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 goal of this mixed methods, user research study is to evaluate the Keep On Keep Up programme for people with Parkinson's (KOKU4PD). The main aims of the study are to: 1. To explore the usability and acceptability of the PD specific KOKU programme from a user and health care professional perspective. 2. To produce a KOKU4PD digital program that is ready for National Health Service (NHS) approval and a future effectiveness evaluation. Participants will use the KOKU4PD app at home for 4 weeks. They will be assessed at baseline and after the 4 weeks to measure aspects of their disease status, mobility, thinking, mood and quality of life. They will also be asked to complete some questionnaires about the usability of the app.
The goal of this clinical trial is to compare recovery in healthy, active runners. The main questions it aimed to answer were whether 7 day supplementation with Vistula TC attenuated: - muscle function - inflammation - soreness following a marathon run. Participants will either consume a spray-dried tart cherry supplement or a calorie-matched placebo-control for 7 days, and complete a marathon. Participants will perform functional tests, be assessed for their perceptual recovery and markers of inflammation and muscle damage via: - maximal voluntary contractions - counter movement jumps - visual analog scales to assess soreness - blood samples
Ajinomoto Cambrooke has developed a PKU protein substitute that is a proprietary blend of purified Glycomacropeptide (GMP) and essential amino acids, under the brand name Glytactin®. One serving of such Glytactin® products contains 20mg or less of Phenylalanine (Phe). The aim of the proposed study is to use this purified GMP-AA-based protein substitute, with less Phe per gram of protein equivalent than other commercially available products, in children with PKU at 100% of their protein substitute intake and evaluate its efficacy and the change in blood Phe in comparison to Phe-free L-AA-based protein substitutes.
The rare sugar D-Allulose, when consumed in a drink before eating has been shown to reduce the blood glucose response to high carbohydrate drinks or meals in people who are healthy, or have elevated fasting blood glucose concentration. However, the effectiveness of D-allulose to suppress blood glucose concentration when added into carbohydrate containing food products has not been previously reported and as the potential use of allulose is as a sucrose replacer in foods, rather than drinks, it is important that effects and efficacy are tested in this format. The study aimed to extend understanding of the acute effects of D-allulose consumption in humans by testing whether post-eating blood glucose concentration can be modified by the presence of D-allulose in a high carbohydrate breakfast and collecting data on any adverse gastrointestinal effects of consuming D-allulose.
The aim of this observational study is to translate the principle of individualised exercise prescription into the evaluation of daily absolute and relative intensity physical activity. The main questions this study aims to answer are: - Phase 1: What does physical activity (intensity) mean to people with COPD? - Phase 2: Are there differences between time spent in absolute and relative physical activity for people with COPD? Phase 1 Participants will take part in semi-structured interview (30-45 minutes) about living with COPD and perceptions of physical activity and how they perceive intensity. This will also include photovoice and photo-elicitation. Demographic information will be recorded and participants will also complete several respiratory symptom questionnaires. Phase 2: Participants will take part in physical activity testing before and after pulmonary rehabilitation while wearing physical activity monitors. Demographic information will be recorded and participants will also complete several respiratory symptom and physical activity questionnaires. Participants will also wear the physical activity monitors for 8 days after the pre-testing sessions and after their final pulmonary rehabilitation class. Sub-study: Participants will be asked to take images of barriers during physical activity, facilitators during physical activity, feelings during physical activity and types of physical activity they take part in for 8 days after their final pulmonary rehabilitation class. Participants will then take part in a semi-structured interview about the images their have taken while doing physical activity.
Researchers are looking for a better way to treat people who have advanced non-small cell lung cancer (NSCLC) with specific genetic changes called epidermal growth factor receptor (EGFR) and human epidermal growth factor receptor 2 (HER2) mutations. Advanced NSCLC refers to a type of lung cancer that has spread from the lungs to nearby tissues or other body parts. People with advanced NSCLC may have changes in certain proteins, like EGFR and HER2, that cause uncontrolled cell growth and increased spread of cancer. In this study, participants will be healthy and will not benefit from taking the study treatment, BAY2927088. However, the study will provide information about how to test BAY2927088 in future studies with people who have advanced NSCLC with EGFR or HER2 mutations. BAY2927088 is under development for the treatment of advanced NSCLC with EGFR or HER2 mutations. It is expected to work against these changed proteins, which might slow down the spread of cancer. Researchers think that BAY2927088 inhibits drug transporters such as P-gp (P-glycoprotein) and breast cancer resistance protein (BCRP). Drug transporters are proteins that help in the movement of certain drugs into, through, and out of the body's cells. Dabigatran is a drug used in the treatment of blood clots in a vein and rosuvastatin is a drug used in the treatment of high cholesterol in the blood. The main purpose of this study is to find out how BAY2927088, taken as multiple doses, affects the levels of dabigatran and rosuvastatin in the blood of healthy participants. For this, researchers will measure the following for dabigatran and rosuvastatin, when given with and without BAY2927088: - Area under the curve (AUC): a measure of the total amount of the drug in participants' blood over time - Maximum observed concentration (Cmax): the highest amount of the drug in participants' blood In this study, participants will take the following treatments: - Dabigatran in the morning of Day 1 and 9. - Rosuvastatin in the morning of Day 3 and 12. - BAY2927088 two times a day in the morning and evening of Days 6 to 15. Participants will be in this study for about 8 weeks with 3 visits to the study clinic. Participants will visit the study clinic: - at least once, 2 to 28 days before the treatment starts, to confirm they can take part in this study - once on the day before the treatment starts and will stay in the clinic until Day 16 of the treatment - once, 7 to 10 days after last dose of BAY2927088, for a health check-up During the study, the doctors and their study team will: - do physical examinations - collect blood samples from the participants to measure the levels of dabigatran, rosuvastatin and of BAY2927088 - check participants' health by performing tests such as blood and urine tests, and checking heart health using an electrocardiogram (ECG) - ask the participants questions about how they are feeling and what adverse events they are having An adverse event is any medical problem that a participant has during a study. The study doctors keep track of all adverse events, irrespective if they think it is related or not to the study treatment.
