single-center, retrospective analysis was performed at the Department of Neurosciences, Foothills Medical Centre, University of Calgary, Canada, over a 12-year period spanning from 2009 to 2022. Institutional review board approval was obtained for the study. Individual consent for the study was waived. The study cohort included 24 patients who underwent endoscopic endonasal surgery for TS or PS meningiomas. The authors define PS and TS meningiomas primarily based on their anatomical location. PS meningiomas originate from the PS at the anterior skull base, located in front of the sella turcica and behind the cribriform plate. TS meningiomas arise from the TS, situated at the junction of the anterior clinoid process and sella turcica, directly above the pituitary gland. When it is difficult to distinguish between both types, the impact on surrounding structures is considered: PS meningiomas affecting the frontal lobes and olfactory structures due to their more anterior position and TS meningiomas more often extending into the optic canal. The surgeries were consistently performed by the same surgeon, Y.P.S, with the collaboration of an ear-nose-throat (ENT) surgeon for the opening and closure procedures. All endoscopic approaches conducted during this period were performed exclusively by the author Y.P.S. Other TS and PS meningiomas were operated on at the neurosurgical department during this timeframe using TCAs. Each participating ENT surgeon utilized a surgical approach involving middle turbinectomy and the procedure included establishing a surgical corridor through the creation of a Hadad–Bassagasteguy flap with the removal of both the posterior bony septum and the anterior cartilaginous septum, shoulder osteotomy and removal of the vomer. All patients underwent preoperative and postoperative cranial magnetic resonance imaging (MRI) assessments, both with and without contrast enhancement.

Inclusion criteria

The study’s inclusion criteria encompassed endoscopic approaches for tumors situated on the midline with extension into the optic canal and vessel encasement. The indication for EEA was tumors that did not extend beyond the medial orbital walls, anterior to the posterior wall of the frontal sinus, or posterior to the posterior clinoid. The primary criterion for suitability for EEA was the ability to achieve a durable reconstruction. Specifically, our study encompassed cases of TS and PS meningiomas that underwent surgery during the mentioned period. These cases underwent a histopathological analysis at the time of surgery and were classified as Meningiomas World Health Organization (WHO) Grade I or II. Of note, due to the retrospective nature of the study, the 24 patients had been evaluated according to the latest WHO classification for tumors of the nervous system at the time of their surgery, including WHO classification versions of 2007, 2013, 2016 or 2022.

Preoperative and postoperative data assessment

Preoperative and postoperative data of these patients were evaluated retrospectively, including demographics, clinical manifestations, image data, endocrine functions, ophthalmological assessments, operative records and clinical and surgical complications. The indication for surgery was based on visual impairment or interval growth on stated tumors observed on repetitive MRI scans. For ophthalmological assessments, visual acuity testing as well as peripheral field testing were conducted. The objective peripheral field testing was based on Humphrey 24–2 protocol, and Humphrey Field Analyzer II. As preoperative ophthalmological assessment, the last available testing before surgery was defined as preoperative data. The study assessed visual impairment in patients with TS and PS meningiomas using pre- and postoperative ophthalmological evaluations conducted separately for each eye. Criteria for visual field changes were based on Humphrey Visual Field Analyzer tests, defining improvement, worsening or stability based on changes in mean deviation (MD) values. Visual field changes were defined based on MD values from Humphrey Visual Field Analyzer tests: improvement was indicated by an increase in MD value of more than 1.0 dB, worsening by a decrease of more than 1.0 dB, and stability by changes within ± 1.0 dB. Visual acuity and field impairment were classified as unchanged, improved, worsened or completely recovered postoperatively. All visual acuity improvements (e.g., from 25/20 to 20/20) were considered as improvements. The postoperative ophthalmological assessment was carried out 1 year after surgery. The pre- and postoperative endocrinological management encompassed various critical elements, including continuous monitoring of urine output on an hourly basis. Additionally, biochemical and endocrine reviews for electrolytes, serum osmolality and pituitary hormone panel were conducted. All patients underwent endocrinological follow-up evaluations during the hospital admission, at 6–8 weeks, at 6 months and at 1 year after surgery to monitor for endocrinological changes. Persistent endocrine dysfunction was determined as persistent medical supplementation for pituitary dysfunction or diabetes insipidus at the 6-month endocrinological assessment. Hyposmia was assessed by patient history during the most recent clinic visit. We asked for a binary response to “Can you smell things like coffee?” and no scales or objective tests were used. The cranial MRI leading to indication to surgery was defined as preoperative MRI. Postoperative MRI was performed in 48 hours and 6–12 months postoperatively. We defined the postoperative volume as no tumor or capsule remnant on postoperative MRI examination and measured the postoperative volume in cm3 in case of subtotal resection or in case of capsule remnant. Preoperative and postoperative volume assessments were carried out using Horos ® software. The volumetric analysis involved a cut-by-cut evaluation and volume computation of the pre- and postoperative tumor volume data. The EEA was tailored to excise the dural tail and the dural tail was included in the pre- and postoperative tumor volume measurements. Pre- and postoperative volume were computed by the first author (L.A.S). Postoperative complete resection was defined as 0.000 cm3 of postoperative tumor volume and tumor volume under or equal to 0.500 cm3 was described as GTR. Postoperative tumor reduction was calculated in percentage.

