View clinical trials related to Klinefelter Syndrome.
Filter by:To obtain whole blood specimens from pregnant subjects to be used for research and development and clinical validation studies of prenatal assays.
Klinefelter syndrome KS is caused by an additional X chromosome in males (47,XXY). Clinical findings are nonspecific during childhood; thus, the diagnosis commonly is made during adolescence or adulthood in males who have small testes with hypergonadotropic hypogonadism and gynecomastia. Virtually all men with Klinefelter syndrome are infertile. Approximately one in 1,000 boys is born with an additional X chromosome—47,XXY, the karyotype that causes Klinefelter syndrome. This karyotype is detected at or before birth in 10 percent of affected boys, and it is found during adulthood in 25 percent of affected men. Almost all men with a 47,XXY karyotype will be infertile; Klinefelter syndrome accounts for 3 percent of male infertility. Klinefelter syndrome is common in infertile men with oligospermia or azoospermia (5 to 10 percent). Infertility in men with Klinefelter syndrome is caused by a precipitous drop in sperm count. If sperm are present, cryopreservation is useful for future family planning with intracytoplasmic sperm injection, and if not, testicular sperm extraction may be pursued. Although there have been multiple reports of successful fertilization by men with Klinefelter syndrome. Mesenchymal stem cell injection in testicular tubules and intra testicular artery using surgical microscope. The period for follow up last from three months to twelve months including semen analysis to detect sperm and hormonal profile .
This research study in infant males with Klinefelter syndrome (47,XXY) will learn more about body composition (muscle and fat) and male hormones and look at the effect of testosterone shots on body composition. The Investigators know that older boys and men with Klinefelter syndrome often have more fat compared to muscle than adults without Klinefelter syndrome, but we do not know if this difference is present at birth or develops over time. The Investigators will learn if body composition and motor skills are improved with testosterone treatment in infants with Klinefelter syndrome.
Men with infertility and normal hormone levels have few options for fertility treatment. Previous research work has suggested that men with infertility may have low levels of the active form of Vitamin A, called retinoic acid, in their testes. We think that giving men with low sperm counts retinoic acid may increase their sperm counts and improve their chances of fathering a pregnancy. We want to see if retinoic acid administration over twenty weeks can increase sperm production and help infertile men become fathers without the need for In vitro fertilization (IVF) and/or intracytoplasmic sperm injection (ICSI). We also want to see if adding calcitriol with retinoic acid will improve sperm motility in a sub-set of subjects.
Klinefelter Syndrome (KS) is the most common sex chromosomal abnormalities (1/600 newborn males), and is characterized by a hypergonadism hypogonadism. Until few years ago, mostly non-mosaic KS was considered as a model of a complete male infertility although few KS (4-8%) have an oligospermia. Recent studies in adult with non-mosaic KS reported the possibility of sperm retrieval by testicular biopsy (TESE) in around 50% cases and more than some pregnancies have been obtained after TESE with Intracytoplasmic Sperm Injection (ICSI). Since 1997, more than one hundred births are described. As some studies shown a decrease of successful sperm retrieval with the increasing of age, we plan to compare the potential of sperm retrieval between two groups "adult" (23-55 years) and "young" after the onset of puberty (15-22 years). The study will be performed by searching spermatozoa on two seminal analyses spaced out 3 months followed by a testicular biopsy if the azoospermia is confirmed on semen analyses.
Klinefelter syndrome occurs in 1 in 600 males and is a common cause of infertility in men. It appears scar tissue forms in these boys' testicles, leading to progressive destruction over their lifetimes. Advanced reproductive technology can be used to surgically retrieve sperm from these individuals, but these methods have a 50% failure rate in adult Klinefelter patients. Younger men have higher success rates, suggesting that adolescence and young adulthood may be the best time to extract sperm, but these techniques have not been studied in Klinefelter patients younger than 26 years of age. Additionally, there is currently no way to predict which Klinefelter patients will have success with these methods and which of them will not. This trial will explore sperm extraction in Klinefelter syndrome in an age range (12-25 years) that has never been studied, with the ultimate hope of improving the potential for fertility in these patients. The specific goals of this study are to determine the ideal age for sperm retrieval in Klinefelter patients and to establish factors that can be used to predict which of these patients will have a higher likelihood of success with advanced reproductive technology. The hypothesis is that younger Klinefelter patients will have higher sperm retrieval rates.
Men with Klinefelter syndrome undergo unilateral subcapsular ochiectomy, and the removed testicular tissue is examined for presence of sperm and cryopreserved in small pieces for fertility treatment and scientific purposes. Prior to operation blood samples are frozen in a biobank.
