9 Clinical Trials for Various Conditions
After initially successful treatment, many children with infantile spasms unfortunately have a relapse, and relapse is linked to poor long-term outcomes such as autism and other forms of epilepsy. The aim of this study is to determine if treatment with low-dose prednisolone is safe, well tolerated, and effective in reducing the risk of relapse.
Infantile spasms are a type of seizure linked to developmental issues. Unfortunately, they are often misdiagnosed, causing delays in treatment. The purpose of this study is to develop a computer program that can reliably differentiate infantile spasms from similar, yet benign movements in videos. This computer program will learn from videos taken by parents of study participants. Quickly recognizing and treating infantile spasms is crucial for ensuring the best developmental outcomes.
The study consists of cohorts where participants are randomized, in a 2:1 ratio, to 1 of 2 sequences, A and B. In each cohort, Sequence A, comprised of participants, who will receive ascending doses of ganaxolone and ascending doses of placebo. Sequence B, comprised of participants, who will receive ascending doses of placebo and ascending doses of ganaxolone. The dosing level in each subsequent cohort will be based upon experience gained from previous cohorts.
To allow open-label extension to patients who have completed Protocol 1042-0500
The main purpose of this study is to evaluate the efficacy of AMZ002 compared to Vigabatrin in participants with newly diagnosed infantile spasms (IS).
This study will be conducted to evaluate the safety, pharmacokinetics (PK), and efficacy of adjunctive GWP42003-P in participants \< 2 years of age with tuberous sclerosis complex (TSC), Lennox-Gastaut syndrome (LGS), or Dravet syndrome (DS).
Investigators at Boston Children's Hospital are conducting research in order to better understand the genetic factors which may contribute to epilepsy and related disorders. These findings may help explain the broad spectrum of clinical characteristics and outcomes seen in people with epilepsy.
The purpose of this study is to collect detailed information about the characteristics and genetics of a large number of individuals with epilepsy.
This study is designed to use positron emission tomography to measure brain energy use. Positron Emission Tomography (PET) is a technique used to investigate the functional activity of the brain. The PET technique allows doctors to study the normal processes of the brain (central nervous system) of normal individuals and patients with neurologic illnesses without physical / structural damage to the brain. When a region of the brain is active, it uses more fuel in the form of oxygen and sugar (glucose). As the brain uses more fuel it produces more waste products, carbon dioxide and water. Blood carries fuel to the brain and waste products away from the brain. As brain activity increases blood flow to and from the area of activity increases also. Researchers can label a sugar with a small radioactive molecule called FDG (fluorodeoxyglucose). As areas of the brain use more sugar the PET scan will detect the FDG and show the areas of the brain that are active. By using this technique researchers hope to answer the following questions; 4. Are changes in brain energy use (metabolism) present early in the course of epilepsy 5. Do changes in brain metabolism match the severity of patient's seizures 6. Do changes in metabolism occur over time or in response to drug therapy