Abstract
Objective
Predicting postoperative persistence and recurrence of Cushing’s disease (CD) remains a clinical challenge, with no universally reliable models available. This study introduces the CuPeR model, an online dynamic nomogram developed to address these gaps by predicting postoperative outcomes in patients with CD undergoing pituitary surgery.
Methods
A retrospective cohort of 211 patients treated for CD between 2010 and 2024 was analyzed. Key patient and tumor characteristics, imaging findings, and treatment details were evaluated. Multivariate logistic regression identified independent predictors of postoperative persistence or recurrence of CD (PoRP-CD), which were then incorporated into the CuPeR model using stepwise selection based on Akaike Information Criterion. Internal validation was performed using a testing dataset, and a user-friendly online nomogram was developed to facilitate immediate, patient-specific risk estimation in clinical practice.
Results
The final predictive model identified four key factors: symptom duration, MRI Hardy’s grade, tumor site, and prior pituitary surgery. Longer symptom duration and a history of prior surgery significantly increased the risk of recurrence, while bilateral tumor location reduced this risk. The model demonstrated an area under the receiver operating characteristic curve (AUC-ROC) of 0.70, with 83% accuracy, specificity of 96%, and sensitivity of 33%.
Conclusions
The CuPeR model may offer a practical tool for predicting PoRP-CD, enhancing preoperative decision-making by providing personalized risk assessments.
Keywords
Cushing’s disease
Transsphenoidal surgery
Nomogram
Recurrence
Disease Persistence
Abbreviations
ACTH
Adrenocorticotropic Hormone
AIC
Akaike Information Criterion
AUC
Area Under the Curve
BMI
Body Mass Index
CD
Cushing’s Disease
CI
Confidence Interval
CRH
Corticotropin-Releasing Hormone
DFS
Disease-Free Survival
DL
Deep Learning
eTSS
Endoscopic Transsphenoidal Surgery
HR
Hazard Ratio
IPSS
Inferior Petrosal Sinus Sampling
ML
Machine Learning
MRI
Magnetic Resonance Imaging
OS
Overall Survival
PoRP-CD
Persistent or Recurrent Cushing’s Disease
SIADH
Syndrome of Inappropriate Antidiuretic Hormone Secretion
TSS
Transsphenoidal Surgery
UFC
Urinary Free Cortisol
Introduction
Cushing’s disease (CD) is a rare endocrine disorder, with an annual incidence rate of approximately 0.24 cases per 100,000 individuals [1]. Transsphenoidal surgery (TSS), performed using either endoscopic or microscopic approaches, remains the cornerstone of treatment for CD. Notably, meta-analytical studies have reported that TSS achieves remission and provides long-term disease control in 71–80 % of patients [[2], [3], [4]]. The remaining cases may experience persistent disease despite surgery, while others may face disease recurrence despite initial remission. In such cases, additional treatment options include second pituitary surgery, pituitary irradiation, targeted medical therapies, and bilateral adrenalectomy, each with varying success rates ranging from 25 % for medical therapy to 100 % for bilateral adrenalectomy [5].
To date, no single predictive factor has proven effective in reliably forecasting treatment outcomes in patients with CD [6]. This underscores the critical need for developing predictive models to assess the likelihood of postoperative recurrence or persistence of Cushing’s disease (PoRP-CD). However, only a limited number of studies have addressed this gap. Notably, two studies from Peking Union Medical College Hospital attempted to tackle this issue using machine learning (ML) and deep learning (DL) approaches [6,7]. These studies utilized demographic, clinical, and paraclinical variables to construct predictive models, with DL approaches showing potential to enhance predictive accuracy [7]. While the results of these models were promising, their applicability in routine clinical practice remains limited. Both studies focused exclusively on patients undergoing their initial transsphenoidal surgery, making them less applicable for cases involving patients with a prior history of pituitary surgery or radiotherapy. Furthermore, these models incorporated both preoperative and postoperative parameters, such as changes in cortisol and adrenocorticotropic hormone (ACTH) levels. However, serum cortisol, ACTH, and comprehensive endocrine testing should be available before any treatment decisions are made, and each patient should ideally be reviewed by a multidisciplinary tumor board, including neurosurgery, radiology, endocrinology, and oncology, prior to pituitary surgery. As such, more comprehensive and practical predictive tool that can support timely clinical decision-making and accommodate a broader range of patient scenarios in the management of CD.
The current study was designed to address these critical limitations and provide a more practical solution for predicting postoperative outcomes in CD. Applying one of the largest available CD cohorts, we incorporated a wide array of patient and tumor characteristics, imaging findings, and treatment details to develop a robust and comprehensive predictive model. This model offers treating surgeons reliable insights into the likelihood of tumor recurrence or persistence. By providing individualized risk predictions, the model is intended to assist clinicians in considering different therapeutic options before pituitary surgery, complementing—but not replacing—standard multidisciplinary decision-making. To further enhance its utility in clinical practice, we also developed an interactive online dynamic nomogram, allowing individualized predictions of postoperative persistence or recurrence.
Methods
Study design, patients, and endpoints
The experimental protocol was approved by the Institutional Review Board of Shahid Beheshti University of Medical Sciences (Tehran, Iran). This retrospective study investigates the clinical outcomes of pituitary surgery in patients with CD underwent pituitary surgery between 2010 and 2024 in the neurosurgery department at Loghman Hakim Hospital. Surgeries were conducted by a group of experienced neurosurgeons under the supervision of the first author (G.S). The primary objective of this study was to develop and validate a predictive model for assessing the risk of PoRP-CD. The secondary objectives were (a) to summarize patient and tumor characteristics; (b) to report surgical outcomes and remission rates following surgery; and (c) to analyze patient survival. This study was performed in accordance with the Declaration of Helsinki, and adheres to the reporting guidelines outlined in the STROBE Statement. Due to retrospective nature of the study informed consent was waived by Shahid Beheshti University of Medical Sciences Ethics Committee. All methods were performed in accordance with the relevant guidelines and regulations.
