There are about 25435 clinical studies being (or have been) conducted in United Kingdom. The country of the clinical trial is determined by the location of where the clinical research is being studied. Most studies are often held in multiple locations & countries.
The purpose of this Post Market Study (PMS) is to evaluate the use of the CardioMEMS HF System in patients with Class III Heart Failure in a commercial setting.
Treatment of cancers of the head and neck, including oropharyngeal tumours, usually consist of a combination of radiotherapy and chemotherapy, although surgery may also play a part. Radiotherapy works by using the high energy x-rays to destroy cancer cells. Head and neck cancers often respond well to radiotherapy in the first instance and a proportion of patients will be cured by this treatment. However, not all of the cancer cells are destroyed by the combination of radiotherapy and chemotherapy and, in some patients, the cancer does come back. Studies have suggested that more efficient killing of cancer cells, and therefore, better cure rates, can be achieved by increasing the radiotherapy dose. However, in the past, this was not possible due to side effects. Intensity Modulated Radiotherapy (IMRT) is a new radiotherapy delivery technique that allows better shaping of the dose to the areas that need irradiating with the potential for fewer side effects. If the investigators use IMRT to deliver an intentionally higher dose of radiation (called a boost) to small selected areas whilst, at the same time giving standard treatment doses to the remaining areas, this approach is called IMRT dose-painting. These selected areas can be identified by a scan called 18F-FDG-PET (18F-fluorodeoxyglucose-positron emission tomography, also known as a 'PET' scan) which is a type of scan that can give information about the activity of a cancer. The purpose of this study is to find out whether the investigators can use IMRT dose-painting to boost the dose to the region inside a tumour which appears most active on 18F-FDG-PET. If this study shows that this approach is well-tolerated, then the investigators may be able to improve cure rates with this treatment. This would need to be tested in a subsequent study.
This is a pilot non-intervention study that aims to introduce PET/MRI, a state of the art new imaging technique, into the radiotherapy treatment pathway of patients with head and neck cancer. Ultimately the investigators aim to establish appropriate scanning and image registration protocols, to allow progression to a randomized trial of adaptive radiotherapy dose escalation. The latter is thought to potentially improve outcomes in this group. Ten patients with squamous cell carcinoma (SCC) of the oropharynx, hypopharynx and larynx, planned for radical treatment with radiotherapy (+/-chemotherapy), will be recruited. Study participants will have two PET/MRI scans, with the radiotherapy immobilization devices in situ. The first will be done prior to the start of radiotherapy, the second half way through treatment. Image quality will be assessed by comparing to standard diagnostic scans and different registration methods will be compared to establish the best way of incorporating PET/MR image data into the radiotherapy planning system. Patient tolerability and workflow considerations will also be qualitatively assessed. Furthermore, a planning study will be conducted to establish relevant treatment protocols for a subsequent dose escalation trial. PET/MRI is an exciting new technology with a lot of potential in the context of adaptive radiotherapy dose escalation. Within this pilot study the investigators aim to address the technical challenges of using it in this context prior to proceeding to a randomized trial.
The purpose of this study is to determine how patients with metastatic castration-resistant prostate cancer, and evidence of a homologous recombination gene deficiency, respond to treatment with rucaparib.
The main objective of the dose-escalation part of the trial is to determine the safety and tolerability, and to determine the Maximum Tolerated Dose and/or the Recommended Phase 2 Dose (RP2D) of BI 754091 on the basis of patients with dose-limiting toxicities (DLTs) in patients with selected advanced solid malignancies. Safety and tolerability will be evaluated by monitoring the occurrence of adverse events (AEs), serious AEs (SAE), and laboratory parameter abnormalities, as well as changes to vital signs. Secondary objectives are the determination of the PK profile of BI 754091 after single and multiple doses of BI 754091, and the preliminary assessment of antitumour activity. In the dose-expansion part of the trial, the main objectives are to further assess the safety, efficacy, PK profile, and biomarkers of BI 754091 in tumours with specific tumour types and/or genetic mutations at the RP2D.
This Phase II, single-arm study is designed to evaluate the effect of atezolizumab treatment in participants with locally advanced or metastatic urothelial bladder cancer. Participants will be enrolled into 1 of 2 cohorts. Cohort 1 (reported here) will consist of participants who are treatment-naïve and ineligible for cisplatin-containing chemotherapy. Cohort 2 will contain participants who have progressed during or following a prior platinum-based chemotherapy regimen. The results of the second cohort are reported separately (NCT02108652). Participants in both cohorts will be given a 1200 milligrams (mg) intravenous (IV) dose of atezolizumab on Day 1 of 21-day cycles. Treatment of participants in Cohort 1 will continue until disease progression per Response Evaluation Criteria in Solid Tumors Version 1.1 (RECIST v1.1) or unmanageable toxicity. Treatment of participants in Cohort 2 will continue until loss of clinical benefit or unmanageable toxicity.
This is a Phase 2, randomized, double-blind, placebo- and active-controlled, parallel group, multicenter study to evaluate the safety, tolerability, and efficacy of VX-440 in dual and triple combination with tezacaftor (TEZ; VX-661) and ivacaftor (IVA; VX-770) in subjects with cystic fibrosis (CF) who are homozygous for the F508del mutation of the CF transmembrane conductance regulator (CFTR) gene (F508del/F508del), or who are heterozygous for the F508del mutation and a minimal function (MF) CFTR mutation not likely to respond to TEZ and/or IVA therapy (F508del/MF).
Atrial fibrillation (AF) is the most common sustained heart rhythm abnormality. Its incidence is increasing partly due to the ageing population and it has been referred to as a growing epidemic. AF results in irregular contractions of the heart causing unpleasant symptoms of palpitations and increasing the risk of stroke, heart failure and death. Percutaneous catheter ablation is a safe treatment option in symptomatic patients with AF. The success rate of these procedures have improved with time due to our better understanding of AF, development of new techniques and technology, and greater physician experience. However, the success rate of these procedures still only remains around 70%. This is contributed to our limited ability to find the areas that drive the AF. STAR mapping is a novel mapping system that has been developed with a view of better identifying the sites that drive AF, through taking into account the mechanisms of AF that have already been demonstrated. Data from this study will be used to refine the identification of drivers in the fibrillation left atrium with enormous potential to simplify ablation and improve success rates and thereby reducing the need for further procedures. To better validate this mapping system the investigators also aim to use it in participants with atrial tachycardia (AT), which is a heart rhythm abnormality of which the mechanism can be readily identified with the existing mapping systems used in clinical practice. The investigators will demonstrate that the STAR mapping algorithm can effectively map AT. To gain further understanding of the changes that occur in the left upper chamber of the heart in the context of AF half of the participants with AF will undergo cardiac magnetic resonance imaging to assess for the presence of scar. This will enhance our understanding of how atrial remodelling promotes AF, which may point to ways of modifying this process and preventing AF.
The purpose of this is to analyse human exhaled breath by means of a device called electronic nose(eNose) in patients with non-alcoholic fatty liver disease (NAFLD) as a way to non-invasive assessment of liver disease.This device is medically adapted and clinically validated in patients with lung conditions.
The objective of this investigation is to confirm the results obtained in a pilot study showing that certain radiological parameters based on computed tomography (CT) scans seem to reliably detect posterior ligament complex (PLC) injury without the need for Magnetic Resonance Imaging (MRI)