Accidental Cushing Syndrome

Posted on February 5, 2024 by MaryO

Abstract

We present a patient with Cushing syndrome secondary to accidental intake of corticosteroid tablets—a 66-year-old woman with a history of well-controlled hypertension, who over the course of a few weeks developed full-blown Cushing syndrome with uncontrolled blood pressure, typical central fat accumulation, and easy bruising. The clinical features further worsened upon increase of the dosage of her antihypertensive medication because of rising blood pressure. Biochemical analyses showed low cortisol and ACTH concentrations. Inspection of the patient’s medications revealed that she had accidentally been taking corticosteroids tablets, prescribed for her husband, instead of antihypertensives, ie, dexamethasone 4 mg and then 8 mg, instead of candesartan at the same dose.

This case highlights the necessity of a thorough review of the medications taken by patients suspected to have exogenous Cushing syndrome, including inspection of the original packaging, and not just relying on information from the patient and electronic health records. This case also highlights the need of special labeling on the packaging for the easy identification of corticosteroid-containing medications given their widespread availability.

Introduction

Cushing syndrome (CS) is a disorder caused by prolonged and excessive exposure to glucocorticoids. The most common cause of CS is exogenous or iatrogenic, ie, CS caused by administration of glucocorticoids due to inflammatory, autoimmune, or neoplastic diseases. Endogenous CS is a rare condition, caused by either hypersecretion of ACTH from the pituitary gland, ectopic ACTH production, or hypersecretion of cortisol from the adrenal glands.

It is of great importance to exclude exogenous CS in all patients who present with signs and symptoms compatible with the syndrome. The following case highlights the need to rule out exogenous CS via a face-to-face review of the medications taken by a patient with CS, rather than only relying on the patient’s history and electronic health record.

Case Presentation

A 66-year-old woman was referred to our department for investigation of suspected CS. She was diagnosed with essential hypertension a couple of years earlier and was prescribed tablet candesartan 4 mg daily. Apart from an otherwise well-controlled hypertension, the patient had a history of bilateral hip replacement, the first performed in 2020 and the second 2 years later.

During the 6 weeks prior to our evaluation, the patient had noticed an increasing fat accumulation around her abdomen, upper back, neck, and over the collar bones, despite minimal increase of her body weight. Moreover, the patient had developed a rounded face and increased growth of facial hair, especially on the chin, as well as thin and fragile skin that bruised easily. About 1.5 weeks before she was referred to our clinic, the dose of candesartan was increased by her general practitioner from 4 to 8 mg daily because of rapidly worsening hypertension, confirmed by monitoring 24-hour ambulatory blood pressure.

Diagnostic Assessment

The physical examination of the patient revealed central obesity and multiple bruises that the patient could not recall. Increased growth of fine hairs on the chin and facial plethora was present. Blood pressure was 165/88 mmHg. The patient did not have any signs of abdominal stretch marks, nor did she have any obvious muscle wasting in the arms and legs (Fig. 1). When comparing to photographs taken about 6 months prior to the examination, the differences were obvious (Fig. 2).

 

Figure 1.

The patient few weeks prior to admission for evaluation of Cushing syndrome.

 

Figure 2.

The patient many months before the onset of Cushing syndrome.

Biochemical evaluation revealed unmeasurable plasma cortisol at 12:00 PM, 4:00 PM, and 6:00 AM (<28 nmol/L, reference 102-535 nmol/L; <1.01 μg/dL, reference 3.69-19.39 μg/dL). Serum ACTH was also undetectable (<0.2 pmol/L, reference 1.6-13.9 pmol/L; <0.91 pg/mL, reference 2.27-63.18 pg/mL), which raised suspicion of exogenous CS. The patient firmly denied any intake of anything other than her candesartan tablets. She even stated that she avoided any analgesics after the hip replacement previously the same year, nor had she received any intra-articular cortisone injection. The patient gave a very trustworthy and consistent impression, which inevitably led us to proceed to further investigation of the adrenal glands and the pituitary gland to exclude rarer forms of CS, such as cyclic CS and/or pituitary apoplexy of an ACTH-producing pituitary adenoma. The magnetic resonance imaging of the pituitary and the computed tomography of the adrenal glands were normal. Except for the low cortisol and ACTH levels, endocrine workup was unremarkable (Table 1).

 
Table 1.

Biochemical evaluation of the patient with Cushing syndrome at baseline, ie, at admission

