127 Clinical Trials for Various Conditions
Single-center pilot prospective observational study to determine feasibility of assessing meniscal tissue vascularity using dynamic contrast-enhanced fluorescence arthroscopy
Glioblastoma multiforme (GBM) and anaplastic astrocytoma (AA) are the most common primary malignant brain tumors. Survival of patients with these brain tumors is directly related to the extent of resection. Consequently, a great deal of effort has been directed at developing techniques and technologies that allow more extensive, safe resections. This study will test a loupe-based wearable device in the clinical setting and compare its accuracy with a large operative microscope to identify tumor tissues. Postoperative histopathological analysis on tumor tissues will be used as gold standards for comparison. The outcome from this study will be a low-cost, miniaturized, easy-to-operate, loupe-based fluorescence imaging device for intraoperative guidance of brain tumor resection with the same level of accuracy as the large microscope.
Primary • To explore the use of OTL38 and fluorescence imaging to detect RCC in partial nephrectomy at the margins of resection, and in lymph node(s) or other metastases during radical nephrectomy.
Removing a tumor from a patients brain is hard to do because, very often, brain tumors do not have boundaries that are easy for the patients surgeon to find. In many cases, the surgeon can't tell exactly where the tumor begins or ends. The surgeon usually can remove most of the patient's tumor by looking at the MRI images that were taken of the patient's brain before surgery. However, the surgeon does not have any good way to tell if the entire tumor has been removed or not. Removing the entire tumor is very important because leaving tumor behind may allow it to grow back which could decrease the chances of survival.
This will be a pilot study of 9 patients undergoing standard-of-care clinically indicated carotid endarterectomy. The nine patients will receive an injection of Indocyanine green (ICG) at a dose of 0.25 mg/kg (maximum 25 mg) as an intravenous bolus. Immediately following endarterectomy, the resected specimen will be immersed in normal saline. Ex vivo fluorescence reflectance imaging (FRI) and immunohistochemistry will be performed. The investigators hypothesize that compared to controls, ICG-injected patients will demonstrate increased ex vivo and microscopic ICG fluorescence signal within areas of plaque.
The purpose of this study is to determine the safety and utility of 5-aminolevulinic acid (ALA) for identifying your tumor during surgery. 5-ALA is not FDA approved at this time. When the investigators remove the tumor from your brain, it is important that they remove all of the tumor and not remove parts of normal brain. Sometimes this can be difficult because the tumor can look like normal brain. In some brain tumors, 5-ALA can make the tumors glow red under blue light. This may make it easier for your doctor to take out all of the tumor from your brain. The purpose of this study is to: * Make sure that 5-ALA helps the doctor remove more of the tumor. * Make sure 5-ALA does not cause any side effects. If you do not want to participate in this study, your doctor(s) will still do their best to remove all of the tumor in your brain. Whether or not you join this study will not change your treatment for your brain tumor.
Extent of resection is a very important prognostic factor affecting survival in individuals diagnosed with a malignant glioma. However, the infiltrative nature of the malignant glioma tumor cells produces indistinct borders between normal and malignant tissues, and the lack of easily identifiable tumor margins confounds attempts at total resection. The investigators propose to identify the borders of malignant gliomas intraoperatively using oral 5-aminolevulinic Acid (5-ALA) which results in fluorescence of the malignant cells and thereby provide an opportunity for more complete tumor resection. When exogenous 5-ALA is provided at increased concentration the tumor cells will become fluorescent under ultraviolet light. This feature identifies the tumor cells intraoperatively and facilitates complete resection. Data collection will include measurement of dose-limiting toxicity, tumor fluorescence, and tumor density. Data analysis will evaluate toxicity, sensitivity, and specificity of 5-ALA. Following completion of the phase 1 portion of this trial, an additional 14 subjects will be entered at the recommended phase 2 dose level in order to further define the above parameters at the recommended phase 2 dose level.
The goal of this clinical research study is to learn about a new minimally invasive glucose monitoring device called Fluorescence Affinity Sensor (FAS). In this study, the FAS will be used to determine its effectiveness for glucose monitoring. Researchers want to find out how the device performs at two different body sites (forearm and abdomen) over 4 hours. The safety and comfort level of the device will also be studied.
