Clinical Efficacy and Safety of Fluconazole Treatment in Patients with Cushing’s Syndrome

Posted on November 23, 2025 by MaryO

Abstract

Background:

Ketoconazole is effective for treating Cushing’s syndrome (CS) but its use is limited by the risk of hepatotoxicity. Fluconazole, with similar antifungal properties, is being investigated as a potentially safer alternative for managing CS. This study aims to evaluate the efficacy and safety of fluconazole in patients with CS.

Methods:

This retrospective study evaluated a total of 22 patients with CS, including 12 with Cushing’s disease (CD), 3 with adrenal Cushing’s syndrome (ACS), and 7 with ectopic Adrenocorticotropic hormone (ACTH) syndrome. Fluconazole was administered orally, ranging from 112.5 to 450 mg daily, with the duration varying from 2 weeks to over 5 years. The efficacy of fluconazole was assessed by changes in 24-hour urinary free cortisol (24-h UFC) levels. Additionally, hepatic safety was assessed by monitoring changes in alanine aminotransferase (ALT) levels.

Results:

Following fluconazole treatment, 24-h UFC levels significantly decreased from 717.6 ± 1219.4 to 184.1 ± 171.8 µg/day (p = 0.035). ALT levels showed an increase from 38.5 ± 28.4 to 56.5 ± 47.8 U/L, though this change was not statistically significant (p = 0.090). ALT levels exceeding the upper limit of normal range (ULN) were observed in 12 patients (54.5%), with only 4 patients (18.2%) showing ALT levels more than three times the ULN. Out of 10 patients who received treatment for over 1 year, 5 patients (50.0%) experienced a recurrence, with 24-h UFC levels more than 1.5 times the ULN within 3 to 12 months after fluconazole treatment.

Conclusion:

Fluconazole effectively reduces hypercortisolism in patients with CS without significant liver injury, suggesting it as a viable therapeutic option for CS. While some cases have shown treatment escape, more studies are required to confirm the long-term efficacy.

Introduction

Cushing’s syndrome (CS) is a complex endocrine disorder characterized by excessive cortisol production, leading to complications such as insulin-resistant hyperglycemia, muscle weakness (proximal myopathy), osteoporosis, cardiovascular diseases, and neuropsychiatric disorders.1 The primary causes of CS include pituitary ACTH-secreting tumor (Cushing’s disease (CD), adrenal neoplasm (adrenal Cushing’s syndrome (ACS)), or nonpituitary ACTH-secreting tumor (ectopic ACTH syndrome (EAS)). The most common cause is CD. If left untreated, CS patients face a 3.8 to 5-fold increase in mortality compared to the general population.2,3 The first-line treatment for CS involves surgical removal of the offending tumor(s). In CD cases, transsphenoidal pituitary surgery achieves success rates between 65% and 90% for microadenomas. However, complete resection can be challenging, especially with macroadenomas, leading to recurrence or persistent hypercortisolism in approximately 20%–25% of patients.4 Alternative treatments include pituitary stereotactic radiosurgery, which effectively controls cortisol levels over several years but carries potential adverse effects.5,6 For EAS patients, managing hypercortisolism while awaiting definitive treatments like surgery is critical.7 Bilateral adrenalectomy offers immediate control over cortisol excess but necessitates lifelong steroid replacement therapy, impacting the quality of life.8 In addition, some corticotropic pituitary tumors may progress post-surgery, requiring further targeted interventions.9
However, some patients were not candidates for surgery due to factors such as advanced age, personal preference against surgery, or the absence of a definitive culprit lesion. When surgery fails to fully correct hypercortisolism (i.e., when 24-h UFC levels do not decrease or even progressively rise in the weeks to months following surgery, indicating persistence or relapse), pharmacotherapy can be employed to reduce cortisol overproduction and enhance clinical outcomes.10,11 In addition, it could be administered before surgical intervention to reduce perioperative complications.12,13 Various medications are used in the treatment of CS, including adrenal steroidogenesis inhibitors, dopamine agonists, somatostatin analogs, or glucocorticoid receptor antagonist.4,14
Ketoconazole, an imidazole fungicide and adrenal steroidogenesis inhibitor, has long been off-label used as the first-line medication for patients with CS who cannot undergo surgery or for whom surgery is non-curative. It reduces cortisol synthesis by inhibiting the side-chain cleavage enzymes 11β-hydroxylase and 17,20-lyase.10 Effective doses range from 200 to 1200 mg daily, but gradual dose increases may be necessary due to the potential for escape from cortisol inhibition.10,15 Ketoconazole is extensively metabolized in the liver, leading to an increased risk of hepatotoxicity.16 In 2013, the U.S. Food and Drug Administration (FDA) issued warnings about the potentially life-threatening liver toxicity associated with ketoconazole. As a result, ketoconazole is no longer available in many regions.
Fluconazole, another azole antifungal agent, has been explored as an alternative treatment for CS. It inhibits adrenal steroidogenesis through the CYP450 pathway, and the effects have been confirmed in vitro, using primary cultures of human adrenocortical tissues and two adrenocortical carcinoma cell lines. The effects were mainly observed in enzymes 11β-hydroxylase and 17α-hydroxylase, which are key in cortisol synthesis.17 Another study also demonstrated that fluconazole inhibits glucocorticoid production in vitro in the adrenal adenoma cell line Y-1.18 Case reports have also documented adrenal insufficiency in patients with severe comorbidities treated with fluconazole, suggesting its potential for managing hypercortisolism.19,20 Fluconazole is characterized by its small molecular size and low lipophilicity. It is minimally metabolized, with approximately 80% excreted unchanged in the urine.16 This contributes to its lower incidence of adverse effects, particularly liver injury. In a cohort study estimating the risk of clinical acute liver injury among users of oral antifungals (fluconazole, griseofulvin, itraconazole, ketoconazole, or terbinafine) in the general population from the General Practice Research Database in the United Kingdom, fluconazole was associated with a lower relative risk of acute liver injury compared to other agents.21
Levoketoconazole, the 2S, 4R enantiomer of ketoconazole, provides enhanced enzyme inhibition with greater therapeutic efficacy and fewer side effects compared to ketoconazole.22 The main challenge with using levoketoconazole in the treatment of CS is the limited data from Randomized controlled trials (RCTs). To date, there are only two prospective studies (SONICS and LOGICS) and one systematic review that evaluate the efficacy and safety of levoketoconazole in this context.2325
Given that existing evidence on fluconazole treatment for CS is primarily limited to case reports, this study aims to evaluate the efficacy and safety of fluconazole in the first relatively large cohort of CS patients.

Patients and methods

Patients

This retrospective study analyzed a total of 22 patients with CS, including 12 cases of CD, 3 cases of ACS, and 7 cases of EAS. For patients who presented with Cushingoid appearance, a 1-mg overnight low-dose dexamethasone suppression test (LDDST) was performed. If the result revealed positive (>1.8 mcg/dL), further surveys were arranged. CS was diagnosed based on 24-h UFC levels (>three times the upper limit of normal range (ULN)), and 2-day LDDST (>1.8 mcg/dL). Once the biochemical diagnosis of CS was confirmed, morning plasma ACTH and cortisol levels were measured to differentiate between ACTH-dependent and ACTH-independent CS. Low ACTH levels (<5 pg/dL) accompanied by elevated cortisol concentrations (>15 mcg/dL) indicated an adrenal origin, consistent with ACTH-independent CS. In such cases, a computed tomography or magnetic resonance imaging scan was performed to evaluate for adrenal masses. If ACTH levels were greater than 5 pg/dL, ACTH-dependent CS was suspected. To identify the source of excessive ACTH secretion—either CD or EAS—further diagnostic testing was conducted, including high-dose dexamethasone suppression test (UFC suppresses >90%, or plasma cortisol suppresses > 50% from baseline, CD is most likely), or corticotropin-releasing hormone (CRH) stimulation test, or desmopressin (DDAVP) stimulation test (ACTH increases >50% and plasma cortisol increases >20% suggests CD), or inferior petrosal sinus sampling (central-to-peripheral ACTH ratio ⩾2 or ⩾3 post CRH or DDAVP suggests CD), or pituitary magnetic resonance imaging (pituitary mass >6 mm suggests CD).1,26 If the patient’s condition allowed, one or more of these tests were performed, and the final diagnosis was made based on a comprehensive interpretation of the combined results.

Methods

After the approval of the Institutional Review Board at Taipei Veterans General Hospital (IRB No. 2021-04-003CC), we conducted a retrospective study, which was waived for informed consent at Taipei Veterans General Hospital. Sample size calculations were not conducted because this was a retrospective study. We surveyed patients diagnosed with CS (CD, ACS, or EAS) who received fluconazole treatment at Taipei Veterans General Hospital in Taipei, Taiwan, between January 1st, 2015, and August 31st, 2020. Fluconazole was administered orally at doses ranging from 112.5 to 450 mg daily, with treatment durations ranging from 2 weeks to over 5 years (Fluconazole was not administered for other treatment purposes, such as infection). The inclusion criteria consisted of a confirmed diagnosis of CS (whether newly diagnosed, persistent, or recurrent) and a history of fluconazole treatment for CS. The exclusion criteria included patients who were not regularly followed up after fluconazole treatment or who lacked complete 24-h UFC data both before and after treatment with fluconazole.
The following data before initiation of treatment were collected: age, gender, body mass index (BMI), alcohol consumption, history of diabetes mellitus, history of chronic hepatitis, baseline 24-hour urinary free cortisol (24-h UFC) levels (reference range: 20–80 µg/day, measured by chemiluminescent immunoassay), morning serum cortisol, morning adrenocorticotropic hormone (ACTH) levels (measured by chemiluminescent immunoassay), and liver function index (alanine aminotransferase (ALT)). In addition, the history of surgery for pituitary tumor or ectopic lesion resection, as well as any other medical treatments apart from fluconazole, was recorded.
24-Hour UFC levels were monitored every 1 to 3 months after initiating fluconazole treatment. The average values from two 24-h UFC measurements (first and second data points within the first 4 months) were used to assess treatment efficacy. For the evaluation of hepatic safety, the maximum ALT level recorded within 6 months after starting fluconazole treatment was compared to the baseline ALT. In this study, we defined ALT levels exceeding three times the ULN as noteworthy liver injury.

Statistical analysis

Data are presented as mean ± standard deviation (SD) or as numbers (percentage), as appropriate. Due to the small sample sizes in some groups and the non-normal distribution of several variables, nonparametric statistical methods were employed to analyze the relationships between variables. Differences between groups were analyzed using the Pearson Chi-squared test, Student’s t-test, or one-way analysis of variance (ANOVA), as appropriate. A p-value less than 0.05 from the ANOVA was considered statistically significant, indicating that at least one group differed significantly from the others. All statistical analyses were performed using the SPSS software package (version 26; IBM Corporation, Armonk, NY, USA).

