Abstract
Cushing’s disease is the most common cause of endogenous hypercortisolemia, and transsphenoidal surgery remains the first line therapy for removal of the ACTH-secreting adenoma. While post-operative remission rates are high in experienced hands, there remains a 2% risk of recurrence per year. Patients with the highest chance for cure are those with small, non-invasive tumors that are visible on pre-operative MRI and identified during surgery and are performed by high-volume pituitary neurosurgeons. Surgery for persistent or recurrent disease is frequently indicated and is most successful in the hands of experienced surgeons and in cases where tumor is visible on MRI.
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Introduction
Transsphenoidal surgery is recommended as first-line therapy for patients with Cushing’s disease (CD) [1]. The goal of surgery is selective adenomectomy to remove the ACTH-secreting tumor. Surgical options include the microscopic transsphenoidal approach, either through sublabial or endonasal exposure, as well as the endoscopic endonasal transsphenoidal approach. Post-operative remission rates range from 65% to greater than 90%, with higher rates of remission achieved by more experienced neurosurgeons and in cases of non-invasive microadenomas visible on pre-operative MRI [2]. Early reoperation for cases of persistent disease is recommended when patients’ plateaued cortisol levels do not meet remission criteria [3]. Reoperation for cases of recurrence is recommended particularly if the tumor is visible and/or the neurosurgeon is experienced and operates at a high-volume pituitary center [4].
Transsphenoidal surgery
Transsphenoidal surgery has been the mainstay approach for pituitary and CD surgery since the 1960s and is performed either by microscopic or endoscopic endonasal technique. Craniotomy is rarely necessary. In recent decades, the use of the endoscopic approach has significantly increased while the microscopic method has decreased, although outcomes and complication rates for CD remain largely equivalent between the two techniques [5]. This shift may in part be because endoscopes offer the advantage of a wider field of view and the capacity to inspect regions of the sella for residual tumor [6]. The endoscopic endonasal transsphenoidal surgery is typically performed by both a neurosurgeon and an otolaryngologist (ENT) with specialization in rhinology. The ENT surgeon obtains endoscopic access into the sphenoid sinus, at which point the neurosurgeon opens the sella and works to find and remove the tumor. Intraoperative navigation is provided by either fluoroscopy or CT- and/or MRI-guided stereotaxy. Endoscope technology has allowed for crisp, high-definition visualization, including 4 K resolution and some surgeons also utilize and prefer 3-D endoscopes [7].
Post-operative remission
Remission criteria
There is no single absolute determinant of post-operative remission; an ideal criterion would correlate with both clinical improvement and minimal risk of recurrence. Early predictors of remission include general indicators of hypoadrenalism, including low fasting serum cortisol (< 2 μg/dL), low 24 h urine free cortisol levels (below 20 μg/24 h), low serum ACTH (less than 5 pg/mL), or low midnight salivary cortisol within the first week after surgery [8]. Some data suggests that morning serum cortisol level less than 1 μg/dL predicts remission with a positive predictive value (PPV) of 96% [8], although other studies have shown that undetectable levels can still be seen in cases which later recur [9].
Remission rates
Remission is seen in approximately 80% of patients with microadenomas and 60% with macroadenomas, with overall remission rates of 68–91% [2]. Patients in remission require glucocorticoid replacement until a cortisol stimulation test demonstrates hypothalamic–pituitary–adrenal (HPA) axis recovery [10]. In some cases, especially in patients with mild hypercortisolism or cyclic Cushing’s disease, remission can be difficult to determine and, occasionally, patients will achieve remission without marked postoperative hypocortisolism or in a delayed fashion up to 4–6 weeks after surgery [3]. Continued outpatient monitoring until postoperative cortisol nadir occurs can usually identify such cases. Nevertheless, patients with persistent serum cortisol levels greater than 5 μg/dL typically warrant early reevaluation by the neuro-endocrinologist and neurosurgeon for possible additional treatment, and patients with cortisol levels between 2 and 5 μg/dL warrant close observation as well [11]. The optimal approach for postoperative testing varies between centers; some withhold glucocorticoid replacement until testing is complete, while others discharge the patient on replacement doses of glucocorticoids and complete testing as an outpatient [12].