Surgical procedure and postoperative care

Patients underwent general anesthesia with orotracheal intubation and were positioned supine with the head secured using a Mayfield head clamp. Cranial neuronavigation was used for interoperative navigation if needed. A free-fat graft from either the thigh or the belly was prepared. Aseptic techniques were employed during draping, and the nasal cavity was prepared with neuro patties soaked in adrenalin for a minimum of 5 minutes to reduce bleeding. Surgical procedures involved the use of 4-mm rigid endoscopes with 0° and 30° angled lenses through both nostrils. A surgical corridor was established through middle turbinectomy, the creation of a Hadad–Bassagasteguy flap with the removal of both the posterior bony septum and the anterior cartilaginous septum, shoulder osteotomy and removal of the vomer. The dura was opened in a curvilinear fashion, and the tumor was exposed at the TS or PS. After devascularization using bipolar cautery along the floor of the planum and tuberculum, the tumor was debulked with careful microdissection to avoid interruption of the arachnoid membrane and vascular structures as much as possible. Skull base defect reconstruction was achieved by using a free fat graft from the abdomen or the thigh and a nasoseptal flap, potentially with the addition of fibrin, to further prevent CSF leaks. In instances where a postoperative CSF leak was identified, a lumbar drain was placed for a duration of 5 days. If the CSF leak persisted despite lumbar drainage, it served as an indication for revision surgery after the initial 5-day period.

Statistical analysis

The data were analyzed by SPSS 26.0. Descriptive statistics were used to present demographics. Presentation of descriptive or inferential statistics involved the use of tables or charts for selected measures. Continuous variables were presented as mean values with standard deviation and categorical variables were described as percentages (%). Numerical values were presented with the precision up to the second decimal place, and rounding was applied to the third decimal place, with values equal or greater than 5 being rounded up. Group comparisons were evaluated by Chi-square test in categorical valuables. The independent t-test was used comparing the percentage reductions in tumor volumes. Correlations were analyzed using the Pearson correlation coefficient. A Receiver Operating Characteristic (ROC) analysis was performed to evaluate the ability of tumor volume to predict the presence of complications (endocrine dysfunction, visual dysfunction, presence of a CSF leak or hyposmia).

The value of p < 0.05 was regarded as statistically significant difference.

Results

Demographic characteristics

In our study, 24 patients underwent EEA for TS and PS meningiomas between 2010 and 2022. The majority of patients were female (87.5%), with a mean age of 51.04 years. The age distribution in our cohort is evenly balanced across gender and tumor localization (PS or TS). Most cases (87.5%) were diagnosed as meningioma WHO Grade I, with a remaining of three cases (12.5%) that were classified as meningioma WHO Grade II. The primary indication for MRI studies was visual deterioration in 75% of cases, while 25% had incidental findings during initial imaging. The mean follow-up duration was 1906.08 days, and the average hospital stay postsurgery was 5.88 days. There were 14 TS meningiomas and 10 PS meningiomas included in the patient cohort.

Preoperative tumor volumes for PS and TS meningiomas averaged 4.724 cm³, reducing significantly postoperatively to 0.215 cm³, with a mean percentage reduction of 92.24%. The range of the preoperative tumor volumes was 12.593 cm³, with the smallest tumor measuring 0.791 cm³ and the largest 13.384 cm³. GTR was achieved in 87.5% of cases. Mean percentage of tumor volume reduction in TS meningiomas was 94.06% and in PS meningiomas 89.88%. The range of the postoperative tumor volumes was 1.056 cm³, with the smallest postoperative volume being 0.000 cm³ and the largest postoperative volume being 1.056 cm³. Of the 24 patients, two had recurrent meningiomas after their initial surgery in their follow-up.

