Active clinical trials for "Cushing Syndrome"

Glucocorticoids are widely used for the treatment of chronic inflammatory diseases. Although glucocorticoids are effective in controlling disease symptoms, continuous use of the drugs can lead to suppression of adrenal hormones or excessive cortisol level in the blood stream. That is, excess blood cortisol level due to glucocorticoid exogenous supply can either inhibit the 'hypothalamus-pituitary-adrenal axis' for adrenal hormones production or result in Cushing symptoms. In the period between 1989 and 2008 in the UK, it was estimated that 0.6%-0.8% of the general adult population were long-term users of oral glucocorticoids. However, there is no data on the risk of adrenal suppression and Cushing syndrome due to chronic use of glucocorticoids in the UK to date. The aim of the study is to investigate the risk of adrenal insufficiency and Cushing syndrome due to long-term use of glucocorticoids in England.

This study will investigate the potential for FK506 binding protein 5 (FKBP5) (and other gene expression markers, for example pentraxin 3 [PTX-3], serum/glucocorticoid regulated kinase 1 [SGK1], and glycogen synthase kinase 3 beta [GSK3b]) to be developed as a biomarker for use in diagnosis of Cushing's syndrome, assessment of effectiveness of medical or surgical treatment, and detection of relapse of endogenous Cushing's syndrome after surgery.

This study investigates the effects of the glucocorticoid hormone cortisol on brain structure and function. Patients with Cushing's disease are studied before and after treatment. Brain imaging and neuropsychologic tests are used to study changes in the hippocampus and thinking and learning functions as well as mood during the period of elevated cortisol. At several intervals after treatment, these are reexamined to study the degree of reversibility of the abnormalities. The contribution of cortisol as well as testosterone and estrogen to dysfunction and recovery is studied. Since elevated cortisol and dysregulation of its secretory system occurs in a significant proportion of the aged and in Alzheimers Disease and Major Depressive Disorder, these studies will help advance knowledge of the role of cortisol in these conditions.

OBJECTIVES: I. Evaluate whether chronic hypercortisolemia is specifically toxic to hippocampal cells and causes structural reduction of hippocampal volume in patients with Cushing's syndrome. II. Determine whether reduced hippocampal volume is associated with specific memory dysfunction. III. Examine the relationships of adrenal androgen to hippocampal volume and memory dysfunction. IV. Examine the reversibility of hippocampal structural changes and cognitive dysfunction after cortisol levels are normalized.

This proposal will evaluate the glucocorticoid mediated changes in body fat distribution and metabolism that occur in patients with Cushing's disease. The objective is to identify the mechanisms that influence both the accumulation of lipodystrophic fat and also the changes in energy expenditure and metabolism that accompany them. The study is designed to determine if the high cortisol and AgRP levels in the blood of people living with Cushing's syndrome, either from taking steroid medications or from tumors, impact body fat and metabolism by turning off brown fat, which is a type of fat that increases one's metabolism.

Several studies have shown that lean mass, in particular muscle mass, is an excellent predictive survival factor in many diseases. A better knowledge of the mechanisms responsible for muscle atrophy and the identification of atrophic process markers are deeply needed for the development of new anti-atrophic therapies. Either as drugs used to treat several medical conditions or as endocrine hormones released in response to many stress situations (e.g., sepsis, cancer, insulinopenia…), glucocorticoids (GC) are recognized to play a major role in skeletal muscle atrophy. Indeed, the inhibition of GC action by a receptor antagonist (RU486) or by muscle-specific invalidation of the GC receptor inhibits the muscle atrophy in these stress situations. Therefore, all these data clearly indicate that GC play a major role in skeletal muscle atrophy observed in several conditions. Emerging evidence has revealed that the skeletal muscle has a secretory function. Human skeletal muscle secretome was first estimated at about 300 proteins by computational analysis and proteomic analysis have recently confirmed these results. Some of these secreted proteins, conceptualized as myokines, can act locally on muscle cells through autocrine/paracrine loops and on surrounding tissues such as muscle blood vessels or can be released into the blood stream to produce systemic effects. One prominent example is interleukin (IL)-6 which is released into circulation by contracting skeletal muscle and can regulate metabolic and inflammatory processes. As IL-6, several other potential myokines have been identified including IL-8, IL-15, insulin-growth factor I (IGF-I), follistatin-like 1 (FSTL1) or fibroblast-growth factor (FGF)-21. Moreover, secreted proteins may also reflected metabolic changes which take place in muscle cells. Indeed, myoblast differentiation is accompanied by dramatic changes in the secreted proteins profile as increased expression of Semaphorins, IGF-I, matrix metalloproteinase (MMP)-2 or Collagens. Thereby, the investigators hypothesized that skeletal muscle atrophy induced by GC is associated with specific alterations of the muscle secretome. The aim of this project is to identify the GC-induced changes in the secretome of human skeletal muscle cells in culture (in vitro approach) and to determine how these changes translate into the circulation of subjects exposed to high concentrations of GC (Cushing's syndrome) (in vivo approach). Characterization of these changes in human subjects should allow to better understand the cellular mechanisms involved in muscle atrophy and might lead to identify circulating biomarkers associated with skeletal muscle atrophy, as telopeptides are for bone tissue.