Results

The baseline characteristics of the patients are summarized in Table 1. No significant differences were found among the etiologies of CS in terms of age, gender, or history of diabetes (p = 0.271, p = 0.253, and p = 0.667, respectively). Cortisol (8AM), ACTH (8AM), and 24-h UFC levels were significantly higher in the EAS group (p = 0.041, p = 0.005, and p = 0.043, respectively) at diagnosis. BMI was significantly lower in the EAS group compared to the other groups (p = 0.002). Alcohol consumption and history of chronic hepatitis, both common causes of liver injury in Taiwan, showed no significant differences among the groups (p = 0.325 and p = 0.765, respectively). Regarding surgical history, eight patients (66.7%) in the CD group had undergone pituitary surgery, while no patients in the ACS group had a history of surgery. In the EAS group, two patients (28.6%) had undergone surgery: one had an anterior mediastinal tumor removal and left upper lung wedge resection, and the other had a suprasellar tumor resection (p = 0.064).

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Table 1. The baseline characteristics of patients with Cushing’s syndrome.
Characteristics All (n = 22) CD (n = 12) ACS (n = 3) EAS (n = 7) p-Value*
Age (years) 54.5 ± 15.5 49.8 ± 15.3 56.0 ± 12.5 61.9 ± 15.9 0.271
Female, n (%) 17 (77.3) 10 (83.3) 3 (100) 4 (57.1) 0.253
Body mass index (kg/m2) 25.1 ± 4.3 27.4 ± 2.8 27.2 ± 1.3 21.0 ± 3.8 0.002
Cortisol (8AM) (µg/dL) 26.7 ± 18.7 21.5 ± 8.6 14.0 ± 4.0 40.3 ± 26.1 0.041
ACTH (8AM) (pg/mL) 151.9 ± 172.1 98.0 ± 63.1 6.4 ± 0.9 306.5 ± 228.3 0.005
24-h UFC (µg/day) 760.5 ± 1387.8 277.9 ± 125.6 107.6 ± 78.2 1891.2 ± 2155.7 0.043
Alcohol consumption, n (%)a 1 (4.5) 0 (0.0) 0 (0.0) 1 (14.3) 0.325
History of diabetes, n (%) 11 (50.0) 5 (41.7) 2 (66.7) 4 (57.1) 0.667
History of chronic hepatitis, n (%) 2 (9.1) 1 (8.3) 0 (0.0) 1 (14.3) 0.765
Surgery history, n (%)b 10 (45.5) 8 (66.7) 0 (0.0) 2 (28.6) 0.064
Using other medication, n (%) 10 (45.5) 4 (33.3) 0 (0.0) 6 (85.7) 0.020
 Etomidate, n (%) 8 (36.4) 3 (25.0) 0 (0.0) 5 (71.4) 0.047
 Metyrapone, n (%) 1 (4.5) 0 (0.0) 0 (0.0) 1 (14.3) 0.325
 Pasireotide, n (%) 1 (4.5) 1 (8.3) 0 (0.0) 0 (0.0) 0.646
Data are expressed as mean ± SD or number (percentage). 24-h UFC (reference range: 20–80 µg/day)
a
Alcohol consumption was defined as men consume more than two alcoholic equivalents per day, while women consume more than one alcoholic equivalent, with one alcoholic equivalent being 10 g of alcohol.
b
Surgery for pituitary tumor or ectopic lesions.
*
p-Value <0.05 from ANOVA, indicating at least one group differed significantly from the others.
24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; ACTH, adrenocorticotropic hormone; CD, Cushing’s disease; EAS, ectopic ACTH syndrome; SD, standard deviation.
During fluconazole treatment, significant differences were observed among the three groups concerning the use of additional medications (p = 0.020). In the CD group, three patients (25%) received etomidate and one patient (8.3%) received pasireotide. No patients in the ACS group received other medications. In the EAS group, five patients (71.4%) received etomidate, and one patient (14.3%) received metyrapone. For patients treated with etomidate, the duration was limited to a few days before switching to fluconazole. One patient received concomitant therapy with pasireotide and fluconazole.
Table 2 presents the laboratory results for hormonal parameters and ALT levels before and after fluconazole treatment. Prior to treatment, there were no statistically significant differences among the three groups in terms of serum cortisol (8AM), ACTH (8AM), 24-h UFC, and ALT levels (p = 0.739, p = 0.239, p = 0.157, and p = 0.738, respectively).

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Table 2. The laboratory exams of hormonal parameters and ALT before and after fluconazole treatment.
Variable All (n = 22) CD (n = 12) ACS (n = 3) EAS (n = 7) p-Value
Cortisol (8AM) before fluconazole (µg/dL) 18.3 ± 10.8 17.8 ± 11.6 14.8 ± 3.4 20.6 ± 12.1 0.739
ACTH (8AM) before fluconazole (pg/mL) 104.5 ± 122.2 101.9 ± 64.7 6.4 ± 0.9 150.7 ± 188.4 0.239
ACTH (8AM) after fluconazole treatment (pg/mL)a 75.7 ± 87.0 65.7 ± 44.3 6.8 ± 1.4 122.4 ± 133.4 0.020
24-h UFC before fluconazole (µg/day) 717.6 ± 1219.4 443.1 ± 391.5 139.2 ± 95.7 1436.0 ± 2000.0 0.157
24-h UFC after fluconazole (µg/day)b 184.1 ± 171.8 132.0 ± 117.3 53.3 ± 30.8 321.9 ± 198.8 0.017
Decline percentage (%) of 24-h UFC after fluconazole 39.2% ± 48.2% 50.2% ± 37.4% 55.8% ± 27.3% 13.1% ± 64.4% 0.228
Normalization of 24-h UFC after fluconazole, n (%) 6 (27.3) 4 (33.3) 2 (66.7) 0 (0.0) 0.074
24-h UFC <1.5× ULN after fluconazole, n (%) 10 (45.5) 6 (50.0) 3 (100.0) 1 (14.3) 0.040
ALT before fluconazole (U/L) 38.5 ± 28.4 42.4 ± 32.6 38.0 ± 14.1 30.8 ± 24.2 0.738
ALT after fluconazole (U/L)c 56.5 ± 47.8 76.7 ± 54.3 28.7 ± 12.7 28.8 ± 13.6 0.091
ALT >ULN after fluconazole, n (%)c 12 (54.5) 8 (66.7) 2 (66.7) 2 (28.6) 0.247
ALT >3× ULN after fluconazole, n (%)c 4 (18.2) 4 (33.3) 0 (0.0) 0 (0.0) 0.130
Data are expressed as mean ± SD or number (percentage). ALT (reference range: male: <41 U/L; female: <33 U/L). 24-h UFC (reference range: 20–80 µg/day).
a
The average of first and second ACTH after fluconazole treatment.
b
The average of first and second 24-h UFC after fluconazole treatment.
c
ALT: maximum in following 6 months.
1.
5×, 1.5 times upper limit of normal range; 3×, 3 times upper limit of normal range; 24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; ACTH, adrenocorticotropic hormone; ALT, alanine aminotransferase; CD, Cushing’s disease; EAS, ectopic ACTH syndrome; ULN, upper limit of normal range.
Twenty-four-hour UFC levels after fluconazole treatment were monitored over the following months. The average values of the first and second 24-h UFC measurements showed significant declines compared to baseline levels as: decreased from 717.6 ± 1219.4 to 184.1 ± 171.8 µg/day in all patients (p = 0.035), decreased form 443.1 ± 391.5 to 132.0 ± 117.3 µg/day in the CD group (p = 0.009), decreased from 139.2 ± 95.7 to 53.3 ± 30.8 µg/day in the ACS group (p = 0.243), and decreased from 1436.0 ± 2000.0 to 321.9 ± 198.8 µg/day in the EAS group (p = 0.147). The percentage decline in 24-h UFC levels following treatment demonstrated a significant reduction as follows: 39.2% ± 48.2% in all patients, 50.2% ± 37.4% in the CD group, 55.8% ± 27.3% in the ACS group, and 13.1% ± 64.4% in the EAS group (p = 0.228) (Table 2 and Figure 1 illustrate these changes).

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Figure 1. 24-h UFC before and after fluconazole treatment in patients with Cushing’s syndrome.
24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; CD, Cushing’s disease; EAS, ectopic ACTH syndrome.
Normalization of 24-h UFC levels (reference range 20–80 μg/day) was observed in six patients (27.3%) across three groups: four patients (33.3%) in the CD group, two patients (66.7%) in the ACS group, and no patients in the EAS group (p = 0.074). Additionally, 10 cases (45.5%) across 3 groups, 6 cases (50%) in the CD group, 3 cases (100%) in the ACS group, and 1 case (14.3%) in the EAS group showed 24-h UFC less than 1.5 times the ULN (p = 0.040). In this study, 10 patients (45.5%) received fluconazole treatment for more than 1 year. Among these, five patients (50.0%) experienced a recurrence of hypercortisolism, with 24-h UFC levels exceeding 1.5 times the ULN within 3–12 months after treatment with fluconazole.
For hepatic safety assessment, the maximum ALT levels within 6 months of fluconazole treatment were analyzed and are presented in Table 2. Compared to baseline levels, ALT increased from 38.5 ± 28.4 to 56.5 ± 47.8 U/L in all patients (p = 0.090), and increased from 42.4 ± 32.6 to 76.7 ± 54.3 U/L in the CD group (p = 0.047). (Table 2 and Figure 2 illustrate these changes). After fluconazole treatment, 12 cases (54.5%) of all patients, 8 cases (66.7%) in the CD group, 2 cases (66.7%) in the ACS group, and 2 cases (28.6%) in the EAS group revealed ALT levels exceeded the ULN (p = 0.247). Additionally, 4 cases (18.2%) of all patients, 4 cases (33.3%) in the CD group, and no cases in the ACS and EAS groups revealed ALT levels more than three times the ULN (p = 0.130).

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Figure 2. ALT before and after fluconazole treatment in patients with Cushing’s syndrome.
ACS, adrenal Cushing’s syndrome; ALT, Alanine aminotransferase; CD, Cushing’s disease; EAS, ectopic ACTH syndrome.

