View clinical trials related to Endocrine System Diseases.
Filter by:The study aims at identifying the predictive markers after one month of Saizen therapy in Growth Hormone Deficiency (GHD) and Turner Syndrome children.
This project is designed to answer the question: Is there an acute IGFBP-3 response in normal children? Our specific hypothesis states that under the influence of growth hormone secretagogues, intact IGFBP-3 molecule will undergo proteolysis and liberate IGFBP-3 fragments, along with other components of the ternary complex. This proteolysis will result in measurable rise in IGFBP-3, which will indicate the subject’s growth hormone status. Short children with growth hormone deficiency will not show an IGFBP-3 response.
To evaluate long-term safety of growth hormone replacement in adult patients with growth hormone deficiency
Multi-center, randomized, controlled, open-label, phase III study comparing the effects of two different dosages of somatropin treatment (in-label or doubled) after 12 and 24 months of treatment, on height velocity in early pubertal children with growth hormone deficiency (GHD). The study will be conducted in Italy. Approximately 26 subjects will participate in this study, distributed as 13 in the in-label dosage group (group A) and 13 in the doubled dosage group (group B).
This trial is conducted in Japan. To investigate the long-term efficacy as assessed by change in fat mass and safety after 48 weeks of treatment of Growth Hormone in adults with Growth Hormone Deficiency, comparing two different treatment regiments.
This trial is conducted in Japan. This protocol describes an extension trial to supply hGH to subjects who wish continuous treatment after the long-term Phase 3 trial (GHLiquid-1519) until hGH products have been approved for GHDA in Japan.
This trial is conducted in Europe. Growth Hormone in young adults with growth hormone deficiency in childhood. This trial compares a treated group of patients with an untreated group of patients.
The purpose of the study is to evaluate the effects of growth hormone (GH) replacement in men and women with a history of acromegaly and who are now growth hormone deficient. We will compare them to persons with a history of acromegaly who have normal GH levels. Acromegaly results when an area in the brain, called the pituitary, produces too much growth hormone. When an individual is cured of acromegaly, the growth hormone levels may be normal or low (that is GH deficiency). Growth hormone deficiency means the body no longer produces as much growth hormone because the pituitary/hypothalamic region was damaged by a tumor or by treatment received. We will study the effects of growth hormone replacement on the health of the heart and blood vessels of GH deficient persons by looking to see if this therapy: 1. has effects on cardiovascular risk markers (special blood tests which indicate how healthy your heart and arteries are) 2. affects the stiffness of the arteries 3. affects your heart rate and the capacity of your heart to respond to changes in body position 4. has different effects depending on whether you are taking estrogen / testosterone. We will assess these measures of health on one occasion in persons with cured acromegaly and normal GH levels and in persons with cured acromegaly who have GH deficiency and a contraindication to receiving GH. GH deficient individuals with no contraindication to receiving GH, will participate in the study for 12 months. Individuals with normal GH levels, or who are GH deficient and have a contraindication to receiving GH, will be asked to return for one more visit (without any interventions).
To show an increase in annual growth rate 3 years after Visit 2. Annual growth rate in standard deviation (SD) after 3 years will be compared to growth rate before the start of GH treatment.
Growth hormone (GH) deficiency (GHD) in adulthood has been associated with changes in body composition (e.g. increased abdominal obesity, and reduced muscle mass), in organ functions (e.g. reduced cardiac systolic function), in metabolic parameters linked to increased risk of cardiovascular disease (e.g. increased serum total and LDL cholesterol, C reactive protein, and plasma fibrinogen), and with reduced bone density. These observations have been used to define the "adult GHD syndrome" and to advocate GH replacement therapy in GHD adults. However, most of the studies have been performed in patients who have had hypothalamic or pituitary diseases, and/or have undergone brain irradiation. Such patients are often chronically sick, and commonly lack other pituitary hormones, whose replacement therapies may not fully restore the physiological functions of the under-active glands. Reliable data on the existence of the AGHD syndrome and its response to GH therapy can be only obtained by studying patients that are otherwise healthy. However, isolated GH deficiency (IGHD) is a rare disease. In addition, up to 50% of patients who have been diagnosed with IGHD in childhood are no longer GH deficient as adults, making such study difficult to perform due to the scarcity of patients population. We have identified a very large homogeneous population of patients who have IGHD due to a homozygous mutation in the GHRH-receptor (GHRHR) gene that resides in a rural area of Brazil. None of the adult dwarf patients has ever been treated with hGH replacement. This population represents a unique model to study the effect of isolated lifetime lack of GH. We propose studies of physiological and metabolic parameters in subjects who are homozygous for this mutation and compare them with normal subjects residing in the same community. The primary goal of this proposal is to determine the consequences of life-long lack of GH on body composition, muscle strength, cardiovascular status, cardiovascular risk factors, thyroid status and bone density and metabolism, and to test which of these parameters are reversed by a 6-month course of GH replacement therapy. In addition, we want to test the hypothesis that heterozygosity for this GHRHR mutation causes a phenotype that may be intermediate between the one present in homozygous normal subjects and in homozygous affected GHD patients. This is relevant because inactivating mutations in the GHRHR are being described with increasing frequency in populations of different genetic background, suggesting that individuals with faulty single GHRHR alleles may be present in significant numbers in the general population.