View clinical trials related to Short Stature.
Filter by:The purpose of the study is to evaluate the predictive value of IGF-1 generation test for growth velocity during GH treatment for 12 months.
Proper growth in children is a complex process regulated by a combination of genetic, nutritional, environmental, hormonal, and others. Growth hormone (GH) is the main hormone regulating the growth from childhood to adulthood. Despite great progress in the field, with the development of recombinant GH for the treatment of growth hormone deficiency (GHD), there is still no reliable method for testing GHD. Physical exertion is one of the significant physiologic stimuli for GH secretion, and it is reliable test for identification of GHD. It is not in use in the clinics because of its complexity. Recently GH secretion following short anaerobic exercise in young adults was tested and also demonstrated significant growth hormone secretion In contrast to adult children's exercise is characterized by an anaerobic nature. There is no data about secretion of growth hormone in response to anaerobic exercise in children. Purpose of the experiment: The purpose of this study is to evaluate the secretion of growth hormone in response to anaerobic exercise in children.
The purpose of this study is to measure the effect of weekly zinc supplementation on schoolchildren with growth deficit or normal stature.
CML is a myeloproliferative disorder defined by the presence of the Philadelphia chromosome, which arises from the reciprocal translocation of genes on chromosomes 9 and 22.It is rare in childhood and accounts for 2-3% of all leukemias in childhood. BCR-ABL gene on Philadelphia chromosome results in a 210kd fused BCR-ABL protein with constitutive tyrosine kinase activity, and subsequent activation of cytoplasmic and nuclear signal transduction pathways including STAT, RAS, JUN, MYC, and phosphatidylinositol-3 kinase. The ultimate result of such activation is the myeloid proliferation and differentiation and suppressed apoptosis. Children present with a higher WBC count, otherwise presentation is nearly identical to adults. Current treatment include tyrosine kinase inhibitors (TKI) and allogeneic stem cell transplant (SCT).Imatinibmesylate inhibits the tyrosine kinase (TK) activity of BCR-ABL1 and several related TKs, including c-kit and the platelet-derived growth factor receptor (PDGFR). Development of tyrosine kinase inhibitor (TKI) therapy has revolutionizedtreatment of CML. Imatinib or second generation TKIs (dasatinib or nilotinib) have become standard front-line therapy forchildren and adults with CML and are also important componentsof therapy for Ph+ acute lymphoblastic leukemia (ALL). TKIs are administered orally and cause a number of side effects including fatigue, hypertension, rash, impaired wound healing, myelosuppression, and diarrhea . The overall toxicity of TKIs, while less life-threatening than conventional cytotoxic chemotherapy, nevertheless is common, and may require dose reduction.Recently, proposed endocrine-related side effects of these agents include alterations in thyroid function, bone metabolism, linear growth, gonadal function, fetal development, glucose metabolism and adrenal function. Growth impairment is one of the major adverse effect of long-term imatinib treatment in children with CML. Multiple case reports have demonstrated growth retardation in children onimatinib.Imatinibmesylate inhibits the TK activity of BCR-ABL1 and several related TKs, including c-kit and theplatelet-derived growth factor receptor (PDGFR). It isthe inhibition of TK activity at the non-BCR-ABL sites that couldbe the likely cause for the adverse effect on growth. Severalstudies in adults have suggested that inhibition of c-kit,c-fms, and PDGF receptors results in modulation of bone metabolism. Other reports are focusing on disturbance of the growth hormone (GH) axis as a mechanism for growth impairment. Receptor and non receptor TK is expressed at multiple levels in GH-IGF-1 axis including GHRH-R, GH-R and IGF-1R. Inhibition of TKs with TKI, at any one of these level, might result in growth impairment. Various studies are available to show that Imainib therapy may cause short stature in children on prolonged treatment but exact mechanism by which this occurs is still not clear. Further, no treatment modality has been tried so far, for short stature in these children. So, the purpose of this study is to study GH-IGF1 axis in these children and to administer GH therapy to GH deficienct children in remission.