It is estimated by WHO (2021) that 1.4 billion individuals across the globe have high blood pressure with only 14% of people managing these elevated levels. Simple and effective lifestyle strategies are required to help people improve their blood pressure and/or attenuate increases in blood pressure with ageing. Exercise is one possible strategy: in previous research, several different types of exercise have been shown to have effects on blood pressure (Blackwell et al., 2017). However, many individuals do not adhere to currently recommended levels of exercise (150 mins of moderate intensity exercise per week), due to a combination of the required time commitment, lack of motivation, and the associated levels of effort / exertion and discomfort (Korkiakangas et al 2009). Thus, there is a need to investigate alternative exercise interventions which will overcome these barriers but remain effective at improving blood pressure (Herrod, Lund, & Phillips, 2021). Low intensity isometric hand grip training (IHGT) has been shown to result in large decreases in rest-ing blood pressure in younger and older age groups, in both men and women, and in individuals with normal as well as elevated baseline blood pressure (Badrov et al, 2013; Bentley et al., 2018; Millar et al., 2014). In this research, IHGT has typically involved performing 4 x 2 IHGT holds at 30% of maximal voluntary contraction, 3 times a week, over a 4-8-week intervention (Millar et al, 2014). Interestingly, there are very few studies that have investigated the effect of changing different protocol parameters on the adaptations in blood pressure, and the minimal effective dose of IHGT is unknown. One important modifiable parameter is training frequency and it is unknown whether reducing the frequency of IHGT will reduce the efficacy for improving blood pressure. Therefore, the aim of this randomised controlled trial is to compare the effect of IHGT with a frequency of 2 or 4 sessions/week on resting blood pressure.
The purpose of this study is to compare ease of handling and vision acuity of two multifocal contact lenses to correct presbyopia that are currently CE marked and on the UK market.
Evaluate a deep-learning model trained on computational histopathology for predicting outcomes in cutaneous squamous cell carcinoma
Background: Some health conditions make breathing difficult and uncomfortable. When this happens every day, it is called chronic breathlessness. Over 3 million people living with heart and lung disease have chronic breathlessness in the UK. Breathlessness is very difficult for patients themselves and their families, resulting in disability and feelings of fear, distress, and isolation. Due a to lack of supportive breathlessness services many patients frequently attend hospital Accident and Emergency (A&E) departments seeking help. Given the on-going challenges faced by the National Health Service (NHS) in the United Kingdom, such as long waiting times, staff shortages, increased demand for services because of the COVID-19 pandemic, there is an urgent need to develop new ways to support those living with chronic breathlessness. One potential solution is to offer support online, as it is estimated that in the UK, 7 out of every 10 people with chronic breathlessness are internet users. With the help of patients and NIHR funding the research team lead by Dr Charles Reilly, developed an online breathlessness supportive website called SELF-BREATHE. SELF-BREATHE provides information and self-management tools such as breathing exercises, that patients can do at home themselves. SELF-BREATHE has been tested as part of its development. SELF-BREATHE is acceptable and valued by patients. But what is unknown is whether SELF-BREATHE improves patients' breathlessness and their life? This is the question this research seeks to answer. Aims 1. To test if using SELF-BREATHE for six-weeks improves patients' breathlessness, their quality of life and whether SELF-BREATHE should be offered within the NHS 2. To see if patients opt to continue to use SELF-BREATHE after six-weeks and what benefits this may have for patients. Methods The research team are undertaking a randomised controlled trial. For this, 246 people living with chronic breathlessness will be recruited in to this study. Each person will be randomly chosen by a computer to continue with their usual care or their usual care plus access to SELF-BREATHE. All study participants will complete questionnaires at the start of the study, thereafter at seven and twelve weeks after randomisation. These questionnaires will ask patients about 1) their breathlessness and its effect on their life and 2) planned and unplanned hospital visits. At the end of the study, we will compare answers to these questionnaires between the two groups at seven and 12 weeks. This will tell if SELF-BREATHE improved patients' breathlessness and reduced their need for unplanned hospital visits e.g., A&E attendances due to breathlessness.