There was no statistically significant difference in volume reduction between TS and PS meningiomas (p = 0.451). No correlation between WHO Grading and preoperative tumor volume is observed in this study. No correlation between gender and tumor volume was seen.

The observed correlation between patient age and preoperative tumor volume in our study cohort is 0.405, indicating a moderate positive correlation (p = 0.055).

Ophthalmological assessment and visual outcome

The study assessed visual impairment in patients with TS and PS meningiomas using pre- and postoperative ophthalmological evaluations conducted separately for each eye. Visual outcomes varied, with all TS meningioma cases exhibiting preoperative visual impairment, while 30% of PS meningioma patients showed no impairment preoperatively. Unilateral preoperative symptomatology was present in 58.33% of cases, and both eyes were affected in 29.17% of patients. In total, 12.5% of all patients showed no visual impairment.

Postoperatively, 75% of patients experienced improved visual conditions in either visual acuity or their temporal field vision at the 1-year follow-up. 16.66% of the study cohort remained stable in regard to their preoperative assessment. The three patients classified as stable postoperatively either had one or two eyes that were initially unaffected and remained unaffected, or they had eyes that were initially affected and remained stable in their postoperative visual assessments. There were no cases of initially unaffected eyes worsening after the surgery. Notably, a small percentage of 8.33% (two patients) exhibited a deterioration in their visual fields after surgery. One patient had worsened right-sided temporal field impairment and one patient exhibited worsened bilateral temporal field impairment after surgery. Both patients who suffered from deteriorated visual fields after surgery had visual field impairment preoperatively. The patients with worsened visual fields had improved visual acuity but were overall classified as having worsened vision postoperatively. No decline in the visual acuity in overall patients was seen in the postoperative ophthalmological assessment. There was no transient postoperative decline in visual acuity or visual fields during the follow-up period.

Correlation analyses indicated no significant association between preoperative tumor volume and visual acuity or temporal field vision (p = 0.272). However, a significant correlation was found between preoperative visual impairment and postoperative visual impairment (worsened or stable) for tumors with a preoperative volume greater than 3 cm3 (p = 0.001).

Postoperative complications

Postoperative complications included CSF leaks in 12.5% of cases with only one patient (4.17%) requiring revision surgery. 8.33% were successfully treated with a lumbar drain. The was no statistically significant correlation between the tumor localization (TS or PS) and the occurrence of a CSF leak. The CSF leak rate was reduced with the more frequent use of the Hadad–Bassagasteguy flap, and the one revision surgery of the cohort occurred on the second EEA surgery performed at the department in 2010. Endocrine dysfunction affected 25% of the patients postoperatively. Only one patient (4.17%) had a persistent endocrine dysfunction (diabetes insipidus for this patient) with 20.84% of the cohort having transient endocrine dysfunction, which resolved during their hospital stay. The patients with transient endocrine dysfunction showed transient hyponatremia and low AM cortisol during their hospital stay. There was no correlation between endocrine dysfunction and tumor volume. Preoperative tumor volumes were not predictive of postoperative complications like endocrine dysfunction, visual impairment or CSF leak, as indicated by the low Area Under the Curve of 0.0435 in the ROC analysis. A single case of postoperative meningitis and a single case of olfactory dysfunction (4.17%) was documented. Notably, the study cohort had no vascular injuries, new neurological deficits, seizures or postoperative mortality.

