32 Clinical Trials for Various Conditions
In this study twenty-five (25) subjects with Crohn's disease scheduled for possible surgical intervention will be recruited for this study and a PET/MR scan using the collagen-binding radiotracer will be performed. The study aims to establish the performance figures of PET/MR using \[68Ga\]CBP8-PET for preoperative detection and differentiation of strictures with a fibrotic component in patients with Crohn's disease by using surgical and histologic findings (when available) as the standard for comparison. Furthermore, the investigators will determine the performance figures with which strictures are identified and characterized by PET/MR using \[68Ga\]CBP8-PET compared to each modality in isolation (PET alone or MR alone). Blood and tissue markers for fibrostenosis will be explored (either predictive or as biomarkers for fibrotic burden), using histologic and molecular testing by using surgical and histologic findings (when available) as the standard for comparison. Lastly the investigators want to determine the performance figures with which strictures are identified and characterized by PET/MR using \[68Ga\]CBP8-PET compared to each modality in isolation (PET alone or MR alone).
This study is for patients who have had surgery to remove brain metastasis and are planned to have stereotactic radiosurgery (SRS) after their brain surgery. It will be optional for patients to have a pre-surgery 18F-Fluciclovine PET/CT scan. The goal of the study is to determine whether a specific imaging agent, known as 18F-Fluciclovine, will help physicians evaluate the extent of surgery and determine if there is any visible tumor above what MRI alone can identify as well as improve the physicians' ability to detect recurring disease. This agent (18F-Fluciclovine) is investigational for the imaging of brain metastases.
This phase II trial tests whether \[18F\]FluorThanatrace by positron emission tomography (PET)/computed tomography (CT) can improve imaging techniques in patients with breast cancer undergoing a standard of care biopsy or surgery. \[18F\]FluorThanatrace is a new radioactive tracer, which is a type of imaging agent that is labeled with a radioactive tag and injected into the body to help with imaging scans. PET is an established imaging technique that utilizes small amounts of radioactivity attached to very minimal amounts of tracer, in the case of this research, \[18F\]FluorThanatrace. Because some cancers take up \[18F\]FluorThanatrace it can be seen with PET. CT utilizes x-rays that traverse body from the outside. CT images provide an exact outline of organs and potential inflammatory tissue where it occurs in patient's body. \[18F\]FluorThanatrace by PET/CT may help detect the activity of a certain enzyme in the body that may be related to cancer growth in patients with breast cancer.
The purpose of this research study is to test new ways to improve the usefulness of the world's first total-body positron emission tomography (PET)/computed tomography (CT) scanner (EXPLORER) by collecting data from PET scans using one of three different imaging agents: 18F-PSMA; 18F-FES; or, 68Ga DOTATATE. These imaging agents are approved by the FDA to be used for patients diagnosed with prostate cancer (18F-PSMA), neuroendocrine tumor (68Ga DOTATATE), or breast cancer (18F-FES).
The overall goal of this protocol is to evaluate the binding of caffeine to adenosine A2A receptors in the brain of participants at risk for developing PD.
The study aims to compare tau targeted radiotracers \[18F\]GTP1 and \[18F\]PI-2620 or \[18F\]MK-6240 in subjects with normal cognition or prodromal to moderate Alzheimer's disease (AD).
The goal of this exploratory study is to test whether \[18F\]3F-PHPG can be used reliably to map the locations of tumors in patients with neuroendocrine tumors. If so, the results of this study will be used to support further development of \[18F\]3F-PHPG as a clinical tool for neuroendocrine tumor localization and staging.
This is a longitudinal, observational study evaluating the imaging characteristics of the tau PET radioligand \[18F\]MK-6240 in Alzheimer's disease (AD), Mild Cognitive Impairment (MCI) and Healthy Volunteer (HV) subjects. Up to 42 subjects, including approximately 28 MCI/mild AD subjects, up to 5 moderate AD subjects, and 9 similarly aged HV subjects will be consented and screened. Imaging procedures include \[11C\]PiB to evaluate amyloid deposition, \[18F\]MK-6240 PET, and structural MRI. All subjects complete an evaluable baseline \[18F\]MK-6240 PET scan, as well as scans at 6, 12 and 24 months post-baseline. If unable to complete the 6 month, 12 month, or 24 month visit, an 18 month and/or 30 month visit may instead be scheduled, totaling a maximum of four time points.