Hormone tested Value Normal Range
Plasma cortisol at 08:00 AM <1.01 mcg/dL (<28 nmol/L) 3.70-19.39 mcg/dL (102-535 nmol/L)
ACTH <0.91 pg/mL (<0.2 pmol/L) 7.27-63.18 pg/mL (1.6-13.9 pmol/L)
TSH 1.0 mIU/L (1.0 mIU/L) 0.4-3.7 mIU/L (0.4-3.7 mIU/L)
Free T4 1.01 ng/dL (13 pmol/L) 0.76-1.32 ng/dL (9.8-17 pmol/L)
IGF-1 142 ng/mL (18.60 nmol/L) 38-162 ng/mL (4.98-21.22 nmol/L)
Prolactin 374 mIU/L (17.58 mcg/L) 63-561 mIU/L (2.96-26.37 mcg/L)
FSH 90 mIU/mL (90 IU/L) 27-133 mIU/mL (post-menopausal) (27-133 IU/L)
LH 16 mIU/mL (16 IU/L) 5.2-62 mIU/mL (post-menopausal) (5.2-62 IU/L)
SHBG 6.07 mcg/mL (54 nmol/L) 2.25-17.42 mcg/mL (20-155 nmol/L)
Testosterone 8.65 ng/dL (0.30 nmol/L) 11.53-34.58 ng/dL (0.4-1.2 nmol/L)
Estradiol <19.07 pg/mL (<70 pmol/L) <28.06 pg/mL (<103 pmol/L) (post-menopausal with no hormone substitute)
Aldosterone 9.05 ng/dL 0.251 pmol/L <23.61 ng/dL (recumbent position) <655 nmol/L
Renin 8.25 mIU/L 2.8-40 mIU/L (recumbent position)
DHEAS 14.81 mcg/dL (0.4 µmol/L) 29.63-181.48 mcg/dL (0.8-4.9 µmol/L)
HbA1c 45 mmol/mol (6.3 %) 31-46 mmol/mol (5-6.4 %)

Abnormal values are shown in bold font. Values in parenthesis are International System of Units (SI).

Abbreviations: ACTH, adrenocorticotropic hormone; TSH, thyroid-stimulating hormone; T4, thyroxine; IGF-1, insulin-like growth factor 1; FSH, follicle-stimulating hormone; LH, luteinizing hormone; SHBG, sex hormone binding globulin; DHEAS, dehydroepiandrosterone sulfate; HbA1c, glycated hemoglobin.

On day 3 after admission, we noted that plasma cortisol at 8:00 AM was measurable, though still low, at 134 nmol/L (4.86 μg/dL), which reinforced our first suspicion of exogenous CS and prompted a more thorough review of the patient’s medication. At this time, we asked the patient to show us the tablets that she had been taking at home and that she still carried in her purse. To the patient’s frank surprise, it turned out that she was indeed carrying tablets containing 4 mg dexamethasone in the belief that they were candesartan 4 mg tablets. The dexamethasone 4 mg tablet the patient had (generic) was white, scored with a diameter of 6 mm (Fig. 3A). The candesartan 4 mg tablet the patient had been dispensed (generic) was also white, scored and with a diameter of 7 mm (Fig. 3B).

 

Figure 3.

A. Tablet Dexamethasone 4 mg. White, scored, diameter 6 × 6 mm. B. Tablet Candesartan 4 mg. White, scored, diameter 7 × 7 mm.

Treatment

The patient was discharged with the same antihypertensive medications as prior to the deterioration and referred to her general practitioner for follow-up of blood pressure. Upon clinical evaluation 5 months after discharge, she showed no signs or symptoms of CS (Fig. 4).

 

Figure 4.

The patient 5 months after the resolution of Cushing syndrome.

Outcome and Follow-up

Thus, the patient had accidentally been taking her husband’s medication, with which the patient had been aiding her husband, and developed a surreptitious iatrogenic CS. In hindsight, the severity of the clinical features had been worsening and resulted in rapid deterioration alongside the increase of the dosage of the antihypertensives from 4 to 8 mg because of the rising blood pressure.

By day 5 after admission, the patient’s plasma cortisol and ACTH concentrations had normalized, as had her blood pressure.

Discussion

Exogenous hypercortisolism is the most common cause of CS, though seldomly published in the literature, and is mainly iatrogenic because of prolonged use of high doses of synthetic glucocorticoids prescribed for the treatment of nonendocrine diseases (1). A recent study has shown that as many as every seventh resident in western Sweden received a glucocorticoid prescription between 2007 and 2014 (2).

The rising use of generic medications during the past decade has resulted in corticosteroids being available in different forms, shapes, and packages that make them less easily recognizable. In many countries, corticosteroids are available over-the-counter in almost any form, whereas a variety of agents such as herbal preparations, tonics, and skin-bleaching creams may also contain corticosteroids to the unawareness of the people using them (34).

There are no large studies regarding how common the unintentional use of medicines or products that contain corticosteroids. However, studies on traditional Chinese medicine have shown that illegally impure herbs and medicines containing corticosteroids are widely used, suggesting that the accidental intake of corticosteroids is more frequent than we may think (35). Many cases of factitious CS have been reported as a cause of exogenous CS, which makes the diagnosis even more challenging (6-8).

The Endocrine Society Clinical Practice Guidelines for the diagnosis of CS recommend that exogenous CS be always excluded before starting the investigation of endogenous CS (9). However, a specific and definitive approach for diagnosing, respectively excluding, exogenous CS is currently lacking. In a recent review, the authors recommend that in addition to asking the patient which medicines they take, the physician should review the electronic health record and ask particularly for medications that are administered via nonoral routes, as well as over-the-counter agents as mentioned earlier (10).

If not confirmed by history, the physician is advised to proceed to the measurement of ACTH and/or dehydroepiandrosterone sulfate as well as screening for synthetic glucocorticoids (10). The results usually show low ACTH, dehydroepiandrosterone sulfate, and cortisol levels even though the clinical picture suggests CS. The cross-reactivity of hydrocortisone or cortisone, which is similar to endogenous steroids, in immunoassay-based measurements of plasma and urinary cortisol may show variable levels of cortisol. These measurements combined with low ACTH can make the diagnostic workup much more complex (7). Screening for exogenous substances with the help of high-performance liquid chromatography is usually positive and constructive (7).