Although most patients with hypercortisolism can be diagnosed and treated the long-term effects of hypercortisolism and its treatment are unknown. This study will attempt to answer the following questions: What is the rate of perioperative complications? Patients with Cushing syndrome often undergo transsphenoidal surgery of the pituitary gland as treatment for the disease. During this surgical procedure the pituitary gland is reached by passing through the sphenoid bone. The risk for patients to develop hypopituitarism in the immediate postoperative period is unknown. Patients with Cushing syndrome have abnormal levels of hormones circulating in the blood and affects of the surgery are often not apparent until long after the procedure. What is the recurrence rate? The recurrence rate of the disease has been estimated between 5 - 10%. However, these figures have not been confirmed. If the actual rate of recurrence is higher than estimated many patients may elect to undergo radiation therapy which has a lower rate of recurrence. Do any factors in the immediate postoperative period predict who will experience a recurrence of Cushing syndrome? What are the long-term complications of hypercortisolism? Studies have shown that patients with hypercortisolism have a four times greater risk of death than people of the same age without hypercortisolism. Researchers tend to believe this figure is too high. However, it is well established that hypercortisolism weakens bones (decreased bone density), causes secondary hypogonadism, increases levels of fat in the blood (hyperlipidemia), and decreases thyroid function (hypothyroidism). The potential for these conditions to be reversed is not known. These questions will be addressed by blood and urine sampling in the postoperative period, and by outpatient follow-up and periodic questionnaires in the first 10 years after curative surgery for Cushing syndrome performed at the NIH.

In this study, we aimed to determine a specific cut-off value for 1mg DST to prevent false positivity usually seen in CRF patients according to the standard cut-off value of 1.8 mcg/dl.

This study will test the accuracy of screening tests for Cushing s syndrome in overweight people with signs of the disorder. Cushing s syndrome is a rare disorder caused by excess production of the hormone cortisol. Patients may have various problems, such as weight gain, high blood pressure, diabetes, infections, mood problems, trouble concentrating, and increased blood clotting. These symptoms are seen in many other disorders as well, complicating the diagnosis. The reliability of tests currently used to diagnose Cushing s syndrome is not known. To test their accuracy, subjects in this study who test positive for Cushing s syndrome will be evaluated at NIH for 2 years to either confirm or refute the laboratory results. Patients between 18 and 75 years of age who are being treated at the George Washington University Weight Management Program (GWUWMP) may participate in this study. Candidates will be screened with a medical history, physical examination, measurement of body fat, blood tests, and oral glucose tolerance test. They will also complete a symptoms checklist and quality of life questionnaire. Participants will be tested for Cushing s syndrome with a saliva collection, 24-hour urine collection, and dexamethasone suppression test (DST). For the DST they will take 1 mg of dexamethasone at night and report to GWUWMP the next morning for a blood draw. All specimens blood, saliva, and urine will be tested for cortisol levels. People whose test results are abnormal will be seen at the NIH outpatient clinic for a medical history, physical examination, and blood tests; bedtime saliva collection; two 24-hour urine collections; and a 2-day 2-mg DST, followed by administration of corticotropin-releasing hormone (CRH). CRH is a naturally occurring hormone that causes cortisol levels to rise. Pre-treatment with dexamethasone prevents CRH from causing an increase in cortisol in healthy people, but not in patients with Cushing s syndrome. For the 2-day DST, the subject takes 0.5 mg dexamethasone every 6 hours for eight doses. Two hours after the last dose, CRH is injected through a catheter (thin plastic tube) inserted into an arm vein. Blood is drawn just before giving CRH to measure dexamethasone and cortisol levels and after giving CRH to measure cortisol levels. People whose test results are normal will not be seen further at NIH. Those with high cortisol levels will have repeat urine and saliva tests every 2 to 8 weeks for up to 24 months, and a 1-mg DST every 3 months during routine clinic visits at GWUWMP. People whose increased cortisol is found to be due to another condition besides Cushing s syndrome will be referred for evaluation and possible treatment. Those diagnosed with Cushing s syndrome will have standard tests to identify the tumor causing the disorder, followed by standard medical and surgical treatment.

Patients with Cushing disease have hormone producing tumors in their pituitary gland. Often these tumors are so small they cannot be detected by magnetic resonance imaging (MRI). The inferior petrosal sinuses are small veins that drain the blood from the pituitary gland. By taking a small sample of blood from these sinuses, doctors can differentiate a small tumor in the pituitary gland from other tumors in the body producing the hormone. Patients with Cushing disease have high levels of the hormone ACTH in the petrosal sinuses. Patients with other causes of Cushing syndrome do not have increased levels of ACTH in the petrosal sinuses. The procedure to collect blood from the petrosal sinus is called Inferior Petrosal Sinus Sampling (IPSS). The technique is very sensitive and can tell the difference between a pituitary tumor and other causes of Cushing syndrome nearly 100% of the time. However, IPSS is very difficult to perform and is only available in a few hospitals. Therefore, researchers are looking for another possible way to diagnose Cushing syndrome that would be less technically difficult and more readily available to patients. ACTH is produced in the pituitary gland as a response to the production of Corticotropin-Releasing Hormone (CRH) in the brain (hypothalamus). This study will compare ACTH levels in the internal jugular veins before and after CRH stimulation with those obtained by conventional IPSS from patients with Cushing's syndrome. Obtaining blood from the jugular veins is a simple, practically risk free procedure that could be done easily in a community hospital on an out patient basis. Researchers believe that CRH stimulation will increase ACTH production from tumors of the pituitary gland (corticotroph adenomas) so that the diagnostic information from jugular venous sampling would be equivalent to that of IPSS. This proposal to develop jugular venous sampling (JVS) with CRH stimulation as a test for the differential diagnosis of Cushing Syndrome would potentially contribute greatly to the medical care of patients with Cushing syndrome, as a less costly, safer and more widely available alternative to IPSS.<TAB>