Preoperative assessments
The “index surgery” was set to the most recent pituitary surgery. Before the index surgery, patients underwent comprehensive clinical evaluations, including biochemical and neurological assessments as well as visual field examinations. This research utilized the Endocrine Society Clinical Practice Guideline to establish the diagnosis of CD [8]. Three main steps were involved in the diagnostic process: in the first step, the focus was on detecting hypercortisolemia, which was determined by examining 24-hour urinary free cortisol levels (normal: <60 mcg/24 h), as well as plasma and salivary cortisol profiles. Low-dose dexamethasone suppression testing was performed using the 2 mg/48 h protocol, which was the standard practice in our institution during the study period (2010 onward) [8]. The second step aimed to confirm ACTH-dependent cause of hypercortisolemia, through measuring plasma ACTH levels. The final step aimed to distinguish Cushing’s disease from ectopic sources of ACTH. This was performed using a high-dose dexamethasone suppression test (8 mg overnight), with a plasma cortisol suppression exceeding 50 % typically considered indicative of a pituitary origin [9].
Next, the patients were subjected to thin-slice (3 mm) 1.5-tesla dynamic pituitary gland magnetic resonance imaging (MRI) with gadolinium contrast. The MR evaluation adhered to a strict protocol, requiring an independent agreement of treating neurosurgeon and radiologist to confirm the diagnosis. MR scans were categorized according to the Hardy and Knosp classifications [10]. Normal scans required to demonstrate the absence of direct signs, including inhomogeneity in the pituitary, as well as indirect signs such as a deviation of the pituitary stalk, bulging or erosion of the Sella contour. In cases where the CD was confirmed but pituitary MRI was inconclusive, bilateral inferior petrosal sinus sampling (IPSS) was performed per standard protocol under corticotropin-releasing hormone (CRH) stimulation [11]. Patients with macroadenoma or signs of elevating the optic chiasm were candidates for Humphrey visual field examination.
Surgical approach
Patients underwent endoscopic transsphenoidal approach using conventional “Two Nostrils–Four Hands” technique [12]. Given the diminutive size and deep-seated location of most adenomas, locating the adenoma emerged as a formidable challenge, particularly when the tumor remained not visualized in pre-operative imaging studies. The surgical procedure entailed extensive drilling of the Sellar floor laterally up to the carotid artery on both sides, providing a comprehensive view of the medial wall of the cavernous sinus and exposure of the anterior and posterior intercavernous sinuses. The exploration of the entire Sella commenced in the region where the original tumor had been localized. Upon identification of a tumor, a selective adenomectomy was performed, accompanied by a thorough inspection of the pituitary gland to detect and eliminate any potential tumor remnants. The removal of any pseudo capsule was executed meticulously.
The primary surgical objective was selective adenomectomy, with further exploration guided by the side recommended by IPSS in cases where no adenoma was initially observed. The exploration involved making a plus-like incision on the corresponding half of the gland, enabling deep exploration to leave no part unexplored. In instances where creamy material suggestive of a tumor was drained after a pituitary incision, a tissue biopsy was obtained, although it was not conclusively considered a tumor. Exploration continued on the opposite side in such cases.
When no distinct adenoma was found, a peri-glandular inspection was conducted to visualize the medial wall of the cavernous sinus, diaphragm, and Sellar floor, aiming to detect an ectopic microadenoma. If an apparent tumor remained undetected, the procedure was repeated on the contralateral side, and a vertical medial incision on the pituitary gland adjacent to the pituitary stalk and neurohypophysis was made as a final effort for tumor detection. In the absence of identified pathology during the surgical procedure, hemi-hypophysectomy was considered on the side where IPSS had detected the gradient or on the side with an apparent or suspicious MRI finding. Considering the typical central location of corticotroph cells in the pituitary gland, microadenoma exploration extended posteriorly and medially to confirm extirpation.
Postoperative assessments
In this study, the patients were closely monitored for signs of diabetes insipidus and syndrome of inappropriate antidiuretic hormone secretion (SIADH). Serum sodium levels, urine-specific gravity, and volume were checked regularly. Following surgery, morning cortisol levels were measured on the first day, and other anterior pituitary hormones were evaluated on day 3. Hydrocortisone therapy was initiated based on the patient’s symptoms, signs of adrenal insufficiency, and low cortisol levels. The first postoperative check-up occurred two weeks after surgery, followed by another at three months, which included a comprehensive assessment of pituitary hormones. This evaluation was repeated every three months for two years and then annually. Additionally, patients underwent a dynamic 1.5-Tesla pituitary MRI at six months post-surgery and annually thereafter, with a minimum follow-up period of 12 months.
Remission was defined as having low cortisol levels, indicated by early morning serum cortisol level ≤ 5 μg/dL within two days post-surgery [13]. Persistent CD was characterized by ongoing hypercortisolism, and postoperative recurrence refers to the reappearance of CD symptoms despite initial remission marked by hypercortisolemia. In case of persistence or recurrence, patients were candidates for second-line treatment options selected by their physicians, including revision surgery, targeted medical therapy, pituitary radiotherapy, or bilateral adrenalectomy. Disease-free survival (DFS) was defined as the time from the index surgery to the first occurrence of disease recurrence or death from any cause, while overall survival (OS) was defined as the time from the index surgery to death from any cause.
Statistical analysis
Categorical variables were expressed as numbers and percentages, and continuous variables as mean, range, and standard deviation. The distribution of variables was checked using the Shapiro-Wilk test, which showed a deviation from normal distribution. Contingency tables were used for categorical variables with Pearson’s Chi-squared or Fisher’s Exact test used to examine their association with outcomes for univariate analyses. For continuous variables, the unpaired t-test was applied to compare means between two independent groups when the data met the assumption of normality. Analyses were conducted with R Statistical Software v4.4.0 (“Puppy Cup”). All statistical inferences were two-sided, and P < 0.05 were considered statistically significant.