Discussion

Our investigation into the endoscopic endonasal approach for TS and PS meningiomas present valuable insights into the treatment paradigm for these challenging lesions. Reference Jimenez, Harrison Snyder and Rabinovich10Reference Clark, Jahangiri and Garcia12 The choice between lower (EEA) and higher (transcranial) surgical routes demands careful consideration of tumor characteristics, patient factors and adjacent structures involvement. Reference Ottenhausen, Banu and Placantonakis27Reference Liu, Christiano, Patel, Tubbs and Eloy29 Our study advocates for EEA, emphasizing its viability as an alternative to transcranial approaches, especially in carefully selected patients. Reference Bander, Singh and Ogilvie11,Reference Schick and Hassler28Reference de Divitiis, Cavallo, Esposito, Stella and Messina34 GTR in PS and TS extra-axial tumors is achieved in 80–95% as reported in the literature. Reference Bander, Singh and Ogilvie11,Reference Yu, Xu, Wu, Liu, Wang and Wang32,Reference Mallari, Thakur and Rhee33,Reference Youngerman, Banu and Gerges35 Favorable outcomes were observed in terms of the extend of tumor resection, which is a crucial predictor for recurrence, with GTR achieved in 87.5% of cases. Reference Magill, Young, Chae, Aghi, Theodosopoulos and McDermott6,Reference Mansouri, Klironomos and Taslimi36 We used reproducible criteria for assessing pre- and postoperative tumor volumes by cross-verifying our findings with the corresponding pre- and postoperative radiology reports. By moving away from the Simpson grading system, which has low validity for these tumor entities, a reproducible assessment of the intraoperative resection volume for both TS and PS meningiomas was achieved. Reference Simpson37,Reference Chotai and Schwartz38 Additionally, a mean tumor size reduction of 92.24% after surgery was observed, further supporting the efficacy of EEA, which is comparable to transcranial approaches. Reference Mastantuoni, Cavallo and Esposito39 Current research and grading scales advocate for the use of EEAs in managing small (<3 cm Reference Chi and McDermott3 ) and midline anterior fossa meningiomas, a practice in line with our center’s decision-making process. Reference Magill, Morshed and Lucas40,Reference Bowers, Altay and Couldwell41 Although the primary focus of EEA is on smaller-sized TS or PS meningiomas, our center has also achieved favorable outcomes for larger tumor volumes. Our analysis did not find any correlation between preoperative tumor volumes and postoperative complications. Larger initial tumor size could not be correlated with a meningioma being WHO Grade II or male gender in this cohort. Reference Magill, Young, Chae, Aghi, Theodosopoulos and McDermott6 Visual impairment, a primary clinical manifestation in these meningiomas, was effectively addressed through EEA, with 87.5% of patients initially presenting with visual deficits. Reference Uede, Ohtaki, Nonaka, Tanabe and Hashi7Reference Sade and Lee9,Reference Nakamura, Roser, Struck, Vorkapic and Samii42 Postoperatively, 91.67% either improved or maintained stable vision, demonstrating the procedure’s efficacy in treating the primary symptom. Reference Mastantuoni, Cavallo and Esposito39,Reference Abbassy, Woodard, Sindwani and Recinos43Reference Padhye, Naidoo and Alexander46 Of note, two cases witnessed a reduction in their previously affected temporal field vision. A decline in temporal field vision after surgery has been reported in similar case studies in the literature, underscoring the complexity and variability of outcomes in these cases. Reference Clark, Jahangiri and Garcia12,Reference Qian, Nie and Zhu31,Reference Kong, Hong and Hong47 The clinical significance of temporal field vision decline in patients is considered more