View clinical trials related to Urogenital Neoplasms.
Filter by:This is a randomized controlled trial where patients undergoing surgical treatment for urogenital cancers will be randomized in a two arms study: surgical treatment + antibiotics OR surgical treatment + placebo.
Radical radiation therapy for prostate cancer is a common treatment that has shown to improve clinical outcomes in a post-operative setting. However, radiation therapy after surgery poses a greater risk for bladder and rectum injury for patients with prostate or bladder cancer. For prostate cancer patients, the risk is further amplified when pelvic nodes are part of the target irradiated volume. For bladder cancer patients, the risk of injury increases when more of the bladder is part of the target volume. Using an adaptive radiation therapy approach allows for correcting any shifts in the target volume. ART approach uses images from treatment to adapt the treatment plan. This study will use Adaptive Radiation Therapy for patients who receive pelvic nodal radiotherapy for either prostate or bladder cancer. Their treatment plans will adapted using MRI scans and CBCT scans taken during their first week of radiotherapy to account for any shifts in the target volume. The purpose of this study is to evaluate the feasibility of ART approach and its and on treatment plan quality metrics for pelvic radiotherapy. Acute and late toxicities will also be evaluated. 40 participants (minimum of 10 bladder cancer patients) will be enrolled. The participants will be followed for a period of 5 years post radiation therapy, during which they will have PSA as per standard practice, along with follow-up questionnaires (EPIC for prostate cancer patients and BUSS for bladder cancer patients).
This research study is evaluating the effectiveness of video and web-based communication in clinical research compared to standard practices.
This study will test an intervention to improve patients' and their caregivers' ability to manage difficult emotions and communicate about the patient's illness. There will be two versions of the intervention used for this study: a culturally tailored version for Latinx participants refined during Phase 1 of this study, and a version of the intervention that was not culturally tailored for Latinx patients and caregivers developed in previous work. The two interventions differ in minor content areas. We will use the culturally tailored intervention for Latinx participants and the non-tailored intervention for non-Latinx participants. This culturally sensitive intervention has the potential to reduce Latino/a patient and caregiver distress and improve patient and caregiver quality of life, shared understanding of the patient's illness, and patients' and caregivers' ability to discuss, identify, and document patients' treatment preferences. The intervention is designed to minimize burden to patients, caregivers, and healthcare institutions to allow for easy integration into clinical practice.
Studies have shown that tumors from the same patient may respond very differently to the same therapeutic agents. This study aims to investigate the genetic basis of tumors that respond abnormally well or poorly to therapeutic agents in an effort to understand the fundamental genetic basis of this response. The present protocol seeks to retrospectively perform Exome, next-generation (DNA) sequencing and/or other molecular techniques on tumor samples to identify the genetic basis of a patient's exceptional response to chemotherapy.
This is a clinical trial studying the administration of NanoDoce as a direct injection to the bladder wall immediately after tumor resection and as an intravesical instillation. All participants will receive NanoDoce, and will be evaluated for safety and tolerability, as well as the potential effects of NanoDoce on urothelial carcinoma.
Our hypothesis is: the nutritional supplement Ocoxin-viusid improves the quality of life of patients, including a better tolerance to neoadjuvant chemotherapy.
Preclinical models of urogenital carcinoma have been emerging as a way to pre-determine drug resistance before therapy is targeted. The implantation of tumor specimens in the chorioallantoic membrane (CAM) of the chicken embryo results in a high-efficiency graft, thus allowing large-scale studies of "tumor avatar". The aim of the study is to develop a tumor culture platform for treatment evaluation. Biopsies will be collected from primary tumors of patients and grafted onto the chorioallantoic membrane of chicken embryos. After tumor implantation at the CAM, tumor growth will be accompanied by imaging that will quantify tumor vascularization, tumor volume, and tumor blood flow. Following tumor growth, "avatars" will be divided into different treatments. Using the "tumor avatar" model together with patient tumors, the investigators will be able to observe the individualized tumor response for each patient in a treatment context, as well as determine the potential drug to be used in each case. These results may support a phenotype-based reading within 7-10 days.
Background: Exome sequencing can identify certain gene mutations in a person's tumor. This can then be used to create cancer treatments. In this study, researchers will make a treatment called a messenger ribonucleic acid (mRNA) vaccine. The vaccine might cause certain tumors to shrink. Objective: To see if the mRNA vaccine is safe and can cause metastatic melanoma or epithelial tumors to shrink. Eligibility: People 18-70 years old with metastatic melanoma or epithelial cancer Design: Participants will be screened under protocol 99-C-0128. Participants will provide samples under protocol 03-C-0277: Participants will provide a piece of their tumor from a previous surgery or biopsy. Participants will have leukapheresis: Blood is removed through a needle in one arm and circulated through a machine that takes out the white blood cells. The blood is then returned through a needle in the other arm. Participants will have many tests: Scans and x-rays Heart and lung function tests Blood and urine tests Participants will receive the mRNA vaccine every 2 weeks for up to 8 weeks. They will get the vaccine as an injection into the upper arm or thigh. They may receive a second course of vaccines if the study doctor determines it is needed. Participants will have follow-up visits approximately 2 weeks after their final vaccine, then 1 month later, then every 1-2 months for the first year, and then once a year for up to 5 years. Each visit may take up to 2 days and include: Physical exam Blood tests Scans Leukapheresis at the first visit
Background: A person s tumor is studied for mutations. When cells are found that can attack the mutation in a person s tumor, the genes from those cells are studied to find the parts that make the attack possible. White blood cells are then taken from the person s body, and the gene transfer occurs in a laboratory. A type of virus is used to transfer the genes that make those white blood cells able to attack the mutation in the tumor. The gene transfer therapy is the return of those white blood cells back to the person. Objective: To see if gene transfer therapy of white blood cells can shrink tumors. Eligibility: People with certain metastatic cancer for which standard treatments have not worked. Design: Participants may complete screening under another protocol. Screening includes: - Getting tumor cells from a previous procedure - Medical history - Physical exam - Scans - Blood, urine, heart, and lung tests The study has 8 stages: 1. Screening tests repeated over 1-2 weeks. Participants will have leukapheresis: Blood is removed by a needle in one arm. A machine removes white blood cells. The rest of the blood is returned by a needle in the other arm. 2. Care at home over approximately 12 weeks. 3. Stopping therapy for 4-6 weeks while their cells are changed in a lab. 4. Hospital stay approximately 3-4 weeks for treatment. An IV catheter will be placed in the chest to administer drugs. 5. Patients on Arm 2 of the study will receive the first dose of pembrolizumab while in the hospital. Three additional doses will be given after the cell infusion 3 weeks apart. 6. Receiving changed cells by catheter. Then getting a drug over 1-5 days to help the cells live longer. 7. Recover in the hospital for 1-2 weeks. Participants will get drugs and have blood and urine tests. 8. Participants will take an antibiotic and maybe an antiviral for at least 6 months after treatment. They will have repeat screening tests at visits every few months for the first year, every 6 months for the second year, then as determined.