Model development and internal validation
The dataset was split by “caret package” into a training set (70 %) and a testing set (30 %) using stratified sampling to ensure representative proportions of outcomes. Binary logistic regression was used to identify predictors of PoRP-CD. Patients with adequate follow-up data were included in the analysis. The variables with a marginal level of association (P < 0.15) in the univariate analysis were further included in the multivariate logistic regression analysis to identify the independent predictors of PoRP-CD. Imported factors included demographic, medical history, imaging and pathology results, and treatment details. To identify predictors of PoRP-CD, a multivariable logistic regression model was developed using stepwise selection based on Akaike Information Criterion (AIC). Model performance, including sensitivity, specificity, and area under the receiver operating characteristic curve (AUC-ROC), was evaluated using internal validation on the test dataset.
Nomogram creation and deployment
A nomogram was constructed using the validated logistic regression model. The nomogram was then integrated into a web-based application using the “Shiny package” in R program. The dynamic nomogram allows clinicians to input patient data and obtain individualized risk predictions for PoRP-CD.
Survival analysis
Survival analysis was conducted to evaluate DFS across various patient subgroups. The log-rank test was applied to assess statistical differences in survival distributions between subgroups. Cox proportional hazard regression was used to estimate hazard ratios (HR) and 95 % confidence intervals (CI). The “survival” and “survminer” R packages were applied in this section.
Results
Patients and tumors characteristics
A total of 211 patients with CD had been treated by a group of experienced neurosurgeons under the supervision of the first author (G.S) between March 2010 and January 2024 in the neurosurgery department at Loghman Hakim Hospital. Table 1 summarizes the baseline characteristics of patients at the timepoint of index surgery. The patients had a mean age of 35.9 ± 12.1 years (range: 11–67), among which 21 patients (9.9 %) were in the pediatric age range, and 165 (78.1 %) were female. Obesity was the most common patients’ symptoms (45.9 %), and physical examination reported centripetal obesity (84.3 %), moon face (75.8 %), and striae (64.4 %) as the most common clinical manifestations. Compared to the adult patients, pediatrics had less common hypertension on physical examination (35.2 vs. 5.9 %) and medical history of diabetes mellitus (36.8 vs. 4.7 %) (P < 0.05). The majority of patients (63.9 %, 135/211) had not received any prior treatment. Among those who had, surgery alone was the most common approach (n = 57, 27.0 %), performed once in 50 patients (23.6 %), twice in 6 patients (2.8 %), and three times in a single patient.
Table 1. Baseline characteristics of adult and pediatric patients with Cushing’s disease.
| Demographics | Total n = 211 |
Adults n = 190 |
Pediatrics n = 21 |
P | Medical Hx | Total n = 211 |
Adults n = 190 |
Ped. n = 21 |
P | Drug-Family Hx | Total n = 211 |
Adults n = 190 |
Ped. n = 21 |
P |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Age; mean-SD (y) | 35.9–12.1 | 38.3–10.2 | 14.8–1.7 | 0<.001 | Hypertension | 97 (45.9) | 92 (48.4) | 5 (23.8) | 0.31 | Cabergoline | 3 (1.4) | 3 (1.5) | 0 | 1.0 |
| Sex; female | 165 (78.1) a | 149 (78.4) | 16 (76.1) | 0.78 | Diabetes mellitus | 71 (33.6) | 70 (36.8) | 1 (4.7) | 0<.001 | Ketoconazole | 12 (5.6) | 12 (6.3) | 0 | 0.61 |
| Marital status; married | 105 (70.0) b | 103 (76.8) b | 2 (12.5) b | 0<.001 | Dyslipidemia | 45 (21.3) | 42 (22.1) | 3 (14.2) | 0.56 | Metyrapone | 0 | − | − | − |
| Smoking status; active–passive-non | 17 (10)-27(17)-113(72) b | 17 (11)–23(15)-101(70) b | 0–4(25)-12(75) b | 0.70 | Prior pituitary surgery | 57 (27.0)) | 51 (26.8) | 6 (28.5) | 1.0 | Pasireotide | 0 | − | − | − |
| Height; mean-SD (cm) | 163.9–8.7 | 163.8–8.9 | 165.1–6.6 | 0.59 | Fatty liver | 37 (17.5) | 32 (16.8) | 5 (23.8) | 0.36 | Somatostatin | 0 | − | − | − |
| Weight; mean-SD (Kg) | 74.1–22.5 | 74.6–22.5 | 69.3–23.1 | 0.58 | Thromboembolism | 6 (2.8) | 6 (3.1) | 0 | 1.0 | |||||
| BMI; mean-SD (Kg/m2) | 28.8–6.1 | 29.0–6.2 | 27.6–5.5 | 0.72 | DVT | 3 (1.4) | 3 (1.5) | 0 | 1.0 | FH of Cushing | 5 (2.3) | 4 (2.1) | 1 (4.7) | 0.43 |
