51 Clinical Trials for Various Conditions
RELIANT 2 is a pragmatic randomized controlled trial. The goal of this study is to compare the diagnostic yield of robotic assisted bronchoscopy with integrated cone beam computed tomography to that of electromagnetic navigation bronchoscopy with integrated digital tomosynthesis in patients undergoing bronchoscopy to biopsy a pulmonary lesion.
This is an investigator-initiated, cluster randomized controlled trial. The primary objective is to compare the diagnostic yield of the Ion™ Endoluminal System (SSCB) to the ILLUMISITE™ Platform (EMN bronchoscopy) in patients undergoing bronchoscopy for peripheral pulmonary lesion (PPL) evaluation.
This research is being done to evaluate the feasibility, and biopsy quality, of using a 1.1mm disposable cryoprobe that is passed through the working channel of the Ion Robotic bronchoscope to collect biopsy tissue.
This study is a retrospective multi-center chart review of patients who underwent an attempted biopsy of one or more pulmonary lesion(s) with the Ion Endoluminal System with the aim of assessing the overall performance of the system.
This study investigates whether using a mobile-CT-assisted bronchoscopy (M-CAB) during a bronchoscopy procedure will better enable the study staff to reach the lung tumor, perform a biopsy, and obtain a diagnosis. One method that doctors use for diagnosing lung tumors is bronchoscopy guided by an X-ray machine (called fluoroscope). Though much better guidance could be provided with a CT scanner when compared to the fluoroscope, the standard CT equipment is very large, fixed in a radiology room, and difficult to use with bronchoscopy. Mobile CT imaging systems may more easily and effectively perform the same tasks of the standard CT imaging in the bronchoscopy room, offering better guidance than the standard fluoroscope.
This phase II trial studies the use of Ion robotic bronchoscope with a mobile computed tomography (CT) scanner to biopsy tumors and inject a fluorescent dye called indocyanine green to mark the tumor during surgery in patients with stage I non-small cell lung cancer or cancer that has spread to the lung (lung metastases). Sometimes small tumors or those that are not on the surface of the lung can be challenging to remove without making larger incisions. Injecting the dye, may help doctors see the tumor more easily, which may allow for smaller incisions and by being able to see the tumor, doctors may be better able to decide where to make the incisions in order to get all of the tumor out.
To collect data on diagnostic yield of thin and ultrathin bronchoscopes with radial probe endobronchial ultrasound (radial EBUS) and transbronchial needle aspiration (TBNA) during routine standard of care bronchoscopy for peripheral pulmonary lesions.
This is a pilot study for placement of a tiny microdevice into lung tumors to more precisely predict tumor-specific drug sensitivity, and to help inform systemic therapeutic decisions. The microdevice will provide a novel technique for interrogating human lung tumor tissue in situ, and will uniquely facilitate assessment of response to multiple drugs simultaneously. This will not only increase the specificity of a particular participant's chosen systemic therapy, it will also augment the speed and efficiency with which investigators are able to make clinical decisions regarding choice of therapy.
In this study, the feasibility of performing robotic navigation of peripheral airways in human subjects for the purpose of biopsying peripheral lung lesions will be evaluated.
Purpose: Patients with peripheral lung nodules require evaluation for lung cancer. Our aim is to assess the diagnostic yield of a new technique, transbronchial cryobiopsies, in patients at risk for lung cancer. Target population: Patients referred for bronchoscopy and lung biopsies as a part of their work up for peripheral lung lesions. Procedures: Patients enrolled will have forceps transbronchial biopsies followed by transbronchial cryobiopsies for their lung lesion during bronchoscopy.
This pilot clinical trial studies how well cone-beam computed tomography (CBCT) works in guiding bronchoscopy in patients with lung lesions. CBCT during bronchoscopy may help doctors to biopsy lung lesions that are harder to reach.