It is increasingly clear that the risk of accidental ingestion of potent medicines can have deleterious effects on health. This leads us to conclude that thorough face-to-face review of the packaging of medications taken by the patient is mandatory and can spare both physicians and patients from a series of unnecessary investigations. Given the high availability, easy access, and catastrophic adverse effects of the unintentional use of corticosteroids, we therefore propose that all corticosteroid-including medications and agents be marked with a recognizable label.

Learning Points

  • Exogenous CS should be always excluded before starting investigation of endogenous CS.
  • Concerning exogenous CS, practitioners should always think broadly and ask for use of herbal preparations, skin-bleaching creams, and any over-the-counter products.
  • Unintentional use of corticosteroids can still be the case even after a thorough review of the electronic records; practitioners should always inspect the medicines the patient has taken.

Contributors

All authors (K.K., O.R., P.T.) made equal contributions to authorship. K.K., O.R., and P.T. were involved in the diagnosis and management of this patient, as well as in manuscript submission. K.K. and P.T. authored the manuscript draft. All authors (K.K., O.R., P.T.) reviewed and approved the final draft.

Funding

No public or commercial funding.

Disclosures

None declared.

Informed Patient Consent for Publication

Signed informed consent was obtained directly from the patient.

© The Author(s) 2024. Published by Oxford University Press on behalf of the Endocrine Society.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.

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Paediatric Cushing Syndrome: Prospective, Multisite, Observational Cohort Study

Posted on January 19, 2024 by MaryO

Summary

Background

Paediatric endogenous Cushing syndrome is a rare condition with variable signs and symptoms of presentation. We studied a large cohort of paediatric patients with endogenous Cushing syndrome with the aim of describing anthropometric, clinical, and biochemical characteristics as well as associated complications and outcomes to aid diagnosis, treatment, and management.

Methods

In this prospective, multisite cohort study, we studied children and adolescents (≤18 years at time of presentation) with a diagnosis of Cushing syndrome. Patients had either received their initial diagnosis and evaluation at the Eunice Kennedy Shriver National Institute of Child Health and Human Development (Bethesda, MD, USA) or been referred from other centres in the USA or outside the USA. We collected participants’ clinical, biochemical, and imaging findings and recorded their post-operative course until their latest appointment.

Findings

Of 342 paediatric patients with a diagnosis of Cushing syndrome, 193 (56%) were female and 149 (44%) male. 261 (76%) patients had corticotroph pituitary neuroendocrine tumours (Cushing disease), 74 (22%) had adrenal-associated Cushing syndrome, and seven (2%) had ectopic Cushing syndrome. Patients were diagnosed at a median of 2 years (IQR 1·0–3·0) after the first concerning sign or symptom, and patients with adrenal-associated Cushing syndrome were the youngest at diagnosis (median 10·4 years [IQR 7·4–13·6] vs 13·0 years [10·5–15·3] for Cushing disease vs 13·4 years [11·0–13·7] for ectopic Cushing syndrome; p<0·0001). Body-mass index z-scores did not differ between the diagnostic groups (1·90 [1·19–2·34] for adrenal-associated Cushing syndrome vs 2·18 [1·60–2·56] for Cushing disease vs 2·22 [1·42–2·35] for ectopic Cushing syndrome; p=0·26). Baseline biochemical screening for cortisol and adrenocorticotropin at diagnosis showed overlapping results between subtypes, and especially between Cushing disease and ectopic Cushing syndrome. However, patients with ectopic Cushing syndrome had higher urinary free cortisol (fold change in median cortisol concentration from upper limit of normal: 15·5 [IQR 12·7–18·0]) than patients with adrenal-associated Cushing syndrome (1·5 [0·6–5·7]) or Cushing disease (3·9 [2·3–6·9]; p<0·0001). Common complications of endogenous Cushing syndrome were hypertension (147 [52%] of 281 patients), hyperglycaemia (78 [30%] of 260 patients), elevated alanine transaminase (145 [64%] of 227 patients), and dyslipidaemia (105 [48%] of 219 patients). Long-term recurrence was noted in at least 16 (8%) of 195 patients with Cushing disease.

Interpretation

This extensive description of a unique cohort of paediatric patients with Cushing syndrome has the potential to inform diagnostic workup, preventative actions, and follow-up of children with this rare endocrine condition.

Funding

Intramural Research Program, Eunice Kennedy Shriver National Institute of Child Health & Human Development, National Institutes of Health.

Introduction

Paediatric endogenous Cushing syndrome is a rare disorder accounting for 5–7% of all reported cases of endogenous Cushing syndrome.1, 2, 3 In children older than 5–7 years and adolescents, endogenous Cushing syndrome is most commonly caused by corticotroph pituitary neuroendocrine tumours (PitNETs) and is termed Cushing disease. By contrast, Cushing syndrome in children younger than 5 years is often associated with adrenal disorders and is termed adrenal-associated Cushing syndrome.4 Albeit rare, a third type termed ectopic Cushing syndrome is caused by neuroendocrine tumours outside the hypothalamic–pituitary axis that secrete adrenocorticotropin or corticotropin-releasing hormone.5, 6 Thus endogenous Cushing syndrome is caused by either adrenocorticotropin-dependent sources (pituitary or ectopic) or adrenocorticotropin-independent (adrenal) hypercortisolemia.