| Symptom duration; mean-SD (m) | 30.7–41.2 | 32.0–43.2 | 20.0–14.2 | 0.78 | MEN | 1 (0.4) | 1 (0.5) | 0 | 1.0 | FH of MEN | 1 (0.4) | 1 (0.5) | 0 | 1.0 |
| Presenting Symptoms | ||||||||||||||
| Obesity | 75 (45.9) b | 66 (45.2) b | 9 (52.9) b | 0.61 | Striae | 10 (6.1) b | 8 (5.4) b | 2 (11.7) b | 0.27 | Headache | 4 (2.4) b | 3 (2.0) b | 1 (5.8) b | 0.35 |
| Menstrual disorders | 16 (9.8) b | 13 (8.9) b | 3 (17.6) b | 0.22 | Edema | 7 (4.2) b | 7 (4.7) b | 0 | 1.0 | Diabetes mellitus | 3 (1.8) b | 3 (2.0) b | 0 | 1.0 |
| Hypertension | 12 (7.3) b | 12 (8.2) b | 0 | 0.61 | Muscular weakness | 7 (4.2) b | 6 (4.1) b | 1 (5.8) b | 0.54 | Bone fracture | 3 (1.8) b | 3 (2.0) b | 0 | 1.0 |
| Blurred vision | 10 (6.1) b | 9 (6.1) b | 1 (5.8) b | 1.0 | Moon face | 6 (3.6) b | 6 (4.1) b | 0 | 1.0 | Other | 10 (6.1) b | 10 (6.8) b | 0 | 0.60 |
| Clinical Manifestations | ||||||||||||||
| Acanthosis nigricans | 35 (16.5) | 34 (17.8) | 1 (4.7) | 0.12 | Easy bruising | 103 (48.8) | 92 (48.4) | 11 (52.3) | 0.91 | Male pat. hair loss | 111 (52.6) | 100 (52.6) | 11 (52.3) | 1.0 |
| Acne | 68 (32.2) | 58 (30.5) | 10 (47.6) | 0.16 | Ecchymosis | 58 (27.5) | 50 (26.3) | 8 (38.0) | 0.37 | dysmenorrhea | 96 (45.4) | 84 (44.2) | 12 (57.1) | 0.49 |
| Ankle edema | 105 (49.7) | 96 (50.5) | 9 (42.8) | 0.57 | Exophthalmia | 50 (23.7) | 47 (24.7) | 3 (14.2) | 0.27 | Moon face | 160 (75.8) | 141 (74.2) | 19 (90.4) | 0.69 |
| Backache | 66 (31.2) | 60 (31.5) | 6 (28.5) | 0.88 | Facial plethora | 97 (45.9) | 85 (44.7) | 12 (57.1) | 0.33 | Osteoporosis | 25 (11.8) | 25 (13.1) | 0 | 0.14 |
| Blurred vision | 70 (33.2) | 67 (35.2) | 3 (14.2) | 0.27 | Fatigue | 146 (69.2) | 130 (68) | 16 (76.1) | 0.76 | Prox. myopathy | 94 (44.5) | 86 (45.2) | 8 (38.0) | 0.63 |
| Buffalo hump | 123 (58.3) | 107 (56.3) | 16 (76.1) | 0.43 | Fracture | 12 (5.6) | 12 (6.3) | 0 | 0.61 | Skin atrophy | 81 (38.4) | 73 (38.4) | 8 (38.0) | 1.0 |
| Centripetal obesity | 178 (84.3) | 159 (83.6) | 19 (90.4) | 0.50 | Headache | 109 (51.6) | 97 (51.0) | 12 (57.1) | 1.0 | Striae | 136 (64.4) | 119 (62.6) | 17 (80.9) | 0.55 |
| Cerebrospinal fluid leakage | 5 (2.3) | 4 (2.1) | 1 (4.7) | 0.41 | Hirsutism | 104 (49.3) | 92 (48.4) | 12 (57.1) | 0.72 | Supraclav. fat pad | 38 (18.0) | 33 (17.3) | 5 (23.8) | 0.67 |
| Cranial nerve palsy | 3 (1.4) | 3 (1.5) | 0 | 1.0 | Hyperpigmentation | 38 (18.0) | 37 (19.4) | 1 (4.7) | 0.12 | Visual field defect | 24 (11.3) | 22 (11.5) | 2 (9.5) | 1.0 |
| Diplopia | 18 (8.5) | 15 (7.8) | 3 (14.2) | 0.41 | Hypertension | 69 (32.7) | 67 (35.2) | 2 (9.5) | 0.009 | Weight gain | 108 (51.1) | 95 (50.0) | 13 (61.9) | 0.39 |
| Prior Treatments | ||||||||||||||
| Treatment naïve | 135 (63.9) | 122 (64.2) | 13 (61.9) | 1.0 | Pituitary surgery alone | 39 (18.4) | 33 (17.3) | 6 (28.5) | 0.23 | Radiotherapy alone | 6 (2.8) | 5 (2.6) | 1 (4.7) | 0.47 |
| Medication alone | 5 (2.3) | 5 (2.6) | 0 | 1.0 | Combination therapy | 17 (8.1) | 17 (8.9) | 0 | 0.22 | Adrenalectomy alone | 11 (5.2) | 10 (5.2) | 1 (4.7) | 1.0 |
| Hormonal Assessments | ||||||||||||||
| Hypothyroidism | 24 (31.1) b | 24 (31.1) b | 0 | 0.09 | GH deficiency | 6 (8.8) b | 6 (8.8) b | 0 | 1.0 | Hypogonadism | 7 (9.8) b | 7 (9.8) b | 0 | 1.0 |
| Panhypopituitarism | 2 (2.5) b | 2 (2.5) b | 0 | 1.0 | ||||||||||
| Imaging Features | ||||||||||||||
| Hardy’s grading (sphenoid bone invasion) 0 1 2 3 4 |
37 (21.1) b 102 (58.2) b 27 (15.4) b 4 (2.2) b 5 (2.8) b |
35 (22.7) b 88 (57.1) b 23 (14.9) b 3 (1.9) b 5 (3.2) b |
2 (9.5) 14 (66.7) 4 (19.0) 1 (4.7) 0 |
0.45 | Hardy’s staging (suprasellar extension) A B C D E |
36 (20.4) b 86 (48.8) b 14 (7.9) b 4 (2.2) b 36 (20.4) b |
34 (21.9) b 73 (47.1) b 14 (9.0) b 2 (1.2) b 32 (20.6) b |
2 (9.5) 13 (62) 0 2 (9.5) 4 (19.0) |
0.07 | Knosp grading
0 |
152 (82.6) b 13 (7.0) b 7 (3.8) b 4 (2.1) b 8 (4.3) b |
135 (82.8) b 10 (6.1) b 6 (3.6) b 4 (2.4) b 8 (4.9) b |
17 (80.9) 3 (14.2) 1 (4.7) 0 0 |
0.46 |
| Tumor size Microadenoma Macroadenoma MR-negative |
122 (58.6) b 50 (24.0) b 36 17.3) b |
111 (59.3) b 42 (22.4) b 34 (18.1) b |
11 (52.3) 8 (38.0) 2 (9.5) |
0.28 | Sphenoid shape Sellar Presellar Conchal |
205 (97.6) b 3 (1.4) b 2 (0.9) b |
184 (97.3) b 3 (1.5) b 2 (1.0) b |
21 (100) 0 0 |
1.0 | Multifocality Unifocal Multifocal |
113 (80.1) 28 (19.8) |
97 (79.5) 25 (20.4) |
16(84.2) 3 (15.7) |
0.79 |
| Invasion c No invasion Cavernous sinus Carotid Dura Clivus |
185 (88.5) b 12 (5.7) b 3 (1.4) b 6 (2.8) b 3 (1.4) b |