Determinants of remission
Several factors have been linked to the likelihood of successful surgical outcome, including small size of tumor (< 10 mm), lack of tumor invasiveness, and ability to identify tumor on preoperative MRI as well as intraoperatively (Table 1). Most studies show an improved rate of remission with microadenomas, with a recent meta-analysis indicating a remission rate of 83% for microadenomas, 68% for macroadenomas, and overall remission rate of 80% [13, 14]. Patients with non-encapsulated macroadenomas may have worse outcomes as these tumors are more likely to be invasive and invasion of the cavernous sinus and dura or suprasellar tumor extension results consistently in a higher incidence of persistent disease [15]. Identification of the adenoma on preoperative MRI has also been linked to improved chance of remission [16, 17] data indicates that remission can be as high as 81% when a lesion is visible on preoperative MRI, as compared to 69% remission rates in MRI negative cases [14]. Intraoperative confirmation of adenoma histopathology has also been linked to improved chance of surgical cure as studies indicate that, on systematic exploration of the gland for small or invisible tumors, the use of intraoperative cytologic smears and/or frozen sections may be useful in achieving remission [18, 19]. Meta-analysis of the effect of microscopic versus endoscopic surgical technique on outcomes for CD shows no major difference in remission or recurrence rates, although there may be a benefit of endoscopic technique for achieving improved remission in cases of macroadenomas [20].
Correlation with surgical experience and technique
Treatment at a high-volume center by an experienced surgeon has been correlated with improved remission rates [21, 22]. While database studies indicate a volume-outcome effect, where surgeons that perform a higher volume of pituitary surgery have reduced morbidity and mortality rates, the exact contribution of surgical experience to surgical success in CD is difficult to document [23, 24]. While some studies show no change in remission rates over a surgeon’s career, several others report improvement with experience over time [9, 16, 22].
Surgical morbidity
Overall, rates of surgical morbidity and mortality remain low, with more experienced surgeons having lower complication rates than less experienced surgeons [25, 26] Surgeon experience has also been associated with shorter postoperative length of stay, and lower costs. The most common complications still occur at relatively low frequency, with new-onset hypopituitarism occurring in approximately 10% of patients, cerebrospinal fluid (CSF) leak in 4–13%, permanent diabetes insipidus (DI) in ~ 2–4%, and venous thromboembolism (VTE) in 1–2%. Data suggests that electrolyte complications, such as DI and post-operative hyponatremia, occur more frequently with surgery for CD as compared to surgery for non-functioning adenomas [27]. Overall, perioperative mortality remains low at < 1% [21]. In systematic review, rates of complication in CD based on microscopic versus endoscopic surgical technique are largely equivalent, with a higher rate of CSF leak with the endoscopic method (12.9% vs 4%) but similar low rates of meningitis (0.1% vs 0.6%) [20].
The role of re-operation
Re-operation for persistent disease
For patients who do not meet criteria for immediate or delayed remission following initial surgery, early reoperation for persistent disease is often recommended, especially for patients with pathologic confirmation of adenoma on initial surgery [28]. Remission rates in reoperation for persistent CD range from 40–70%, with a recent meta-analysis indicating remission rate of 54% in persistent disease [14, 29]. Although early re-operation (within a few weeks) is technically less difficult given minimal early post-operative scarring, data supports waiting until cortisol levels have plateaued before proceeding with a second surgery [3], as delayed remission may occur as late as one month after surgery and patients with mild hypercortisolism or cyclic Cushing’s disease may not have marked postoperative hypocortisolism. Due to increased gland sampling or even partial or total removal of the pituitary gland in a second surgery, reoperation leads to higher rates of hypopituitarism, DI, and CSF leak [30].
Re-operation for recurrence
Recurrent disease at 5 years occurs at a rate of approximately 10–15%, increasing to 20–25% at 10 years, or approximately 2% per year [13, 31]. Patients who did not have postoperative hypocortisolemia (nadir AM cortisol > 2ug/dL) or experienced delayed biochemical remission following initial surgery have a significantly increased risk for recurrence as compared to patients with immediate remission after surgery [3, 14, 32]. Additional predictors of recurrence include history of revision surgery and tumor size > 10 mm [14]. There are multiple diagnostic techniques for surveillance of recurrence; late-night salivary cortisol (LNSC) levels and 24-h urine free cortisol (UFC) levels are commonly assessed, with data indicating that LNSC may be the most sensitive for recurrence [33]. With the advent of new pharmacologic agents, there are now a number of treatment modalities for the management of recurrent disease, but repeat transsphenoidal surgery remains a viable treatment option, especially in patients with visible tumor on MRI [34,35,36]. At high-volume centers, reoperation performed in the absence of detectable adenoma on MRI is more successful when there has been proven ACTH-staining adenoma on pathology or a central ACTH gradient on IPSS at the initial operation [34, 35]. Tumor features such as size, invasiveness, and extrasellar extension should be considered when weighing the role and benefit of surgery over other treatment options like radiation therapy [16]. Remission rates after reoperation vary widely in the literature, ranging from 40 to 80%, at least in part because of different indications for re-operation, remission criteria, and follow-up duration [30]. A recent meta-analysis found overall remission rates for recurrence to be 80% [14]. As with initial surgery, findings of tumor and positive histopathology have correlated with increased remission rates in some studies of reoperation [37]. Although the literature reports higher rates of both surgical (i.e., CSF leak, meningitis) and endocrinological complications (i.e., DI and hypopituitarism) with repeat versus initial surgery, serious morbidity remains low and is less likely in experienced hands [16].