Patients with adults-onset Cushing syndrome typically present with weight gain, skin manifestations (striae, hirsutism, acne, and easy bruising), and abnormal fat deposition.7, 8, 9 Paediatric Cushing syndrome differs from adult-onset Cushing syndrome in aspects including effects on growth (weight gain with concomitant height deceleration), atypical physical presentation (such as lack of centripetal obesity or typical striae), delayed or suppressed puberty, and variable mental health problems and neurocognitive function deficits.10 Diagnosis of paediatric Cushing syndrome is therefore challenging, and delayed evaluation is common.

Research in context

Evidence before this study

Endogenous Cushing syndrome is a rare endocrine condition. Diagnosis can be challenging and delay treatment. We searched PubMed for articles published in English on paediatric Cushing syndrome using terms “Cushing” AND “children” from database inception to May 5, 2023. Although several case series of paediatric Cushing disease were identified, only a few studies of the various causes of paediatric endogenous Cushing syndrome were available.

Added value of this study

To our knowledge, this cohort of paediatric endogenous Cushing syndrome of various causes is one of the largest sources of cumulative clinical, anthropometric, and biochemical data on the presentation, diagnosis, and management. We confirm that baseline biochemical data cannot aid differential diagnosis of Cushing syndrome subtypes. However, evidence suggests that minimally invasive stimulation tests could be a safe alternative to interventional sampling procedures such as inferior petrosal sinus sampling. We provide the prevalence of complications related to Cushing syndrome. Long-term outcomes of paediatric patients with pituitary corticotroph tumours recurrence is possible up to 8 years after initial remission.

Implications of all the available evidence

Data from this large paediatric cohort inform the evaluation, diagnosis, and long-term care of patients with paediatric Cushing syndrome. We recommend an algorithm for the diagnosis of patients and screening of complications. Screening for recurrence in patients with Cushing disease is indicated for this age group, at least for the first decade after surgery.

We have evaluated a large cohort of children and adolescents with endogenous Cushing syndrome of various causes. The aim of the study was to document anthropometric, clinical, and biochemical characteristics, complications, and outcomes of paediatric endogenous Cushing syndrome to aid clinicians in the diagnosis and management of these patients.

Section snippets

Study design and participants

In this prospective, multisite cohort study, we screened participants who, from 1995 to 2023, had enrolled in studies under protocols 97-CH-0076 (clinicaltrials.gov, NCT00001595), 95-CH-0059 (NCT00001452), and 00-CH-0160 (NCT00005927) at the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD, Bethesda, MD, USA). Paediatric patients (18 years or younger at time of presentation) with a diagnosis of Cushing syndrome were eligible for inclusion in the study. We

Results

342 patients with paediatric Cushing syndrome were included in the study (table 1). 278 patients were referred from centres in the USA, and 64 patients were referred from centres outside of the USA. 261 (76%) patients were diagnosed with Cushing disease, 74 (22%) patients were diagnosed with adrenal-associated Cushing syndrome, and seven (2%) patients were diagnosed with ectopic Cushing syndrome. Patients with adrenal-associated Cushing syndrome were diagnosed at a younger age than patients

Discussion

We present extensive and unique data on presentation, diagnosis, and follow-up of paediatric patients with three diagnostic types of endogenous Cushing syndrome. Clinical and anthropometric characteristics were similar across subtypes of Cushing syndrome, but biochemical tests differed. We also present extensive information on complications; hypertension, insulin resistance, dyslipidaemia, and elevated ALT were common. Long-term follow-up of patients revealed excellent postoperative prognosis,

Data sharing

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Declaration of interests

CAS holds patents on the function of the PRKAR1APDE11A, and GPR101 genes and related issues; his laboratory had received research funding on GPR101, and on abnormal growth hormone secretion and its treatment by Pfizer. CAS receives support from ELPEN and has been consulting for Lundbeck Pharmaceuticals and Sync. CT reports receiving research funding on treatment of abnormal growth hormone secretion by Pfizer.

References (38)

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Metformin Inhibits Cell Proliferation and ACTH Secretion In AtT20 Cells Via Regulating the Mapk Pathway

Posted on January 16, 2024 by MaryO

Abstract

We investigated the impact of metformin on ACTH secretion and tumorigenesis in pituitary corticotroph tumors. The mouse pituitary tumor AtT20 cell line was treated with varying concentrations of metformin. Cell viability was assessed using the CCK-8 assay, ACTH secretion was measured using an ELISA kit, changes in the cell cycle were analyzed using flow cytometry, and the expression of related proteins was evaluated using western blotting. RNA sequencing was performed on metformin-treated cells. Additionally, an in vivo BALB/c nude xenograft tumor model was established in nude mice, and immunohistochemical staining was conducted for further verification. Following metformin treatment, cell proliferation was inhibited, ACTH secretion decreased, and G1/S phase arrest occurred. Analysis of differentially expressed genes revealed cancer-related pathways, including the MAPK pathway. Western blotting confirmed a decrease in phosphorylated ERK1/2 and phosphorylated JNK. Combining metformin with the ERK1/2 inhibitor Ulixertinib resulted in a stronger inhibitory effect on cell proliferation and POMC (Precursors of ACTH) expression. In vivo studies confirmed that metformin inhibited tumor growth and reduced ACTH secretion. In conclusion, metformin inhibits tumor progression and ACTH secretion, potentially through suppression of the MAPK pathway in AtT20 cell lines. These findings suggest metformin as a potential drug for the treatment of Cushing’s disease.