The aim of this clinical study is to 1) establish a healthy database for nuclear perfusion imaging of the lower extremities and 2) assess the prognostic value of radiotracer-based perfusion imaging for predicting clinical outcomes in patients with peripheral artery disease (PAD) who are undergoing lower extremity revascularization procedures. We hypothesize that radiotracer imaging of the lower extremities will provide a sensitive non-invasive imaging tool for quantifying regional abnormalities in skeletal muscle perfusion and evaluating responses to medical treatment.
This phase I trial studies how well fluorine F 18 fluorthanatrace positron emission tomography (PET)/computed tomography (CT) works in patients with solid tumors. Fluorine F 18 fluorthanatrace is a radioactive tracer, a type of imaging agent that is labeled with a radioactive tag and injected into the body to help with imaging scans. PET/CT uses a scanner to make detailed, computerized pictures of areas inside the body. PET/CT with Fluorine F 18 fluorthanatrace may allow more tumor cells to be found in patients with ovarian, fallopian tube, or primary peritoneal cancer.
The purpose of this study is to test Cerenkov luminescence imaging, which is a different way to take pictures of thyroid cancer and/or any tumors with (existing or suspected) nodal metastases in the neck, supraclavicular, axillary and/or inguinal region.
Background: The new drug 18F-PF-06445974 has a little radioactivity. This can be seen by a positron emission tomography (PET) scan. The drug helps researchers see a protein, PDE4B, in the brain. Looking at PDE4B in the living brain might show how it is involved in psychiatric and neurological disorders. One part of the study will look at how the study drug is distributed in the brain. Another part will study how brain measures vary. Objectives: To measure the protein PDE4B in the brain. To test how a new radioactive chemical, 18F-PF-06445974, is distributed in the body. Eligibility: Healthy adults ages 18 and older Design: Participants will have 1-3 visits over a year. Each will be 2-5 hours. Women will have a pregnancy test each time.
Up to 40 evaluable women with known or suspected epithelial ovarian, fallopian tube, or primary peritoneal cancer will participate in two different imaging cohorts. The Biodistribution cohort will include up to 4 patients and the Dynamic cohort will include up to 36 patients. Human dosimetry will be calculated from the Biodistribution cohort. The Dynamic cohort date will evaluate preliminary information on uptake of \[18F\]FTT in gynecological cancer and compare with PARP-1 activity in tissue.
This study will estimate how fast two antiepileptic drugs (Levetiracetam and Brivaracetam) enter the human brain. Brain imaging will be used to measure how quickly the radioactive probe \[11C\]UCB-J exits the brain when Levetiracetam or Brivaracetam are given. This will be used to estimate how fast the antiepileptic drugs enter the brain.
