View clinical trials related to Adrenal Insufficiency.
Filter by:In mitotane treated patients, serum cortisol cannot be used to diagnose hypoadrenalism, since mitotane increases cortisol binding globulin levels (CBG), artificially raising total cortisol. Salivary free cortisol (SC) is not affected by CBG alterations, and reflects the free serum cortisol. In the current study, investigators will assess serum and SC responses during low-dose cosyntropin stimulation test in healthy volunteers, mitotane-induced hypoadrenal patients on steroid replacement therapy and in patients who suffer from hypoadrenlism caused from other etiology. Investigators will compare results between groups and try to demonstrate the superiority of SC in assessing adrenal function in mitotane treated patients.
Previous study showed that afternoon cosyntropin testing was associated with a sevenfold increased likelihood of failing the 1μg test. However, in that study, investigators used a 20.3 cm plastic tube, which might have led to uncompleted cosyntropin delivery. In ther current study investigators will study afternoon 1μg cosyntropin cortisol stimulation using a short 2.5 cm tube.
This was an open label, randomised, single dose study, comprising Part A (undertaken in two separate three-period crossover cohorts denoted as A1 and A2) and Part B (undertaken in one four-period crossover cohort), to evaluate the PK of Chronocort® in healthy male volunteers. The washout interval in both Part A and Part B was 1-week in between each treatment period.
This was an open label, randomized, single dose, three period crossover pharmacokinetic study of Chronocort® in 30 healthy male volunteers. The study was conducted in smaller sub groups (Group 1, n=18 and Group 2, n=12).
To describe clinical outcomes and both primary and secondary care health care resource use in patients who have been prescribed either immediate-release (IR) hydrocortisone or modified-release (MR) hydrocortisone or prednisolone in the UK.
The purpose of this study is to compare cardio-metabolic risk, glucose tolerance, and night time blood pressure between healthy control subjects and patients with adrenal insufficiency. No intervention will be administered and the study is observational only.
Little is known regarding the incidence and clinical impact of AI in neonates during the acute postoperative period following separation from CPB. In a randomized control pilot study performed by the UAB CVICU research team, prophylactic post-CPB hydrocortisone infusions improved some postoperative outcomes, especially in those that acquired AI7. In an attempt to further explore post-CPB AI, a retrospective analysis of data from this study was performed. Of the 40 neonates included in the study, one-third (32.5%) developed AI following CPB (as determined by low-dose, 1 µg, cosyntropin stimulation test). Almost all of these subjects had normal response to cosyntropin stimulation pre-CPB. Subjects that developed AI demonstrated more hemodynamic instability, increased serum lactate and required more colloid resuscitation in the immediate post-CPB period in the operating room. Recent evidence has begun to highlight potential morbidity associated with perioperative steroid administration. Our cardiac surgery program is changing clinical practice and ceasing to give preoperative steroids to all patients (previously only neonatal CPB patients received preoperative methylprednisolone). With the possibility that preoperative steroid administration, and not CPB, primarily causes the high incidence of AI, it is prudent to further investigate the benefit and/or harm of perioperative steroid administration
The study will investigate 27 hour profiles of hormones in the subcutaneous tissue of healthy subjects and patients with Addison's, Congenital Adrenal Hyperplasia, Growth Hormone Deficiency, acromegaly, Cushings and Primary Hyperaldosteronism during conventional diagnostic and therapeutic follow-up. The 27 hour monitoring by ULTRADIAN takes into account the rhythm of hormones throughout the day. It is hoped that this information may in the future improve and simplify diagnostic procedures. Follow-up of patients in endocrinology still remains difficult including clinical signs of over and under-treatment, questionnaires of quality of life and blood testing necessitating often retesting. Simplification of the diagnostic procedure by obtaining detailed knowledge about the rhythm of hormones may contribute to the improvement and individualization of treatment and may decrease morbidity and mortality of endocrine patients.
There are two main stimulation tests used to decide if a patient has cortisol deficiency. It is the "synacthen test", were we stimulate the patient with intramuscular or intravenous synacthen ( ACTH) to see how much cortisol the adrenals are capable of producing, and it is the "Insulin hypoglycemia test" were we give the patient insulin to provoke a hypoglycemia, and look at the adrenal response to that stimulus. The cut off values for a normal response is based on old immunological assays no longer in use. Assays with a lot of interference and cross reactivity leading to measurement of higher values for cortisol than what we measure on the highly specific LCMS/MS ( Liquid chromatography mass spectrometry methode) that we are using for cortisol today. So, there is a need for new cut off values for a normal response to such tests. The purpose of this study is to produce such new cutoff values by performing the test in 120 healthy controls. We also want to perform the test in patient groups normally going trough this tests according to the same protocol as the control persons, to evaluate the new cutoffs in different patient groups.
Background: Endocrine glands give off hormones. Researchers want to learn more about the disorders that affect these glands in children. These disorders might be caused by changes in genes. Genes contain DNA, which is the blueprint of how a cell works. Researchers want to identify the genes involved in endocrine and metabolic disorders. This might help develop new ways to diagnose and treat the disorders. Objective: To study the inheritance of endocrine or metabolism disorders. Eligibility: Children ages 3month-18 with known or suspected endocrine or metabolism disorders. Family members ages 3months-100. They may participate in the DNA part of the study. Design: Participants will be screened with a review of their medical records. Their parents or guardians will allow the records to be released. Participants will have a clinic visit. This may include a physical exam and medical history. Parents or guardians will give their consent for the study. Participants may have tests, surgery, or other procedures to help diagnose or treat their condition. These could include: Blood, urine, and saliva tests Growth hormone test Pituitary and adrenal function tests Picture of chromosomes Imaging tests. These may include X-ray, ultrasound, scans, or a skeletal survey. Genetic tests Sleep study Medical photographs If surgery is done, a tissue sample will be taken. Participants may have follow-up visits for diagnosis and treatment. Participating relatives will have one visit. This will include medical history and blood and saliva tests. The blood and saliva will be used for DNA testing.