CLINICAL TRIALS PROFILE FOR POTASSIUM PERCHLORATE
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All Clinical Trials for potassium perchlorate
| Trial ID | Title | Status | Sponsor | Phase | Start Date | Summary |
|---|---|---|---|---|---|---|
| NCT00058721 ↗ | Single Photon Emission Computed Tomography to Study Receptors in Parkinson's Disease | Completed | National Institute of Neurological Disorders and Stroke (NINDS) | 2003-04-01 | This study will use single photon emission computed tomography, or SPECT (see below), to examine brain nicotine receptors in evaluating the role of a chemical called acetylcholine in memory and other problems in Parkinson's disease (PD). Acetylcholine acts by binding to these nicotine receptors. Healthy normal volunteers and patients with Parkinson's disease 40 years of age and older, with or without dementia, may be eligible for this study. Candidates will be screened with physical and neurological examinations, a pen and paper test of memory and other mental functions, blood tests, and, for women of childbearing potential, a pregnancy test. Patients with cognition problems will have more intensive mental function tests. All participants will undergo the following procedures: - Magnetic resonance imaging (MRI): This test uses a strong magnetic field and radio waves to show structural and chemical changes in the brain. During the scan, the subject lies on a table in a narrow cylinder (the scanner). The time required in the scanner is about 1 hour, during which the subject is asked to lie very still for 10 to 15 minutes at a time. He or she can speak with a staff member via an intercom system at all times during the procedure. - SPECT: This nuclear medicine test produces a picture of the receptors in the brain. On the night before the scan, the day of the scan, and for 4 days after the scan, subjects take an oral dose of potassium iodide to protect the thyroid gland from the radioactive tracer used in the SPECT procedure. (People allergic to potassium iodide will take potassium perchlorate instead.) Before the scan, small radioactive markers containing 99Tc are glued to the subject's head. Two catheters (thin, flexible tubes) are placed in veins in the arms to inject the radioactive tracer [123I]5-I-A-85380 and to draw blood samples. Another catheter is placed in an artery in the wrist to draw arterial blood samples. During the scan, the subject lies on a bed with his or her head held still with a head holder. The scans are taken over a 6-hour period after injection of [123I]5-I-A-85380. An electrocardiogram, respiration, and blood pressure measures are taken before the tracer is injected, then 5 minutes after the injection, and again 30 to 60 minutes after the injection. Blood and urine samples are collected 5 to 6 hours after starting the scan. Participants are asked to urinate at least every 2 hours for 12 hours after injection of [123I]5-I-A-85380 to decrease radiation exposure. | |
| NCT00061789 ↗ | Imaging of Brain Receptors in Healthy Volunteers and in Patients With Schizophrenia | Completed | National Institute of Mental Health (NIMH) | Phase 2 | 2003-02-01 | This study will use single photon emission computed tomography (SPECT) to study brain nicotine receptors (proteins on the surface of brain cells) in healthy subjects and in patients with schizophrenia. Autopsy findings in patients with schizophrenia show changes in their nicotine receptors. This study will use SPECT to look at these receptors in living schizophrenia patients and compare them with those in healthy subjects. The following individuals between 21 and 50 years of age (or between 21 and 80 years of age for Group 1 only) are eligible for this study: healthy non-smokers (Group 1); schizophrenia patients who smoke (Group 2); schizophrenia patients who do not smoke (Group 3); healthy smokers (Group 4); healthy non-smokers (Group 5). Patients with schizophrenia must be taking olanzapine (Zyprexa) or risperidone (Risperdal) for at least 6 months. All candidates will be screened at the first visit. Group 1 participants will have three more visits; Groups 2 through 5 will have two more visits. Visit 1 All participants will be screened with physical and neurological examinations; blood and urine tests; and neuropsychological tests to assess their ability to learn and remember words and numbers, to pay attention, and to quickly perform motor tasks, such as putting pegs into a piece of wood. In addition, they will have an eye movement test and event-related potential testing. For the eye test, the subject sits in a chair and leans forward with the chin on a chin rest. A band is tied around the head and very small amounts of invisible (infrared) light are shined into the eyes. The light is reflected back and measured. Wire electrodes are placed around the area of the eye and cheek to monitor eye blinks and eye movements. Subjects are asked to follow a light with their eyes and to look away from a light. For event- related potential testing, electrodes are placed on the scalp, forehead and cheeks, and brain activity is recorded while the subject identifies particular pictures and sounds. Visit 2 (and Visit 3 for Group 1) Participants will have a SPECT scan. On the night before the scan, the day of the scan, and for 4 days after the scan, subject take an oral dose of potassium iodide to protect the thyroid gland from the radioactive tracer used in the SPECT procedure. (Individuals allergic to potassium iodide will take potassium perchlorate instead.) For the SPECT scan, small radioactive markers containing 99mTc are glued to the subject's head. Two catheters (thin, flexible tubes) are placed in veins in the arms to inject the radioactive tracer [123I]5-I-A-85380 and to draw blood samples. During the scan, the subject lies on a bed with his or her head held still with a headholder. The scans are taken over a 9-hour period after injection of the tracer injection. An electrocardiogram, respiration, and blood pressure measures are taken before injection of [123I]5-I-A-85380, then 5 minutes after the injection, and again 30 to 60 minutes after the injection. Breath samples are collected every 60 minutes. Blood and urine samples are collected 5 to 6 hours after starting the scan. Group 1 subjects will have a second SPECT scan within 4 weeks of the first. Visit 3 (Visit 4 for Group 1) Participants will have a magnetic resonance imaging (MRI) scan. For this procedure, the subject lies on a table that slides into a narrow metal cylinder with a strong magnetic field for the scan. The scanner uses a magnetic field and radio waves to produce images that show structural and chemical changes in tissues. The test lasts up to 1 hour. |