Discussion

To date, our study is the largest retrospective analysis providing the evaluation of the clinical efficacy and safety of fluconazole treatment in patients with CS. The major findings demonstrated that 24-h UFC levels significantly decreased across all groups after fluconazole treatment, with more than 50% reduction in both the CD and ACS groups. However, the EAS group showed only a 13.1% decline in 24-h UFC levels, although with a large interval (SD 64.4%) and small case numbers in this group, indicating greater variability in response and heterogeneity in this group. Regarding hepatic safety, while ALT levels increased after fluconazole treatment, particularly in the CD group, the changes were not statistically significant in other groups. The significant increase in ALT levels (42.4 ± 32.6 to 76.7 ± 54.3 U/L) in the CD group, but mild—less than two times ULN, may also be related to the high variability (large SD). Importantly, there was no severe hepatotoxicity in the study, because only four patients (18.2%) revealed ALT levels more than three times the ULN.
Fluconazole can be administered either intravenously or orally. Several case reports highlight its effectiveness and safety: Teng Chai et al. reported successful long-term treatment of recurrent CD in a 50-year-old woman using fluconazole with cabergoline, resulting in significant clinical and biochemical improvement without adverse effects.27 Zhao et al. reported that fluconazole normalized cortisol levels pre-surgery in a 48-year-old woman with CD and pulmonary cryptococcal infection.28 In another case, fluconazole with low-dose metyrapone normalized cortisol levels for 6 months in a 61-year-old woman with recurrent CD prior to radiotherapy.29 Riedl et al. demonstrated fluconazole’s efficacy and safety in an 83-year-old woman with CS from adrenocortical carcinoma.18 Canteros et al. reported effective cortisol reduction with mild side effects from fluconazole in a 39-year-old woman with EAS, enabling successful bilateral adrenalectomy.30 An 80-year-old woman with CS of unknown origin also showed effective cortisol control with fluconazole.31 Two of these six cases suffered from hepatic dysfunction at fluconazole doses over 400 mg/day; however, liver enzyme levels returned to normal after dosage reduction. A secondary analysis of a dose-adjustment trial for fluconazole in the treatment of invasive mycoses examined 85 patients who received prolonged high-dose treatment. For these cases, 27% experienced clinical symptoms, and 42% exhibited abnormal laboratory results. The common side effects were <5% of anorexia, hair loss, headache, and 12% of eosinophilia. However, these adverse effects did not progress, leading the study to conclude that fluconazole is well tolerated and generally safe.32
Ketoconazole has been used to treat hypercortisolism by inhibiting CYP450 enzymes, specifically 11β-hydroxylase and 17α-hydroxylase, and fluconazole has similar properties.17 Previous studies suggest that fluconazole is less potent in inhibiting glucocorticoid production compared to ketoconazole, with varying effects; however, cortisol reduction with fluconazole use has been confirmed.17,18 Unlike ketoconazole, which is extensively metabolized in the liver and associated with significant hepatotoxicity, fluconazole is minimally metabolized in the liver.16 According to the FDA, the risk of serious liver injury from ketoconazole is higher than with other azole agents.33 In our study of 22 patients, fluconazole was well tolerated, with no significant elevations in liver enzyme levels observed during 6 months of treatment. These findings suggest that fluconazole may represent a safer alternative to ketoconazole for the treatment of CS.
In five studies involving 310 patients with CS treated with an average dose of 673.9 mg/day of ketoconazole over an average of 12.6 months, normalization of urinary free cortisol was achieved in 64.3% of patients (median 50%, range 44.7%–92.9%). However, 23% of initially responsive patients eventually lost biochemical control.34 Another retrospective study of 200 patients with CD receiving ketoconazole at an average dose of 600 mg/day found that 64.7% of patients treated for over 2 years achieved UFC normalization, while 15.4% experienced recurrence, or “escape,” from cortisol control.15 In our study, 10 patients (45.5%) received fluconazole treatment for over 1 year, with 5 of these patients (50%) showing 24-h UFC levels not exceeding 1.5 times the ULN in the following 3–12 months (under control without escape). The long-term control of hypercortisolism with fluconazole appears to be less effective than with ketoconazole. However, this could be attributed to the small sample size in our study.
Table 1 shows baseline morning ACTH levels at diagnosis for all patients before any treatment, highlighting a statistically significant difference. In comparison, Table 2 presents morning ACTH levels prior to fluconazole treatment, where no statistical difference was observed. This is likely due to some patients in the CD and EAS groups having previously undergone surgery or received other medical treatments, which might reduce the tumor burden and the levels of ACTH.
Recent studies suggest that levoketoconazole demonstrates good efficacy and safety in the management of CS.2325 However, no head-to-head trials have been conducted to compare ketoconazole, levoketoconazole, and fluconazole directly. Therefore, further clinical trials are warranted to provide clearer insights into the comparative efficacy and safety of these therapeutic options in CS.
The limitations of this study include its retrospective design, which lacked comparator groups, and the small sample sizes in the ACS and EAS groups. In addition, patients were treated by different physicians, each using their own clinical judgment, without standardized follow-up protocols, making some data difficult to collect and analyze. The heterogeneity in dosing regimens also posed challenges in assessing the dose-response relationship. Besides, the relationship between the timing and dosages of other medications (etomidate, pasireotide, and metyrapone) and their effects on laboratory findings is challenging to analyze due to the limited number of cases. There were no statistically significant differences in ACTH level changes before and after fluconazole treatment among the three groups. This may be a limitation, as we only monitored the first and second ACTH measurements following fluconazole treatment. Further investigations with longer monitoring of ACTH levels may be necessary. The study’s observation period was approximately 5.5 years, but further investigation is required to confirm the long-term efficacy and safety of fluconazole treatment in CS.

Conclusion

This study demonstrates that fluconazole is effective in treating patients with CS, as evidenced by a significant reduction in 24-h UFC levels. Moreover, fluconazole was generally well tolerated, with a minimal risk of liver injury, suggesting it may be an effective and safe option for managing hypercortisolism in CS.

Acknowledgments

The authors thank the Medical Sciences & Technology Building of Taipei Veterans General Hospital for providing experimental space and facilities.

ORCID iD

Footnotes

Ethics approval and consent to participate This study was approved by the Institutional Review Board at Taipei Veterans General Hospital (IRB No. 2021-04-003CC). Due to the retrospective nature of this study, informed patient consent was waived.

Consent for publication Not applicable.

Author contributions

Tang-Yi Liao: Data curation; Formal analysis; Writing – original draft.
Yi-Chun Lin: Data curation; Writing – review & editing.
Chun-Jui Huang: Data curation; Writing – review & editing.
Chii-Min Hwu: Conceptualization; Data curation.
Liang-Yu Lin: Conceptualization; Data curation; Funding acquisition; Investigation; Methodology; Writing – review & editing.

Funding The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This study was partly supported by research grants (Grant Nos. V108C-197, V109C-179, V110C-198, V111D62-002-MY3, V112C-183, V113C-094, V114C-116, and V114D77-002-MY3-1) to L.Y.L. from Taipei Veterans General Hospital, Taipei, Taiwan and MOST 111-2314-B-075-040-MY2 to L.Y.L. from National Science and Technology Council, Taiwan. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests The authors declare that there is no conflict of interest.

Availability of data and materials The data and materials generated and analyzed in the study are available from the corresponding author on reasonable request.

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9. Assié G, Bahurel H, Coste J, et al. Corticotroph tumor progression after adrenalectomy in Cushing’s disease: a reappraisal of Nelson’s Syndrome. J Clin Endocrinol Metab 2007; 92(1): 172–179.
10. Schteingart DE. Drugs in the medical treatment of Cushing’s syndrome. Expert Opin Emerg Drugs 2009; 14(4): 661–671.
11. Nieman LK. Medical therapy of Cushing’s disease. Pituitary 2002; 5(2): 77–82.
12. Valassi E, Franz H, Brue T, et al. Preoperative medical treatment in Cushing’s syndrome: frequency of use and its impact on postoperative assessment: data from ERCUSYN. Eur J Endocrinol 2018; 178(4): 399–409.
13. Varlamov EV, Vila G, Fleseriu M. Perioperative management of a patient with Cushing Disease. J Endocr Soc 2022; 6(3): bvac010.
14. Pivonello R, De Martino MC, De Leo M, et al. Cushing’s syndrome. Endocrinol Metab Clin North Am 2008; 37(1): 135–ix.
15. Castinetti F, Guignat L, Giraud P, et al. Ketoconazole in Cushing’s disease: is it worth a try? J Clin Endocrinol Metab 2014; 99(5): 1623–1630.
16. Como JA, Dismukes WE. Oral azole drugs as systemic antifungal therapy. N Engl J Med 1994; 330(4): 263–272.
17. van der Pas R, Hofland LJ, Hofland J, et al. Fluconazole inhibits human adrenocortical steroidogenesis in vitro. J Endocrinol 2012; 215(3): 403–412.
18. Riedl M, Maier C, Zettinig G, et al. Long term control of hypercortisolism with fluconazole: case report and in vitro studies. Eur J Endocrinol 2006; 154(4): 519–524.
19. Albert SG, DeLeon MJ, Silverberg AB. Possible association between high-dose fluconazole and adrenal insufficiency in critically ill patients. Crit Care Med 2001; 29(3): 668–670.
20. Santhana Krishnan SG, Cobbs RK. Reversible acute adrenal insufficiency caused by fluconazole in a critically ill patient. Postgrad Med J 2006; 82(971): e23.
21. García Rodríguez LA, Duque A, Castellsague J, et al. A cohort study on the risk of acute liver injury among users of ketoconazole and other antifungal drugs. Br J Clin Pharmacol 1999; 48(6): 847–852.
22. Creemers SG, Feelders RA, De Jong FH, et al. Levoketoconazole, the 2S,4R enantiomer of ketoconazole, a new steroidogenesis inhibitor for Cushing’s syndrome treatment. J Clin Endocrinol Metabol 2021; 106: 1618–1630.
23. Fleseriu M, Pivonello R, Elenkova A, et al. Efficacy and safety of levoketoconazole in the treatment of endogenous Cushing’s syndrome (SONICS): a phase 3, multicentre, open-label, single-arm trial. Lancet Diabet Endocrinol 2019; 7: 855–865.
24. Pivonello R, Zacharieva S, Elenkova A, et al. Levoketoconazole in the treatment of patients with endogenous Cushing’s syndrome: a double-blind, placebo-controlled, randomized withdrawal study (LOGICS). Pituitary 2022; 25: 911–926.
25. Patra S, Dutta D, Nagendra L, et al. Efficacy and safety of levoketoconazole in managing Cushing’s syndrome: a systematic review. Indian J Endocr Metab 2024; 28: 343–349.
26. Sharma ST; AACE Adrenal Scientific Committee. An individualized approach to the evaluation of Cushing Syndrome. Endocr Pract 2017; 23(6): 726–737.
27. Teng Chai S, Haydar Ali Tajuddin A, Wahab NA, et al. Fluconazole as a safe and effective alternative to ketoconazole in controlling hypercortisolism of recurrent Cushing’s disease: a case report. Int J Endocrinol Metab 2018; 16(3): e65233.
28. Zhao Y, Liang W, Cai F, et al. Fluconazole for hypercortisolism in Cushing’s disease: a case report and literature review. Front Endocrinol (Lausanne) 2020; 11: 608886.
29. Burns K, Christie-David D, Gunton JE. Fluconazole in the treatment of Cushing’s disease. Endocrinol Diabetes Metab Case Rep 2016; 2016: 150115.
30. Canteros TM, De Miguel V, Fainstein-Day P. Fluconazole treatment in severe ectopic Cushing syndrome. Endocrinol Diabetes Metab Case Rep 2019; 2019(1): 19-0020.
31. Schwetz V, Aberer F, Stiegler C, et al. Fluconazole and acetazolamide in the treatment of ectopic Cushing’s syndrome with severe metabolic alkalosis. Endocrinol Diabetes Metab Case Rep 2015; 2015:1 50027.
32. Stevens DA, Diaz M, Negroni R, et al. Safety evaluation of chronic fluconazole therapy. Fluconazole Pan-American Study Group. Chemotherapy 1997;43(5):371–377.
33. Greenblatt HK, Greenblatt DJ. Liver injury associated with ketoconazole: review of the published evidence. J Clin Pharmacol 2014; 54(12): 1321–1329.
34. Pivonello R, De Leo M, Cozzolino A, et al. The treatment of Cushing’s disease. Endocr Rev 2015; 36(4): 385–486.