Removing a tumor from your brain is hard to do because, very often, brain tumors do not have boundaries that are easy for your surgeon to find. In many cases, the surgeon can't tell exactly where the tumor begins or ends. The surgeon usually can remove most of your tumor by looking at the MRI images that were taken of your brain before surgery. However, the surgeon does not have any good way to tell if the entire tumor has been removed or not. Removing the entire tumor is very important because leaving tumor behind may allow it to grow back which could decrease your chances of survival. It is possible to detect tumor cells by making them glow with a specific color of light (a process called fluorescence). This can be done by having you take the drug, ALA, before your surgery. ALA is a molecule that already exists in the cells of your body. Once enough of it is in your body, it gets converted into another molecule named PpIX. If blue light is shined on a tumor that has enough PpIX, it will glow with red light (fluorescence) that can be detected with a special camera. In this study, we want to determine how the fluorescence (red light) is related to the tumor which appears in the images that are normally taken of your brain (which the surgeon uses to guide the removal of your tumor) and the tumor tissue that will be removed during your surgery. Removing the entire tumor is very important because leaving tumor behind may allow it to grow back which could decrease your chances of survival.
The purpose of this study is to document the additional detection of papillary bladder cancer and the reduced early recurrence due to the improved detection and resection of these tumors after Hexvix cystoscopy compared to standard cystoscopy in patients with papillary bladder cancer.
Active inflammation plays a key role in causing Coronary Artery Disease (CAD) and Peripheral Arterial Disease (PAD). Since inflammation is so important in how these diseases start, are diagnosed, and treated, being able to see it clearly in each patient could lead to more personalized and effective care - and may help prevent heart attacks. Right now, there's no imaging technology available to clearly see inflammation inside the coronary arteries. We hope to learn how an imaging drug; called LUMISIGHT (Pegulicianine) can help detect inflammation in blood vessels compared with saline, a harmless saltwater solution. If we find out that LUMISIGHT is active in humans, we might be able to use it for detecting plaque risk in the future.
This study is evaluating whether a medication called 5-aminolevulinic acid (5-ALA), approved by the FDA for use in brain surgery, can help improve the visibility of upper tract urothelial tumors during surgery. Patients undergoing ureteroscopic tumor resection will receive 5-ALA prior to surgery, and surgeons will use special blue light to help identify abnormal tissue that might not be seen under standard white light. The goal is to assess whether this technique can enhance tumor detection and removal.
The purpose of this study is to determine whether an indocyanine green (ICG) fluorescence imaging system (cBPI) can be used to provide surgeons with information about bone health or bone blood flow. This will help surgeons better understand the healing potential of bone and relative risk of complication. This is important to help surgeons select the most appropriate treatment for severe traumatic injuries and infections.
The main Objective of this study is to determine the safety and feasibility of a prototype ActivSightTM in identifying the ureter in real-time during elective laparoscopic abdominopelvic surgery after pre-surgical administration of riboflavin. This study seeks to identify the ureter only; ActivSight™ will not be used to Safety and Feasibility of ActivSightTM in the Identification of the Ureter via Riboflavin Fluorescence guide treatment or the surgical procedure. As such, this is a non-significant risk study. Riboflavin is a common dietary supplement and will be administered at dosages shown previously to be well-tolerated for migraine prophylaxis \[6\]. ActivSight™ is an imaging system connected to the standard laparoscopic system already existing in the OR at the site. Changes made to the commercial ActivSight™ hardware for this study introduce no significant risk
The goal of this clinical trial is to compare the use of two photon fluorescence microscopy for detecting residual basal cell carcinoma during standard local excision.
This study evaluates the effectiveness of intraoperative indocyanine green dye and fluoroscopic technology in confirming negative margins after tumor removal.
The goal of this clinical trial is to learn if the areas of stressed cells in the retina correlate to areas of disease identified in standard imaging and whether the images are helpful to identify potential areas of concern before symptoms or disease occurs. The main question it aims to answer is: * to evaluate patterns of increased autofluorescence FPF in the setting of geographic atrophy Participants will undergo FPF imaging using the OcuMet Beacon system.
This phase I/II trial studies the side effects and how well fluorescence image guided surgery followed by intraoperative photodynamic therapy for improving local tumor control in patients with colorectal cancer that has spread to nearby tissue or lymph nodes (locally advanced) or that has come back after a period of improvement (recurrent). Fluorescence image guided surgery uses a drug named aminolevulinic acid hydrochloride. Aminolevulinic acid hydrochloride is a photosensitizing agent, meaning that is activated by light and, is converted to another drug in cancer cells more than in normal cells. The converted drug emits fluorescence red light when activated with low power blue light. It is used to assist the surgeon to see cancer cells and small cancerous tissue that may have been missed during routine surgery. In addition to emitting fluorescence light, the converted drug in the cancer cells and tissue can be activated with red laser light to kill cancer cells. This procedure is called photodynamic therapy (PDT). Performing fluorescence image guided surgery followed by intraoperative photodynamic therapy after the surgical removal of the colorectal tumor before the surgical site will be closed may be effective and improve outcomes in patients with locally advanced or recurrent colorectal cancer.
The aim of this study is to determine if fluorescence with or without indocyanine green can facilitate safe and accurate thyroid and parathyroid surgery.
