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While tremendous progress has been made against HIV, both in preventing the infection and in treating AIDS, the disease it causes, AIDS-related malignancies like Kaposi sarcoma (KS) remain a significant health burden, in both the U.S. and especially the developing world. In many cases, multiple KS lesions develop simultaneously, and may progress and regress independently. Photographs are an essential part of the evaluation for KS, as reflected in their formal usage described in the KS Tumor Assessment Manual of Procedures. However, acquiring a clear, informative photo is not trivial, since anatomy is 3D and conventional imaging is 2D. The importance of accurate, quantitative 3D information is especially pronounced for the treatment of KS because when a tumor responds positively to treatment, the initial change is usually a flattening of the lesion, without any significant change in the projected 2D area. To evaluate the vertical space, along with other characteristics of a KS lesion, we have created an innovative imaging system, SkinScan3D, utilizing new commercial liquid lens technologies and AI based image analysis software, with strategies borrowed from astronomical imaging techniques previously used on NASA space telescopes. In this study, the investigators will develop and demonstrate a protocol for recording measurable 3D parameters, which may be used in a longitudinal study to rigorously monitor therapeutic responses of KS and statistically compare with that of the conventional AMC criteria.
This phase of the protocol (protocol part B), seeks to evaluate the new formulation in healthy normal volunteers to confirm the new formulation provides comparable human dosimetry to which was seen and published in protocol part A. Additionally, the new formulation will be studied utilizing an expanded patient population to include patients with confirmed diagnosis of multiple myeloma (MM), low-grade lymphoma, or MM and lymphoma patients who are status post bone marrow transplant (BMT) with negative imaging and suspected recurrence.
This is a phase I/Ib imaging study of granzyme B, 64-copper granzyme targeting restricted interaction peptide specific to family member B (64Cu-GRIP B) Positron Emission Tomography (PET) in patients with relapsed/refractory non-Hodgkin's lymphoma (NHL) receiving CD19-directed Chimeric antigen receptor T cells (CAR-T) therapy. The proposed study represents the first-ever lymphoma patient imaging studies with 64Cu-GRIP B PET. The tracer is designed to detect extracellular granzyme B as it is secreted by activated immune cells in the tumor microenvironment, which may highlight tumors that will exhibit a durable response to Cluster of Differentiation 19 (CD19)-directed CAR T-cell therapy.
The goal of this observational study is to identify targetable neural substrates of depression in Parkinson's Disease for the first time in people with Parkinson's between the ages of 40 and 80, who are experiencing symptoms of depression.
Background Acute lymphoblastic leukemia (ALL) accounts for about 25 percent of childhood cancers and for about 20 percent of adult leukemias. The disease can be treated with CAR T-cell infusion but non-central nervous system (CNS) extramedullary disease (EMD) is associated with lower rates of complete remission. 18-fludeoxyglucose (18F-FDG) positron emission tomography-computed tomography (PET-CT) has been shown to be effective for detection of non-CNS EMD in ALL. Pre and post CAR T-cell infusion may help to predict outcomes and risk of early progression. Objectives To describe the number of adults with relapsed/refractory B-cell ALL who proceed to CAR T-cell therapy. Eligibility Participants \>=18 years with relapsed/refractory B-cell ALL who are being screened for CAR T-cell clinical trial enrollment, and Participants \<18 with relapsed/refractory B cell ALL who are being screened for CAR T-cell clinical trial enrollment and have a clinical indication for FDG PET-CT prior to CAR infusion. Design Pilot study to add screening FDG PET-CT as part of the pre-CAR T-cell baseline evaluation with additional imaging at day 28 and future timepoints pending evidence of non-CNS EMD on initial scan.
The goal of this clinical trial is to investigate the use of an FDA-cleared retinal blood flow imaging instrument called the XyCAM RI and XyCAM FC (Vasoptic Medical, Inc., Columbia, MD) in glaucoma management. The main question it aims to answer are: * Can the investigators use blood flow to discriminate between eyes with early-stage glaucoma and variable-matched controls? * Can the investigators validate that the XyCAM FC simultaneously captures both stereo fundus photography and ocular blood flow monitoring? Participants will be * measured for their blood pressure, heart rate, height, and weight * dilated with tropicamide * imaged using the XyCAM RI, fundus photography, optical coherence tomography, and standard automated perimetry * imaged using the XyCAM RI while inhaling 100% oxygen through a mask
The primary aim of our pilot study is to determine whether fibrosis in the heart can be measured with \[68Ga\]CBP8, a positron emission tomography (PET) probe, using PET/magnetic resonance imaging (MRI) imaging, in 30 individuals with documented cardiac amyloidosis. The investigators will also enroll 15 individuals with recent myocardial infarction and 15 individuals with hypertrophic cardiomyopathy as positive controls for fibrosis, and the investigators will enroll 5 individuals without cardiovascular disease to undergo \[68Ga\]CBP8 PET/MRI imaging as a healthy control group. The primary hypothesis of this study is that \[68Ga\]CBP8 will bind to interstitial collagen and quantify myocardial fibrosis in patients with cardiac amyloidosis. The investigators hypothesize that \[68Ga\]CBP8 uptake will be greater in patients with cardiac amyloidosis, myocardial fibrosis, and hypertrophic cardiomyopathy than in healthy controls. Secondly, the investigators also hypothesize that \[68Ga\]CBP8 activity more strongly correlates with standard MRI measures in patients with recent myocardial infarction and hypertrophic cardiomyopathy (where extracellular expansion is caused by myocardial fibrosis/collagen deposition) than in patients with cardiac amyloidosis (where myocardial fibrosis is combined with infiltration).
Lymphatic transport was previously examined by these investigators using Near InfraRed Indocyanine Green fluorescence imaging (NIR-ICG) of the upper extremities. They established reliable and reproducible methodologies in RA patients. The purpose of this phase 2 pilot is to study RA disease progression and effectiveness as well as the mechanism of action of clinical interventions using established NIR-ICG methodologies in previous studies.
The purpose of this study is to find out whether pre-operative mpMRI using additional MRI sequences may improve surgical outcomes by providing more accurate information about the extent and acidity of the tumor than standard MRI, and to see whether the use of the fluorescent imaging agent pHLIP ICG and NIRF imaging during surgery is a safe approach that may allow the surgeon to see the tumor and nearby tissues that contain cancer cells more clearly and remove them completely. During the Phase IIa part of this study, the safe dose of pHLIP ICG will be used that makes it easy for the surgeon to see the tumor and the nearby tissues and structures that may contain cancer cells. This study is the first to test pHLIP ICG in people, and the first to test the use of pHLIP ICG with mpMRI and NIRF imaging in surgery for breast cancer.
This phase II trial studies the side how well hyperpolarized carbon C 13 pyruvate (HP C-13 pyruvate) magnetic resonance imaging (MRI) works in monitoring patients with prostate cancer on active surveillance who have not received treatment. Diagnostic procedures, such as MRI, may help visualize HP C-13 pyruvate uptake and breakdown in tumor cells.