Despite technological advancements directed towards the diagnosis of peripheral pulmonary lesions, an optimal approach has yet to be designed. The potential advantages of catheter based techniques include the ability to utilize instruments smaller than the diameter of a conventional bronchoscope, thereby allowing better access to the lung periphery. The drawbacks of a catheter based approach include the relative inability to steer a conventional catheter, and the inability to perform direct visualization and airway inspection through a conventional catheter. This study will evaluate a novel steerable catheter system with optical capabilities and pair this with electromagnetic navigation bronchoscopy to biopsy peripheral pulmonary lesions.
This is a phase II protocol to determine the safety and feasibility of Intraoperative CT fluoroscopy guidance for lung resection for small nodules.
RATIONALE: Evaluating specific proteins in the blood may be an effective and noninvasive procedure to help doctors determine if a patient has early non-small cell lung cancer. PURPOSE: This clinical trial is studying proteomic profiling to see how well it works in diagnosing non-small cell lung cancer in patients who are undergoing resection for suspicious (abnormal) stage I lung lesions.
The objectives of this study are to evaluate intraoperative percutaneous lung lesion marking assisted by electromagnetic guided percutaneous navigation and related tools.
The purpose of this study is to evaluate outcomes following electromagnetic navigation bronchoscopy™ (ENB™) procedures using the superDimension™ navigation system.
The purpose of this study is to compare the yield of two methods for obtaining a lung tissue sample: Procedure #1: standard fiberoptic bronchoscopy (FB) with fluoroscopy, and Procedure #2: ultrathin bronchoscope procedure with fluoroscopy and radial endobronchial ultrasound (R-EBUS). These two procedures are similar in that they both: (1) enable your doctor to look inside your lungs with a device called a bronchoscope, and (2) Use fluoroscopy, which is a technique that uses X-rays to see your lungs. This will give the doctor an opportunity to use either of the bronchoscopy methods described above and compare the tests to see if R-EBUS provides better results than standard bronchoscopy.
The primary objective of this study is to evaluate the performance of the Ion Endoluminal System with real-world use for pulmonary lesion localization or biopsy.
Navigational bronchoscopy (NB) is used to access peripheral and central parenchymal lung lesions via endobronchial and transbronchial approach. Currently there are multiple platforms available to provide guidance to reach the peripheral and central lesions in the lung which are inaccessible via traditional video bronchoscopy. Traditionally NB is done under fluoroscopic guidance using C-arm but with development of Cone Beam CT and 3D reconstruction technology, fluoroscopy can be enhanced to much higher resolution and can also provide real time 3D augmentation of the lesion. It also enables the user to obtain a CT of the Chest to confirm the real time location of the lesion and the bronchoscopic biopsy catheter and instruments. This has proven to improve the yield and sensitivity of Navigational bronchoscopic guided Biopsy of the lung nodules and masses. Out of the various navigational platforms we have, most of them are based on Electromagnetic guidance and some on Shape sensing technology. Some of the platforms have fixed angle catheter while the newer robotic platforms have articulating catheters with much more range of motion. So far we do not have any data directly comparing the diagnostic yield of Electromagnetic navigational bronchoscopy with Robotic shape sensing guided bronchoscopy while using Cone Beam CT and Augmented fluoroscopy with both the platforms. With my study, I want to examine the change in diagnostic yield and sensitivity of fixed angle ENB guided bronchoscopy and articulating robotic shape sensing bronchoscopy both using Cone Beam CT with 3D reconstruction.
Electromagnetic navigation bronchoscopy (ENB) is used to access peripheral and central parenchymal lung lesions via endobronchial and transbronchial approach. Traditionally ENB is done under fluoroscopic guidance using C-arm but with development of Cone Beam CT and 3D reconstruction technology, fluoroscopy can be enhanced to much higher resolution and can also provide real time 3D augmentation of the lesion. It also enables the user to obtain a CT of the Chest to confirm the real time location of the lesion and the bronchoscopic biopsy catheter and instruments. This is thought to improve the yield and sensitivity of ENB guided Biopsy of the lung nodules and masses but has not been proven in a prospective trial. With my study, I want to examine the effect of Cone Beam CT with 3D reconstruction on the diagnostic yield and sensitivity of Electromagnetic Navigational Bronchoscopic biopsy of the lung lesions.
