56 Clinical Trials for Various Conditions
The goal of this clinical trial is to compare the performance of a novel non-invasive respiratory monitoring system against the gold standard methods (capnography) in human subjects. The main question it aims to answer is whether the novel monitoring system comparable to the current standards.
An observational study will be conducted in approximately 14 participants to evaluate the ability of a wearable, wireless acoustic Respiratory Monitoring System (RMS) to accurately measure a participant's respiratory rate, tidal volume, minute ventilation, and duration of apnea in a noisy environment. Sensor accuracy will be measured with adaptive filtering and active noise cancellation turned on versus turned off.
The goal of this observational study is collect data to evaluate the efficacy of the RMS system in monitoring, recording, and presenting respiratory function data to the user in participants scheduled for pulmonary function testing (PFT). Participants will complete: * 60 episodes of data collection with a decreased tidal volume * 30 episodes of data collection with an increased tidal volume * 80 episodes with normal tidal volume breathing The TSS will continuously transmit sound data to an adjacent personal computer (PC) via Bluetooth Low-Energy (BLE). TSS trachea sound data will be recorded on the PC and then transmitted via a secure wireless network to an RTM cloud account that is HIPPA compliant. Reference breathing data will be simultaneously recorded using an FDA approved hospital ventilator (Hamilton Medical, HAMILTON-C1) with a calibrated pneumotach, capnometer, and a tight-fitting face mask. This system accurately measures and records a spontaneously breathing patient's RR, TV, MV, and end-tidal carbon dioxide concentration.
Many post-operative complications arise from patients who breathe inadequately. Inadequate respiration, whether the result of surgery or the anesthesia, causes a decrease in blood oxygen saturation and an increase in carbon dioxide partial pressure. Both of these surrogate measurements of respiration may pose a challenge to measure. Some administer exogenous oxygen to all patients as they leave the operating room in order to maintain the blood oxygen saturation. This renders the oximeter a less sensitive metric of depressed respiration. In the face of decreased respiration, the carbon dioxide levels continue to increase slowly and often go undetected unless blood gases are measured. Indeed carbon dioxide blood levels are the only metric to detect inadequate ventilation using this surrogate index. Monitoring ventilation is a serious challenge outside of critical care settings. In fact, there are no monitors available that can measure tidal volume or relative tidal volume outside of these settings. Linshom is a novel instrument that tracks relative respiration by measuring the excursions of the temperature swings between inspiration and expiration and normalizing them to the patient's breathing. This monitor may be the first non-invasive monitor to measure relative tidal volume in non-critical care settings. The purpose of this study is to determine whether a non-invasive, temperature-based respiratory instrument can track tidal volume (Vt) in patients. The investigators hypothesize that the Linshom device can accurately and consistently track tidal volume as measured by closed loop mechanical ventilator.
Respiratory depression occurs in labor and delivery; noticeably when neuraxial opioids are given.Pathophysiological respiratory depression -failure to respond to hypercapnia or hypoxia - is challenging to measure clinically.American Society of Anesthesiologist guidelines recommend suitable respiratory monitoring for 24 hours post cesarean delivery (CD). Use of capnograph will enable us to assess breath-by-breathe respiration in a population receiving neuraxial opioids - potentially at risk for respiratory depression. Our aim is to assess our ability to capture maternal postpartum respiratory parameters in a cohort following opioid neuraxial administration for CD.
This is an open-label, non-randomized, prospective, descriptive study of the Nellcor™ Bedside Respiratory Patient Monitoring System using the Nellcor™ Respiration Rate parameter and Nellcor™ Adult Respiratory Sensor The study is intended to gain further information in the clinical space on the function of the Nellcor™ Respiration Rate parameter. The primary objective is to describe spot check (e.g. manual observation) of respiration rate versus cumulative automated counting (trend) of respiratory rate as measured using the Nellcor™ Bedside Respiratory Patient Monitoring System with the Nellcor™ Respiration Rate parameter.
The investigator goal is to test a new device to see if it can provide continuous and simultaneous monitoring of heart and lung function.
Integrated pulmonary index (IPI) is a tool that monitors respiratory status. It takes into account four parameters: respiratory rate, end-tidal CO2, heart rate and O2 saturation using a pulse oximeter and specialized sidestream CO2 monitor. The device can continuously monitor and display the patient's ventilatory state as a single digit, 1-10. In addition, trends can be kept and it can provide early indication of changes in respiratory status. IPI has only been studied in pediatric patients who are under sedation; however, more uses for the monitoring tool are a possibility. One of those possibilities is to use IPI to monitor pediatric patients during the weaning and extubation process to determine if a specific number, or less than a specific number, is associated with extubation failure. Therefore, clinicians and physicians would be better able to determine if the patient is ready for extubation.
The EverOn™ system developed by EarlySense, Ltd., the sponsor of this study, is intended to assist hospitals to better address and improve recognition and response to changes in a patient's condition. The system, monitors the patient while in bed consists of a contact-free sensor that is placed under the bed mattress and identifies respiratory and heart rates, degree of patient's movement or agitation while in bed as well as patient's actual exit out of the bed. The EverOn system does not require a physical contact with the patient, eliminating the need for any direct contact electrodes, leads, cuffs or nasal cannulae.
This study will monitor physical bio-markers such as heart rate, respiratory rate, and temperature to detect potential respiratory infections.
