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The goal of this clinical trial is to compare a new way of using magnetic resonance-guided adaptive radiation therapy (MRgART) to the standard of care linear accelerator (LINAC) radiation treatment in people with cancer in the thoracic region near the heart. The main question it aims to answer is whether MRgART affects the heart differently than LINAC. Participants will: * Receive radiation therapy * Undergo MRIs and bloodwork * Complete quality of life questionnaires
This clinical trial evaluates earlier symptom management through remote electronic symptom monitoring (such as through an app on patient's phone), and accessibility of palliative care self-referral by patients with thoracic cancer and caregivers by proxy (legal representative). Thoracic cancer occurs in the chest and often causes symptoms for patients. Patients and/or their caregivers are often unable to attend in-person clinic visits for various reasons. The most frequently reported symptom by patients at initial palliative care consultations is pain, and caregivers' most common concerns are pain management for the patient, stress reduction, and fears about patient decline. Earlier palliative care referral can help control these symptoms before they worsen, providing a better quality of life for patients and caregivers. improve physical and emotional functioning for patients and caregivers in cancer care. This study may help researchers learn how an electronic symptom monitoring program may provide an earlier and more accessible way for patients with thoracic cancer to receive palliative care.
The study aims to determine maximum tolerated dose (MTD) or recommended combination dose of the MTA-cooperative PRMT5 inhibitor AMG 193 administered in combination with other therapies in adult participants with metastatic or locally advanced methylthioadenosine phosphorylase (MTAP)-deleted thoracic tumors. The study also aims to determine the safety profile of AMG 193 administered in combination with other therapies in adult participants with metastatic or locally advanced MTAP-deleted thoracic tumors.
This is a phase 2 pragmatic study that evaluates the clinical benefit of continuing systemic therapy with the addition of locally ablative therapies for oligo-progressive solid tumors as the primary objective. The primary outcome measure is the time to treatment failure (defined as time to change in systemic failure or permanent discontinuation of therapy) following locally ablative therapy.
The purpose of this research study is to learn more about the inherited risk for developing lung cancer.
The purpose of this research study is to develop a method of using magnetic resonance imaging (MRI) to evaluate lung tumors and other thoracic malignancies. An MRI is a scanning device that uses magnets to make images (pictures) of the body. This study is being done to determine what series of reactions (metabolic pathways) pulmonary nodules use as they burn sugar as fuel for growth. The manner in which the tumor burns (metabolizes) sugar for fuel is being investigated by using a natural, slightly modified, sugar solution (13C-glucose) and studying a small sample of the tumor once it is removed at the time of surgery.
This is an observational study involving the collection of patient-generated health data using an Apple Watch, a home pulse oximeter, and a smartphone during a course of proton beam radiotherapy for lung cancer. The study period over which this information is collected will range from the day of study enrollment until two weeks after radiotherapy completion. Subjects will complete a short satisfaction survey at the end of the study period. Other information that is collected as part of routine care for this patient population will be extracted from subjects' medical records during the study period and afterwards.
TNG462-C102 is a Phase 1/2, open-label, multicenter study designed to determine the safety, tolerability, PK, PD, and preliminary antineoplastic activity of oral TNG462 in combination with RMC-6236 or RMC-9805. The study comprises a dose escalation phase and a dose expansion phase.
This phase III trial studies how well pafolacianine works for identifying cancerous lesions in children and adolescent patients with primary solid tumors or solid tumors that have spread from where they first started (primary site) to other places in the body (metastatic). Pafolacianine is a fluorescent imaging agent that targets folate receptors which are overexpressed in many cancers and is used with near infrared (NIR) imaging during surgery to identify tumor cells. NIR uses a special camera that uses wavelengths in the infrared range to visualize and locate the tumor cells that are lit up by the pafolacianine. Giving pafolacianine for NIR imaging may work better than other imaging agents in identifying cancerous lesions in pediatric patients with solid tumors.
Cone beam computed tomography (CBCT) is an imaging technology that is incorporated into many modern radiation therapy systems. The quality of conventional CBCT is good enough to align patients for their daily radiation therapy but CBCT images have poor contrast and are susceptible to imaging artefacts that limit their usability for other tasks in the radiation therapy workflow. Varian Medical Systems, the sponsor of this study, has developed new CBCT imaging technology called HyperSight that so far has demonstrated increased image quality compared with conventional CBCT images. This new HyperSight CBCT imager has previously been built into Varian Halcyon and Ethos treatment machines, where the imager is enclosed in a ring that rotates around the patient. Now, HyperSight has been built into a Varian treatment machine, called TrueBeam, where the imager is mounted on a C-shaped arm that rotates around you to acquire an image. This study is being done to evaluate the image quality of HyperSight CBCT compared to conventional CBCT images, and to determine whether HyperSight CBCT can improve the process of delivering radiation treatments. The goal of this study is to collect images from this new HyperSight-TrueBeam CBCT imager from a variety of patients and locations in the body. The images will be analyzed to determine whether their quality is high enough to use for tasks other than positioning patients for treatment. For example, the study will determine whether the HyperSight images could be used to calculate a radiation plan.