This study is designed to evaluate clinical safety and diagnostic accuracy of the robotic-assisted bronchoscopy with biopsy performed with the Monarch™ Endoscopy Platform in a broad range of patients with pulmonary lesions.
Patients with medically inoperable primary soft tissue lesion of the lung will have transbronchial microwave ablation performed via transbronchial approach by an interventional pulmonologist or thoracic surgeon using CT imaging. Prior to the ablation procedure, the treating physician will use endobronchial ultrasound to confirm staging. Patients will be followed for one year following the ablation procedure for efficacy and safety.
This is a clinical trial to evaluate the use of peritumoral injection of near-infrared dye indocyanine green to identify lung lesions and sentinel lymph nodes. The primary purpose is to determine if the use of ICG injected via navigational bronchoscopy, CT-guided or transthoracic allows us to identify the first lymph node that drains from the tumor, and thus would be the most likely site for metastatic disease, and remove it for analysis to improve the ability to detect tumor in this node and to remove this additional site that potentially contains tumor cells. Using this intraoperative imaging technique, we aim to improve the identification of lung nodules for resection and the intraoperative identification of sentinel lymph nodes in the event that a lymphadenectomy is performed.
The goal of this clinical research study is to test the use of a minimally invasive multimodality image-guided (MIMIG) intervention system used for performing a lung biopsy. The safety of the MIMIG intervention system will also be studied.
The primary Study hypothesis is that the ProLung Test will demonstrate safety and efficacy in the risk stratification of patients with pulmonary lesions identified by CT that are suspicious for lung cancer. A statistically significant result will indicate that patients with a high ProLung Test result have a greater risk of developing lung cancer than patients with a low test result. There are three Specific Aims of this study: 1. Optimize and confirm the stability of the ProLung Test risk-stratification algorithm in patients with a diagnosis. 2. Externally validate the efficacy of the ProLung Test risk-stratification algorithm by comparing the test result to the conclusive patient diagnosis. 3. Assess the safety and tolerability of the ProLung Test procedures. Study Design This Study consists of two distinct phases, Stabilization and Validation. The Study will collect data from multiple sites (3 to 12), and each site may enroll patients and collect data for the Stabilization and Validation Phases with a minimum of three sites for the Validation Phase.
In this particular study the physicians want to use a new technique of how they obtain the PET/CT pictures. It is called breath-hold (BH) PET/CT". As the name suggests, they will ask the patient to hold their breath for about 20-30 seconds, and only during that time will they obtain pictures. This is repeated several times. In contrast to the standard PET/CT scan, they expect less "blurring" of the pictures, so that they can see the tumor better and measure the uptake of radioactive sugar in the tumor better and more reliably. Basically, this is the difference between taking pictures of a runner as compared to taking pictures of a person standing still. Since PET images need to be obtained over several minutes and people can not hold their breath for this extended time, we break the procedure into several cycles of 20-30 seconds (or longer, if possible) and then add all the "frozen" pictures in the end into one. They want to know if BH PET/CT scan measure changes in the cancer during therapy (i.e., from the baseline scan before therapy to the follow up scan at within 4 weeks later).
This study will compare two clinically accepted protocols for surveillance imaging in individuals who are found to have a small pulmonary nodule on chest computed tomography (CT) scans.
This is a study to assess the combination of PXD101 and 5-Fluorouracil (5-FU)in patients with advanced solid tumors. The primary goal of the study is to understand the safety, anti-tumor activity, and how the study drug behaves within the body when given with 5-Fluorouracil (5-FU).
The purpose of this study is to evaluate the ability of a new type of CT computer program(MeVis™)to accurately analyze and measure the size and changes in metastatic Liver and Lung tumors. This study will evaluate the data from current CT evaluation methods using the MeVis™ 3-D software.
The technique of intraprocedural electrogram morphology as a measure of lesion effectiveness in an attempt to achieve durable PVI, clearly led to shortened procedural time, radiation exposure, and superiority in outcomes, with the implementation of a reproducible, readily available intraprocedural tool that can be applied universally.