| NCT00273351 ↗ | Imaging and Genetic Biomarkers of Parkinson Disease (PD) Onset and Progression in High-risk Families | Completed | Molecular NeuroImaging | Phase 2 | 2006-01-01 | Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by rigidity, bradykinesia, postural instability, and tremor. Clinical decline reflects ongoing degeneration of dopamine-containing neurons. A critical unmet need for clinical research is to improve early detection of these diseases by developing tools to assist with earlier diagnosis. Biomarkers are broadly defined as characteristics that are objectively measured and evaluated as indicators of normal biological processes, pathogenic processes, or pharmacologic responses to a therapeutic intervention (Biomarkers Defintions Working Group 2001). Development of reliable biomarkers for PD would dramatically accelerate research on PD etiology, pathophysiology, disease progression and therapeutics. Specific biomarkers may be useful at the onset of neurodegeneration, the onset of disease, and/or to mark disease progression. The biomarkers in this study include brain imaging with a radioactively labelled drug (Beta-CIT), computerized testing of memory, attention, motor speed, judgment and handwriting, and assessments of speech and smell. Subjects may also be asked to provide a blood sample for genetic and biochemical testing. |
| NCT00273351 ↗ | Imaging and Genetic Biomarkers of Parkinson Disease (PD) Onset and Progression in High-risk Families | Completed | United States Department of Defense | Phase 2 | 2006-01-01 | Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by rigidity, bradykinesia, postural instability, and tremor. Clinical decline reflects ongoing degeneration of dopamine-containing neurons. A critical unmet need for clinical research is to improve early detection of these diseases by developing tools to assist with earlier diagnosis. Biomarkers are broadly defined as characteristics that are objectively measured and evaluated as indicators of normal biological processes, pathogenic processes, or pharmacologic responses to a therapeutic intervention (Biomarkers Defintions Working Group 2001). Development of reliable biomarkers for PD would dramatically accelerate research on PD etiology, pathophysiology, disease progression and therapeutics. Specific biomarkers may be useful at the onset of neurodegeneration, the onset of disease, and/or to mark disease progression. The biomarkers in this study include brain imaging with a radioactively labelled drug (Beta-CIT), computerized testing of memory, attention, motor speed, judgment and handwriting, and assessments of speech and smell. Subjects may also be asked to provide a blood sample for genetic and biochemical testing. |
| NCT00273351 ↗ | Imaging and Genetic Biomarkers of Parkinson Disease (PD) Onset and Progression in High-risk Families | Completed | Institute for Neurodegenerative Disorders | Phase 2 | 2006-01-01 | Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by rigidity, bradykinesia, postural instability, and tremor. Clinical decline reflects ongoing degeneration of dopamine-containing neurons. A critical unmet need for clinical research is to improve early detection of these diseases by developing tools to assist with earlier diagnosis. Biomarkers are broadly defined as characteristics that are objectively measured and evaluated as indicators of normal biological processes, pathogenic processes, or pharmacologic responses to a therapeutic intervention (Biomarkers Defintions Working Group 2001). Development of reliable biomarkers for PD would dramatically accelerate research on PD etiology, pathophysiology, disease progression and therapeutics. Specific biomarkers may be useful at the onset of neurodegeneration, the onset of disease, and/or to mark disease progression. The biomarkers in this study include brain imaging with a radioactively labelled drug (Beta-CIT), computerized testing of memory, attention, motor speed, judgment and handwriting, and assessments of speech and smell. Subjects may also be asked to provide a blood sample for genetic and biochemical testing. |
| NCT01524861 ↗ | Sympathetic Heart Innervation in Patients With Tako-Tsubo Cardiomyopathy | Completed | Second University of Naples | Phase 4 | 2011-12-01 | Stress (tako-tsubo) cardiomyopathy (SC) is a rapidly reversible form of acute heart failure reported to be triggered by stressful events and associated with a distinctive left ventricular (LV) contraction pattern. SC mimics acute coronary syndrome and is accompanied by reversible left ventricular apical ballooning in the absence of angiographically significant coronary artery stenosis. sympathetic activity dysfunction appears to play a very important role in the pathophysiology of takotsubo cardiomyopathy. In most cases, myocardial scintillography with 123Imetaiodobenzylguanidine (MIBG) showed altered captation of the radiotracer in several heart segments. In particular, the apical myocardium has poor sympathetic innervations and an uptake reduction in MIBG tracer. A hypothesis for this finding could be that the intense discharge of adrenalin, acting on heart segment with different and abnormal innervation, may produce a transient heart failure characterized by a particular shape of the left ventricle. While studies have shown that heterogeneous MIBG distribution, decreased MIBG uptake and increased norepinephrine content were completely prevented by α-lipoic acid or by L-acetyl carnitine administrations in diabetic cardiomyopathy, no studies have examined the effects of these therapies on tako-tsubo cardiomyopathy. On this basis, the investigators study will evaluate whether the dysfunction of adrenergic cardiac innervation, evaluated by MIBG, persist after previous experience of transient stress-induced cardiac dysfunction. Moreover, the investigators will assess whether the medications that restore sympatho-vagal alterations in diabetic cardiomyopathy, such as α-lipoic acid and L-acetyl carnitine, will improve the adrenergic cardiac innervation, in patients with SC. |
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