165 (87.7) b 11 (5.8) b 3 (1.5) b 6 (3.1) b 3 (1.5) b |
20 (95.2) b 1 (4.8) b 0 0 0 |
1.0 | Tumor site Right lobe Left lobe Bilateral Central Stalk |
22 (15.6)) b 16 (11.3)) b 51 (36.1) b 49 (34.7) b 3 (2.1) b |
20 (16.2) b 13 (10.5) b 43 (34.9) b 45 (36.5) b 2 (1.6) b |
2 (11.1) b 3 (16.6) b 8 (44.4) b 4 (22.2) b 1 (5.5) b |
0.38 | Empty sella No Yes |
207 (98.1) 4 (1.8) |
187 (98.4) 3 (1.5) |
20(95.2) 1 (4.7) |
0.34 |
| Pituitary apoplexy No Yes |
185 (97.3) b 5 (2.6) b |
167 (98.2) b 3 (1.7) b |
18 (90.0) b 2 (10.0) b |
0.08 | Kissing carotids No Yes |
209 (99.0) 2 (0.9) |
188 (98.9) 2 (1.0) |
21 (100) 0 |
1.0 | |||||
- a
-
the numbers in parentheses represent the percentage for each patient group.
- b
-
percentage after ruling out missing data.
- c
-
one patient had invasion to cavernous sinus and carotid and another one had clivus and dural invasion.
A comprehensive preoperative hormonal assessment was conducted on 77 patients (36.4 %), revealing hormonal dysregulation in 28 patients (36.3 %). Hypothyroidism was the most common abnormality, affecting 35 % of those assessed (24 out of 77). On MRI scans, most tumors were microadenomas (58.6 %), with fewer macroadenomas (24.0 %) and some cases with no detectable tumor (17.3 %). Tumors were commonly localized bilaterally (36.1 %) or centrally (34.7 %), and most were unifocal (80.1 %). Knosp grading indicated no cavernous sinus invasion in the majority (82.6 %), with only 6.4 % showing grades 3–4. According to Hardy’s grading, most patients had mild sphenoid bone invasion, predominantly grade 1 (58.2 %). For Hardy’s staging of suprasellar extension, nearly half were at stage B (48.8 %), with smaller groups in stages A and E (20.4 % each), and fewer in stages C and D. Other MRI findings are summarized in Table 1. There was no significant difference between adult and pediatric patients in terms of hormonal and imaging findings (P > 0.05). Pathology reports were available for 36 patients. The most common finding was sparse cellularity, observed in 11 patients (30.6 %) followed by dense cellularity identified in 9 patients (25 %). Crooke cell changes were the least common, present in 7 patients (19.4 %). Nine specimens (25 %) had no tumor identified in the sample submitted to pathology.
Treatment details and outcomes
A total of 36 patients (17.1 %) underwent preoperative IPSS, among which 13 had right lateralization, 13 left, 4 bilateral, 3 central, 2 central-right, and 1 central-left. Pituitary surgery was predominantly performed using the endoscopic transsphenoidal (eTSS) approach (98.5 %, 208/211), while the transplanum approach was used in 3 patients (1.5 %). Adenomectomy was the most common surgical procedure (n = 187, 88.6 %), followed by total hypophysectomy in 17 patients (8.1 %) and hemi-hypophysectomy in 7 patients (3.3 %). In addition, four patients in the total hypophysectomy group and one patient in the adenomectomy group also underwent hypophyseal stalk resection. Information on disease persistence or recurrence was available for 204 patients. Median follow-up of patients was 58.4 months (range: 4.5–170.4 months) after index surgery. In total, 23 patients (11.2 %) experienced persistent disease following the index surgery, while 10 patients (4.9 %) had disease recurrence, with a median time to recurrence of 7 months (range: 1–78 months). The median recurrence-free interval for the entire cohort was 37 months.
The surgical complication rates were as follows (Fig. 1A): cerebrospinal fluid leaks were observed in 22 patients (10.4 %), followed by cranial nerve injury in 7 patients (3.3 %) and meningitis in 5 patients (2.3 %). Carotid injury and intracerebral bleeding each occurred in 3 patients (1.4 %). Nasal bleeding, the need for a ventriculoperitoneal shunt, and embolic events were each reported in 1 patient (0.4 %). Perioperative mortality was observed in one female patient (0.4 %) due to an iatrogenic carotid injury. This patient had previously undergone three pituitary surgeries and received radiotherapy at the pituitary site. Hormonal dysregulation following surgery included hypothyroidism in 99 patients (46.9 %), diabetes insipidus in 76 patients (36 %), hypogonadism in 28 patients (13.2 %), growth hormone deficiency in 10 patients (4.7 %), and panhypopituitarism in 7 patients (3.3 %) (Fig. 1B).
Fig. 1. Rates of surgical complications. (a) Intraoperative complications; (b) hormonal dysregulation rates following surgery.