The purpose of this study is to characterize the perfusion of neuromas using indocyanine green fluorescence angiography
The purpose of this study is to objectively assess lymphatic function before, during, and immediately after Neuroglide treatment in lower trunk and leg lymphatic vessels, torso, axillary regions, inguinal regions, upper extremities, and cervical/neck and to determine any VAS (Visual Analog Scale, a commonly used measure of pain perception) score change after Neuroglide treatment.
This study investigates fluorescence image-guided surgery to allow precise identification of necrotic tissue both preoperatively and intraoperatively in burn patients. Furthermore, it uses a multi-model approach to elucidate the localization of ICG in inflammation and necrosis to determine how this novel use of a well-known fluorescence marker can be optimized to aid in surgical decision making. This proposal will provide the necessary data to support the design of a larger clinical trial to study the feasibility and efficacy of this technology to improve the precision of necrosis detection and removal and improve wound healing outcomes. Up to 100 participants will be on study for up to approximately 24 days.
This is a non-randomized, open-label, single-center, safety and imaging feasibility study of Pegsitacianine, an intraoperative fluorescence imaging agent.
This study allows head and neck cancer surgeons to specifically visualize cancerous cells apart from normal healthy tissue. 5-aminolevulinic acid (5-ALA) is a safe and effective FDA-approved agent successfully used by neurosurgeons for FGS of different brain tumors is given to the patients preoperatively. Using specific wavelengths of light as well as specialized magnified lenses the surgeons use this technique to assist in tumor resection.
The objective of this study is to assess whether Near-Infrared Fluorescence/NIR Imaging perfusion alters intraoperative management of the flap or of the participant wound bed.
This Phase 2 study is an open-label, single-arm trial where each patient is his/her own "intrapatient" control. All patients will receive a single dose of pegsitacianine prior to standard of care surgery.
This is a prospective single arm, single center study estimating percentage of successful critical anatomy recognition in laparoscopic cholecystectomy surgeries using SPY fluorescence imaging and ICG, with each surgery also providing a white light 360 degree images. The primary objective is to determine the percentage of successful critical anatomy recognition using intra-operative SPY fluorescence imaging and ICG: and to describe complications associated with intra-operative decision making in patients undergoing laparoscopic cholecystectomy.
The proposed research aims to be a pilot feasibility study to evaluate intraoperative fluorescence angiography (IFA) as an aid for acute debridement in orthopaedic trauma.
Fluorescence-guided resection using 5-ALA induced tumor fluorescence of malignant gliomas allows for better identification of tumor tissue and more radical resection in select patients and improvements in progression-free and overall survival. With new developments in surgical microscopy, the development of digital exoscopes have provided advanced visualization as well as improvements in ergonomics and accessibility of the surgical field. The use of the exoscope in 5-ALA fluorescence-guided tumor surgery has the potential to enhance the ability of the surgeon to remove brain tumors with high efficacy. While algorithms for use of 5-ALA fluorescence have been optimized for use with traditional microscopes, the use of fluorescence techniques in newer digital exoscopes have not been developed. The primary outcome of the study is to obtain parameters to optimize visualization of fluorescence intensity and perform optimization based on the intensities achieved. The operating ORBEYE exoscope will be fitted with a blue light filter. All experiments will be performed in darkened operating rooms. The ORBEYE exoscope will be set up at constant distances from the target and incident light intensities. The focal distance and light intensity settings will be recorded from the data displayed on the microscope. Patients (experimental group) will receive 5ALA treatment before operation, blue light filter imagining will take place after tacking up dura and prior to direct resection. The expected outcomes of image analysis will be to have a set of exoscope parameters optimized for visualization of 5ALA tissue in different tumor types. This 5ALA characterization of visualization parameters has never been completed on an exoscope. Optimizing ORBEYE exoscope parameters will define a standard in glioma resection using 5ALA under a novel exoscopic filter as well as contribute insight into the use of the fluorescent filter for additional tumor types.
Breast conserving surgery (BCS) is performed on patients with breast cancer to resect and completely remove the cancer while conserving as much of the surrounding healthy tissue as possible. Current methods do not allow surgeons to determine the completeness of surgical resection in real-time. This often results in the need for a second surgical procedure, or in some cases more than two surgical procedures in order to have confidence that all cancer has been removed. This Phase 3 study will evaluate the safety and efficacy of the fluorescent imaging agent PD G 506 A for the real-time visualization of cancer during standard of care breast conserving surgery. PD G 506 A is an investigational drug which is converted in the body into a fluorescent molecule that accumulates in cancer cells. Patients receiving PD G 506 A will undergo standard of care breast conserving surgery followed by fluorescence imaging and removal of any potentially cancerous tissue left behind in the surgical cavity.