 

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Clinical Efficacy and Safety of Fluconazole Treatment in Patients with Cushing’s Syndrome

Posted on November 11, 2025 by MaryO

Abstract

Background:

Ketoconazole is effective for treating Cushing’s syndrome (CS) but its use is limited by the risk of hepatotoxicity. Fluconazole, with similar antifungal properties, is being investigated as a potentially safer alternative for managing CS. This study aims to evaluate the efficacy and safety of fluconazole in patients with CS.

Methods:

This retrospective study evaluated a total of 22 patients with CS, including 12 with Cushing’s disease (CD), 3 with adrenal Cushing’s syndrome (ACS), and 7 with ectopic Adrenocorticotropic hormone (ACTH) syndrome. Fluconazole was administered orally, ranging from 112.5 to 450 mg daily, with the duration varying from 2 weeks to over 5 years. The efficacy of fluconazole was assessed by changes in 24-hour urinary free cortisol (24-h UFC) levels. Additionally, hepatic safety was assessed by monitoring changes in alanine aminotransferase (ALT) levels.

Results:

Following fluconazole treatment, 24-h UFC levels significantly decreased from 717.6 ± 1219.4 to 184.1 ± 171.8 µg/day (p = 0.035). ALT levels showed an increase from 38.5 ± 28.4 to 56.5 ± 47.8 U/L, though this change was not statistically significant (p = 0.090). ALT levels exceeding the upper limit of normal range (ULN) were observed in 12 patients (54.5%), with only 4 patients (18.2%) showing ALT levels more than three times the ULN. Out of 10 patients who received treatment for over 1 year, 5 patients (50.0%) experienced a recurrence, with 24-h UFC levels more than 1.5 times the ULN within 3 to 12 months after fluconazole treatment.

Conclusion:

Fluconazole effectively reduces hypercortisolism in patients with CS without significant liver injury, suggesting it as a viable therapeutic option for CS. While some cases have shown treatment escape, more studies are required to confirm the long-term efficacy.

Introduction

Cushing’s syndrome (CS) is a complex endocrine disorder characterized by excessive cortisol production, leading to complications such as insulin-resistant hyperglycemia, muscle weakness (proximal myopathy), osteoporosis, cardiovascular diseases, and neuropsychiatric disorders.1 The primary causes of CS include pituitary ACTH-secreting tumor (Cushing’s disease (CD), adrenal neoplasm (adrenal Cushing’s syndrome (ACS)), or nonpituitary ACTH-secreting tumor (ectopic ACTH syndrome (EAS)). The most common cause is CD. If left untreated, CS patients face a 3.8 to 5-fold increase in mortality compared to the general population.2,3 The first-line treatment for CS involves surgical removal of the offending tumor(s). In CD cases, transsphenoidal pituitary surgery achieves success rates between 65% and 90% for microadenomas. However, complete resection can be challenging, especially with macroadenomas, leading to recurrence or persistent hypercortisolism in approximately 20%–25% of patients.4 Alternative treatments include pituitary stereotactic radiosurgery, which effectively controls cortisol levels over several years but carries potential adverse effects.5,6 For EAS patients, managing hypercortisolism while awaiting definitive treatments like surgery is critical.7 Bilateral adrenalectomy offers immediate control over cortisol excess but necessitates lifelong steroid replacement therapy, impacting the quality of life.8 In addition, some corticotropic pituitary tumors may progress post-surgery, requiring further targeted interventions.9
However, some patients were not candidates for surgery due to factors such as advanced age, personal preference against surgery, or the absence of a definitive culprit lesion. When surgery fails to fully correct hypercortisolism (i.e., when 24-h UFC levels do not decrease or even progressively rise in the weeks to months following surgery, indicating persistence or relapse), pharmacotherapy can be employed to reduce cortisol overproduction and enhance clinical outcomes.10,11 In addition, it could be administered before surgical intervention to reduce perioperative complications.12,13 Various medications are used in the treatment of CS, including adrenal steroidogenesis inhibitors, dopamine agonists, somatostatin analogs, or glucocorticoid receptor antagonist.4,14
Ketoconazole, an imidazole fungicide and adrenal steroidogenesis inhibitor, has long been off-label used as the first-line medication for patients with CS who cannot undergo surgery or for whom surgery is non-curative. It reduces cortisol synthesis by inhibiting the side-chain cleavage enzymes 11β-hydroxylase and 17,20-lyase.10 Effective doses range from 200 to 1200 mg daily, but gradual dose increases may be necessary due to the potential for escape from cortisol inhibition.10,15 Ketoconazole is extensively metabolized in the liver, leading to an increased risk of hepatotoxicity.16 In 2013, the U.S. Food and Drug Administration (FDA) issued warnings about the potentially life-threatening liver toxicity associated with ketoconazole. As a result, ketoconazole is no longer available in many regions.
Fluconazole, another azole antifungal agent, has been explored as an alternative treatment for CS. It inhibits adrenal steroidogenesis through the CYP450 pathway, and the effects have been confirmed in vitro, using primary cultures of human adrenocortical tissues and two adrenocortical carcinoma cell lines. The effects were mainly observed in enzymes 11β-hydroxylase and 17α-hydroxylase, which are key in cortisol synthesis.17 Another study also demonstrated that fluconazole inhibits glucocorticoid production in vitro in the adrenal adenoma cell line Y-1.18 Case reports have also documented adrenal insufficiency in patients with severe comorbidities treated with fluconazole, suggesting its potential for managing hypercortisolism.19,20 Fluconazole is characterized by its small molecular size and low lipophilicity. It is minimally metabolized, with approximately 80% excreted unchanged in the urine.16 This contributes to its lower incidence of adverse effects, particularly liver injury. In a cohort study estimating the risk of clinical acute liver injury among users of oral antifungals (fluconazole, griseofulvin, itraconazole, ketoconazole, or terbinafine) in the general population from the General Practice Research Database in the United Kingdom, fluconazole was associated with a lower relative risk of acute liver injury compared to other agents.21
Levoketoconazole, the 2S, 4R enantiomer of ketoconazole, provides enhanced enzyme inhibition with greater therapeutic efficacy and fewer side effects compared to ketoconazole.22 The main challenge with using levoketoconazole in the treatment of CS is the limited data from Randomized controlled trials (RCTs). To date, there are only two prospective studies (SONICS and LOGICS) and one systematic review that evaluate the efficacy and safety of levoketoconazole in this context.2325
Given that existing evidence on fluconazole treatment for CS is primarily limited to case reports, this study aims to evaluate the efficacy and safety of fluconazole in the first relatively large cohort of CS patients.

Patients and methods

Patients

This retrospective study analyzed a total of 22 patients with CS, including 12 cases of CD, 3 cases of ACS, and 7 cases of EAS. For patients who presented with Cushingoid appearance, a 1-mg overnight low-dose dexamethasone suppression test (LDDST) was performed. If the result revealed positive (>1.8 mcg/dL), further surveys were arranged. CS was diagnosed based on 24-h UFC levels (>three times the upper limit of normal range (ULN)), and 2-day LDDST (>1.8 mcg/dL). Once the biochemical diagnosis of CS was confirmed, morning plasma ACTH and cortisol levels were measured to differentiate between ACTH-dependent and ACTH-independent CS. Low ACTH levels (<5 pg/dL) accompanied by elevated cortisol concentrations (>15 mcg/dL) indicated an adrenal origin, consistent with ACTH-independent CS. In such cases, a computed tomography or magnetic resonance imaging scan was performed to evaluate for adrenal masses. If ACTH levels were greater than 5 pg/dL, ACTH-dependent CS was suspected. To identify the source of excessive ACTH secretion—either CD or EAS—further diagnostic testing was conducted, including high-dose dexamethasone suppression test (UFC suppresses >90%, or plasma cortisol suppresses > 50% from baseline, CD is most likely), or corticotropin-releasing hormone (CRH) stimulation test, or desmopressin (DDAVP) stimulation test (ACTH increases >50% and plasma cortisol increases >20% suggests CD), or inferior petrosal sinus sampling (central-to-peripheral ACTH ratio ⩾2 or ⩾3 post CRH or DDAVP suggests CD), or pituitary magnetic resonance imaging (pituitary mass >6 mm suggests CD).1,26 If the patient’s condition allowed, one or more of these tests were performed, and the final diagnosis was made based on a comprehensive interpretation of the combined results.