Multivariate analysis on the predictors of Persistent/Recurrent Cushing’s disease
To identify potential predictive factors for PoRP-CD, we conducted a comprehensive binary logistic regression analysis, examining key clinical and imaging variables (Table 2). In the univariate analysis, factors including symptom duration (OR [odds ratio] 1.01, 95 % CI [confidence interval] 1.00–1.02, P = 0.04), MRI Hardy’s grade (OR 1.62, 95 % CI 0.98–2.69, P = 0.05), and previous pituitary surgery (OR 3.56, 95 % CI 1.39–9.07, P = 0.007) demonstrated significant association with PoRP-CD. MR-reported tumor size showed increased odds of recurrence with an increased tumor size (OR for microadenoma vs. no tumor: 2.41, 95 % CI: 0.50–11.53; OR for macroadenoma vs. no tumor: 4.15, 95 % CI 0.80–21.42), though the effect was not statistically significant (P > 0.05). To impede missing the marginal significant factors, three factors with P values between 0.05 and 0.15 were also included in the multivariate analysis, including “MRI Knosp grading”, “MR-reported tumor site”, and “previous pituitary radiotherapy”. In the multivariate analysis, “symptom duration” was positively correlated with recurrence, with an odds ratio (OR) of 1.03 (95 % CI: 1.01–1.06, P = 0.01), indicating a higher risk of recurrence with prolonged symptoms. Additionally, a history of “previous pituitary surgery” was significantly associated with recurrence, with an OR of 4.67 (95 % CI: 1.04–20.89, P = 0.04). Other factors, including tumor grading, tumor site, and previous radiotherapy, did not reach statistical significance.
Table 2. Regression analysis of patient and tumor’s factors related to postoperative persistence or recurrence in Cushing disease.
| Parameters | Univariate Analysis | Multivariate Analysis | ||
|---|---|---|---|---|
| OR (95 % CI) | P | OR (95 % CI) | P | |
| Age | 0.97 (0.94–1.01) | 0.23 | ||
| Sex (male vs. female) | 1.17 (0.39–3.50) | 0.77 | ||
| Smoking (active smoker vs. non) | 0.78 (0.65–10.28) | 0.77 | ||
| Family history of CD (positive vs. negative) | 0.01 (0–Inf) | 0.99 | ||
| Family history of MEN (positive vs. negative) | 0.01 (0–Inf) | 0.99 | ||
| Preoperative BMI | 1.03 (0.94–1.13) | 0.43 | ||
| Symptom duration | 1.01 (1.00–1.02) | 0.04 ** | 1.03 (1.01–1.06) | 0.01 ** |
| Preop serum ACTH (high vs. normal) | 0.88 (0.13–6.00) | 0.90 | ||
| Preop free serum cortisol (high vs. normal) | 1.18 (0.40–3.45) | 0.74 | ||
| Preop urine free cortisol (high vs. normal) | 0.15 (0.01–2.98) | 0.21 | ||
| Knosp grading (ref: grade 0) | 1.41 (0.93–2.15) | 0.10 * | 1.56 (0.61–3.97) | 0.34 |
| Hardy’s grading (ref: grade 0) | 1.62 (0.98–2.69) | 0.05 ** | 1.98 (0.54–7.21) | 0.29 |
| Hardy’s staging (ref: stage A) | 2.97 (0.61–14.38) | 0.17 | ||
| Tumor size Macro vs. no tumor Micro vs. no tumor |
4.15 (0.80–21.42) 2.41 (0.50–11.53) |
0.17 | ||
| Multifocality (multifocal vs. unifocal) | 1.68 (0.44–6.42) | 0.44 | ||
| MR-based tumor sitea Bilateral vs. central Left vs. central Right vs. central Stalk vs. central |
0.16 (0.01–1.53) 0.82 (0.18–4.40) 0.49 (0.09–2.82) 5.33 (0.37–144.16) |
0.14 * | 0.34 (0.02–3.95) 0.23 (0.01–3.12) 5.36 (0.19–146.38)
|
0.03 ** 0.39 0.27 0.31 |
| Invasion (pos. vs. neg.) | 1.18 (0.31–4.51) | 0.80 | ||
| Surgical approach (transplanum vs. eTSS) | 6.21 (0.37–103.55) | 0.20 | ||
| Surgical type (adenomectomy vs. hypophysectomy) | 1.55 (0.46–5.22) | 0.47 | ||
| Histopathology Dense type vs. Crooke’s cell adenoma Normal appearing vs. Crooke’s cell adenoma Sparse type vs. Crooke’s cell adenoma |
2.00 (0.09–69.06) 0.80 (0.04–23.23) 0.28 (0.01–9.45) |
0.56 | ||
| Ki-67 (>3% vs. ≤ 3 %) | 1.34 (0.14–12.64) | 0.79 | ||
| Previous pituitary surgery (yes vs. no) | 3.56 (1.39–9.07) | 0.007 ** | 4.67 (1.04–20.89) | 0.04 ** |
| Previous pituitary radiotherapy (yes vs. no) | 3.36 (0.89–12.62) | 0.07 * | 3.63 (0.28–46.07) | 0.31 |
| Postop decrease in BMI | 0.90 (0.73–1.03) | 0.22 | ||
Abbreviations: ACTH − Adrenocorticotropic Hormone; BMI − Body Mass Index; CD − Cushing’s Disease; CI − Confidence Interval; eTSS − Endoscopic Transsphenoidal Surgery; Inf − Infinity; MEN − Multiple Endocrine Neoplasia; MR − Magnetic Resonance; OR − Odds Ratio; PoRP-CD − Persistent or Recurrent Cushing’s Disease; Preop − Preoperative; Postop − Postoperative.
aMR-reported.
* Significant at the level of 0.15.
** Significant at the level of 0.05.
The stepwise selection–in both forward and backward directions–retained four predictors— symptom duration, Hardy’s grading, tumor site, and prior surgery —for the final model. The final multivariate model with four predictors of “symptom duration”, “MRI Hardy’s grading”, “tumor site”, and “previous pituitary surgery” demonstrated significant associations for “symptom duration” (OR 1.03, 95 % CI 1.005–1.05, P = 0.02), previous pituitary surgery (OR 4.61, 95 % CI 1.12–22.0, P = 0.03), and a certain tumor site; tumors located bilaterally had significantly lower odds of recurrence compared to central tumors (OR 0.01, 95 % CI 0.0002–0.45, P = 0.02). On the testing dataset, the four-factor model achieved an AUC of 0.70, specificity of 96 %, and sensitivity of 33 %. The model’s accuracy in predicting PoRP-CD is 83 %.
