View clinical trials related to Polymorphism, Genetic.
Filter by:1. The plasma concentrations of agomelatine and its two metabolites are simultaneously determined by High performance liquid chromatography-tandem mass spectrometry; 2. The gene polymorphisms of CYP1A2, ABCB1 and CYP2C9 are detected by fluorescence in situ hybridization or fluorescence polymerase chain reaction; 3. The correlation of CYP1A2, ABCB1, CYP2C9 gene polymorphisms with the blood concentration of agomelatine and its two metabolites is investigated by pharmacokinetic study; 4. According to the correlation between the above genotypes and blood drug concentration, a lean medication guidance scheme for agomelatine will be formed.
Nausea and vomiting affects 25-30% of individuals in the post-operative period and can reach more than 70-80% in high-risk patients. inherited factors may play a significant role in individual susceptibility and clinical research on hereditary factors involved in the pathogenesis of Postoperative nausea and vomiting (PONV) and chemotherapy nausea and vomiting (CINV) is relatively new. The aim of this study is to investigate whether inter-individual differences related to PONV are associated with genetic factors. 300 patients will be evaluated in postoperative oncological surgeries. The peripheral leukocyte DNA will be extracted by the Salting Out Procedure method and processed to genotyping for 48 SNPs from 15 candidate genes by real-time PCR by the Taqman method. The possible associations with demographic data and factors related to surgery will be analyzed by univariate and multivariate analysis.
The study will compare two invasive methods (FFR -fractional flow reserve and iFR—instantaneous wave free ratio) for assessment of hemodynamic impact of coronary stenosis on myocardial perfusion. There is a very good correlation between these methods for the assessment of hemodynamic significance in a broad spectrum of lesions. However, this correlation decreases significantly near the cut off points for each method. The investigators will try to find possible explanations for these differences by detailed morphology assessment of coronary stenosis using optical coherence tomography (OCT), analysis of gene polymorphisms that play a role in vasodilatation, and by shear stress analysis. The head-to-head comparison between FFR and iFR is not simple, because there is no "gold standard" for assessment of hemodynamic significance. Studies comparing these methods have used hyperemic stenosis resistance (HSR). For this kind of measurement it is necessary to measure the speed of blood flow. This is usually done by a Doppler analysis of flow. Unfortunately, the Doppler signal can yield many artificial or erroneous indicators, and obtaining a good quality signal is frequently time-consuming. These are the reasons that HSR has not been used in routine practice. The investigators have developed a new console and software that can provide real time analysis of the Doppler signal. It allows us to easily measure HSR, and to differentiate between the FFR and iFR measures through intrabeat analysis of microvascular resistance (lowest microvascular resistance is an essential condition for proper pressure measurement). Using this tool, it is possible to automatically identify the point of lowest microvascular resistance during each cardiac beat. The pressure gradient can then be measured at that point. This approach can eliminate almost all uncertainties in assessment of the pressure gradient produced by coronary stenosis. This tool can potentially improve the existing methods used to precisely reveal a significant stenosis. This should increase the number of hemodynamic guided procedures.
Background: - Differences in peoples genes can make them respond to drugs in different ways. Methadone and buprenorphine are two drugs used to treat drug addiction. A study showed that African Americans with a certain genetic marker did better using one kind of drug treatment over the other. Researchers want to see if they can repeat these findings. They also want to study other things that affect how well people do in treatment. Objective: - To see if certain genetic markers and other facts about a person s life can predict how well they do in treatment for addiction to opioids and cocaine. Eligibility: - African American adults age 18 and over. They must be former or current participants in an Archway Treatment Clinic study. They must have been on a stable dose of either study drug for at least 12 weeks. They also must have given urine samples regularly for at least 10 weeks. Design: - Participants will come to the clinic for 1 visit lasting about 2 hours. - Participants will give 1 teaspoon of blood for genetic testing. They will be asked if their sample can be used in future studies. - If researchers cannot get enough blood, they will do a cheek swab. This will collect skin cells for genetic testing. - Participants will fill out 3 questionnaires. - Results of genetic testing and answers to questionnaires will be kept private.
The purpose of the study is to assess the status of brain-derived neurotrophic factor brain (BDNF) and how the brain behaves in response to skill acquisition. Specifically we will investigate the relationship of the status of BDNF with cortical excitability changes and learning that occur during a motor training paradigm. We aim to 1) determine cortical excitability changes by using transcranial magnetic stimulation (TMS) before and after training; 2) to determine finger tracking accuracy before and after training; and 3) determine the presence of BDNF polymorphism in each participant. We are testing healthy adults in this study, and eventually would like to apply to persons who have neurologic disorders such as stroke or dystonia. By applying a magnetic field to the outside of the head, electrical currents are produced within the brain that can stimulate brain tissue. Using TMS, the brain can be studied to gain a greater understanding of the mechanisms associated with cortical excitability in healthy and patient populations. There is limited knowledge of what influence genetic biomarkers such as BDNF have on cortical excitability changes within the cortex following learning. Studies have indicated that people without this certain gene are less likely to show changes in brain excitability during TMS and during motor learning than people with this gene
It is known that with increasing age sexual desire is declining in women. Decreasing levels of androgens are believed to have an influence, but cannot explain the loss of libido completely. A possible explanation might be that the effect of the androgen is depending on the functionality of the androgen receptor. It is known that this functionality is genetically determined by the polymorphism of the androgen receptor gene. In the gene there is a varying number of CAG-repeats: the longer the CAG-Repeat, the lower the functionality of the androgen receptor, the lower the effect of the androgens. In this pilot study, the investigators would like to invite 45 healthy heterosexual middle-aged women to the University Hospital of Bern, where they answer questionnaires about their sexual function and where they give a blood sample to assess the testosterone serum levels and the genetically determined androgen receptor subtype. The investigators believe that lower androgen levels and/or longer CAG-repeats in the androgen receptor gene are related to lower libido scores in healthy middle-aged women.
