View clinical trials related to Prostatic Neoplasms.
Filter by:The main idea behind MICRO-LEARNER is to provide new insights about the response of healthy tissues to radiation by using information from the micro-environment obtained by biological measurements and imaging. This new knowledge will be included in current available predictive models of radio-induced toxicity, thus allowing to add unique biological characteristics of patients to dosimetry and treatment/clinical related variables. MICRO-LEARNER focuses on prostate cancer (PCa) and head-and-neck cancer (HNCa). For both cancers, radiotherapy is effectively used as curative treatment, in single modality or within a multidisciplinary approach including surgery (PCa) and/or chemotherapy (HNCa). Prediction and reduction of radio-induced side effects are becoming a priority: for PCa, high survival rates should be accompanied by a very low rate of moderate/severe toxicities; for HNCa, there is the need to tailor radiation dose according to disease recurrence risk profile. The shared aim of both cancers is to balance the improvement in outcome with a well-tolerated toxicity profile. Recent research indicates that the intestinal/salivary bacteria are strongly suspected of being very important in mediating the response to inflammation and lesions. Although their balance deeply changes during radiotherapy, studies done so far in the field of the microbiota-host relationship in radiotherapy have not addressed their role in insurgence of radiation toxicity. In this study, the investigators will assess how microbial populations evolve and how this influences the host and radiation induced toxicity in a significant number of patients. Moreover, the individual response at the tissue microstructure level, through analysis of images with advanced bioengineering techniques, will be determined. Results from this research, besides suggesting new ways to predict patients at risk of relevant side-effects, may also suggest possible treatments to change the baseline microbiota of patients at high risk or to modify it during therapy, in order to mitigate toxicity. Understanding the microbiota-radiotherapy interaction may thus lead to novel, effective and inexpensive ways of assessing and managing complications of cancer treatment.
A Phase II Randomized Trial of Hypofractionated Proton Therapy in Patients With A Localized Prostate Adenocarcinoma
The aim of this project is to determine whether androgen deprivation therapy (ADT) decreases left ventricular function in prostate cancer patients. If found successful, this may lead to improved cardiovascular health via treatment and/or lifestyle interventions in prostate cancer populations.
This study aims to examine whether Smart After-Care service (Internet-and mobile-based lifestyle intervention) has an effect on patients' satisfaction and clinical outcomes in patients with prostate cancer on androgen deprivation therapy. Patients with prostate cancer on androgen deprivation therapy will participate in the study. The study design is a randomized controlled trial. The patients were randomly assigned to intervention or usual care groups. Intervention patients received Smart After-Care service for 3 months. Primary endpoint was an increase in patients' physical function as assessed using 2 minute walking test. Secondary endpoints included improvement in muscle strength, short physical performance battery, body composition, and health-related quality of life.
Current agents administered in therapeutic regimens of prostate cancer employ different mechanisms to eliminate neoplastic cells by inducing substantial apoptosis and causing tumor regression. Treatment with neoadjuvant chemotherapy before radical prostatectomy may better control the tumor before it has the chance to convert into the disease of castration-resistant prostate cancer (CRPC), which is finally refractory to most modalities of clinical intervention with a clinically lethal nature.
A dose-response relationship for radiation in the management of prostate cancer is well established. Local recurrence of prostate cancer after external beam radiotherapy occurs in at least 40% of patients treated because of inability to deliver sufficient dose through external beam techniques. These patients respond well to re-irradiation using brachytherapy with about 50% of selected patients remaining free of recurrence 5 years after salvage. Advanced imaging using multiparametric Magnetic Resonance Imaging (mpMRI) allows identification of the site of recurrence, permitting partial prostate salvage brachytherapy. There is extensive literature on Low Dose Rate salvage brachytherapy but less on High Dose Rate.
Salvage brachytherapy in combination with interstitial hyperthermia for locally recurrent prostate carcinoma following external beam radiation therapy.
Through a better understanding of the biology of significant (lethal) prostate cancer, we hope to develop new markers/targets from urine metabolomics for more effective screening and prevention of significant prostate cancer. In the meantime, with these new markers we may substantially reduce overtreatment of insignificant PC.
The study aims to identify potential urine marker metabolites as predictive or prognostic markers for treatment outcomes in patients with prostate cancer.
The overall goal of this research is to validate and develop a non-invasive imaging biomarker of prostate cancer detection, progression, and recurrence. Development of such a biomarker may be useful to differentiate indolent from aggressive prostate cancer phenotypes allowing for selection of an appropriate risk adaptive therapy.