Predicting persistent or recurrent Cushing’s disease–The CuPeR nomogram
A nomogram was developed based on the multivariate model comprising four key predictors: “Symptom duration”, “MRI Hardy’s grading”, “Previous pituitary surgery”, and “MRI-reported tumor site” (Fig. 2). This nomogram visually represents the impact of each predictor on the likelihood of PoRP-CD. The total score derived from the nomogram aligns with the probability scales, allowing for estimation of the risk of PoRP-CD. Higher cumulative points correspond to an increased likelihood of persistent or recurrent disease. To facilitate individualized predictions of postoperative persistence or recurrence, we developed an online dynamic nomogram (link: https://cushing.shinyapps.io/cuper/).
Fig. 2. Nomogram for predicting postoperative persistence or recurrence of Cushing’s disease (PoRP-CD). This nomogram visually represents the predictive model for assessing the risk of recurrence or persistence of Cushing’s disease following surgery. Each predictor variable—Symptom duration (months), Knosp grading, Hardy’s grading, previous pituitary surgery, and tumor site— contributes a point value that aligns with the “Linear Predictor” scale, which maps to the “Probability of Persistence” scale, allowing estimation of recurrence likelihood.
Survival analysis
Survival analysis demonstrated a steady, gradual decline in DFS across the entire cohort, with the median DFS not reached despite substantial follow-up (Fig. 3A). Among the predefined variables, Hardy’s Grade 3 was associated with a significantly worse DFS compared with Grade 0 (HR = 6.02, 95 % CI: 1.09–33.02, P = 0.03) (Fig. 3B), whereas other Hardy’s Grades did not reach statistical significance (P > 0.05). Regarding tumor site, no site was a statistically significant risk factor for DFS; stalk tumors showed a trend toward poorer DFS but did not reach significance (HR = 5.09, 95 % CI: 0.84–30.63, P = 0.07) (Fig. 3C). Patients with a history of previous pituitary surgery had significantly worse DFS (HR = 4.72, 95 % CI: 2.29–9.75, P < 0.01) (Fig. 3D). In contrast, symptom duration was not associated with poor DFS (HR = 1.26, 95 % CI: 0.56–2.81, P = 0.57) (Fig. 3E). A similar analysis on OS was not performed, as only five events were recorded among the 211 patients (2.36 %), rendering meaningful statistical analysis infeasible.
Fig. 3. Disease-free survival (DFS) analysis. (A) Kaplan-Meier curve of DFS for the entire cohort, showing a gradual decline over time; (B) DFS stratified by Hardy’s Grade, demonstrating significant impact of grade 3 on survival outcomes (P = 0.03); (C) DFS by tumor site, highlighting no significant association between tumor site and survival care (P > 0.05); (D) DFS based on previous surgery status, indicating a higher risk of recurrence or death in patients with prior surgical interventions (P < 0.01); (E) DFS by symptom duration, highlighting no significant association (P = 0.57).
Discussion
In this large cohort study, we developed the CuPeR model, a comprehensive predictive tool for PoRP-CD, by analyzing diverse patient and tumor characteristics, imaging findings, and treatment details. This model identified four key predictors—symptom duration, MRI Hardy’s grade, tumor site, and previous pituitary surgery. Multivariate analysis revealed that longer symptom duration and a history of prior surgery significantly increased recurrence risk, while bilateral tumor location was associated with a reduced risk. Validated with an AUC of 0.70 and 83 % accuracy on the testing dataset, the model offers significant clinical utility by providing treating surgeons with valuable insights into postoperative outcomes.
This study is among the few to develop a predictive model for estimating PoRP-CD (Table 3). Previous efforts, such as those by Liu et al. [6] and Fan et al. [7], employed machine learning and deep learning methodologies, respectively, demonstrating promising results (AUCs of 0.78 and 0.86). However, both studies were limited in their applicability to many clinical settings, as they focused solely on patients undergoing initial surgeries and incorporated postoperative parameters, which are unavailable for preoperative decision-making. By addressing these gaps, our study contributes a more practical tool for use in diverse clinical scenarios. Moreover, the findings of this study align with predictors identified in prior research. For instance, factors such duration of symptoms and history of previous pituitary surgery have been highlighted as critical for recurrence [6,14]. Importantly, our inclusion of MRI-based predictors and preoperative variables ensures the model’s relevance during preoperative planning, distinguishing it from previous approaches.
Table 3. Studies on predictive models or patients and tumors predictive factors of post-operative remission of Cushing’s disease.