critical than nasal field vision decline and should be factored in when evaluating these conditions. However, a weighting factor for temporal field decline was not included in this retrospective study or similar studies. Reference Crabb, Smith, Glen, Burton and Garway-Heath48 Importantly, there were no new occurrences of newly assessed temporal field defects or worsening of visual acuity after endoscopic, endonasal surgery in our study cohort. Complications, particularly CSF leaks – a common concern in EEA – were observed in 12.5% of our cases aligning with the average percentage reported in EEA-treated TS and PS meningioma populations. Reference de Divitiis, Cavallo, Esposito, Stella and Messina18,Reference de Divitiis, Esposito, Cappabianca, Cavallo and de Divitiis19,Reference Mahmoud, Nader and Al-Mefty21,Reference Laufer, Anand and Schwartz22,Reference Qian, Nie and Zhu31,Reference Kong, Hong and Hong47,Reference Fatemi, Dusick, de Paiva Neto, Malkasian and Kelly49 Recent findings from a meta-analysis suggest a decreasing trend in postoperative CSF leaks, attributed to improved closure techniques, which is consistent with our results. Reference Zamanipoor Najafabadi, Khan and Muskens23,Reference Hadad, Bassagasteguy and Carrau50,Reference Cavallo, Solari, Somma and Cappabianca51 Our study emphasizes that the occurrence of a CSF leak as a possible complication should not deter the consideration of EEA. The low complication rates in our study affirm the proficiency of the surgical approach employed by ENT surgeons using the “3-F” technique and Hadad–Bassagasteguy flap significantly reducing postoperative CSF leaks. Postoperative complications beyond CSF leaks were infrequent, with only 4.17% experiencing persistent endocrine dysfunction. In the case under discussion, the patient exhibited persistent diabetes insipidus, no anterior gland hypopituitarism was seen in our patient cohort. EEAs have been associated with significant implications for olfaction in TS or PS meningiomas, particularly when extended procedures are undertaken. Reference Gardner, Kassam and Thomas45,Reference Carvalho, Dolci and Rickli52,Reference Dolci, Miyake and Tateno53 Olfactory dysfunction emerges as postoperative complication in both EEA and TCA for PS and TS meningiomas. Published literature indicates diverse rates of postoperative hyposmia following EEA and TA, ranging anywhere from 10% to 65% of patients experiencing impaired olfaction. Reference Bander, Singh and Ogilvie11,Reference Ved, Mo and Hayhurst54 In our study, we observed a minimal postoperative hyposmia rate of only 4.17%, highlighting the overall safety of EEA for olfaction in TS and PS meningiomas. Reference Clark, Jahangiri and Garcia12 The study’s strength lies in its single-center, single-surgeon design, ensuring surgical homogeneity and comprehensive patient outcomes understanding. The extended follow-up duration, no patient loss in follow-up and the novel inclusion of pre- and postoperative volumetric measurements contribute valuable insights. However, limitations, such as a relatively small cohort, the retrospective nature of the study and the absence of information regarding the duration of visual symptoms before surgery affect the generalizability of our findings. Another limitation of the recent study is the absence of a standardized visual assessment tool, such as the Unified Visual Function Scale (UVFS), which would facilitate easier comparison between treatment groups and allow for a more accurate evaluation of the clinical relevance of visual impairment or improvement. Reference Makarenko, Ye, Gooderham and Akagami55 Despite these limitations, this study provides substantial evidence supporting EEA as a safe and effective option for selected TS and PS meningiomas.

