View clinical trials related to Proton Therapy.
Filter by:The purpose of this protocol is to determine toxicity and efficacy of proton therapy in combination with standard concomitant platinum-based chemotherapy and standard image-guided adaptive brachytherapy (IGABT) in patients with locally advanced cervical cancer (LACC). The over-all aim is to maintain a high disease control and at the same time reduce acute morbidity as well as late side effects after treatment.
This study is a clinical trial of prospective, single-arm objective performance criteria. This trial will be conducted in clinical trial sites with a total of 47 subjects enrolled. All of subjects will be treated with radiation therapy using the medical device Varian ProBeam Proton Therapy System (ProBeam), aim to compare the data with objective performance criteria (OPC) to evaluate the effectiveness and safety of ProBeam radiotherapy system for oncology patients, providing a clinical basis for the medical device registration.
To our knowledge, the investigators have not found any scientific article dealing with cooperation between radiation oncologists and medical radiation technologists in the context of monitoring patients undergoing radiotherapy. Cooperation protocols between health professionals are in progress but concern mainly technical procedures (ultrasound, laserthermal sessions). This study aims to evaluate whether MERMs, after training by physicians, can monitor clinical signs (for usual well-described toxicities) during treatment via a dedicated consultation. This approach participates in the development of new professions and cooperation protocols between health professionals. This mission of accompaniment on a dedicated time would make it possible to develop the caring role of the medical electroradiology manipulator.
Radiotherapy for advanced-stage head and neck squamous cell carcinoma (HNSCC) results in an unfavorable 5-year overall survival of 40%, and there is a strong biological rationale for improving outcome by combinatorial treatment with immunotherapy. However, also immunosuppressive effects of radiotherapy have been reported and recently a randomized phase-III trial failed to show any survival benefit following the combination of a PD-L1 inhibitor with chemoradiotherapy. The hypothesis is that the combination of these individually effective treatments failed because of radiation-induced lymphodepletion and that the key therefore lies in reforming conventional radiotherapy, which typically consists of large lymphotoxic radiation fields of 35 fractions. By integrating modern radiobiology and individually established innovative radiotherapy concepts, the patient's immune system could be maximally retained. This will be achieved by 1) increasing the radiation dose per fraction so that the total number of fractions can be reduced (HYpofractionation), 2) by redistributing the radiation dose towards a higher peak dose within the tumor center and a lowered elective-field dose (Dose-redistribution) and 3) by using RAdiotherapy with protons instead of photons (HYDRA). The objectives of this study are to determine the safety of HYDRA with protons and photons by conducting two parallel phase-I trials. HYDRA's efficacy will be compared to standard of care (SOC). The immune effects of HYDRA-protons will be evaluated by longitudinal immune profiling and compared to HYDRA-photons and SOC (with protons and photons). There will be a specific focus on actionable immune targets and their temporal patterns that can be tested in future hypofractionated-immunotherapy combination trials. This trial therefore is an important step towards future personalized immuno-radiotherapy combinations with the ultimate goal to improve survival for patients with HNSCC.
The PROTECT trial will test the hypothesis that proton (PT) -enabled radiation dose reductions to sensitive, normal tissues will result in lower rates of treatment-related pulmonary complications in esophageal cancer compared to standard photon therapy (XT).
For a young patient, the conditions of proton therapy treatment can be stressful. Adjusting the environment can be a source of avoiding this physical and psychological discomfort impacting the quality of treatment. A fixed, long, uncomfortable position is the main cause of stress, already present due to the cancerous therapeutic course. It extends the positioning time. For the patient and the optimization of his treatment, solutions must be sought. Relaxation in virtual reality is efficient, simple and non-medicinal and could reduce stress in children and allow irradiation in very good conditions. We will assess the effectiveness of the virtual reality session using objective (placement time, helmet tolerance) and subjective (perceived anxiety via a dedicated questionnaire) criteria. This is the first pediatric virtual reality study, supported by the French Group of Pediatric Radiotherapists, to reduce anxiety in radiotherapy. Multiple benefits from this pilot study are expected, such as improved reception conditions, treatment parameters and better acceptance of proton therapy sessions.
This is an interventional, single arm, open-label, feasibility trial with gemcitabine and nab-paclitaxel, followed by concomitant proton therapy and capecitabine, followed by re-evaluation and surgery (when feasible) for patients with borderline resectable pancreatic cancer.
Rationale: Chordomas and chondrosarcomas located in the axial skeleton are malignant neoplasms of bone. These tumors share the same clinical challenges, as the effect of the disease is more a function of their local aggressiveness than their tendency to metastasize (20% metastasize). The local aggressive behavior can cause debilitating morbidity and mortality by destruction of nearby located critical neurovascular structures. Imaging has, in addition to histopathology, a role in diagnosis and in guiding (neo)adjuvant and definitive treatment. Despite the low sensitivity to radiotherapy, proton radiotherapy has been successfully used as an adjunct to resection or as definitive treatment for aggressive chordomas and chondrosarcomas, making it a standard indication for proton therapy in the Netherlands. Chordomas and chondrosarcomas consist, especially after previous therapy, of non-viable and viable tumor components. Identification of these viable components by functional imaging is important to determine the effect of previous therapy, as change in total tumor volume occurs more than 200 days after change of functional imaging parameters. Objective: The main objective of this study is to determine if functional MRI parameters change within 6 months, and earlier than volumetric changes after start of proton beam therapy. This would allow timely differentiation between affected and unaffected (viable) tumor components, which can be used for therapy adjustment. Secondary objectives: Determine which set of parameters (PET-CT and secondary MRI) can predict clinical outcome (tumor specific mortality, development of metastases, morbidity secondary to tumor activity and morbidity secondary to treatment); determine what type of imaging can accurately identify viable tumor nodules relative to critical anatomical structures; improving understanding of relevance of changing imaging parameters by correlating these with resected tumor. Study design: Prospective cohort study Study population: LUMC patients diagnosed with primary or recurrent chordoma or chondrosarcoma in the axial skeleton. A number of 20 new patients per year is expected. Main study parameters: Volumetric and functional MR imaging parameters including permeability parameters. Secondary parameters are generated by PET-CT (SUV, MTV and TLG), MR (perfusion, permeability and diffusion), therapy (proton beam dose mapping, surgery) and clinical outcome. End points are disease specific survival, progression free survival (including development of metastases), side effects of treatment, and functional outcome (see CRF). In patients who are treated with surgical resection following neo-adjuvant therapy, the surgical specimen will be correlated with imaging findings. Nature and extent of the burden and risks associated with participation, benefit and group relatedness: Treatment and clinical management will not be affected in this study, thus the additional burden, risks, and benefits associated with participation in this study are minimal. Two extra MRI and one PET-CT examination will be planned during proton therapy.
The main objective is to detect with TESLA multiparametric 3 MRI, the MRI secondary changes to protontherapy irradiation and to correlate them with TEL mapping, physical dose and biological dose. A model should thus be able to be proposed at the end of the study.
The purpose of this research study is to compare the effects (good and bad) on subjects and their cancer using proton radiation therapy in combination with immunotherapy(ie. Programmed cell death protein 1, also known as PD-1 antibody) in multiple metastases.