Background: - Previous research has shown that dopamine, a brain chemical, is involved in decision making. Different genes influence how much dopamine people have in their brains and how that affects their behavior. Researchers will study if genes associated with dopamine affect decision making and impulsiveness. All participants will take tests; some will have brain images taken. Researchers will study the test responses and images; they will look for how differences in these genes affect different types of decision making. Objectives: - To see if genes involved in a brain chemical, dopamine, are related to impulsiveness on behavioral tests. Eligibility: - Healthy adults ages 18 to 55. Design: - Participants will be screened with a medical history and physical exam. - All participants in this study will have at least 1 outpatient visit to the NIH Clinical Center. Each visit will last 2 4 hours. At the first visit: - A blood sample will be taken only from participants that have not been previously enrolled in 95-M-0150 - Participants will be given tests of their memory, attention, concentration, and thinking. - Some participants will have a second visit. It will be scheduled as soon as possible after the first. At the second visit: - Participants will have an MRI (magnetic resonance imaging). They will have to lie in a scanner for up to 2 hours. The MRI uses magnets, radio waves, and computers to produce detailed pictures of the brain. - Participants will repeat the tests from the first visit. Some will be done during the MRI.
Background: - Small differences in genes may alter responses to drugs. One gene that has different forms is the mu opioid receptor gene. People with one form of this gene are more sensitive to alcohol. People with a different form are sometimes more sensitive to pain. Morphine and other prescription pain pills produce pain relief by acting at the mu opioid receptor. Researchers want to see the effect of morphine on brain reward and subjective effects. Morphine is a strong but short-acting pain medication that is sometimes used for anesthesia during surgery. Objectives: - To compare the effect of morphine on brain measures of dopamine release using imaging. Eligibility: - Individuals between 21 and 55 years of age who have previously taken pain pills prescribed to treat pain from a medical or dental procedure. Design: - This study has a screening phase and a study phase. The screening phase involves one or two visits of 5 to 6 hours. The study phase consists of 4 study visits. Each study visit will take about 8 hours. - Participants will be screened with a medical and psychiatric history and physical exam. They will be asked about drinking and drug-taking history, and any family history of alcoholism or drug abuse. Blood, urine, and breath samples will be collected. - During the first study visit, an MRI scan may be performed, questionnaires completed, and a blood sample collected for genetic testing. - During study visit 2, participants will test their pain sensitivity by placing one hand in cold water. Pupil diameter will be measured after the sensitivity test. After a blood sample is taken, participants will receive the morphine or a salt solution. The sensitivity test and pupil diameter test will be repeated. Final blood samples will be collected. A brief physical exam will also be performed. - During study visits 3 and 4, participants will receive morphine or a salt solution during a PET scan. Questionnaires to assess subjective effects will be administered. Final blood samples will be collected. A brief physical exam will also be performed. - Participants will stay in the clinic until the effects of the drug have worn off after study visits 2, 3, and 4. - About 1 week after the study session, participants will have a follow-up phone call.
Background: - Many people who lose a limb feel pain in the missing limb. This feeling is called phantom limb pain. Researchers do not fully understand what causes this pain. Differences in people's genes may play a role. Comparing the genes of people with and without phantom limb pain may help researchers better understand this feeling, who is likely to develop it, and how to treat it. Objectives: - To study whether genetic differences affect phantom limb pain. Eligibility: - Individuals at least 18 years of age who have lost an arm or leg at least 3 months ago. Design: - Participants will be screened with a medical history and physical exam. - Participants will answer questions about how they lost the limb, and whether they feel phantom limb pain. They will also have a test to measure their sensitivity to heat and cold. - Participants will provide a blood sample for genetic testing.
Goal: The primary goal of this study is to longitudinally investigate, in head and neck cancer (HNC) patients, the potential fibrosis-lymphedema continuum. Specifically, we will examine the development, patterns, progression, and prevalence of late-effect fibrosis and/or lymphedema, explore potential biological correlatives including pro-inflammatory cytokines and genetic polymorphisms, and evaluate the relationship among late-effect fibrosis and/or lymphedema and select psychosocial stressors that potentially interact with cytokine pathways. H: A minimum of 20 percent of HNC patients will experience late-effect fibrosis and/or lymphedema. H: We will be able to differentiate characteristics patterns of the development of late-effect fibrosis and/or lymphedema. H: We will be able to differentiate patterns of symptoms associated with late-effect fibrosis and/or lymphedema. H: We will be able to differentiate patterns of inflammatory response and the development of late-effect fibrosis and/or lymphedema. H: Select polymorphisms will increase the likelihood of development of late-effect fibrosis and/or lymphedema. H: Incidence and severity of late-effect fibrosis and/or lymphedema will correlate with total dose of radiation to involved anatomical site. H: HNC patients with fibrosis and/or lymphedema experience greater levels of depression and social withdrawal than those without these conditions.