Introduction

Pituitary neuroendocrine tumors (PitNETs) are common intracranial tumors with an incidence of 1/1000, and pituitary corticotroph tumors (corticotroph PitNETs) account for approximately 15% of all PitNETs. Most corticotroph PitNETs are functional tumors with clinical manifestations of Cushing’s disease characterized by central obesity, hypertension, diabetes mellitus, and psychosis (Cui et al., 2021). The increased cortisol due to the overproduction of adrenocorticotropic hormone (ACTH) significantly reduces the overall quality of survival and life expectancy of patients (Sharma et al., 2015; Barbot et al., 2018). Currently, treatment of corticotroph PitNETs mainly relies on surgery resection, pharmacologic therapy or radiotherapy may be considered for patients with residual tumors or those who are unable to undergo surgery. While several agents, such as cabergoline and pasireotide, are clinically approved, the effect is unsatisfactory, and potentially serious side effects exist. Therefore, there is an urgent need to develop novel therapeutic drugs for corticotroph PitNETs.

Metformin is a biguanide hypoglycemic agent for the treatment of type 2 diabetes. In addition to its hypoglycemic effect, numerous studies identified the therapeutic role of metformin in the prevention and treatment of various tumors including small cell lung cancer, colorectal cancer, breast cancer, ovarian cancer, and neuroendocrine tumors (Lu et al., 2022; Kamarudin et al., 2019; Wang et al., 2019; Thakur et al., 2019), making metformin a promising adjuvant drug in the therapy of cancers. Besides, it has been reported that metformin improves metabolic and clinical outcomes in patients treated with glucocorticoids. However, to date, limited studies explore the potential anti-cancer effect of metformin in corticotroph PitNETs. Recent studies report the use of metformin for blood glucose and body weight control in patients with Cushing’s disease (Ceccato et al., 2015), while the role of metformin on ACTH secretion and tumor growth in corticotroph PitNETs remains to be elucidated.

In the current study, we investigated the effect of metformin in corticotroph PitNETs and performed RNA-sequencing to identify the potential mechanisms of metformin. We found that metformin inhibited cell proliferation and ACTH secretion of AtT20 cells in a dose-dependent manner. Besides, metformin induced cell cycle arrest via decreased ERK1/2 phosphorylation and increased P38 phosphorylation. Our results revealed that metformin is a potential drug for corticotroph PitNET therapy.

Section snippets

Cell culture

The ACTH-secreting mouse pituitary tumor cell line AtT-20 was purchased from the American Type Culture Collection (ATCC; Manassas, VA, USA). Cells were cultured in F-12K medium (ATCC; Catalog No. 30-2004), supplemented with 15% fetal bovine serum (FBS; Gibco), and 2.5% horse serum (Gibco) as suggested. AtT20 cells were cultured in a humidified incubator at 37 °C in 5% CO2.

Reagents and drugs

Metformin and Ulixertinib were purchased from MedChemExpress (MCE), Metformin was dissolved in sterile H2O and prepared as a

Results

Metformin inhibits cell proliferation and ACTH secretion, and leads to cell cycle arrest in AtT20 cells.

We used CCK-8 assay to detect the cell viability of AtT20 cells after treatment with different concentrations of metformin at 24 h, 48 h, and 72 h. The results showed that metformin significantly inhibited the proliferation of AtT20 cells in a dose-dependent manner (Fig. 1A). Similarly, prolonged (6 days) treatment of AtT20 cells with a lower concentration (400 μM) of metformin also inhibited

Discussion

Metformin, acting by binding to PEN2 and initiating the subsequent AMPK signaling pathway in lysosomes, is the most commonly used oral hypoglycemic agent (Hundal et al., 2000; Ma et al., 2022). Previous reports demonstrated metformin as a potential anti-tumor agent in cancer therapy (Evans et al., 2005). Metformin, either alone or in combination with other drugs, has been shown to reduce cancer risk in a variety of tumors including pituitary neuroendocrine tumors (PitNETs) (Thakur et al., 2019;

Conclusion

Our study demonstrated that metformin suppressed cell proliferation and decreased ACTH secretion in AtT20 cells via the MAPK pathway. Our results revealed that metformin is a potential anti-tumor drug for the therapy of corticotroph PitNETs, which deserves further study.

Funding

This study was supported by the National Natural Science Foundation of China (82072804, 82071559).

CRediT authorship contribution statement

Yingxuan Sun: Conceptualization, Formal analysis, Investigation, Writing – original draft, Writing – review & editing. Jianhua Cheng: Data curation, Formal analysis, Visualization, Writing – original draft, Writing – review & editing. Ding Nie: Formal analysis, Writing – review & editing. Qiuyue Fang: Data curation, Formal analysis, Writing – review & editing. Chuzhong Li: Conceptualization, Supervision, Writing – original draft, Writing – review & editing, Funding acquisition. Yazhuo Zhang:

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.

Acknowledgement

We thank Mr. Hua Gao (Cell Biology Laboratory, Beijing Neurosurgical Institute, China) for support with the techniques.

