5 Clinical Trials for Hemangioma
The purpose of this study is to find out if pulsed dye laser treatment or timolol maleate 0.5% gel can help infants who have a hemangioma. The investigators also want to find out if pulsed dye laser treatment and timolol maleate 0.5% gel are safe to use without causing too many side effects. Hemangioma is a common type of birthmark. These birthmarks happen when many new blood vessels grow in a specific area on the skin. Blood vessels are tiny tubes that carry blood through the body. No one knows what causes blood vessels to group together. Most birthmarks don't hurt at all and they usually aren't a sign of any kind of illness. Lots of newborns have these birthmarks on their bodies, like between the eyebrows. These birthmarks usually disappear within the first few months to years of life. These birthmarks tend to disappear spontaneously. Most hemangiomas are not treated unless the hemangioma threatens the child's health, which occurs in about 1 in 3 children with hemagiomas. Pulsed dye laser is widely used in children, and is approved by the U.S. Food and Drug Administration (FDA) for treating hemangioma. The FDA has approved timolol maleate to treat glaucoma in adults, but the FDA has not approved timolol maleate to treat hemangiomas in children. About 7 infants with hemangiomas have received timolol maleate. The results so far show that timolol maleate may be helpful and safe in treating hemangiomas in infants. An important question being tested in this study is whether pulsed-dye laser or timolol maleate can prevent hemangioma from growing when used very early after birth.
The purpose of this study is to assess the baseline sleep pattern disruption for patients starting oral propranolol at the standard BID dosing regimen compared to the control (timolol) group and to determine if there is a significant improvement in the sleep patterns in infants taking oral propranolol on the TID dosing regimen versus the control (timolol) group
The project aims to develop prognostic and diagnostic blood tests for symptomatic brain hemorrhage in patients diagnosed with cavernous angiomas, a critical clinical challenge in a disease affecting more than a million Americans. We further examine whether blood biomarkers can replace or enhance the accuracy of advanced imaging in association with lesional bleeding. The project tests a novel integrational approach of biomarker development in a mechanistically defined cerebrovascular disease, with a clinically relevant context of use.
Lymphatic anomalies are a rare subset of vascular anomalies that are poorly understood. the understanding of the natural history, long-term outcomes, risk factors for morbidity and mortality, and the relative benefit of medical therapies and procedures is limited.The goal of this project is to better understand these diseases and improve the care of theses rare patients. To do this, the investigators are conducting an observational study of patients with lymphatic anomalies, including an annual follow-up questionnaire to gather prospective data on mortality, morbidity, treatments, and functionality as well as quality of life.
Background: Ollier disease (OD) and Maffucci syndrome (MS) are rare disorders that increase the risk of cancers in cartilage tissue. These tumors can lead to severe skeletal deformities beginning in childhood. People with OD or MS are also at an increased risk of blood vessel disorders and specific cancers. Researchers want to learn more about what causes these disorders. Objective: To understand the genetic causes of OD and MS. Eligibility: People aged 2 years and older who have OD or MS with cartilage tumors or blood vessel disorders. Design: Participants will stay at the NIH clinic for 5 days. They will undergo these procedures: A physical exam with blood tests. DXA (dual-energy X-ray absorptiometry) scan. The DXA scan measures the density of bones. Participants will lie on a table while a machine uses low-level X-rays to scan their body. MRI (magnetic resonance imaging) scan. An MRI uses strong magnets to take pictures of the tissues inside the body. Participants will lie on a table that slides into a large tube. A contrast dye may be injected through a needle inserted into a vein in the arm. X-rays. Some participants may have full-body X-rays instead of an MRI. X-rays take pictures of bones and other internal tissues and organs, such as the heart, lungs, and airways. PET (positron emission tomography) and CT (computed tomography) scans. Adult participants will have 2 other scans. The PET scan will include a radioactive injection into a vein. They will also have a full-body CT scan.