Conclusions

In summary, this study seeks to advance our understanding of endoscopic endonasal surgery outcomes for TS and PS meningiomas. Through an examination of our patient cohort from a single center, we emphasize the effectiveness of minimally invasive endoscopic skull base techniques in yielding favorable clinical and resection outcomes. Our study demonstrates promising visual and endocrinological outcomes, coupled with a minimal incidence of CSF leaks and olfactory dysfunction, further supporting the safety of this approach. Importantly, there was no statistically significant correlation between preoperative tumor volumes and postoperative complications, highlighting the robustness of the endoscopic endonasal approach across varying tumor sizes. These findings contribute to the solidification of this approach for managing TS and PS meningiomas. However, the significance of these results warrants additional scrutiny through larger, multicenter studies for this tumor entity.

Author contributions

LAS: Literature search, drafting the article, conception and design, acquisition of data, analysis and interpretation of data.

YPS: Drafting the article, conception and design, acquisition of data.

Funding statement

None.

Competing interests

None.

References

Arai, H, Sato, K, Okuda, etal. Transcranial transsphenoidal approach for tuberculum sellae meningiomas. Acta Neurochir (Wien). 2000;142:751–6.CrossRefGoogle ScholarPubMed
Kane, AJ, Sughrue, ME, Rutkowski, MJ, et al. Anatomic location is a risk factor for atypical and malignant meningiomas. Cancer. 2011;117:1272–8.CrossRefGoogle ScholarPubMed
Chi, JH, McDermott, MW. Tuberculum sellae meningiomas. Neurosurg Focus. 2003;14:e66.CrossRefGoogle ScholarPubMed
Fernandez-Miranda, JC, Pinheiro-Nieto, C, Gardner, PA, Snyderman, CH. Endoscopic endonasal approach for a tuberculum sellae meningioma. J Neurosurg. 2012;32:E8.Google ScholarPubMed
Taha, AN, Erkmen, K, Dunn, IF, Pravdenkova, S, Al-Mefty, O. Meningiomas involving the optic canal: pattern of involvement and implications for surgical technique. Neurosurg Focus. 2011;30:E12.CrossRefGoogle ScholarPubMed
Magill, ST, Young, JS, Chae, R, Aghi, MK, Theodosopoulos, PV, McDermott, MW. Relationship between tumor location, size, and WHO grade in meningioma. Neurosurg Focus. 2018;44:E4.CrossRefGoogle ScholarPubMed
Uede, T, Ohtaki, M, Nonaka, T, Tanabe, S, Hashi, K. [Characteristics of visual impairment complicated with planum sphenoidale and tuberculum sellae meningiomas and their surgical results]. No Shinkei Geka. 1996;24:1093–8.Google ScholarPubMed
Wang, Q, Lu, XJ, Ji, WY, et al. Visual outcome after extended endoscopic endonasal transsphenoidal surgery for tuberculum sellae meningiomas. World Neurosurg. 2010;73:694700.CrossRefGoogle ScholarPubMed
Sade, B, Lee, JH. High incidence of optic canal involvement in tuberculum sellae meningiomas: rationale for aggressive skull base approach. Surg Neurol. 2009;72:118–23.CrossRefGoogle ScholarPubMed
Jimenez, AE, Harrison Snyder, M, Rabinovich, EP, et al. Comparison and evolution of transcranial versus endoscopic endonasal approaches for suprasellar meningiomas: a systematic review. J Clin Neurosci. 2022;99:302–10.CrossRefGoogle ScholarPubMed
Bander, ED, Singh, H, Ogilvie, CB, et al. Endoscopic endonasal versus transcranial approach to tuberculum sellae and planum sphenoidale meningiomas in a similar cohort of patients. J Neurosurg. 2018;128:40–8.CrossRefGoogle Scholar
Clark, AJ, Jahangiri, A, Garcia, RM, et al. Endoscopic surgery for tuberculum sellae meningiomas: a systematic review and meta-analysis. Neurosurg Rev. 2013;36:349–59.CrossRefGoogle ScholarPubMed
Couldwell, WT, Weiss, MH, Rabb, C, Liu, JK, Apfelbaum, RI, Fukushima, T. Variations on the standard transsphenoidal approach to the sellar region, with emphasis on the extended approaches and parasellar approaches: surgical experience in 105 cases. Neurosurgery. 2004;55:539–50.CrossRefGoogle Scholar
Jho, HD, Ha, HG. Endoscopic endonasal skull base surgery: part 1--the midline anterior fossa skull base. Minim Invasive Neurosurg. 2004;47:18.Google ScholarPubMed
Kassam, A, Snyderman, CH, Mintz, A, Gardner, P, Carrau, RL. Expanded endonasal approach: the rostrocaudal axis. Part I. Crista galli to the sella turcica. Neurosurg Focus. 2005;19:E312.Google Scholar