This clinical trial will enroll up to 130 adult women with a confirmed diagnosis of clinical stage 1 or 2 breast cancer who are undergoing breast cancer surgery with lumpectomy or mastectomy and planned axillary sentinel node biopsy procedure. Participants will undergo lymphatic mapping with technetium Tc-99m (99mTc) sulfur colloid in accordance with routine clinical practice. Injections of 99mTc sulfur colloid will take place the afternoon prior to planned next morning surgery or on the morning of surgery. Participants will undergo lymphoscintigraphy in accordance with standard clinical practice. Immediately prior to operation, after the induction of anesthesia in the operating room, up to 1cc of 0.5% indocyanine green (ICG) solution will be injected subdermally close to the tumor or into the subareolar region after disinfection of the breast skin. ICG movement will be facilitated by manual massage and monitored with fluorescence imaging. ICG fluorescence will be elicited and detected by Photodynamic Eye (PDE) camera. The lymphatic drainage, made evident by the fluorescent dye, will be monitored in real time on a monitor. The fluorescence will be followed towards the armpit region (axilla) and time for the fluorescence to reach the axilla will be recorded. Following standard practice, an incision will be made in the armpit region. Fluorescent lymph nodes (ICG positive) will be localized and removed and analyzed by a pathologist. Node removal will continue until no residual fluorescence is visible in the axilla. Removed nodes will be tested for radioactivity using a standard gamma-detecting probe and the counts per minute will be recorded. Finally, the armpit region will be inspected with the gamma probe to determine if there are any residual radioactive nodes. Residual sentinel nodes (the first node to receive lymph from a tumor) will be removed. For the purposes of this study, the sentinel status of a node will be defined as being flagged as sentinel by either one or both of the ICG or 99mTc methods. The goal of the project is to confirm that axillary lymphatic mapping with ICG leads to similar nodes being labeled as sentinel as lymphatic mapping with 99mTc-labeled radiotracer.
In this phase 1 pilot study, positron emission tomography (PET/CT) imaging will be used to determine the biodistribution, metabolism and excretion of a novel radiotracer \[18F\]Fluortriopride (\[18F\]FTP).
This study is being done to determine the safety, biodistribution, and radiation dosimetry of 18F-DCFPyL, and to detect prostate cancer by visual analysis.
Objective Ionotropic glutamate receptors are ligand-gated ion channels responsible for most of the excitatory neurotransmission in the mammalian central nervous system (CNS). Based on pharmacology, they have been grouped into three subtypes-NMDA, AMPA and kainate. In recent years it has become apparent that the receptors do not function alone, but in the company of auxiliary proteins that regulate their activity \[1\]. Some of these have been shown to modulate AMPA receptor trafficking, gating and pharmacology and are classified as transmembrane AMPA receptor regulatory proteins, or TARPs ( \>=-2, \>=-3, \>=-4, \>=-5, \>=-7, and \>=-8). Genetic data indicate a possible role of TARPs in schizophrenia, depression, epilepsy, neuropathic pain, and bipolar disorder \[1\]. In a preclinical collaboration with Eli Lilly, we developed a promising radioligand, 18F-TARP252 to image TARP \>=-8 using positron emission tomography (PET). This protocol covers three phases: * Phase 1: kinetic brain imaging to quantify TARP \>=-8 in brain relative to concurrent measurement of the parent radioligand in arterial plasma; * Phase 2: if 18F-TARP252 is successful in Phase 1, we will estimate the radiation-absorbed doses by performing whole body imaging; * Phase 3: test-retest analysis of brain binding relative to concurrent measurement of the parent radioligand in arterial plasma. Study Population Healthy adult female and male volunteers (n=22, ages 18 - 55) will undergo brain imaging. An additional eight healthy volunteers will undergo whole body dosimetry analysis. Design For quantification of TARP \>=-8, 22 healthy controls will have brain PET imaging using 18F-TARP252 and an arterial line. Some of them will have a test-retest scan. Eight additional subjects will have a whole body PET scan for dosimetry. For dosimetry, no arterial line will be used. Outcome Measures To assess quantitation of TARP \>=-8 with 18F-TARP252, we will primarily use two outcome measures: the identifiability and time stability of distribution volume calculated with compartmental modeling. In test-retest study, we will calculate the retest variability. We will assess whole-body biodistribution and dosimetry of 18F-TARP252 by calculating doses to organs and effective dose to the body.