Methods

After the approval of the Institutional Review Board at Taipei Veterans General Hospital (IRB No. 2021-04-003CC), we conducted a retrospective study, which was waived for informed consent at Taipei Veterans General Hospital. Sample size calculations were not conducted because this was a retrospective study. We surveyed patients diagnosed with CS (CD, ACS, or EAS) who received fluconazole treatment at Taipei Veterans General Hospital in Taipei, Taiwan, between January 1st, 2015, and August 31st, 2020. Fluconazole was administered orally at doses ranging from 112.5 to 450 mg daily, with treatment durations ranging from 2 weeks to over 5 years (Fluconazole was not administered for other treatment purposes, such as infection). The inclusion criteria consisted of a confirmed diagnosis of CS (whether newly diagnosed, persistent, or recurrent) and a history of fluconazole treatment for CS. The exclusion criteria included patients who were not regularly followed up after fluconazole treatment or who lacked complete 24-h UFC data both before and after treatment with fluconazole.
The following data before initiation of treatment were collected: age, gender, body mass index (BMI), alcohol consumption, history of diabetes mellitus, history of chronic hepatitis, baseline 24-hour urinary free cortisol (24-h UFC) levels (reference range: 20–80 µg/day, measured by chemiluminescent immunoassay), morning serum cortisol, morning adrenocorticotropic hormone (ACTH) levels (measured by chemiluminescent immunoassay), and liver function index (alanine aminotransferase (ALT)). In addition, the history of surgery for pituitary tumor or ectopic lesion resection, as well as any other medical treatments apart from fluconazole, was recorded.
24-Hour UFC levels were monitored every 1 to 3 months after initiating fluconazole treatment. The average values from two 24-h UFC measurements (first and second data points within the first 4 months) were used to assess treatment efficacy. For the evaluation of hepatic safety, the maximum ALT level recorded within 6 months after starting fluconazole treatment was compared to the baseline ALT. In this study, we defined ALT levels exceeding three times the ULN as noteworthy liver injury.

Statistical analysis

Data are presented as mean ± standard deviation (SD) or as numbers (percentage), as appropriate. Due to the small sample sizes in some groups and the non-normal distribution of several variables, nonparametric statistical methods were employed to analyze the relationships between variables. Differences between groups were analyzed using the Pearson Chi-squared test, Student’s t-test, or one-way analysis of variance (ANOVA), as appropriate. A p-value less than 0.05 from the ANOVA was considered statistically significant, indicating that at least one group differed significantly from the others. All statistical analyses were performed using the SPSS software package (version 26; IBM Corporation, Armonk, NY, USA).

Results

The baseline characteristics of the patients are summarized in Table 1. No significant differences were found among the etiologies of CS in terms of age, gender, or history of diabetes (p = 0.271, p = 0.253, and p = 0.667, respectively). Cortisol (8AM), ACTH (8AM), and 24-h UFC levels were significantly higher in the EAS group (p = 0.041, p = 0.005, and p = 0.043, respectively) at diagnosis. BMI was significantly lower in the EAS group compared to the other groups (p = 0.002). Alcohol consumption and history of chronic hepatitis, both common causes of liver injury in Taiwan, showed no significant differences among the groups (p = 0.325 and p = 0.765, respectively). Regarding surgical history, eight patients (66.7%) in the CD group had undergone pituitary surgery, while no patients in the ACS group had a history of surgery. In the EAS group, two patients (28.6%) had undergone surgery: one had an anterior mediastinal tumor removal and left upper lung wedge resection, and the other had a suprasellar tumor resection (p = 0.064).
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Table 1. The baseline characteristics of patients with Cushing’s syndrome.
Characteristics All (n = 22) CD (n = 12) ACS (n = 3) EAS (n = 7) p-Value*
Age (years) 54.5 ± 15.5 49.8 ± 15.3 56.0 ± 12.5 61.9 ± 15.9 0.271
Female, n (%) 17 (77.3) 10 (83.3) 3 (100) 4 (57.1) 0.253
Body mass index (kg/m2) 25.1 ± 4.3 27.4 ± 2.8 27.2 ± 1.3 21.0 ± 3.8 0.002
Cortisol (8AM) (µg/dL) 26.7 ± 18.7 21.5 ± 8.6 14.0 ± 4.0 40.3 ± 26.1 0.041
ACTH (8AM) (pg/mL) 151.9 ± 172.1 98.0 ± 63.1 6.4 ± 0.9 306.5 ± 228.3 0.005
24-h UFC (µg/day) 760.5 ± 1387.8 277.9 ± 125.6 107.6 ± 78.2 1891.2 ± 2155.7 0.043
Alcohol consumption, n (%)a 1 (4.5) 0 (0.0) 0 (0.0) 1 (14.3) 0.325
History of diabetes, n (%) 11 (50.0) 5 (41.7) 2 (66.7) 4 (57.1) 0.667
History of chronic hepatitis, n (%) 2 (9.1) 1 (8.3) 0 (0.0) 1 (14.3) 0.765
Surgery history, n (%)b 10 (45.5) 8 (66.7) 0 (0.0) 2 (28.6) 0.064
Using other medication, n (%) 10 (45.5) 4 (33.3) 0 (0.0) 6 (85.7) 0.020
 Etomidate, n (%) 8 (36.4) 3 (25.0) 0 (0.0) 5 (71.4) 0.047
 Metyrapone, n (%) 1 (4.5) 0 (0.0) 0 (0.0) 1 (14.3) 0.325
 Pasireotide, n (%) 1 (4.5) 1 (8.3) 0 (0.0) 0 (0.0) 0.646
Data are expressed as mean ± SD or number (percentage). 24-h UFC (reference range: 20–80 µg/day)
a
Alcohol consumption was defined as men consume more than two alcoholic equivalents per day, while women consume more than one alcoholic equivalent, with one alcoholic equivalent being 10 g of alcohol.
b
Surgery for pituitary tumor or ectopic lesions.
*
p-Value <0.05 from ANOVA, indicating at least one group differed significantly from the others.
24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; ACTH, adrenocorticotropic hormone; CD, Cushing’s disease; EAS, ectopic ACTH syndrome; SD, standard deviation.
During fluconazole treatment, significant differences were observed among the three groups concerning the use of additional medications (p = 0.020). In the CD group, three patients (25%) received etomidate and one patient (8.3%) received pasireotide. No patients in the ACS group received other medications. In the EAS group, five patients (71.4%) received etomidate, and one patient (14.3%) received metyrapone. For patients treated with etomidate, the duration was limited to a few days before switching to fluconazole. One patient received concomitant therapy with pasireotide and fluconazole.
Table 2 presents the laboratory results for hormonal parameters and ALT levels before and after fluconazole treatment. Prior to treatment, there were no statistically significant differences among the three groups in terms of serum cortisol (8AM), ACTH (8AM), 24-h UFC, and ALT levels (p = 0.739, p = 0.239, p = 0.157, and p = 0.738, respectively).
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Table 2. The laboratory exams of hormonal parameters and ALT before and after fluconazole treatment.
Variable All (n = 22) CD (n = 12) ACS (n = 3) EAS (n = 7) p-Value
Cortisol (8AM) before fluconazole (µg/dL) 18.3 ± 10.8 17.8 ± 11.6 14.8 ± 3.4 20.6 ± 12.1 0.739
ACTH (8AM) before fluconazole (pg/mL) 104.5 ± 122.2 101.9 ± 64.7 6.4 ± 0.9 150.7 ± 188.4 0.239
ACTH (8AM) after fluconazole treatment (pg/mL)a 75.7 ± 87.0 65.7 ± 44.3 6.8 ± 1.4 122.4 ± 133.4 0.020
24-h UFC before fluconazole (µg/day) 717.6 ± 1219.4 443.1 ± 391.5 139.2 ± 95.7 1436.0 ± 2000.0 0.157
24-h UFC after fluconazole (µg/day)b 184.1 ± 171.8 132.0 ± 117.3 53.3 ± 30.8 321.9 ± 198.8 0.017
Decline percentage (%) of 24-h UFC after fluconazole 39.2% ± 48.2% 50.2% ± 37.4% 55.8% ± 27.3% 13.1% ± 64.4% 0.228
Normalization of 24-h UFC after fluconazole, n (%) 6 (27.3) 4 (33.3) 2 (66.7) 0 (0.0) 0.074
24-h UFC <1.5× ULN after fluconazole, n (%) 10 (45.5) 6 (50.0) 3 (100.0) 1 (14.3) 0.040
ALT before fluconazole (U/L) 38.5 ± 28.4 42.4 ± 32.6 38.0 ± 14.1 30.8 ± 24.2 0.738
ALT after fluconazole (U/L)c 56.5 ± 47.8 76.7 ± 54.3 28.7 ± 12.7 28.8 ± 13.6 0.091
ALT >ULN after fluconazole, n (%)c 12 (54.5) 8 (66.7) 2 (66.7) 2 (28.6) 0.247
ALT >3× ULN after fluconazole, n (%)c 4 (18.2) 4 (33.3) 0 (0.0) 0 (0.0) 0.130
Data are expressed as mean ± SD or number (percentage). ALT (reference range: male: <41 U/L; female: <33 U/L). 24-h UFC (reference range: 20–80 µg/day).
a
The average of first and second ACTH after fluconazole treatment.
b
The average of first and second 24-h UFC after fluconazole treatment.
c
ALT: maximum in following 6 months.
1.
5×, 1.5 times upper limit of normal range; 3×, 3 times upper limit of normal range; 24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; ACTH, adrenocorticotropic hormone; ALT, alanine aminotransferase; CD, Cushing’s disease; EAS, ectopic ACTH syndrome; ULN, upper limit of normal range.
Twenty-four-hour UFC levels after fluconazole treatment were monitored over the following months. The average values of the first and second 24-h UFC measurements showed significant declines compared to baseline levels as: decreased from 717.6 ± 1219.4 to 184.1 ± 171.8 µg/day in all patients (p = 0.035), decreased form 443.1 ± 391.5 to 132.0 ± 117.3 µg/day in the CD group (p = 0.009), decreased from 139.2 ± 95.7 to 53.3 ± 30.8 µg/day in the ACS group (p = 0.243), and decreased from 1436.0 ± 2000.0 to 321.9 ± 198.8 µg/day in the EAS group (p = 0.147). The percentage decline in 24-h UFC levels following treatment demonstrated a significant reduction as follows: 39.2% ± 48.2% in all patients, 50.2% ± 37.4% in the CD group, 55.8% ± 27.3% in the ACS group, and 13.1% ± 64.4% in the EAS group (p = 0.228) (Table 2 and Figure 1 illustrate these changes).
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Figure 1. 24-h UFC before and after fluconazole treatment in patients with Cushing’s syndrome.
24-h UFC, 24-hour urinary free cortisol; ACS, adrenal Cushing’s syndrome; CD, Cushing’s disease; EAS, ectopic ACTH syndrome.
Normalization of 24-h UFC levels (reference range 20–80 μg/day) was observed in six patients (27.3%) across three groups: four patients (33.3%) in the CD group, two patients (66.7%) in the ACS group, and no patients in the EAS group (p = 0.074). Additionally, 10 cases (45.5%) across 3 groups, 6 cases (50%) in the CD group, 3 cases (100%) in the ACS group, and 1 case (14.3%) in the EAS group showed 24-h UFC less than 1.5 times the ULN (p = 0.040). In this study, 10 patients (45.5%) received fluconazole treatment for more than 1 year. Among these, five patients (50.0%) experienced a recurrence of hypercortisolism, with 24-h UFC levels exceeding 1.5 times the ULN within 3–12 months after treatment with fluconazole.
For hepatic safety assessment, the maximum ALT levels within 6 months of fluconazole treatment were analyzed and are presented in Table 2. Compared to baseline levels, ALT increased from 38.5 ± 28.4 to 56.5 ± 47.8 U/L in all patients (p = 0.090), and increased from 42.4 ± 32.6 to 76.7 ± 54.3 U/L in the CD group (p = 0.047). (Table 2 and Figure 2 illustrate these changes). After fluconazole treatment, 12 cases (54.5%) of all patients, 8 cases (66.7%) in the CD group, 2 cases (66.7%) in the ACS group, and 2 cases (28.6%) in the EAS group revealed ALT levels exceeded the ULN (p = 0.247). Additionally, 4 cases (18.2%) of all patients, 4 cases (33.3%) in the CD group, and no cases in the ACS and EAS groups revealed ALT levels more than three times the ULN (p = 0.130).
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Figure 2. ALT before and after fluconazole treatment in patients with Cushing’s syndrome.
ACS, adrenal Cushing’s syndrome; ALT, Alanine aminotransferase; CD, Cushing’s disease; EAS, ectopic ACTH syndrome.

