View clinical trials related to Respiratory Disorder.
Filter by:The purpose of this observational trial is to advance digital health monitoring through the analysis of Photoplethysmography (PPG) waveforms collected via RE.DOCTOR Vitals software. The study aims to collect a diverse and extensive dataset of PPG waveforms, alongside traditional physiological measurements, for the purpose of enhancing existing algorithms and machine learning models used in health monitoring. The primary focus is on improving the accuracy and reliability of algorithms in interpreting PPG data to derive meaningful insights into physiological parameters. The main questions it aims to answer are: - How can extensive datasets of PPG waveforms be utilized to enhance existing algorithms and machine learning models? - How do correlations between PPG waveforms and key physiological parameters (such as glucose levels, blood pressure, heart rate, respiration rate) contribute to refining algorithms for more accurate and reliable health predictions? Participants will be asked to: - Continuously monitor their health using smartphone applications. - Allow the collection of PPG waveforms in diverse settings. - Engage in tasks related to monitor health parameters using medically approved devices
Bronchial fibroscopy (BF) is a routine practice examination in critical care areas. It can be useful either for the diagnosis of the causal pathology of respiratory distress or for the diagnosis of lung infection, sometimes nosocomial. In patients in spontaneous and conscious ventilation, BF are performed vigil after local anesthesia according to the recommendations of the Société de Pneumologie de langue Française. The good tolerance of the examination and its good conduct may require the use of anxiolytics, sedatives or analgesics to limit the traumatic experience of a highly anxiety-provoking examination. Virtual reality (VR) combines a set of paramedical techniques (hypnosis, music therapy, sophrology) and is now a non-drug alternative to improve the tolerance of certain invasive gestures.VR has been shown to reduce pain and anxiety during first pathways placement or digestive endoscopies. To date, there is no evidence of the benefit of VR when performing semi-urgent BF in critical care areas.
AIM: To advance the development and accuracy of the Lifelight® app for the measurement of vital signs, therefore developing a non-invasive and easy-to-perform means of measuring vital signs which can be implemented across a wide range of settings, both within hospitals and out in the community. METHOD: Lifelight® is a computer program ("app") for measuring vital signs which can be used on smart devices that contain a camera. It is able to measure all of the vital signs by measuring very small changes in skin colour that occur each time the heart beats. This means that it does not need to touch the patient. The investigators believe this could be an effective way of measuring vital signs, especially during the COVID-19 pandemic when prevention of cross-contamination between patients is essential. Patients are also likely to be reassured by a contactless approach. The app uses data from looking at a person's face to calculate the vital signs. This is possible because there are tiny changes in facial skin that occur each time the heart beats. The investigators believe Lifelight® could be an effective way of measuring vital signs. The app is still under development, which means that it is still "learning" the best match between the information it collects from the face and the values of vital signs measured using the standard equipment. The app should become more accurate in calculating the vital signs as it sees more and more information from patients. So far, the app has seen data from inpatients, outpatients, patients attending GP surgeries and healthy people. This has improved its accuracy in measuring vital signs. However, the app needs to see more information so that it can be sufficiently accurate for specific clinical applications such as long-term monitoring of hypertension. To do this, it particularly needs to see information from people with abnormal blood pressures and blood oxygen levels. In order to capture the full range of observations, the app will need to be trialled with some of the most critically ill patients - some of these will not have capacity to consent to participation in the study. It also needs to see more data from people with different skin tones so the investigators can be sure it is accurate for all patients. To do this, the investigators will recruit people who are attending one of two hospitals, either as an inpatient, an outpatient, a friend/relative of a patient, or a member of hospital staff. The exact number will depend on how quickly the app "learns" and how many of the vital signs are outside of the normal range. The investigators will take the participant's vital signs using standard clinical equipment whilst recording a video of their face. The investigators will use most of these measurements and video to teach the app how to become more accurate at measuring vital signs. The investigators will keep the remaining data separate and use it to test how accurate the app is. All of the data will be kept securely. The investigators will also collect feedback from participants and healthcare staff on their experiences using the app and information that allows us to assess whether there are any savings to the healthcare economy through use of this technology.
Primary Objective: To evaluate the efficacy of dupilumab as assessed by the reduction at Week 24 in sinus opacification on computerized tomography (CT) scan in the dupilumab group only Secondary Objectives: - To evaluate the efficacy of dupilumab as assessed by the reduction at Week 24 in sinus opacification on CT scan and sinus total symptom score (sTSS) compared to placebo - To evaluate the safety and tolerability of dupilumab in CRSsNP patients compared to placebo - To evaluate the pharmacokinetics (PK) of dupilumab in CRSsNP patients compared to placebo - Assessment of immunogenicity to dupilumab over time compared to placebo
Acute respiratory infections and other respiratory and cardiology diseases like COPD or heart failure are important causes of morbidity and mortality around the world. Telemedicine is defined as the delivery of health care and the sharing of medical knoledge over distances using telecommunication systems. Inexpensive techologies offer the possibility of a direct, real-time connection between the patient or the other end. These technologies help to the physicians to manage different symptoms and cardio-respiratory diseases. A real-time wireless tele-stethoscopy system was designed to allow a physician to receive real-time cardio-respiratory sounds from a remote auscultation, as well as video images showing where the technician is placing the stethoscope on the patient´s body. Actually, the lack of physicians in rural areas of developing countries makes difficult their correct diagnosis and treatment. Furthermore, in the majority of health systems, the patients are shared between primary care and medical specialty in hospitals. The tele-stethoscopy system through telemedicine could help to the physicians or health-care technicians in the majority of health systems and especially in rural areas of developing countries without physicians to manage the patients. For this reason, the goal of this project is the clinical validation of an open real-time tele-stethoscope systme (EHAS-Fundatel digital stethoscope) previously designed, with different specialist (pneumologists, cardiologists and internists.)