A single center, open-label baseline controlled imaging study to designed to assess whether Positron Emission Tomography (PET) measurements of myocardial Fatty Acid (FA) metabolism performed with \[18F\]FluorbetaOx correlates with measurements using \[11C\]palmitate. This study involves the investigational use of a PET radioactive tracer, fluorine-18 radiolabeled fatty acid analog, \[18F\]FluorbetaOx designed to measure beta oxidation of fatty acids in the myocardium. The investigators propose to evaluate the feasibility of the method in heart failure patients with dilated non-ischemic cardiomyopathy (DCM) with or without type-2 diabetes mellitus (T2DM) and obese subjects (Body Mass Index of ≥ 30kg/m2) with or without T2DM and normal healthy subjects to provide a wide range of perturbations in myocardial FA metabolism. Specific objectives include: 1. To assess the diagnostic quality of \[18F\]FluorbetaOx PET images and kinetics at the proposed 10 millicurie (mCi) dose. 2. To quantitatively determine the relationship between PET measurements of myocardial FA metabolism obtained with \[18F\]FluorbetaOx and those using \[11C\]Palmitate. 3. To calculate human dosimetry based on the human biodistribution of \[18F\]FluorbetaOx. 4. Correlate measurements of myocardial FA metabolism with changes in left ventricular (LV)structure and function performed on a clinically indicated echocardiography at 6-9 months after imaging.
This open label, non-randomized, parallel group study will evaluate \[11C\]-RO5011232 as radiotracer for brain mGlu5 receptor occupancy and investigate the binding of RO49917523 to human mGlu5 brain receptor at steady-state in healthy volunteers. In Parts I, II and III, positron emission tomography (PET) assessments of specific uptake of the radiotracer and whole body dosimetry will be made after intravenous injection of \[11C\]-RO5011232. In Part IV, subjects will receive RO4917523 orally daily for 14 days while receiving three single intravenous bolus injections of \[11C\]-RO5011232. The anticipated time on study treatment is up to 4 weeks.
Some patients are at risk for life-threatening fast heart rates. These can frequently be treated by using a catheter inside the heart to burn away the cells that create the fast heart rates. The purpose of this study is to image the nerves inside the heart of those patients. The investigators want to find out if abnormalities in the nervous system in the heart can help the physician to find the area that needs to be burnt away.
The purpose of this study is to evaluate the potential of \[18F\]-ML-10 to serve as an imaging tool for the early detection of response of brain metastases to radiation therapy. Such early detection may help early identification of responsive and non-responsive lesions. The experimental design of the present study aims to evaluate the potential of PET imaging with \[18F\]-ML-10 to address the currently unmet clinical need for very early (within one day)assessment of response to therapy. Currently, response assessment is available only after several weeks or months after completion of therapy, when tumor shrinkage can be detected by anatomical imaging (by MRI). Early detection of tumor response to treatment is now widely-recognized as a highly-desirable goal in oncology, and is respectively the target of intense research worldwide. In the future, the option to know early upon treatment administration, that the treated tumor is a non-responsive, may improve clinical management of patients with brain metastases of solid tumors.
This study will evaluate the feasibility of using a sub-therapeutic dose of a fluorine-18 analogue of NP-59 (\[18F\]FNP-59) to image the adrenal gland. Some participants are healthy normal subjects but have undergone interventions to manipulate hormones while other participants have known adrenal pathology.
This exploratory, first-in-man, phase 0 study will evaluate the feasibility of using a sub-therapeutic dose of a fluorine-18 analogue of NP-59 (\[18F\]FNP-59) to image the adrenal gland in healthy normal subjects. The researchers believe that \[18F\]FNP-59 would greatly improve the imaging characteristics, by providing a PET imaging cholesterol analogue with significantly improved radiation dosimetry.
The objectives of this study are to determine the: 1. Diagnostic value of stress induced RV changes on Lexiscan stress MPI as compared to Exercise stress MPI in predicting a significant CAD. 2. Prognostic value of stress induced RV changes on Lexiscan stress MPI in predicting adverse short-term and long-term clinical outcomes after the index test.
The purpose of this study is to evaluate a novel PET tracer (\[11C\]AS2471907), and to use \[11C\]AS2471907 to assess the level and time-course of enzyme occupancy in the human brain prior to and following single oral dose administration of ASP3662.