Discussion

To date, our study is the largest retrospective analysis providing the evaluation of the clinical efficacy and safety of fluconazole treatment in patients with CS. The major findings demonstrated that 24-h UFC levels significantly decreased across all groups after fluconazole treatment, with more than 50% reduction in both the CD and ACS groups. However, the EAS group showed only a 13.1% decline in 24-h UFC levels, although with a large interval (SD 64.4%) and small case numbers in this group, indicating greater variability in response and heterogeneity in this group. Regarding hepatic safety, while ALT levels increased after fluconazole treatment, particularly in the CD group, the changes were not statistically significant in other groups. The significant increase in ALT levels (42.4 ± 32.6 to 76.7 ± 54.3 U/L) in the CD group, but mild—less than two times ULN, may also be related to the high variability (large SD). Importantly, there was no severe hepatotoxicity in the study, because only four patients (18.2%) revealed ALT levels more than three times the ULN.
Fluconazole can be administered either intravenously or orally. Several case reports highlight its effectiveness and safety: Teng Chai et al. reported successful long-term treatment of recurrent CD in a 50-year-old woman using fluconazole with cabergoline, resulting in significant clinical and biochemical improvement without adverse effects.27 Zhao et al. reported that fluconazole normalized cortisol levels pre-surgery in a 48-year-old woman with CD and pulmonary cryptococcal infection.28 In another case, fluconazole with low-dose metyrapone normalized cortisol levels for 6 months in a 61-year-old woman with recurrent CD prior to radiotherapy.29 Riedl et al. demonstrated fluconazole’s efficacy and safety in an 83-year-old woman with CS from adrenocortical carcinoma.18 Canteros et al. reported effective cortisol reduction with mild side effects from fluconazole in a 39-year-old woman with EAS, enabling successful bilateral adrenalectomy.30 An 80-year-old woman with CS of unknown origin also showed effective cortisol control with fluconazole.31 Two of these six cases suffered from hepatic dysfunction at fluconazole doses over 400 mg/day; however, liver enzyme levels returned to normal after dosage reduction. A secondary analysis of a dose-adjustment trial for fluconazole in the treatment of invasive mycoses examined 85 patients who received prolonged high-dose treatment. For these cases, 27% experienced clinical symptoms, and 42% exhibited abnormal laboratory results. The common side effects were <5% of anorexia, hair loss, headache, and 12% of eosinophilia. However, these adverse effects did not progress, leading the study to conclude that fluconazole is well tolerated and generally safe.32
Ketoconazole has been used to treat hypercortisolism by inhibiting CYP450 enzymes, specifically 11β-hydroxylase and 17α-hydroxylase, and fluconazole has similar properties.17 Previous studies suggest that fluconazole is less potent in inhibiting glucocorticoid production compared to ketoconazole, with varying effects; however, cortisol reduction with fluconazole use has been confirmed.17,18 Unlike ketoconazole, which is extensively metabolized in the liver and associated with significant hepatotoxicity, fluconazole is minimally metabolized in the liver.16 According to the FDA, the risk of serious liver injury from ketoconazole is higher than with other azole agents.33 In our study of 22 patients, fluconazole was well tolerated, with no significant elevations in liver enzyme levels observed during 6 months of treatment. These findings suggest that fluconazole may represent a safer alternative to ketoconazole for the treatment of CS.
In five studies involving 310 patients with CS treated with an average dose of 673.9 mg/day of ketoconazole over an average of 12.6 months, normalization of urinary free cortisol was achieved in 64.3% of patients (median 50%, range 44.7%–92.9%). However, 23% of initially responsive patients eventually lost biochemical control.34 Another retrospective study of 200 patients with CD receiving ketoconazole at an average dose of 600 mg/day found that 64.7% of patients treated for over 2 years achieved UFC normalization, while 15.4% experienced recurrence, or “escape,” from cortisol control.15 In our study, 10 patients (45.5%) received fluconazole treatment for over 1 year, with 5 of these patients (50%) showing 24-h UFC levels not exceeding 1.5 times the ULN in the following 3–12 months (under control without escape). The long-term control of hypercortisolism with fluconazole appears to be less effective than with ketoconazole. However, this could be attributed to the small sample size in our study.
Table 1 shows baseline morning ACTH levels at diagnosis for all patients before any treatment, highlighting a statistically significant difference. In comparison, Table 2 presents morning ACTH levels prior to fluconazole treatment, where no statistical difference was observed. This is likely due to some patients in the CD and EAS groups having previously undergone surgery or received other medical treatments, which might reduce the tumor burden and the levels of ACTH.
Recent studies suggest that levoketoconazole demonstrates good efficacy and safety in the management of CS.2325 However, no head-to-head trials have been conducted to compare ketoconazole, levoketoconazole, and fluconazole directly. Therefore, further clinical trials are warranted to provide clearer insights into the comparative efficacy and safety of these therapeutic options in CS.
The limitations of this study include its retrospective design, which lacked comparator groups, and the small sample sizes in the ACS and EAS groups. In addition, patients were treated by different physicians, each using their own clinical judgment, without standardized follow-up protocols, making some data difficult to collect and analyze. The heterogeneity in dosing regimens also posed challenges in assessing the dose-response relationship. Besides, the relationship between the timing and dosages of other medications (etomidate, pasireotide, and metyrapone) and their effects on laboratory findings is challenging to analyze due to the limited number of cases. There were no statistically significant differences in ACTH level changes before and after fluconazole treatment among the three groups. This may be a limitation, as we only monitored the first and second ACTH measurements following fluconazole treatment. Further investigations with longer monitoring of ACTH levels may be necessary. The study’s observation period was approximately 5.5 years, but further investigation is required to confirm the long-term efficacy and safety of fluconazole treatment in CS.

Conclusion

This study demonstrates that fluconazole is effective in treating patients with CS, as evidenced by a significant reduction in 24-h UFC levels. Moreover, fluconazole was generally well tolerated, with a minimal risk of liver injury, suggesting it may be an effective and safe option for managing hypercortisolism in CS.

Acknowledgments

The authors thank the Medical Sciences & Technology Building of Taipei Veterans General Hospital for providing experimental space and facilities.

ORCID iD

Footnotes

Ethics approval and consent to participate This study was approved by the Institutional Review Board at Taipei Veterans General Hospital (IRB No. 2021-04-003CC). Due to the retrospective nature of this study, informed patient consent was waived.

Consent for publication Not applicable.

Author contributions

Tang-Yi Liao: Data curation; Formal analysis; Writing – original draft.
Yi-Chun Lin: Data curation; Writing – review & editing.
Chun-Jui Huang: Data curation; Writing – review & editing.
Chii-Min Hwu: Conceptualization; Data curation.
Liang-Yu Lin: Conceptualization; Data curation; Funding acquisition; Investigation; Methodology; Writing – review & editing.
Funding The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This study was partly supported by research grants (Grant Nos. V108C-197, V109C-179, V110C-198, V111D62-002-MY3, V112C-183, V113C-094, V114C-116, and V114D77-002-MY3-1) to L.Y.L. from Taipei Veterans General Hospital, Taipei, Taiwan and MOST 111-2314-B-075-040-MY2 to L.Y.L. from National Science and Technology Council, Taiwan. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests The authors declare that there is no conflict of interest.

Availability of data and materials The data and materials generated and analyzed in the study are available from the corresponding author on reasonable request.