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From https://www.sciencedirect.com/science/article/abs/pii/S0303720723002915

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Evaluation of Psoriasis Patients With Long-Term Topical Corticosteroids for Their Risk of Developing Adrenal Insufficiency, Cushing’s Syndrome and Osteoporosis

Posted on January 3, 2024 by MaryO

In this study, we will investigate the possible side effects of psoriasis patients using long-term topical corticosteroids (TCS) such as adrenal insufficiency, Cushing’s Syndrome (CS) and osteoporosis and determine how these side effects develop.

Forty-nine patients were included in the study. The patients were divided into two groups based on the potency of the topical steroid they took and the patients’ ACTH, cortisol and bone densitometer values were evaluated.

There was no significant difference between the two groups regarding the development of surrenal insufficiency, CS and osteoporosis. One patient in group 1 and 4 patients in group 2 were evaluated as iatrogenic CS. ACTH stimulation tests of these patients in group 2 showed consistent results with adrenal insufficiency, while no adrenal insufficiency was detected in the patient in Group 1. Patients who used more than 50g of superpotent topical steroids per week compared to patients who used 50g of superpotent topical steroids per week. It was identified that patients who used more than 50g of superpotent topical steroids had significantly lower cortisol levels, with a negatively significant correlation between cortisol level and the amount of topical steroid use ( < .01).Osteoporosis was detected in 3 patients in group 1 and 8 patients in Group 2. Because of the low number of patients between two groups, statistical analysis could not be performed to determine the risk factors.

Our study is the first study that we know of that investigated these three side effects. We have shown that the development of CS, adrenal insufficiency and osteoporosis in patients who use topical steroids for a long time depends on the weekly TCS dosage and the risk increases when it exceeds the threshold of 50 grams per week. therefore, our recommendation would be to avoid long-term use of superpotent steroids and to choose from the medium-potent group if it is to be used.

ABOUT THE CONTRIBUTORS

Betul Erdem

Department of Dermatology, Van Training and Research Hospital, Van, Turkey.

Muzeyyen Gonul

Department of Dermatology, Ministry of Health, Ankara Etlik City Hospital, Ankara, Turkey.

Ilknur Ozturk Unsal

Department of Endocrine and Metabolic Disease, Ministry of Health, Ankara Etlik City Hospital, Ankara, Turkey.

Seyda Ozdemir Sahingoz

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Radiation-induced Undifferentiated Malignant Pituitary Tumor After 5 Years of Treatment for Cushing Disease

Posted on December 11, 2023 by MaryO

Abstract

The occurrence of a second neoplasm possibly constitutes an adverse and uncommon complication after radiotherapy. The incidence of a second pituitary tumor in patients irradiated for adrenocorticotropic hormone secreting pituitary adenoma is rare. We report a case of a 40-year-old female with Cushing disease who underwent surgical management followed by radiotherapy. After 5 years of initial treatment, an increase in tumor size was evident at the same location, with a significant interval growth of the parasellar component of the lesion. Histology revealed an undifferentiated highly malignant sarcoma. In the span of next 2 years, the patient was followed with 2 repeat decompression surgeries and radiotherapy because of significant recurrent compressive symptoms by locally invasive malignant tumor. Despite the best efforts, the patient remained unresponsive to multiple treatment strategies (eg, surgical resections and radiotherapy) and succumbed to death.

Introduction

Radiation therapy is a commonly used modality for primary or adjuvant treatment of pituitary adenoma. It is also used as an adjuvant therapy for Cushing disease with persistent or aggressive tumor growth or recurrent disease after surgery. The immediate sequelae of radiotherapy for pituitary tumors include nausea, fatigue, diminished taste and olfaction, and hair loss [1]. One frequent long-term side effect is hypopituitarism. The incidence rate of new-onset hypopituitarism after conventional radiotherapy is approximately 30% to 100% after a follow-up of 10 years, whereas after stereotactic radiosurgery or fractionated radiotherapy, the incidence is approximately 10% to 40% at 5 years [2].

The occurrence of a second neoplasm after cranial radiotherapy constitutes possibly one of the most adverse complications. Tumors such as meningioma, glioma, and sarcoma are the most frequently reported secondary neoplasms after pituitary irradiation [3]. The cumulative probability of a second brain tumor in patients irradiated for pituitary adenoma and craniopharyngioma is approximately 4% [4].

We report 1 such case with detailed clinical, histopathological, and radiological characteristics because of its rarity and associated high mortality of radiation-induced sarcoma.

Case Presentation

The patient first presented at 40 years of age with complaints of weight gain, new-onset diabetes mellitus, hypertension, and cushingoid features in 2014. She was diagnosed with Cushing disease (24-hour urinary cortisol 1384 mcg/24 hours [3819 nmol/24 hours; reference >2 upper limit of normal], low-dose dexamethasone suppression test serum cortisol 16.6 mcg/dL [457.9 nmol/L], ACTH 85 pg/mL [18.7 pmol/L; reference range, <46 pg/mL, <10 pmol/L]) caused by invasive adrenocorticotropic hormone-secreting giant adenoma. The initial imaging revealed a homogenously enhanced pituitary macroadenoma with a size of 42 × 37 × 35 mm with suprasellar extension and encasing both the internal carotid arteries with mass effect on optic chiasma and sellar erosion. The patient underwent tumor excision by endoscopic transsphenoidal transnasal approach. Partial excision of the tumor was achieved because of cavernous sinus invasion. Histopathology and immunohistochemical stains demonstrated a corticotrophin-secreting (ACTH-staining positive) pituitary adenoma with MIB labeling index of 1% to 2%. Because biochemical remission was not achieved (urinary cortisol 794 mcg/24 hours [2191 nmol/24 hours]; ACTH 66 pg/mL [14.5 pmol/L; reference range, <46 pg/mL, <10 pmol/L]), the patient was started on ketoconazole and was received fractionated radiotherapy with a dose of 5040 cGy in 28 fractions.