Prevedello, DM, Doglietto, F, Jane, JA, Jagannathan, J, Han, J, Laws, ER. History of endoscopic skull base surgery: its evolution and current reality. J Neurosurg. 2007;107:206–13.CrossRefGoogle ScholarPubMed
Solares, CA, Ong, YK, Snyderman, CH. Transnasal endoscopic skull base surgery: what are the limits? Curr Opin Otolaryngol Head Neck Surg. 2010;18:17.CrossRefGoogle ScholarPubMed
de Divitiis, E, Cavallo, LM, Esposito, F, Stella, L, Messina, A. Extended endoscopic transsphenoidal approach for tuberculum sellae meningiomas. Neurosurgery. 2007;61:229–37.Google ScholarPubMed
de Divitiis, E, Esposito, F, Cappabianca, P, Cavallo, LM, de Divitiis, O. Tuberculum sellae meningiomas: high route or low route? A series of 51 consecutive cases. Neurosurgery. 2008;62:556–63.CrossRefGoogle ScholarPubMed
Muskens, IS, Briceno, V, Ouwehand, TL, et al. The endoscopic endonasal approach is not superior to the microscopic transcranial approach for anterior skull base meningiomas-a meta-analysis. Acta Neurochir (Wien). 2018;160:5975.CrossRefGoogle ScholarPubMed
Mahmoud, M, Nader, R, Al-Mefty, O. Optic canal involvement in tuberculum sellae meningiomas: influence on approach, recurrence, and visual recovery. Neurosurgery. 2010;67(3 Suppl Operative): ons108-18.Google ScholarPubMed
Laufer, I, Anand, VK, Schwartz, TH. Endoscopic, endonasal extended transsphenoidal, transplanum transtuberculum approach for resection of suprasellar lesions. J Neurosurg. 2007;106:400–6.CrossRefGoogle ScholarPubMed
Zamanipoor Najafabadi, AH, Khan, DZ, Muskens, IS, et al. Trends in cerebrospinal fluid leak rates following the extended endoscopic endonasal approach for anterior skull base meningioma: a meta-analysis over the last 20 years. Acta Neurochir (Wien). 2021;163:711–9.CrossRefGoogle ScholarPubMed
Sankhla, SK, Jayashankar, N, Khan, MA, Khan, GM. Surgical management of tuberculum sellae meningioma: our experience and review of the literature. Neurol India. 2021;69:1592–600.CrossRefGoogle ScholarPubMed
Zhang, C, Ding, J, Liu, Y, et al. Endoscopic endonasal approach for resection of tuberculum sellae meningioma: a promising surgical approach. J Craniofac Surg. 2020;31:1815–8.CrossRefGoogle ScholarPubMed
Lopez, F, Suarez, V, Costales, M, Rodrigo, JP, Suarez, C, Llorente, JL. Endoscopic endonasal approach for the treatment of anterior skull base tumours. Acta Otorrinolaringol Esp. 2012;63:339–47.Google ScholarPubMed
Ottenhausen, M, Banu, MA, Placantonakis, DG, et al. Endoscopic endonasal resection of suprasellar meningiomas: the importance of case selection and experience in determining extent of resection, visual improvement, and complications. World Neurosurg. 2014;82:442–9.CrossRefGoogle ScholarPubMed
Schick, U, Hassler, W. Surgical management of tuberculum sellae meningiomas: involvement of the optic canal and visual outcome. J Neurol Neurosurg Psychiatry. 2005;76:977–83.CrossRefGoogle ScholarPubMed
Liu, JK, Christiano, LD, Patel, SK, Tubbs, RS, Eloy, JA. Surgical nuances for removal of tuberculum sellae meningiomas with optic canal involvement using the endoscopic endonasal extended transsphenoidal transplanum transtuberculum approach. Neurosurg Focus. 2011;30:E2.CrossRefGoogle ScholarPubMed
Kulwin, C, Schwartz, TH, Cohen-Gadol, AA. Endoscopic extended transsphenoidal resection of tuberculum sellae meningiomas: nuances of neurosurgical technique. Neurosurg Focus. 2013;35:E6.CrossRefGoogle ScholarPubMed
Qian, K, Nie, C, Zhu, W, et al. Surgical management of tuberculum sellae meningioma: transcranial approach or endoscopic endonasal approach? Front Surg. 2022;9:979940.CrossRefGoogle ScholarPubMed
Yu, P, Xu, T, Wu, X, Liu, Z, Wang, Y, Wang, Y. The expanded endoscopic endonasal approach for treatment of tuberculum sellae meningiomas in a series of 40 consecutive cases. Sci Rep. 2021;11:4993.CrossRefGoogle Scholar
Mallari, RJ, Thakur, JD, Rhee, JH, et al. Endoscopic endonasal and supraorbital removal of tuberculum sellae meningiomas: anatomic guides and operative nuances for keyhole approach selection. Oper Neurosurg (Hagerstown). 2021;21:E71E81.CrossRefGoogle ScholarPubMed
de Divitiis, E, Cavallo, LM, Esposito, F, Stella, L, Messina, A. Extended endoscopic transsphenoidal approach for tuberculum sellae meningiomas. Neurosurgery. 2008;62:1192–201.CrossRefGoogle ScholarPubMed