Clinical considerations and recommendations for pituitary surgery for CD
In summary, we recommend patients with CD undergo surgery as primary therapy in specialized pituitary tumor centers of excellence [38]. Surgery should be performed by an experienced pituitary neurosurgeon and follow-up done by a multidisciplinary team including a pituitary endocrinologist. If the original procedure is unsuccessful, re-operation can be considered. In cases of recurrence, we suggest repeat transsphenoidal surgery in patients with biochemical evidence of recurrent CD especially if tumor is visible on MRI and particularly if the first surgery was not performed by a high-volume pituitary neurosurgeon. If MRI does not show tumor presence, reoperation might be appropriate if an experienced surgeon at a high-volume center considers it feasible and positive pathology or a central gradient on IPSS was seen before the initial operation.
References
Nieman LK, Biller BMK, Findling JW et al (2015) Treatment of Cushing’s syndrome: an endocrine society clinical practice guideline. J Clin Endocrinol Metab 100:2807–2831
Alexandraki KI, Kaltsas GA, Isidori AM et al (2013) Long-term remission and recurrence rates in Cushing’s disease: predictive factors in a single-centre study. Eur J Endocrinol 168:639–648
Valassi E, Biller BMK, Swearingen B et al (2010) Delayed remission after transsphenoidal surgery in patients with Cushing’s disease. J Clin Endocrinol Metab 95:601–610
Fleseriu M, Auchus R, Bancos I et al (2021) Consensus on diagnosis and management of Cushing’s disease: a guideline update. Lancet Diabetes Endocrinol 9:847–875
Goshtasbi K, Lehrich BM, Abouzari M et al (2020) Endoscopic versus nonendoscopic surgery for resection of pituitary adenomas: a national database study. J Neurosurg 134:816–824
Rolston JD, Han SJ, Aghi MK (2016) Nationwide shift from microscopic to endoscopic transsphenoidal pituitary surgery. Pituitary 19:248–250
Barkhoudarian G, Romero AD, Laws ER (2013) Evaluation of the 3-dimensional endoscope in transsphenoidal surgery. Neurosurgery 73:74–78 (discussion ons78–9)
Lonser RR, Nieman L, Oldfield EH (2017) Cushing’s disease: pathobiology, diagnosis, and management. J Neurosurg 126:404–417
Yap LB, Turner HE, Adams CBT, Wass JAH (2002) Undetectable postoperative cortisol does not always predict long-term remission in Cushing’s disease: a single centre audit*. Clin Endocrinol 56:25–31
Fleseriu M, Hashim IA, Karavitaki N et al (2016) Hormonal replacement in hypopituitarism in adults: an endocrine society clinical practice guideline. J Clin Endocrinol Metab 101:3888–3921
Biller BMK, Grossman AB, Stewart PM et al (2008) Treatment of adrenocorticotropin-dependent Cushing’s syndrome: a consensus statement. J Clin Endocrinol Metab 93:2454–2462
Varlamov EV, Vila G, Fleseriu M (2022) Perioperative management of a patient with Cushing disease. J Endocr Soc 6:bvac010
Swearingen B, Biller BM, Barker FG 2nd et al (1999) Long-term mortality after transsphenoidal surgery for Cushing disease. Ann Intern Med 130:821–824
Stroud A, Dhaliwal P, Alvarado R et al (2020) Outcomes of pituitary surgery for Cushing’s disease: a systematic review and meta-analysis. Pituitary 23:595–609
Hammer GD, Blake Tyrrell J, Lamborn KR et al (2004) Transsphenoidal microsurgery for Cushing’s disease: initial outcome and long-term results. J Clin Endocrinol Metab 89:6348–6357
Hofmann BM, Hlavac M, Martinez R et al (2008) Long-term results after microsurgery for Cushing disease: experience with 426 primary operations over 35 years. J Neurosurg 108:9–18
Prevedello DM, Pouratian N, Sherman J et al (2008) Management of Cushing’s disease: outcome in patients with microadenoma detected on pituitary magnetic resonance imaging. J Neurosurg 109:751–759
Lim JS, Lee SK, Kim SH et al (2011) Intraoperative multiple-staged resection and tumor tissue identification using frozen sections provide the best result for the accurate localization and complete resection of tumors in Cushing’s disease. Endocrine 40:452–461