Diagnostic Assessment

For the next 5 years, at yearly follow-up, 400 mg ketoconazole was continued in view of insufficient control of ACTH secretion. During follow-up, the size of the tumor was stable at approximately 23 × 16 × 33 mm after radiotherapy with no significant clinical and biochemical changes.

Five years after surgery and radiotherapy, the patient developed cerebrospinal fluid rhinorrhea; imaging revealed a cystic transformation of the suprasellar component and increase in the size of the tumor to 39 × 22 × 26 mm, which included visualization of a parasellar component of size 29 × 19 × 15 mm. The patient continued on ketoconazole. The patient was also advised to undergo hypofractionated radiotherapy but did not return for follow-up.

Treatment

In 2021, 1.5 years after the last visit, the patient developed severe headache, altered sensorium, ptosis, focal seizures, and left-sided hemiparesis. During this episode, the patient had an ACTH of 66 pg/mL (14.53 pmol/L; reference range, <46 pg/mL [<10 pmol/L]) and baseline cortisol of 25 mcg/dL (689 nmol/L; reference range, 4-18 mcg/dL [110-496 nmol/L]). Repeat imaging revealed a significant decrease in the suprasellar cystic component but an increase in the size of the parasellar component to 38 × 21 × 25 mm from 29 × 19 × 15 mm, which was isointense on T1 and T2 with heterogeneous enhancement. Significant brain stem compression and perilesional edema was also visible. The patient underwent urgent frontotemporal craniotomy and decompression of the tumor. On pathological examination, the tumor tissue was composed of small pleomorphic round cells arranged in sheets and cords separated by delicate fibrocollagenous stroma. Cells had a round to oval hyperchromatic nucleus with scanty cytoplasm. Areas of hemorrhage, necrosis, and a few apoptotic bodies were seen. The tumor tissue had very high mitotic activity of >10/10 hpf and MIB labeling index of 70%. Immunohistochemistry demonstrated positivity for vimentin, CD99, and TLE-1. Dot-like positivity was present for HMB 45, synaptophysin. INI-1 loss was present in some cells. Ten percent patchy positivity was present for p53. The tumor cells, however, consistently failed to express smooth muscle actin, CD34, Myf-4, epithelial membrane antigen, desmin, LCA, SADD4, CD138, and S-100 protein. ACTH and staining for other hormones was negative. Based on the immunological and histochemical patterns, a diagnosis of high-grade poorly differentiated malignant tumor with a probability of undifferentiated sarcoma was made.

Because of the invasion of surrounding structures and surgical inaccessibility, repeat fractionated radiotherapy was given with a dose of 4500 cGy over 25 fractions at 1.8 Gy daily to the planned target volume via image-guided fractionated radiotherapy. During the next 1.5 years, patient improved clinically with no significant increase in the size of tumor (Fig. 1). The patient was gradually tapered from ketoconazole and developed hypopituitarism requiring levothyroxine and glucocorticoid replacement. There was a significant improvement in the power of the left side and ptosis.

 

Figure 1.

Contrast-enhanced T1 magnetic resonance imaging dynamic pituitary scan (A, sagittal; B, axial; C, coronal sections) reveals postoperative changes with residual enhancing tumor in the right lateral sella cavity with extension into the right cavernous sinus and parasellar region encasing the cavernous and inferiorly extends through the foramen ovale below the skull base up to approximately 1.5 cm. Anteriorly, it extends up to the right orbital apex and posteriorly extends along the right dorsal surface of clivus.

Outcome and Follow-up

After 1.5 years of reradiation in 2022, the patient again developed palsies of the abducens, trigeminal, oculomotor, and trochlear cranial nerve on the right side and left-sided hemiparesis. A significant increase in tumor size to 50 × 54 × 45 mm with anterior, parasellar, and infratentorial extension was seen (Fig. 2). Again, repeat decompression surgery was done. Two months after surgery, there was no improvement in clinical features and repeat imaging suggested an increased size of the tumor by 30%, to approximately 86 × 68 × 75 mm. Nine years after initial presentation, the patient had an episode of aspiration pneumonia and died.

 

Figure 2.

Contrast-enhanced T1 magnetic resonance imaging dynamic pituitary images (A, sagittal; B, axial; C, coronal sections) after 1.5 years of a second session of radiotherapy reveal a significant interval increase in size of heterogeneously enhancing irregular soft tissue in sellar cavity with extension into the right cavernous sinus and parasellar region when compared with previous imaging. Superiorly, it extends in the suprasellar region, causing mass effect on the optic chiasma with encasement of the right prechiasmatic optic nerve and right-sided optic chiasma. Inferiorly, the lesion extends into the sphenoid sinus. Posteriorly, there is interval increase in the lesion involving the clivus and extending into the prepontine and interpeduncular cistern. Anteriorly, mass has reached up to the right orbital apex optic nerve canal, which shows mild interval increase.