References

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2. Clayton RN, Raskauskiene D, Reulen RC, et al. Mortality and morbidity in Cushing’s disease over 50 years in Stoke-on-Trent, UK: audit and meta-analysis of literature. J Clin Endocrinol Metab 2011; 96(3): 632–642.
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4. Biller BM, Grossman AB, Stewart PM, et al. Treatment of adrenocorticotropin-dependent Cushing’s syndrome: a consensus statement. J Clin Endocrinol Metab 2008; 93(7): 2454–2462.
5. Castinetti F, Nagai M, Morange I, et al. Long-term results of stereotactic radiosurgery in secretory pituitary adenomas. J Clin Endocrinol Metab 2009; 94(9): 3400–3407.
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10. Schteingart DE. Drugs in the medical treatment of Cushing’s syndrome. Expert Opin Emerg Drugs 2009; 14(4): 661–671.
11. Nieman LK. Medical therapy of Cushing’s disease. Pituitary 2002; 5(2): 77–82.
12. Valassi E, Franz H, Brue T, et al. Preoperative medical treatment in Cushing’s syndrome: frequency of use and its impact on postoperative assessment: data from ERCUSYN. Eur J Endocrinol 2018; 178(4): 399–409.
13. Varlamov EV, Vila G, Fleseriu M. Perioperative management of a patient with Cushing Disease. J Endocr Soc 2022; 6(3): bvac010.
14. Pivonello R, De Martino MC, De Leo M, et al. Cushing’s syndrome. Endocrinol Metab Clin North Am 2008; 37(1): 135–ix.
15. Castinetti F, Guignat L, Giraud P, et al. Ketoconazole in Cushing’s disease: is it worth a try? J Clin Endocrinol Metab 2014; 99(5): 1623–1630.
16. Como JA, Dismukes WE. Oral azole drugs as systemic antifungal therapy. N Engl J Med 1994; 330(4): 263–272.
17. van der Pas R, Hofland LJ, Hofland J, et al. Fluconazole inhibits human adrenocortical steroidogenesis in vitro. J Endocrinol 2012; 215(3): 403–412.
18. Riedl M, Maier C, Zettinig G, et al. Long term control of hypercortisolism with fluconazole: case report and in vitro studies. Eur J Endocrinol 2006; 154(4): 519–524.
19. Albert SG, DeLeon MJ, Silverberg AB. Possible association between high-dose fluconazole and adrenal insufficiency in critically ill patients. Crit Care Med 2001; 29(3): 668–670.
20. Santhana Krishnan SG, Cobbs RK. Reversible acute adrenal insufficiency caused by fluconazole in a critically ill patient. Postgrad Med J 2006; 82(971): e23.
21. García Rodríguez LA, Duque A, Castellsague J, et al. A cohort study on the risk of acute liver injury among users of ketoconazole and other antifungal drugs. Br J Clin Pharmacol 1999; 48(6): 847–852.
22. Creemers SG, Feelders RA, De Jong FH, et al. Levoketoconazole, the 2S,4R enantiomer of ketoconazole, a new steroidogenesis inhibitor for Cushing’s syndrome treatment. J Clin Endocrinol Metabol 2021; 106: 1618–1630.
23. Fleseriu M, Pivonello R, Elenkova A, et al. Efficacy and safety of levoketoconazole in the treatment of endogenous Cushing’s syndrome (SONICS): a phase 3, multicentre, open-label, single-arm trial. Lancet Diabet Endocrinol 2019; 7: 855–865.
24. Pivonello R, Zacharieva S, Elenkova A, et al. Levoketoconazole in the treatment of patients with endogenous Cushing’s syndrome: a double-blind, placebo-controlled, randomized withdrawal study (LOGICS). Pituitary 2022; 25: 911–926.
25. Patra S, Dutta D, Nagendra L, et al. Efficacy and safety of levoketoconazole in managing Cushing’s syndrome: a systematic review. Indian J Endocr Metab 2024; 28: 343–349.
26. Sharma ST; AACE Adrenal Scientific Committee. An individualized approach to the evaluation of Cushing Syndrome. Endocr Pract 2017; 23(6): 726–737.
27. Teng Chai S, Haydar Ali Tajuddin A, Wahab NA, et al. Fluconazole as a safe and effective alternative to ketoconazole in controlling hypercortisolism of recurrent Cushing’s disease: a case report. Int J Endocrinol Metab 2018; 16(3): e65233.
28. Zhao Y, Liang W, Cai F, et al. Fluconazole for hypercortisolism in Cushing’s disease: a case report and literature review. Front Endocrinol (Lausanne) 2020; 11: 608886.
29. Burns K, Christie-David D, Gunton JE. Fluconazole in the treatment of Cushing’s disease. Endocrinol Diabetes Metab Case Rep 2016; 2016: 150115.
30. Canteros TM, De Miguel V, Fainstein-Day P. Fluconazole treatment in severe ectopic Cushing syndrome. Endocrinol Diabetes Metab Case Rep 2019; 2019(1): 19-0020.
31. Schwetz V, Aberer F, Stiegler C, et al. Fluconazole and acetazolamide in the treatment of ectopic Cushing’s syndrome with severe metabolic alkalosis. Endocrinol Diabetes Metab Case Rep 2015; 2015:1 50027.
32. Stevens DA, Diaz M, Negroni R, et al. Safety evaluation of chronic fluconazole therapy. Fluconazole Pan-American Study Group. Chemotherapy 1997;43(5):371–377.
33. Greenblatt HK, Greenblatt DJ. Liver injury associated with ketoconazole: review of the published evidence. J Clin Pharmacol 2014; 54(12): 1321–1329.
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Xeris Presents New Post Hoc Analysis on Effects of Levoketoconazole (Recorlev®) in Cushing’s Syndrome Patients at ENDO 2024

Posted on June 6, 2024 by MaryO

In patients with Cushing’s syndrome maintained on Recorlev, a lower baseline mUFC was associated with higher cortisol normalization rate.

Lower mUFC at baseline was also associated with lower maintenance dose requirements and lower rates of potentially clinically important liver-related adverse events and liver test abnormalities.

The SONICS study previously showed that Recorlev treatment was effective at normalizing cortisol across the spectrum of Cushing’s syndrome severity.

Xeris Biopharma Holdings, Inc. (Nasdaq: XERS), a growth-oriented biopharmaceutical company committed to improving patients’ lives by developing and commercializing innovative products across a range of therapies, today announced it presented a post-hoc analysis from its previously published SONICS study on the effects of levoketoconazole (Recorlev®) in adults with Cushing’s syndrome at ENDO 2024 in Boston, June 1-4, 2024.

“The results of this analysis suggest that patients with Cushing’s syndrome/disease with lower mUFC(s) normalize at a higher rate than those with more severe disease and may require lower doses of Recorlev and experience lower rates of liver-related adverse events. This exploratory analysis brings further perspective to the importance of individualizing and tailoring medical management,” said James Meyer, PharmD, Xeris’ Senior Director, Publications and Medical Communications.

Title: Effects of Levoketoconazole on 24-hour Mean UFC (mUFC) in the SONICS Study: Relation to Baseline mUFC in Adults with Cushing’s Syndrome: A Post-hoc Analysis (SAT-085)

This post-hoc exploration included all enrolled patients in SONICS who were treated and had a post-baseline mUFC, aiming to further elucidate relationships between baseline biochemical disease severity, drug dose, and intermediate-term mUFC response. For the current analyses, 92 patients treated with levoketoconazole and with baseline mUFC measurement (modified ITT) were stratified into 3 baseline mUFC subgroups: Group 1 (≤ 2.5x upper limit of normal (ULN)); Group 2 (>2.5x to ≤ 5x ULN); or Group 3 (>5x ULN) and analyzed in respect to mUFC response, average daily dose, and adverse events following 6 months of maintenance therapy. Groups 1 and 2 were similar in baseline characteristics; whereas Group 3 differed with younger age, fewer female participants, more recently diagnosed, and more frequently on prior therapy.

Group 2 (Baseline mUFC 267.9 nmol/D) had the highest apparent mUFC response rate (12/33 [36.4%]), 95% CI 0.20, 0.54) as compared with Group 1 (Baseline mUFC 498.7 nmol/D) (12/38 [31.6%], 95% CI 0.16, 0.47) or Group 3 (Baseline mUFC 1672.8 nmol/D) (5/21 [23.8%]; 95% CI 0.01, 0.55); Group 3 having a notably lower response.

Daily doses of levoketoconazole were related to baseline mUFC. Thus, Group 3 used a nominally higher average daily dose (631 mg and 741 mg) during maintenance therapy and at the last dose in the 6-month maintenance phase (regardless of completion status) than Group 1 (475 mg and 545 mg) or Group 2 (548 mg and 611 mg).

Group 3 had more liver-related AEs of special interest than Group 1 or 2 (14% vs 7.9% or 3.0%) and more AEs leading to discontinuation (24% vs 12% or 16%). Group 3 had a higher incidence of liver test (ALT, AST, GGT) abnormalities compared to Group 1 and Group 2.

This post hoc analysis demonstrated:

  • Normalization of mUFC with levoketoconazole in Cushing’s syndrome patients maintained on levoketoconazole in the SONICS study for up to 6 months appeared to vary inversely with baseline mUFC.
  • Lower mUFC at baseline was also associated with lower maintenance dose requirements and lower rates of potentially clinically important liver-related AEs and liver test abnormalities.
  • Whether observed baseline characteristic differences between the highest tertile of baseline mUFC and the 2 lower tertiles were simply coincidental to or confounders or mediators of the described relationships with mUFC remains to be explored.

About Cushing’s Syndrome

Endogenous Cushing’s syndrome is a rare, serious, and potentially fatal endocrine disease caused by chronic elevated cortisol exposure–often the result of a benign tumor of the pituitary gland. This benign tumor tells the body to overproduce high levels of cortisol for a sustained period of time, which often results in characteristic physical signs and symptoms that are distressing to patients. The disease is most common among adults between the ages of 30–50, and it affects women three times more often than men. Women with Cushing’s syndrome may experience a variety of health issues including menstrual problems, difficulty becoming pregnant, excess male hormones (androgens), primarily testosterone, which can cause hirsutism (growth of coarse body hair in a male pattern), oily skin, and acne.3

Additionally, the multisystem complications of the disease are potentially life threatening. These include metabolic changes such as high blood sugar or diabetes, high blood pressure, high cholesterol, fragility of various tissues including blood vessels, skin, muscle, and bone, and psychological disturbances such as depression, anxiety, and insomnia.3 Untreated, the five-year survival rate is only approximately 50%.4

About Recorlev®

Recorlev® (levoketoconazole) is a cortisol synthesis inhibitor for the treatment of endogenous hypercortisolemia in adult patients with Cushing’s syndrome for whom surgery is not an option or has not been curative.1 Endogenous Cushing’s syndrome is a rare but serious and potentially lethal endocrine disease caused by chronic elevated cortisol exposure.2 Recorlev is the pure 2S,4R enantiomer of ketoconazole, a steroidogenesis inhibitor.1 Recorlev has demonstrated in two successful Phase 3 studies to significantly reduce mean urine free cortisol.1

The Phase 3 program for Recorlev included SONICS and LOGICS, two multinational studies designed to evaluate the safety and efficacy of Recorlev when used to treat endogenous Cushing’s syndrome. The SONICS study met its primary and secondary endpoints, significantly reducing and normalizing mean urinary free cortisol concentrations without a dose increase.1,2 The LOGICS study, which met its primary endpoint and key secondary endpoint, was a double-blind, placebo-controlled randomized-withdrawal study of Recorlev that was designed to supplement the efficacy and safety information provided by SONICS.1 The ongoing open-label OPTICS study will gather further useful information related to the long-term use of Recorlev.

Recorlev was approved by the US FDA in December 2021 and received orphan drug designation from the FDA and the European Medicines Agency for the treatment of endogenous Cushing’s syndrome.

Indication & Important Safety Information for Recorlev®

BOXED WARNING: HEPATOTOXICITY AND QT PROLONGATION
HEPATOTOXICITY

Cases of hepatotoxicity with fatal outcome or requiring liver transplantation have been reported with oral ketoconazole. Some patients had no obvious risk factors for liver disease. Recorlev is associated with serious hepatotoxicity. Evaluate liver enzymes prior to and during treatment.

QT PROLONGATION

Recorlev is associated with dose-related QT interval prolongation. QT interval prolongation may result in life-threatening ventricular dysrhythmias such as torsades de pointes. Perform ECG and correct hypokalemia and hypomagnesemia prior to and during treatment.

INDICATION

Recorlev is a cortisol synthesis inhibitor indicated for the treatment of endogenous hypercortisolemia in adult patients with Cushing’s syndrome for whom surgery is not an option or has not been curative.

Limitations of Use

Recorlev is not approved for the treatment of fungal infections.