Background: - Overweight and obese children and adults often have lower levels of growth hormone in the blood. Regulation of growth hormone may be tied to weight and free fatty acids in the blood. Current tests of growth hormone (such as those used when evaluating the heights of children who are markedly shorter than other children of comparable age) may be affected by other factors, including obesity. Researchers are interested in evaluating the levels of growth hormone and free fatty acids in the blood of children between 7 and 14 years of age who weigh more than children of a comparable age, or who are shorter than other children of a comparable age and have been recommended for growth hormone testing as part of an evaluation for their height. Objectives: - To determine the effect of changes in free fatty acids in the blood on changes in growth hormone secretion in overweight or shorter children and young adolescents. Eligibility: - Children and adolescents between 7 and 14 years of age who weigh more than or are shorter than other children of a comparable age and do not have any medical illnesses. Design: - Participants will have two study visits, one of which will be a half day screening visit in the outpatient clinic and one of which will require 2 nights as an inpatient at the National Institutes of Health Clinical Center. - Participants should not eat or drink anything except water after 10 PM the night before or on the morning of the screening visit. - At the screening visit, participants will have a physical examination and medical history, provide blood and urine samples, have an oral glucose tolerance test (to check blood sugar levels), and have an x-ray of the left hand to check bone age. - The inpatient study visit will involve a physical examination and medical history, a full x-ray scan to study body fat and muscle, frequent blood tests throughout the visit, and various medications to stimulate growth hormone production and lower levels of free fatty acids in the blood.
Obesity, now a global epidemic, is a leading cause of illness and mortality in the developed world. To better understand the pathophysiological mechanisms that underlie weight disorders, increasing attention is being paid to central regulatory elements in energy homeostasis, including food intake and energy expenditure. The human hormone ghrelin is secreted as a preprohormone (preproghrelin), from which two hormones with antagonistic effects are derived: ghrelin, which has orexigenic effects and obestatin, which has anorexigenic effects. Ghrelin's actions are mediated by GH secretagogue receptor (GHSR). Ghrelin synthesis occurs predominantly in epithelial cells of the fundus of the stomach. . As the ligand for GHSR, ghrelin stimulates secretion of GH. In both rodents and humans, ghrelin regulates hunger though its action on hypothalamic feeding centers. Other effects of ghrelin include stimulating gastric emptying, positive effects on cardiovascular function, increasing intestinal peristalsis, and positive exocrine and paracrine pancreatic secretion. Despite its important physiological role, its precise regulatory mechanisms remain ambiguous. Thus, it has been suggested that mutations in ghrelin and its receptor will present clinically with obesity, eating disorders or growth disturbances. To date, only four different mutations have been reported in GHSR and no mutations have been found in the ghrelin gene. Working hypothesis and aims: We hypothesize that mutations in ghrelin or in its receptor, GHSR, affect appetite regulation and cause growth and eating disorders.
This is a two arm, randomized, prospective, intervention study in order to determine the effects of growth hormone treatment on eating regulation and to compare between the growth responses with or without nutritional intervention in short stature children. The study will include 30 short stature children that are about to initiate growth hormone treatment and will last for one year. After 4 months of treatment, children will be randomized into two groups: 1. Control group that will continue with growth hormone treatment without any other intervention. 2. Study group that will be a given a nutritional intervention in addition to growth hormone treatment. At screening visit and during the study the following parameters will be evaluated: height, weight, growth markers in the blood and urine, child eating behavior questionnaire, blood tests, hormonal tests and resting energy expenditure measurements.
The protein polymorphism of the growth hormone receptor characterized by the genomic deletion of exon 3 has been linked to the magnitude of the first-year-growth response to growth hormone (GH) in girls with Turner syndrome. Objective: to study the long-term effect of GH therapy in Turner syndrome in correlation to this GHR polymorphism in a mainly retrospective design (chart-review).
Objective: This study is designed to determine whether growth hormone treatment in children 8 to 18 years of age alters function of the lining of the arteries. This may play a role in increasing or decreasing the risk of heart disease. Methods. Twenty children, for whom growth hormone therapy will be otherwise provided, will be studied before and 3 months after starting growth hormone. Subjects can be on other hormonal replacements but no other medications. Each study will be done in the fasting state. The blood vessel function will be determined by measuring the change in forearm blood flow before and after blocking flow to the arm for 5 minutes. Blood will be drawn after the test to measure glucose, insulin and fats.
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.