View clinical trials related to Pulse Rate.
Filter by:The goal of this observational study is to assess whether the continuous non-invasive haemodynamic monitor MOH200 (measuring blood pressure as well as pulse rate) is effective or not in people undergoing general anesthetic surgeries for more than 60 minutes with planned invasive blood pressure and pulse oximeter monitoring. Researchers will compare blood pressure data derived from MOH200 to the invasive blood pressure (IBP) data to see if the MOH200 is effective to measure the blood pressure of a surgical person. Also, researchers will compare pulse rate data drived from MOH200 to that from the pulse oximeter to see if the MOH200 is effective to measure the pulse rate of a surgical person. Participants will be asked to be applied with MOH200 monitoring while IBP monitoring and pulse oximeter are applied. And after 30 minutes of the surgery, researchers will monitor the adverse effects occurred on the skin of participants to assess the safety of MOH200.
The VERDICT-2 verification study will examine the accuracy of the Cloud DX Vitaliti Continuous Vital Signs Monitor (Model: CVSM-1A) in an ambulatory context with healthy participants. The objective is to determine the accuracy of continuous non-invasive vital signs metrics including respiration, pulse rate, oxyhemoglobin saturation (SpO2), core temperature, heart rate, and cNIBP against standard comparator devices guided by consensus standards.
The aim of this trial study is to identify the effect of S-VR on comfort and self-efficacy of symptom management in cancer patients undergoing chemotherapy. Additional objectives of this study include: (a) identifying the effect of S-VR on anxiety in chemotherapy patients; (b) identifying the effect of S-VR on pain intensity of chemotherapy patients; (c) identifying the effect of S-VR on vital signs (pulse and blood pressure) of chemotherapy patients. Participants is randomly assigned into two group: SVR intervention group and control group. In the SVR group, participants will use a VR device (head-mounted display/HMD) with 360-degree natural panoramic and music relaxation contents. Control group will receive standard care in the form of guided imagery leaflet. The research will adhere to the ethical standards outlined in the Declaration of Helsinki and its subsequent amendments, as well as the protocol under reviewed by Medical and Health Research Ethics Committee (MHREC) Faculty of Medicine, Public Health and Nursing Universitas Gadjah Mada - Dr. Sardjito General Hospital Yogyakarta (Approval Number: KE/FK/0301/EC/2023). A formal informed consent will be obtained from all study participants. Validation number: 63f81182672f3 (http://komisietik.fk.ugm.ac.id/validasi)
The vital signs (pulse, systolic and diastolic blood pressure, respiratory rate, oxygen saturation and body temperature) are critical in assessing the severity and prognosis of infections. The devices used today for measuring the vital signs have to be in physical contact with the patients. There is an apparent risk of transferring infections from one patient to the next (or to healthcare professionals). Accurately obtaining vital signs is also important when managing other categories of patients where it may be relevant to obtain some of the vital signs such as pulse and blood pressure. This project aims to evaluate a new camera-based system for contactless measurement of vital signs.
This proposal describes the development of a 'Sensing ET Tube'. This device will replace the standard endotracheal (ET) tube used in anaesthesia and in ventilated intensive care patients and provide key vital signs monitoring utilising optoelectronic sensors. Continuous monitoring of patients' arterial oxygen saturation is essential during surgery, however pulse oximeters often misread or fail altogether as a result of peripheral vasoconstriction, hypotension or hypovolaemia. The Sensing ET Tube will allow continuous measurement of oxygen saturation and other parameters, such as pulse rate, from a single internal site, and will reduce the number of surface sensors placed on the skin and the number of electrical connections to the patient. The applicants have already developed similar sensor technology in the oesophagus and other internal locations. A pilot clinical evaluation of the device will be completed in anaesthetised patients undergoing surgery. The project will lead to further development of a multi-sensor tracheal platform for comprehensive anaesthesia and intensive care monitoring.