View clinical trials related to Neoplastic Syndromes, Hereditary.
Filter by:An electronic decision aid will be used to assist individuals in choosing a multi-gene panel with their medical oncologist instead of a genetic counselor. A decision aid may facilitate quality decisions around the selection of a specific multi-gene panel without a genetic counselor. Upon completion of the decision aid, participants will be asked to indicate their decision about whether to pursue genetic testing and which specific multi-gene panel to pursue. A survey will then be administered to assess participants' opinions on the decision aid.
A prospective, non-interventional study to evaluate the impact of a process engineering intervention on screening and testing outcomes for common hereditary cancer syndromes in community-based OB/GYN settings.
Purpose This study is an 'N-of-one' observational study focusing on individuals with a hereditary predisposition to cancer due to a genetic mutation in the TP53 gene. An individual with this mutation has a >90% chance of developing many different forms of cancer in their lifetime. Since germline TP53 gene mutation carriers are highly susceptible to cancer, cancer prevention strategies and early cancer detection strategies are crucial. Unfortunately, the current standard of care for monitoring germline TP53 gene mutation carriers for early signs of cancer is yearly MRI scans and intermittent blood draws. Villani et al. showed that standard monitoring is inadequate and introduced a more sophisticated protocol for early cancer detection. We extended the Villani et al. protocol to include a number of markers for early detection and are currently vetting their utility, in terms of their inherent variability, patient tolerability of frequent interrogation, and ability to show changes that might indicate a need for further examination. In addition to the markers being collected, important covariate information, such as diet, sleep, and activities are being collected (via, e.g., wearable wireless devices) in order to take them into account in assessing the levels of the markers at a single data collection time or over time. One important aspect of the protocol is to identify changes, rather than specific levels, in marker status over time for an individual that might be indicative of tumor formation, essentially exploiting the concept of 'personalized thresholds' discussed by Drescher et al. If any indication of the presence of a cancer, tumorigenic process, or general sign of ill-health is observed, the protocol calls for a discussion of the findings among the research team, followed by a discussion between the clinical lead on the research team and the primary care provider and/or specialists overseeing a participating patient's care, possible validation of the assay(s) motivating the discussions, and a decision on how to intervene on the part of the primary care provider and/or specialists.
After informed consent, participants will be asked to complete a medical/family history questionnaire and provide a blood sample. Participants will also be asked for their permission for study investigators to access medical records and/or recontact them for updates to their medical and family histories. Data and biospecimens will be stored for potential future research projects.
This study will look at genetic changes which occur in the development of male and female breast cancer and other cancer. It will use a new technology called DNA microarray hybridization that looks at a wide array of genes to identify disease-associated patterns in the human genome (complete set of human genes). Numerous studies have linked particular genes to a given disease, but there is very little information on patterns of gene expression (production of proteins from genetic coding) in the entire human genome. Pinpointing genetic abnormalities in disease may help classify different forms of cancer and perhaps lead to new avenues of treatment or prevention. A primary goal of this study will be to create a database of gene expression for human cancers and other disorders that will provide the basis for finding genetic abnormalities in disease. Tumors specimens used in this study will be taken from tissues biopsied from patients with breast, colon cancer, sarcomas or melanoma as part of their routine care. Patients in the study will be among those receiving care at the: Department of Oncology, University Hospital, University of Lund, Sweden (breast cancer); Department of Medicine, University of Michigan, Ann Arbor, Michigan (breast cancer); Surgery Branch, National Cancer Institute, Bethesda, Maryland (melanoma), Johns Hopkins Univ. (colon cancer), Memorial Sloan Kettering (sarcoma). Patients in the study will have a family history taken and will complete a questionnaire. Some patients will be asked to have a blood test. Breast cancer patients will have a mammogram if one has not been done within the last year.
Investigation of the causes of genetic defects relating to hereditary urologic malignancies will be undertaken. These rare disorders result from inherited or newly arising mutations in genes involved in the development and function of different organ systems. As specific disease syndromes are recognized and the responsible genes identified, mutations in individual families can be identified. Correlation of mutation sites with clinical information will help determine how specific gene segments encode important functional protein domains. Families with urologic malignant disorders of known or suspected genetic basis will be enrolled. Genetic linkage studies will include all available family members, while gene sequence analysis will be performed on affected individuals. Unaffected family members or unrelated normal individuals will serve as controls. The family members will be identified by the proband or proband's parent when the initial pedigree is taken. Subjects considered by the investigators to be appropriate for linkage studies will be invited to participate by the local genetics provider or by the investigators, who will then connect these members to their own local providers for enrollment. In our studies of inherited urologic malignant disorders, there may be individuals from renal cancer families who do not undergo clinical evaluation for the presence of an inherited urologic malignant disorder at the National Institutes of Health because of their health problems, geographical location, or personal preference. Even though these individuals do not undergo a clinical evaluation of their suspected inherited urologic malignant disorder at the National Institutes of Health, they may have rare diseases that are extremely important to study. Therefore, we intend to collect blood samples for genetic studies from these individuals to facilitate linkage analysis and disease gene identification. Samples will be collected either by the individual's physician and sent to NIH, or will be collected by NIH physicians at either the individual's off-site location or at the NIH.
Women who are at high risk for breast cancer, either because of linkage to high risk breast and ovarian cancer families, or because of a carcinoma in the opposite breast, will be studied. Women will have a physical examination and mammography to ensure that no breast abnormalities are present. Eligible women will undergo biopsy of the breast to obtain normal breast tissue. Short-term cell cultures will be established from this tissue and early passages of the short-term cell lines will be stored. A bank of high risk normal mammary epithelial cells will be established. To further characterize the mammary epithelial cells in this population of women, cell cultures will subsequently be analyzed for their growth and metabolic properties, sensitivity to chemopreventive agents, steroid receptor characteristics, oncogene expression and regulation, and genetic changes.
The purpose of this study is to identify affected individuals in families with prostate cancer and to use this information to identify genetic markers closely-linked to the disease gene.