Discussion

Radiation-induced tumors were initially described by Cahan et al in 1948. They also described the prerequisites for a tumor to be classified as a radiation-induced sarcoma [5]. The modified Cahan criteria state that (1) the presence of nonmalignancy or malignancy of a different histological type before irradiation, (2) development of sarcoma within or adjacent to the area of the radiation beam, (3) a latent period of at least 3 years between irradiation and diagnosis of secondary tumor, and (4) histological diagnosis of sarcoma, can be classified as radiation-induced sarcoma [5].

Our patient fulfilled the criteria for a radiation-induced sarcoma with a highly malignant tumor on histopathology. Radiation-induced sarcomas after functional pituitary tumors, especially Cushing disease, are rarely reported. One of the case reports revealed a high-grade osteoblastic osteosarcoma 30 years after treatment for Cushing disease with transsphenoidal resection and external beam radiotherapy [6]. In our case, there was a lag period of approximately 5 years before the appearance of a second highly undifferentiated, malignant, histologically distinct tumor. The cellular origin of this relatively undifferentiated tumor cannot be determined with certainty. However, the interlacing sarcomatous and adenomatous components resulting from distinct positive immunohistochemistry may indicate that the sarcomatous component may be derived from the preexisting pituitary adenoma.

A hormonally functional pituitary tumor is not itself expected to be associated with an increased risk of secondary malignancy, except in the case of GH-secreting tumors and those with a hereditary cancer syndrome. Although not proven, immunosuppression from hypercortisolism in Cushing disease has been proposed as a contributor to secondary tumor development [7]. Other mechanisms causing increased risk of secondary malignancy can be double-stranded DNA damage and genomic instability caused by ionizing radiation and germline mutations in tumor suppressor genes such as TP53 and Rb [7].

Radiation-induced intracranial tumors were studied in a multicenter, retrospective cohort of 4292 patients with pituitary adenoma or craniopharyngioma. Radiotherapy exposure was associated with an increased risk of a second brain tumor with a rate ratio of 2.18 (95% CI, 1.31-3.62, P < .0001). The cumulative probability of a second brain tumor was 4% for the irradiated patients and 2.1% for the controls at 20 years [7]. In another study including 426 patients irradiated for pituitary adenoma between 1962 and 1994, the cumulative risk of second brain tumors was 2.0% (CI, 0.9-4.4) at 10 years and 2.4% (95% CI, 1.2-5.0) at 20 years. The relative risk of a second brain tumor compared with the incidence in the normal population is 10.5 (95% CI, 4.3-16.7) [8].

The incidence of radiation-induced sarcomas has been estimated at 0.03% to 0.3% of patients who have undergone radiation therapy. The risk of radiation-induced sarcomas increases with field size and dose. In a systemic review and analysis of 180 cases of radiation-induced intracranial sarcomas, the average dose of radiation delivered was 51.4 ± 18.6 Gy and latent period of sarcoma onset was 12.4 ± 8.6 years. A total of 49 cases were developed after radiation treatment of pituitary adenomas (27.2%). The median overall survival time for all patients with sarcoma was 11 months, with a 5-year survival rate of 14.3% [9].

Our patient received approximately 50 Gy twice through fractionated radiotherapy, resulting in larger field size and significantly higher dose than one would expect with a modern stereotactic treatment. Such a high dose of radiation is indeed a risk factor for secondary malignancy. In our patient, in a period of 2 months, there was already >30% tumor growth after recent repeat decompression surgery.

The risk of secondary malignancy is thought to be much lower with stereotactic radiosurgery than conventional external beam radiation therapy, with an estimated cumulative incidence of 0.045% over 10 years (95% CI, 0.00-0.34) [10]. However, long-term follow-up data for patients receiving stereotactic radiation therapy are shorter and thus definitive conclusions cannot be made at this stage.

Our case highlights a rare but devastating long-term complication of pituitary tumor irradiation after Cushing disease. The limited response to various available treatment options defines the aggressive nature of radiation-induced malignancy.

Learning Points

  • The occurrence of a second neoplasm constitutes possibly one of the most adverse and rare complication after radiotherapy.
  • The incidence of radiation-induced sarcomas has been estimated at 0.03% to 0.3% of patients, but cases after Cushing disease are rarely reported.
  • Patients often present with advanced disease unresponsive to various treatment modalities because of aggressive clinical course.
  • New modalities with stereotactic radiosurgery and proton beam therapy are to be reviewed closely for risk assessment of secondary tumor.

Acknowledgments

The authors acknowledge Dr. Ishani Mohapatra for her support with histopathology and interpretation.

Contributors

All authors made individual contributions to authorship. G.B., S.K.M., and V.A.R. were involved in diagnosis and management of the patient. G.B. was involved in the writing of this manuscript and submission. V.P.S. was responsible for patient surgeries. All authors reviewed and approved the final draft.

Funding

The authors received no financial support for the research, authorship, and/or publication of this article.

Disclosures

The authors have nothing to disclose.

Informed Patient Consent for Publication

Signed informed consent could not be obtained from the patient or a proxy but was approved by the treating institute.

Data Availability Statement

Data sharing is not applicable to this article as no data sets were generated or analyzed during the current study.

© The Author(s) 2023. Published by Oxford University Press on behalf of the Endocrine Society.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.

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