View clinical trials related to Prostate Cancer.
Filter by:The investigators will assess the feasibility of intraoperative use of C-arm cone-beam CT imaging for intraoperative dosimetric evaluation in prostate low-dose-rate (LDR) brachytherapy. Patients recruited are those who will receive standard LDR brachytherapy for prostate cancer treatment. Consenting patients will undergo additional 3D C-arm cone-beam CT imaging (3D C-arm) and motorized trans-rectal ultrasound (TRUS). Volumetric and dosimetric measures will be compared to those using the standard Day-0 CT images. The investigators hope that the intraoperative 3D C-arm provides quality assurance measures sufficient to eliminate the need for Day-0 CT LDR brachytherapy and provide the opportunity for intraoperative modification of seed delivery plan.
This trial is a three-armed randomized controlled trial which will explore the utility of an implementation intention intervention on aerobic and resistance exercise in older (60+) prostate and breast cancer survivors and improving quality of life. It is expected that those in the experimental groups will report greater increases in their physical activity, resulting in greater improvements in their quality of life.
The purpose of this study is to assess enzalutamide plus leuprolide in patients with high-risk nonmetastatic prostate cancer progressing after radical prostatectomy or radiotherapy or both. The randomized / blinded portion of the study is now completed following primary endpoint analyses. The study remains ongoing in open label format.
The main purpose of this study is to collect the safety data of Sumitomo Heavy Industries' proton therapy equipment for the treatment of solid cancer patients in Linkou Chang Gung Memorial Hospital, including the patients' early-stage adverse reactions and the efficacy on tumors, as well as to assess the operating functionality of the proton therapy system.
The investigators hypothesize that this single-cell analysis can be used to evaluate prostate needle-core biopsies prospectively even in non-homogenous samples by providing profiles of proteomic and phenotypic signatures. These profiles will in turn enable better predictions of the malignant progression of prostate cancers in the settings of current clinical practice.
A single arm phase II study of SBRT for prostate cancer to primarily assess acute and late toxicity and secondarily PSA outcomes and quality of life measurements of an extreme hypofractionated regimen of 36.25Gy in 5 fractions over 10-11 days.
The purpose of this study is to better understand prostate cancer changes after radiation treatment, through magnetic resonance imaging (MRI). MRI is an imaging test that allows doctors to see prostate gland without any operation procedures. It can help identifying the tumors in the prostate. For patients with newly diagnosed prostate cancer, MRI may help doctors manage treatment better and sooner.
External beam radiotherapy (RT) is one of the standard curative treatment options for patients with prostate cancer (PC). Several randomised trials have shown excellent long-term biochemical outcome with higher radiation doses. Nowadays, RT for PC commonly consists of delivering 74-80 Gy in 2 Gy fractions, resulting in an overall treatment time of 7-8 weeks. The sensitivity of different tissues to fractionation changes can be quantified through the alpha/beta ratio in the linear-quadratic model. Dose-response analysis of PC patients treated with both external beam RT and brachytherapy has led to the hypothesis that the alpha/beta ratio of PC is lower than for most other tumors and approaches a value characteristic of late responding tissues. Values between 1.2 and 3.9 Gy have been calculated. If the alpha/beta ratio of PC is indeed low, then hypofractionating RT treatments can theoretically maintain high bioequivalent tumor doses, shorten overall treatment time and decrease late toxicities.The advantages in terms of patient convenience and treatment cost are obvious. There is level I evidence that shows that hypofractionated radiotherapy schedules have at least equivalent biochemical outcome with only a small increase in acute but not late toxicity when compared to conventional fractionation RT schedules. Results on different hypofractionation schedules have been reported, however the optimal hypofractionation is not clear so far. In this randomised trial we would like to compare 2 different radiotherapyschedules: 16 fractions à rato of 4 fractions a week versus 25 fractions à rato of 5 fractions a week. The incidence on acute toxicity and early late toxicity (i.e. within 2 year post radiotherapy) and the impact on quality of life will be registrated and compared. The study will be performed in 2 stages. For stage 1, sample size was calculated to rule out an upper limit of 40% of patients with RTOG grade 2 or worse bowel (GI) complications with an expected rate of 25%, based on a one-stage Fleming-A'Hern design. A power of 83.0% (alpha level 0.038 one-sided) was obtained when including 72 patients per group (144 patients in total). If 22 or more patients out of 72 had grade 2 or worse GI complications, then the study arm was to be rejected. To allow for a dropout of 10%, 160 patients were included in stage 1. Sample size for stage 2 was calculated analogously allowing ruling out an upper limit of 35% of patients with RTOG grade 2 or worse GI complications with an expected rate of 25%. When including 155 patients per group (310 in total) a power of 85.7% (alpha level 0.049 one-sided) was obtained. If 45 or more patients out of 155 had grade 2 or worse GI complications, then the study arm was to be rejected. The sample size for stage 1 and stage 2 combined was set at 346 (173 per group), with a 10% allowance for dropout.
This study is being performed to verify the ability to use minimally invasive transurethral ultrasonic imaging technology for the purpose of identifying prostate cancer. Transurethral ultrasonic prostate imaging, may in the future, be used for detection and monitoring these disease processes to minimize the need for obtaining surgical biopsy specimens. The hypothesis is that tissue-density variations, as revealed in diagnostic ultrasonic imaging, results in unique image signatures for identification of prostate cancer. This imaging procedure provides a multifaceted view of the entire in-situ gland. The current use of Prostate Specific Antigen (PSA) for determining the likelihood of presence of cancer in the prostate gland requires interpretation and has a good but limited to predict prostate cancer on biopsy, with significant false prediction rates. More importantly as a blood test, the PSA test lacks the ability to pinpoint the location of the cancer within the prostate gland. Preliminary study findings have suggested that "Transurethral Ultrasonic Scanning" (TUUS) presents the desired improved diagnostic sensitivity for detection of cancer within the imaged prostate gland, and has the intrinsic capability to provide high resolution images of the transverse and future three-dimensional views of the entire gland better than currently used Transurethral Ultrasound (TRUS). Two important goals of the practicality of this minimally invasive technology will be assessed by this study. 1. The ability of TUUS to directly detect prostate cancer locations in the prostate. 2. The use of TUUS to successfully guide the prostate needle biopsy to cancer loci with a high rate accuracy.
The purpose of this research study is to learn about: 1) improving control of prostate cancer using an extra high dose radiation treatment to the MRI defined high risk tumor areas, in addition to the standard radiation treatment to the rest of the prostate; 2) preserving quality of life by reducing dose to the nearby organs at risk around the prostate; and 3) establishing the relationship of pre- and post-treatment MRI to MRI-directed biopsy results at 2-2.5 years after treatment.