Youngerman, BE, Banu, MA, Gerges, MM, et al. Endoscopic endonasal approach for suprasellar meningiomas: introduction of a new scoring system to predict extent of resection and assist in case selection with long-term outcome data. J Neurosurg. 2020;135:113–25.CrossRefGoogle ScholarPubMed
Mansouri, A, Klironomos, G, Taslimi, S, et al. Surgically resected skull base meningiomas demonstrate a divergent postoperative recurrence pattern compared with non-skull base meningiomas. J Neurosurg. 2016;125:431–40.CrossRefGoogle ScholarPubMed
Simpson, D. The recurrence of intracranial meningiomas after surgical treatment. J Neurol Neurosurg Psychiatry. 1957;20:2239.CrossRefGoogle ScholarPubMed
Chotai, S, Schwartz, TH. The simpson grading: is it still valid? Cancers (Basel). 2022;14:2007.CrossRefGoogle ScholarPubMed
Mastantuoni, C, Cavallo, LM, Esposito, F, et al. Midline skull base meningiomas: transcranial and endonasal perspectives. Cancers (Basel). 2022;14:2878.CrossRefGoogle ScholarPubMed
Magill, ST, Morshed, RA, Lucas, CG, et al. Tuberculum sellae meningiomas: grading scale to assess surgical outcomes using the transcranial versus transsphenoidal approach. Neurosurg Focus. 2018;44:E9.CrossRefGoogle ScholarPubMed
Bowers, CA, Altay, T, Couldwell, WT. Surgical decision-making strategies in tuberculum sellae meningioma resection. Neurosurg Focus. 2011;30:E1.CrossRefGoogle ScholarPubMed
Nakamura, M, Roser, F, Struck, M, Vorkapic, P, Samii, M. Tuberculum sellae meningiomas: clinical outcome considering different surgical approaches. Neurosurgery. 2006;59:1019–28.CrossRefGoogle ScholarPubMed
Abbassy, M, Woodard, TD, Sindwani, R, Recinos, PF. An overview of anterior skull base meningiomas and the endoscopic endonasal approach. Otolaryngol Clin North Am. 2016;49:141–52.CrossRefGoogle ScholarPubMed
Brunworth, J, Padhye, V, Bassiouni, A, et al. Update on endoscopic endonasal resection of skull base meningiomas. Int Forum Allergy Rhinol. 2015;5:344–52.CrossRefGoogle ScholarPubMed
Gardner, PA, Kassam, AB, Thomas, A, et al. Endoscopic endonasal resection of anterior cranial base meningiomas. Neurosurgery. 2008;63:3652.CrossRefGoogle ScholarPubMed
Padhye, V, Naidoo, Y, Alexander, H, et al. Endoscopic endonasal resection of anterior skull base meningiomas. Otolaryngol Head Neck Surg. 2012;147:575–82.CrossRefGoogle ScholarPubMed
Kong, DS, Hong, CK, Hong, SD, et al. Selection of endoscopic or transcranial surgery for tuberculum sellae meningiomas according to specific anatomical features: a retrospective multicenter analysis (KOSEN-002). J Neurosurg. 2018;130:838–47.CrossRefGoogle ScholarPubMed
Crabb, DP, Smith, ND, Glen, FC, Burton, R, Garway-Heath, DF. How does glaucoma look?: patient perception of visual field loss. Ophthalmology. 2013;120:1120–6.CrossRefGoogle ScholarPubMed
Fatemi, N, Dusick, JR, de Paiva Neto, MA, Malkasian, D, Kelly, DF. Endonasal versus supraorbital keyhole removal of craniopharyngiomas and tuberculum sellae meningiomas. Neurosurgery. 2009;64:269–84.Google ScholarPubMed
Hadad, G, Bassagasteguy, L, Carrau, RL, et al. A novel reconstructive technique after endoscopic expanded endonasal approaches: vascular pedicle nasoseptal flap. Laryngoscope. 2006;116:1882–6.CrossRefGoogle ScholarPubMed
Cavallo, LM, Solari, D, Somma, T, Cappabianca, P. The 3F (Fat, flap, and flash) technique for skull base reconstruction after endoscopic endonasal suprasellar approach. World Neurosurg. 2019;126:439–46.CrossRefGoogle ScholarPubMed
Carvalho, ACM, Dolci, RLL, Rickli, JCK, et al. Evaluation of olfactory function in patients undergoing endoscopic skull base surgery with nasoseptal flap. Braz J Otorhinolaryngol. 2022;88:1521.CrossRefGoogle ScholarPubMed
Dolci, RLL, Miyake, MM, Tateno, DA, et al. Postoperative otorhinolaryngologic complications in transnasal endoscopic surgery to access the skull base. Braz J Otorhinolaryngol. 2017;83:349–55.CrossRefGoogle ScholarPubMed
Ved, R, Mo, M, Hayhurst, C. Olfactory outcomes after resection of tuberculum sella and planum sphenoidale meningiomas via a transcranial approach. J Neurol Surg B Skull Base. 2022;83:296304.Google Scholar
Makarenko, S, Ye, V, Gooderham, PA, Akagami, R. A novel scale for describing visual outcomes in patients following resection of lesions affecting the optic apparatus: the unified visual function scale. J Neurosurg. 2018;129:1438–45.CrossRefGoogle ScholarPubMed