CONTRAINDICATIONS

  • Cirrhosis, acute liver disease or poorly controlled chronic liver disease, baseline AST or ALT > 3 times the upper limit of normal, recurrent symptomatic cholelithiasis, a prior history of drug induced liver injury due to ketoconazole or any azole antifungal therapy that required discontinuation of treatment, or extensive metastatic liver disease.
  • Taking drugs that cause QT prolongation associated with ventricular arrythmias, including torsades de pointes.
  • Prolonged QTcF interval > 470 msec at baseline, history of torsades de pointes, ventricular tachycardia, ventricular fibrillation, or prolonged QT syndrome.
  • Known hypersensitivity to levoketoconazole, ketoconazole or any excipient in Recorlev.
  • Taking certain drugs that are sensitive substrates of CYP3A4 or CYP3A4 and P-gp.

WARNINGS AND PRECAUTIONS

Hepatotoxicity

Serious hepatotoxicity has been reported in patients receiving Recorlev, irrespective of the dosages used or the treatment duration. Drug-induced liver injury (peak ALT or AST greater than 3 times upper limit of normal) occurred in patients using Recorlev. Avoid concomitant use of Recorlev with hepatotoxic drugs. Advise patient to avoid excessive alcohol consumption while on treatment with Recorlev. Routinely monitor liver enzymes and bilirubin during treatment.

QT Prolongation

Use Recorlev with caution in patients with other risk factors for QT prolongation, such as congestive heart failure, bradyarrythmias, and uncorrected electrolyte abnormalities, with more frequent ECG monitoring considered. Routinely monitor ECG and blood potassium and magnesium levels during treatment.

Hypocortisolism

Recorlev lowers cortisol levels and may lead to hypocortisolism with a potential for life-threatening adrenal insufficiency. Lowering of cortisol levels can cause nausea, vomiting, fatigue, abdominal pain, loss of appetite, and dizziness. Significant lowering of serum cortisol levels may result in adrenal insufficiency that can be manifested by hypotension, abnormal electrolyte levels, and hypoglycemia. Routinely monitor 24-hour urine free cortisol, morning serum or plasma cortisol, and patient’s signs and symptoms for hypocortisolism during treatment.

Hypersensitivity Reactions

Hypersensitivity to Recorlev has been reported. Anaphylaxis and other hypersensitivity reactions including urticaria have been reported with oral ketoconazole.

Risks Related to Decreased Testosterone

Recorlev may lower serum testosterone in men and women. Potential clinical manifestations of decreased testosterone concentrations in men may include gynecomastia, impotence and oligospermia. Potential clinical manifestations of decreased testosterone concentrations in women include decreased libido and mood changes.

ADVERSE REACTIONS

Most common adverse reactions (incidence > 20%) are nausea/vomiting, hypokalemia, hemorrhage/contusion, systemic hypertension, headache, hepatic injury, abnormal uterine bleeding, erythema, fatigue, abdominal pain/dyspepsia, arthritis, upper respiratory infection, myalgia, arrhythmia, back pain, insomnia/sleep disturbances, and peripheral edema.

DRUG INTERACTIONS

  • Consult approved product labeling for drugs that are substrates of CYP3A4, P-gp, OCT2, and MATE prior to initiating Recorlev.
  • Sensitive CYP3A4 or CYP3A4 and P-gp Substrates: Concomitant use of Recorlev with these substrates is contraindicated or not recommended.
  • Atorvastatin: Use lowest atorvastatin dose possible and monitor for adverse reactions for dosages exceeding 20 mg daily.
  • Metformin: Monitor glycemia, kidney function, and vitamin B12 and adjust metformin dosage as needed.
  • Strong CYP3A4 Inhibitors or Inducers: Avoid use of these drugs 2 weeks before and during Recorlev treatment.
  • Gastric Acid Modulators: See Full Prescribing Information for recommendations regarding concomitant use with Recorlev.

USE IN SPECIFIC POPULATIONS

Lactation: Advise not to breastfeed during treatment and for one day after final dose.

To report SUSPECTED ADVERSE REACTIONS, contact Xeris Pharmaceuticals, Inc. at 1-877-937-4737 or FDA at 1-800-FDA-1088 or www.fda.gov/medwatch.

Please see Full Prescribing Information including Boxed Warning.

About Xeris

Xeris (Nasdaq: XERS) is a growth-oriented biopharmaceutical company committed to improving patient lives by developing and commercializing innovative products across a range of therapies. Xeris has three commercially available products; Gvoke®, a ready-to-use liquid glucagon for the treatment of severe hypoglycemia, Keveyis®, a proven therapy for primary periodic paralysis, and Recorlev® for the treatment of endogenous Cushing’s syndrome. Xeris also has a robust pipeline of development programs to extend the current marketed products into important new indications and uses and bring new products forward using its proprietary formulation technology platforms, XeriSol™ and XeriJect®, supporting long-term product development and commercial success.

Xeris Biopharma Holdings is headquartered in Chicago, IL. For more information, visit www.xerispharma.com, or follow us on XLinkedIn, or Instagram.

Forward-looking Statement

Any statements in this press release other than statements of historical fact are forward-looking statements. Forward-looking statements include, but are not limited to, statements about future expectations, plans and prospects for Xeris Biopharma Holdings, Inc. including statements regarding expectations for the release of clinical data, post hoc analyses or results from clinical trials, including the SONICS study, the market and therapeutic potential of its products and product candidates, including the levoketoconazole (Recorlev®), the potential utility of its formulation platforms and other statements containing the words “will,” “would,” “continue,” “expect,” “should,” “anticipate” and similar expressions, constitute forward-looking statements within the meaning of The Private Securities Litigation Reform Act of 1995. These forward-looking statements are based on numerous assumptions and assessments made in light of Xeris’ experience and perception of historical trends, current conditions, business strategies, operating environment, future developments, geopolitical factors, and other factors it believes appropriate. By their nature, forward-looking statements involve known and unknown risks and uncertainties because they relate to events and depend on circumstances that will occur in the future. The various factors that could cause Xeris’ actual results, performance or achievements, industry results and developments to differ materially from those expressed in or implied by such forward-looking statements, include, but are not limited to, its financial position and need for financing, including to fund its product development programs or commercialization efforts, whether its products will achieve and maintain market acceptance in a competitive business environment, its reliance on third-party suppliers, including single-source suppliers, its reliance on third parties to conduct clinical trials, the ability of its product candidates to compete successfully with existing and new drugs, and its and collaborators’ ability to protect its intellectual property and proprietary technology. No assurance can be given that such expectations will be realized and persons reading this communication are, therefore, cautioned not to place undue reliance on these forward-looking statements. Additional risks and information about potential impacts of financial, operational, economic, competitive, regulatory, governmental, technological, and other factors that may affect Xeris can be found in Xeris’ filings, including its most recently filed Annual Report on Form 10-K filed with the Securities and Exchange Commission, the contents of which are not incorporated by reference into, nor do they form part of, this communication. Forward-looking statements in this communication are based on information available to us, as of the date of this communication and, while we believe our assumptions are reasonable, actual results may differ materially. Subject to any obligations under applicable law, we do not undertake any obligation to update any forward-looking statement whether as a result of new information, future developments or otherwise, or to conform any forward-looking statement to actual results, future events, or to changes in expectations.

1. Recorlev [prescribing information]. Chicago, IL: Xeris Pharmaceuticals, Inc.; 2021. 2. Fleseriu M, et al. Lancet Diabetes Endocrinol. 2019;7(11):855-865. 3. Pivonello R et al. Lancet Diabetes Endocrinol. 2016; 4: 611-29. 4. Plotz CM, et al. Am J Med. 1952 November;13(5):597-614.

Recorlev®, Xeris Pharmaceuticals®, Xeris CareConnectionTM, Keveyis®, Gvoke®, and Ogluo® are trademarks owned by or licensed to Xeris Pharmaceuticals, Inc. PANTHERx Rare Pharmacy is a service mark of PANTHERx Rare, LLC. All other trademarks referenced herein are the property of their respective owners. All rights reserved. US-PR-22-00001 1/22

From https://www.morningstar.com/news/business-wire/20240603311134/xeris-presents-new-post-hoc-analysis-on-effects-of-levoketoconazole-recorlev-in-cushings-syndrome-patients-at-endo-2024

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FDA Puts Strict Limits on Oral Ketoconazole Use

Posted on August 3, 2013 by MaryO

By John Gever, Deputy Managing Editor, MedPage Today

SILVER SPRING, Md. — Oral ketoconazole (Nizoral) should never be used as first-line therapy for any type of fungal infection because of the risk of liver toxicity and interactions with other drugs, the FDA said Friday.

The agency ordered a series of label changes and a new medication guide for patients that emphasize the risks, which also include adrenal insufficiency. It noted that the restrictions apply only to the oral formulation, not topical versions.

Late Thursday, the chief advisory body for the FDA’s European counterpart went further. The EU’s Committee on Medicinal Products for Human Use (CHMP) recommended that member nations pull oral ketoconazole from their markets entirely.

Both the FDA and the CHMP cited studies indicating high risks of severe, acute liver injury in patients taking the drug. Studies using the FDA’s adverse event reporting system and a similar database in the U.K. indicated that liver toxicity was more common with oral ketoconazole than with other anti-fungals in the azole class.

The FDA also said that oral ketoconazole “is one of the most potent inhibitors” of the CYP3A4 enzyme. This effect can lead to sometimes life-threatening interactions with other drugs metabolized by CYP3A4, and also to adrenal insufficiency, since the enzyme also catalyzes release of adrenal steroid hormones.

“This accounts for clinically important endocrinologic abnormalities observed in some patients (particularly when the drug is administered at high dosages), including gynecomastia in men and menstrual irregularities in women,” the FDA said.

The only indication for oral ketoconazole still supported by the FDA is for use in life-threatening mycoses in patients who cannot tolerate other anti-fungal medications or when such medications are unavailable.

In such instances, the FDA said, physicians should assess liver function before starting the drug. It is contraindicated in patients with pre-existing liver disease, and patients should be instructed not to drink alcohol or use other potentially hepatotoxic drugs.

Adrenal function should also be monitored in patients using the drug.

The CHMP also indicated the topical formulations of ketoconazole should stay on the market, but it found no basis for keeping the oral form available for any purpose.

“Taking into account the increased rate of liver injury and the availability of alternative anti-fungal treatments, the CHMP concluded that the benefits did not outweigh the risks,” the panel indicated in a statement.

It recommended that physicians stop prescribing oral ketoconazole and that they should review alternatives in patients currently receiving the drug. The committee also said that patients now taking oral ketoconazole “make a non-urgent appointment” with their physicians to discuss their treatment.

From MedPage Today

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