This phase I/II clinical trial evaluates if using a radiotracer targeting granzyme B, 64-copper granzyme targeting restricted interaction peptide specific to family member B (64 Cu-GRIP B) with positron emission tomography (PET) imaging can be safe and useful for detecting granzyme B (GrB) in patients with advanced cancers that has spread to nearby tissue or lymph nodes (advanced). Granzyme B (GrB) is a biomarker produced by immune cells in response to immunotherapy, which may highlight tumors that are more likely to respond to treatment. The study population is focused on genitourinary (GU) malignancies, including renal cell and urothelial cancer, two tumor types with high mutational burden and tumor infiltrating lymphocytes compared to other tumor types, and have a predictable response rate at the population level to immune checkpoint inhibitors. The information gained from this trial may allow researchers to develop future trials where 64Cu-GRIP B PET may serve as a biomarker to monitor early response to immunomodulatory therapies which are used to stimulate or suppress the immune system and may help the body fight cancer.
Background: A radiotracer (or tracer) is a radioactive substance. It is used in Positron Emission Tomography (PET) imaging to help see specific sites in the body. Researchers want to learn if a new tracer can help them better identify hepatocellular cancer (HCC) in people. Objective: To learn if a radiotracer called 18F-DCFPyL can identify sites of HCC better than current standard imaging. Eligibility: Adults aged 18 years and older who may have HCC based on previous standard imaging. Design: Participants will be screened with a medical history, physical exam, and blood tests. They will have a computed tomography (CT) and/or magnetic resonance imaging (MRI) scan. Participants will have a whole-body PET/CT scan. The PET and CT scanners use x-rays to make pictures of the inside of the body. The PET uses a tracer to help make the pictures. Participants will get an intravenous (IV) injection of 18F-DCFPyL 1 hour before the scan. Within two weeks, participants will have a 18F-FDG PET/CT scan. 18F-FDG is a commonly used tracer. They will get 18F-FDG via IV 1 hour before the scan. Participants will have a CT/MRI within 2 months of the first 18F-DCFPyL PET/CT. Participants will have standard treatment for their cancer. During treatment, they will have a tumor biopsy. If the biopsy shows they do not have HCC, they will be removed from the study. For participants who have HCC and their cancer was identified in the 18F-DCFPyL PET/CT, they will have a second 18F-DCFPyL PET/CT and 18F-FDG PET/CT. Participants will have follow-up visits every 3 months for 2 years. Then they will have yearly visits for 3 years.
This research is being done to see if an investigational radioactive imaging agent (radiotracer) called 18F-DCFPyL can help us find prostate cancer at its original site in the prostate gland and in distant sites (bone, lymph nodes) in men diagnosed with prostate cancer before surgery.
This study will compare serotonin transporter proteins in people with alcoholism and healthy volunteers to examine how these proteins may be related to the inability of people with alcoholism to appropriately regulate their alcohol consumption. Serotonin transporters regulate levels of the brain chemical serotonin. Problems in this regulation have been implicated in alcoholism. Healthy normal volunteers and people who suffer from alcoholism who are between 18 and 75 years of age may be eligible for this study. Candidates are screened with a medical history and physical examination, psychiatric diagnostic interview, blood and urine tests, an electrocardiogram, urine toxicology screen, and written psychological evaluations. Participants undergo positron emission tomography (PET) and magnetic resonance imaging (MRI) scanning to measure serotonin transporter levels in the brain. PET uses small amounts of a radioactive chemical called a tracer that "labels" the serotonin transporters in the brain. The tracer used in this study is \[11C\]DASB. For the procedure, the subject lies on the scanner bed. A special mask is fitted to the head and attached to the bed to help keep the subject's head still during the scan so the images will be clear. A brief scan is done just before the radioactive tracer is injected. This scan provides measures of the brain that will help in the precise calculation of information from subsequent scans. After the tracer is injected through a catheter (plastic tube) placed in the arm, pictures are taken for about 2 hours. MRI uses a magnetic field and radio waves to produce pictures of brain structure. The subject lies on a bed that slides into the tube-like scanner, wearing earplugs to muffle loud noises the machine makes when the magnetic fields are switched. The scan takes about an hour, during which time the subject can communicate with the technician.