| Empty Cell | Year | Country | Study Size | Methods | Main Findings | Ref. |
|---|---|---|---|---|---|---|
| Predictive Models | ||||||
| Comprising 8 factors: age, disease coarse, morning serum ACTH (preop), morning serum cortisol (preop), urine free cortisol (preop), morning serum ACTH nadir (postop), morning serum cortisol nadir (postop), urine free cortisol nadir (postop) |
2019 | China | 354 | Machine-learning using Random Forest algorithm | Sensitivity 87 %, specificity 58 % AUC 0.78 |
[6] |
| Comprising 5 factors: age, disease coarse, morning serum ACTH (postop), morning serum cortisol nadir (postop), urine free cortisol nadir (postop) |
2021 | China | 354 | Deep-learning using factorization‑machine based neural approach | AUC 0.86 | [7] |
| Predictive Factors | ||||||
| Serum cortisol < 35 nmol/L (6–12 w after surgery) | 1993 | UK | 11 | Prospective | Favorable long-term remission rate | [15] |
| Serum 11-deoxycortisol > 150 nmol/L after metyrapone test at 14 days post-surgery | 1997 | Netherlands | 29 | Retrospective | Higher risk of recurrence Sensitivity 100 %, specificity 75 % |
[16] |
| Serum cortisol < 2 μ/dL (3–8 d after surgery) | 2001 | Japan | 49 | Retrospective | Recurrent disease in 4 % of patients | [17] |
| MRI-based tumor size and cavernous sinus invasion | 2003 | Italy | 26 | Retrospective | Unfavorable factors of persistent disease | [18] |
| No histological evidence of adenoma | 2007 | US | 490 | Retrospective | Lower remission rate | [19] |
| Long-term hypocortisolism after surgery (≥13 m) | 2017 | India | 230 | Retrospective | Favorable for remission Sensitivity 46 %, specificity 100 % |
[20] |
| Greater decrease in BMI after surgery Lower DHEAS before surgery |
2017 | Taiwan | 41 | Retrospective | Favorable factors for higher remission | [21] |
| High serum ACTH/cortisol ratio before surgery | 2018 | Turkey | 119 | Retrospective | Risk factor for disease recurrence | [22] |
| USP8 mutation | 2018 | Germany | 48 | Retrospective | Higher recurrence rate | [23] |
| Serum cortisol < 107 nmol/L after betamethasone suppression test following surgery | 2018 | Sweden | 28 | Interventional | Sensitivity 85 %, specificity 94 % AUC 0.92 |
[24] |
| Tumor visualization on MRI before surgery | 2022 | Spain | 40 | Retrospective | Favorable factor for remission | [25] |
Abbreviations: ACTH − Adrenocorticotropic Hormone; AUC − Area Under the Curve; BMI − Body Mass Index; DHEAS − Dehydroepiandrosterone Sulfate; MRI − Magnetic Resonance Imaging; PoRP-CD − Persistent or Recurrent Cushing’s Disease; Preop − Preoperative; Postop − Postoperative; USP8 − Ubiquitin Specific Peptidase 8.
Several other studies aimed to explore the predictive value of single predictors. Braun et al. (2020) summarized the predictors for CD remission following TSS in a systematic review. Key predictors include pre-surgical identification of the tumor via MRI and the absence of adenoma invasion into the cavernous sinus. Postoperative hormonal levels, particularly low cortisol (< 2 µg/dL) and ACTH levels (< 3.3 pmol/L) as well as low cortisol levels (< 35 nmol/L) at 6–12 weeks post-surgery and sustained hypocortisolism requiring long-term replacement therapy, were significant indicators of remission. Additionally, post-surgical decreases in BMI contributed to favorable outcomes. Other reported predictors included a high level of surgical expertise, younger patient age, non-mutant USP8 corticotroph tumors, and swift recovery from postoperative adrenal insufficiency [5].
This study has certain limitations that should be acknowledged. The reliance on retrospective data may result in potential biases in variable selection and data completeness. While the model demonstrated good predictive accuracy, its limited sensitivity may restrict its ability to identify all high-risk patients. Moreover, the model has not been externally validated in independent cohorts, which limits its generalizability to other clinical settings. Despite these limitations, the study possesses significant strengths that underscore its contribution to the field. Applying one of the largest CD cohorts, it provides a robust statistical foundation and enhances the reliability of the findings. The comprehensive inclusion of diverse patient and tumor characteristics, imaging findings, and treatment details resulted in a clinically relevant and well-rounded predictive model. Notably, this model stands out for its applicability to a broader spectrum of patients, including those with prior surgeries or radiotherapy, addressing a gap left by earlier studies. Furthermore, the development of an online dynamic nomogram bridges the gap between research and clinical practice, allowing personalized predictions and aiding surgeons in making informed decisions before pituitary surgery.
Although this study incorporated long-term follow-up (median 58 months) to define persistence and recurrence and to internally validate the model, external validation in prospective, multi-institutional cohorts remains essential to confirm its broader applicability. Although the CuPeR model incorporates a wide array of clinical, radiological, biochemical, and demographic variables, other potential prognostic factors were not included and may warrant consideration in future studies. For instance, the presence of osteoporosis, degree of tumor invasion, and early recovery of the adrenal axis during the postoperative period have all been reported as relevant predictors of outcomes in Cushing’s disease [26]. Moreover, the role of surgical expertise is critical, as higher surgeon and institutional experience are strongly associated with improved remission and lower recurrence rates [27]. Incorporating novel parameters, such as genetic markers or advanced imaging techniques, could further enhance the predictive accuracy and clinical utility of the model. Prospective implementation of the nomogram in routine clinical workflows will provide valuable insights into its performance and its potential to improve patient outcomes.
Conclusions
This study introduced a practical, predictive model for estimating the risk of postoperative persistence and recurrence in Cushing’s disease, possibly offering a reliable tool for preoperative planning. By integrating key clinical predictors into an interactive online dynamic nomogram, the CuPeR model may provide surgeons with personalized risk assessments to aid in preoperative planning. Its focus on preoperative data ensures broader applicability, paving the way for tailored therapeutic strategies and improved patient outcomes in diverse clinical scenarios.
Funding details
None.
CRediT authorship contribution statement
Guive Sharifi: Supervision, Conceptualization. Elham Paraandavaji: Investigation, Data curation. Nader Akbari Dilmaghani: Investigation, Data curation. Tohid Emami Meybodi: Investigation, Data curation. Ibrahim Mohammadzadeh: Investigation, Data curation. Neginalsadat Sadeghi: Investigation, Data curation. Amirali Vaghari: Visualization. Behnaz Niroomand: Visualization. Seyed Mohammad Tavangar: Resources. Mohammad reza Mohajeri Tehrani: Validation. Zahra Davoudi: Resources. Marjan Mirsalehi: Writing – review & editing. Seyed Ali Mousavinejad: Validation, Resources. Farzad Taghizadeh-Hesary: Writing – review & editing, Writing – original draft.
Informed consent
Not applicable.
Declaration of competing interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Acknowledgements
None.
The data that support the findings of this study are available on request from the corresponding author.
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https://www.sciencedirect.com/science/article/pii/S2214623725000353
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