This study will elucidate how the parental origin of the X-chromosome influences health status as well as metabolic fate in Klinefelter patients. Epigenetics and transcriptome-research will be directly linked to the metabolic and inflammatory pattern of actual patients to improve care for them. The Klinefelter Syndrome is one of the most common genetic disorders in men. The patients have one supernumerary X-chromosome, which is partly active and disturbs a normal male development. Testosterone deficiency in form of primary hypogonadism is a common feature in these men. Such a condition promotes clinically relevant metabolic patterns related to a pro-inflammatory status and diabetes mellitus type 2 (insulin resis-tance), cardiovascular disease as well as infertility. However, the variety of pathologies is pro-nounced between patients and low testosterone concentrations cannot fully explain the wide scope of pathologies in these men. Some patients become clinically obvious during puberty and adoles-cence, some in their thirties or later and all exhibit a huge variation in phenotype. Switching on and off of specific genes on the X-chromosome is differential, depending on the origin either from the maternal or paternal side. Hence, an influence on the clinical picture is hypothesised. Thus, key targets are clarification of the parental origin of the supernumerary X chromosome and elucidation of methylation and expression profile of pivotal X-chromosomal genes. These will be related to clinically relevant metabolic and inflammatory patterns as well as fertility to identify individual risks as well as treatment strategies for Klinefelter patients.
Klinefelter syndrome is the most common sex-chromosome disorder in men with a prevalence of 1 in 660 men. The syndrome is associated with hypogonadism. Many patients with Klinefelter syndrome have psychological complaints and physical discomfort. Some patients report a positive effect of testosterone treatment, whereas others do not. The aim of this study is: (i) To investigate quality of life in patients with Klinefelter syndrome. (ii) To investigate functional, physical and mental health in patients with Klinefelter syndrome. Questionnaire concerning mental and physical health and life quality are sent out to patients with KS and to age-, educational- and zipcode-matched men from the general population. The questionnaire include questions about housing, income, marital status, fatherhood, medication, chronic disease,school and education, attachment to the labor, sexual and erectile function, life quality, mental and physical health, satisfaction with life and symptoms of attention deficits hyperactivity disorders.
The human genetic material consists of 46 chromosomes of which two are sex chromosomes. The sex-chromosome from the mother is the X and from the father the Y-chromosome. Hence a male consist of one Y and one X chromosome and a female of 2 X-chromosomes. Alterations in the number of sex-chromosomes and in particular the X-chromosome is fundamental to the development of numerous syndromes such as Turner syndrome (45,X), Klinefelter syndrome (47,XXY), triple X syndrome (47,XXX) and double Y syndrome (47,XYY). Despite the obvious association between the X-chromosome and disease only one gene has been shown to be of significance, namely the short stature homeobox gene (SHOX). Turner syndrome is the most well characterized and the typical diseases affecting the syndrome are: - An Increased risk of diseases where one's own immune system reacts against one's own body (autoimmune diseases) and where the cause of this is not known; For example diabetes and hypothyroidism. - Increased risk of abortion and death in uteri - Underdeveloped ovaries with the inability to produce sex hormones and being infertile. - Congenital malformations of the major arteries and the heart of unknown origin. - Alterations in the development of the brain, especially with respect to the social and cognitive dimensions. - Increased incidence obesity, hypertension, diabetes and osteoporosis. In healthy women with to normal X-chromosomes, the one of the X-chromosomes is switched off (silenced). The X-chromosome which is silenced varies from cell to cell. The silencing is controlled by a part of the X-chromosome designated XIC (X-inactivation center). The inactivation/silencing of the X-chromosome is initiated by a gene named Xist-gene (the X inactivation specific transcript).This gene encodes specific structures so called lincRNAs (long intervening specific transcripts) which are very similar to our genetic material (DNA) but which is not coding for proteins. The final result is that women are X-chromosome mosaics with one X-chromosome from the mother and the other X from the father. However, numerous genes on the X-chromosome escape this silencing process by an unknown mechanism. Approximately two third of the genes are silenced, 15 % avoid silencing and 20 percent are silenced or escape depending on the tissue of origin. The aforementioned long non-protein-coding parts of our genetic material (LincRNAs) are abundant and produced in large quantities but their wole as respect to health and disease need further clarification. Studies indicate that these LincRNAs interact with the protein coding part of our genetic material modifying which genes are translated into proteins and which are not. During this re-modelling there is left foot prints on the genetic material which can indicate if it is a modification that results in silencing or translation of the gene. It is possible to map these foot prints along the entire X-chromosome using molecular techniques like ChIP (Chromatin immunoprecipitation) and ChIP-seq (deep sequencing). The understanding achieved so far as to the interplay between our genetic material and disease has arisen from genetic syndromes which as the X-chromosome syndromes are relatively frequent and show clear manifestations of disease giving the researcher a possibility to identify genetic material linked to the disease. Turner and Klinefelter syndrome are, as the remaining sex chromosome syndromes, excellent human disease models and can as such help to elaborate on processes contributing to the development of diseases like diabetes, hypothyroidism, main artery dilation and ischemic heart disease. The purpose of the study is to: 1. Define the changes in the non-coding part of the X-chromosome. 2. Identify the transcriptome (non-coding part of the X-chromosome)as respect to the RNA generated from the X-chromosome. 3. Identify changes in the coding and non-coding parts of the X-chromosome which are specific in relation to Turner syndrome and which can explain the diseases seen in Turner syndrome. 4. Study tissue affected by disease in order to look for changes in the X-chromosome with respect to both the coding and non-coding part of the chromosome. 6. Determine if certain genes escape X-chromosome silencing and to establish if this is associated with the parent of origin.