Qiao N, Swearingen B, Hedley-Whyte ET, Tritos NA (2019) The utility of intraoperative cytological smear and frozen section in the surgical management of patients with Cushing’s disease due to pituitary microadenomas. Endocr Pathol 30:180–188
Broersen LHA, Biermasz NR, van Furth WR et al (2018) Endoscopic vs. microscopic transsphenoidal surgery for Cushing’s disease: a systematic review and meta-analysis. Pituitary 21:524–534
Petersenn S, Beckers A, Ferone D et al (2015) Therapy of endocrine disease: outcomes in patients with Cushing’s disease undergoing transsphenoidal surgery: systematic review assessing criteria used to define remission and recurrence. Eur J Endocrinol 172:R227–R239
Rees DA, Hanna FWF, Davies JS et al (2002) Long-term follow-up results of transsphenoidal surgery for Cushing’s disease in a single centre using strict criteria for remission. Clin Endocrinol 56:541–551
Ciric I, Ragin A, Baumgartner C, Pierce D (1997) Complications of transsphenoidal surgery: results of a national survey, review of the literature, and personal experience. Neurosurgery 40:225–236 (discussion 236–7)
Barker FG 2nd, Klibanski A, Swearingen B (2003) Transsphenoidal surgery for pituitary tumors in the United States, 1996–2000: mortality, morbidity, and the effects of hospital and surgeon volume. J Clin Endocrinol Metab 88:4709–4719
Honegger J, Grimm F (2018) The experience with transsphenoidal surgery and its importance to outcomes. Pituitary 21:545–555
de Vries F, Lobatto DJ, Verstegen MJT et al (2021) Outcome squares integrating efficacy and safety, as applied to functioning pituitary adenoma surgery. J Clin Endocrinol Metab 106:e3300–e3311
Donofrio CA, Losa M, Gemma M et al (2017) Safety of transsphenoidal microsurgical approach in patients with an ACTH-secreting pituitary adenoma. Endocrine 58:303–311
Ram Z, Nieman LK, Cutler GB Jr et al (1994) Early repeat surgery for persistent Cushing’s disease. J Neurosurg 80:37–45
Perez-Vega C, Ramos-Fresnedo A, Tripathi S et al (2022) Treatment of recurrent and persistent Cushing’s disease after first transsphenoidal surgery: lessons learned from an international meta-analysis. Pituitary. https://doi.org/10.1007/s11102-022-01215-1
Cardinal T, Zada G, Carmichael JD (2021) The role of reoperation after recurrence of Cushing’s disease. Best Pract Res Clin Endocrinol Metab 35:101489
Roelfsema F, Biermasz NR, Pereira AM (2012) Clinical factors involved in the recurrence of pituitary adenomas after surgical remission: a structured review and meta-analysis. Pituitary 15:71–83
Sughrue ME, Shah JK, Devin JK et al (2010) Utility of the immediate postoperative cortisol concentrations in patients with Cushing’s disease. Neurosurgery 67:688–695
Amlashi FG, Swearingen B, Faje AT et al (2015) Accuracy of late-night salivary cortisol in evaluating postoperative remission and recurrence in Cushing’s disease. J Clin Endocrinol Metab 100:3770–3777
Rutkowski MJ, Flanigan PM, Aghi MK (2015) Update on the management of recurrent Cushing’s disease. Neurosurg Focus 38:E16
Patil CG, Veeravagu A, Prevedello DM et al (2008) outcomes after repeat transsphenoidal surgery for recurrent Cushing’s disease. Neurosurgery 63:266–271
Capatina C, Hinojosa-Amaya JM, Poiana C, Fleseriu M (2020) Management of patients with persistent or recurrent Cushing’s disease after initial pituitary surgery. Expert Rev Endocrinol Metab 15:321–339
Feng M, Liu Z, Liu X et al (2018) Diagnosis and outcomes of 341 patients with Cushing’s disease following transsphenoid surgery: a single-center experience. World Neurosurg 109:e75–e80
Casanueva FF, Barkan AL, Buchfelder M et al (2017) Criteria for the definition of Pituitary Tumor Centers of Excellence (PTCOE): a Pituitary Society Statement. Pituitary 20:489–498
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Jones, P.S., Swearingen, B. Pituitary surgery in Cushing’s disease: first line treatment and role of reoperation. Pituitary 25, 713–717 (2022). https://doi.org/10.1007/s11102-022-01254-8
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DOI: https://doi.org/10.1007/s11102-022-01254-8