The purpose of this study is to compare thermographic estimates of respiratory rate to manual counting (visual inspection) and thoracic impedance-based methods. Thermographic methods rely on detection of temperature changes in the nose and mouth that occur as room temperature air passes through the nose and mouth during ventilation, and may offer a non-invasive means of measuring respiratory rate without requiring any patient contact.
To validate the Respiration Rate Version 2.0 algorithm, housed in the Nellcor Bedside Respiratory Patient Monitoring System, for performance during motion conditions.
Use of an investigational oximetry system to evaluate the triggering of the "sensor off" status with the marketed off-the-shelf sensors.
This is a clinical performance testing to validate the accuracy of the Airvo 3 device with respiratory rate algorithm manufactured by Fisher \& Paykel Healthcare for continuous respiratory rate monitoring.
The aim of this research is to build systems that can recognize when people are stressed and then provide them with relaxation prompts in the moment to reduce their likelihood of being stressed, smoking, or overeating in the near future. Using these systems should help smokers be more effective in their attempts to quit by reducing their tendency to lapse when they are stressed or experiencing other negative moods or behaviors.
To compare two ways to test breathing after surgery in acute care setting. One method tests oxygen level of the blood, and one method will test oxygen and the carbon dioxide that is breathed out.
This study plans to learn more about specific breathing and activity recommendations for patients after surgery. Participants will be monitored after abdominal surgery to identify what activities help them breathe better and reduce complications after surgery.
Recently, interest in ways to monitor and care for patients remotely has significantly increased due to concerns for infection control as well as a way to increase access to regular clinic visits that may be limited for socioeconomic and geographic reasons. However, remote care can be limited by a lack of objective data to help guide clinical care. With respect to respiratory disease, caring for patients remotely may be enhanced by the ability of patients to monitor at home such things as vital signs, lung sounds, and lung function by spirometry. Enhanced methods to follow symptoms and track medication compliance may also be beneficial. These enhancements could improve care and quality of life both for persons with acute respiratory illnesses and those with chronic respiratory disease (such as asthma or COPD). The purpose of this study is to develop and study methods for patients to monitor their respiratory health at home and make that data available to medical providers to improve their care.
This study uses the AirGo band to monitor changes in tidal ventilation in spontaneously breathing patients with COVID-19 associated respiratory failure. It aims to recognize patterns of ventilation associated with worsening respiratory failure in this patient population. If successful, this study will lead to the development of new robust methods for real-time, continuous monitoring of respiratory function in patients with respiratory failure. In turn, such monitoring methods may enable improvements in the medical management of respiratory failure and timing of interventions.
This is a prospective observational study using a mobile study platform (app) that is designed for use on Android phones. Study participants will provide baseline demographic and medical information and report symptoms of respiratory infection on a weekly basis using the app. Participants will also report use of prevention techniques on the weekly survey. Mobility data will be collected passively using the sensors on the participant's smartphone, if the participant has granted the proper device permissions. The overall goals of the study are to track spread of coronavirus-like illness (CLI), influenza-like illness (ILI) and non-specific respiratory illness (NSRI) on a near-real time basis and identify specific behaviors associated with an increased or decreased risk of developing these conditions.
This study will test the accuracy of an investigational, non-invasive device for measuring heart rate and respiratory rate. The device emits radiowaves that allows it to pick up subtle changes in a person's chest wall, which allows it to calculate the heart rate and respiratory rate. We propose to study whether the device's measurements are accurate and reproducible in patients with chronic obstructive pulmonary disease (COPD) or asthma. The device undergoing study has been evaluated in healthy volunteers, but its accuracy in vital sign monitoring in patients with respiratory conditions has not yet been established. This study will serve as the foundation for additional work to assess the device's accuracy in measuring a patient's overall "work of breathing" or respiratory effort. Future work will examine the device's accuracy in measuring work of breathing in patients having an exacerbation of their underlying respiratory condition. The primary aim of this study will be to assess the validity of heart rate and respiratory rate measurements in patients with either COPD or asthma.
Currently, all patients in the hospital are woken up throughout the night to check for vital signs, no matter how sick they are. The investigators are doing this study to determine whether skipping routine vital sign checks at night improves participant sleep quality and satisfaction without increasing the risk of adverse events.
The primary objective of this study is to study in heart failure (HF) patients to better assess HF disease state, which can aid in management and improve outcomes. Primary aims of the study include: (1) Measure HR and RR at rest and during daily activity using the WHOOP device. (2) Correlate HR and RR response to activity to New York Heart Association (NYHA) class and 90-day HF hospitalization rate. (3) Identify additional predictors of NYHA class and HF hospitalization rate for algorithm development to use the WHOOP device as a clinical tool for HF management.
The objective of this project is to evaluate clinical significance of measuring maternal blood estriol levels, after the administration of antenatal corticosteroids to enhance lung maturity. The investigators will test for associations of the change in maternal estriol with the development of respiratory distress syndrome. The investigators are also interested in determining whether salivary estriol is a valid surrogate to estriol blood assays. In addition the investigators will correlate these changes to pharmacokinetic (PK), pharmacodynamics (PD), and pharmacogenetic measures of betamethasone administration and fetal respiratory outcome
Respiratory physiology involves a complex interplay of elements including control of breathing, respiratory drive, pulmonary mechanics, distribution of ventilation and gas exchange. Body position may also play an important role in respiratory mechanics. While effective methods exist for measuring these variables, they are typically measured in isolation rather than in combination. In pulmonary disease, decreasing mechanical stress and strain and optimizing transpulmonary pressure or the distending pressure across the lung, minimizing overdistention and collapse are central to clinical management. Obesity has a significant impact on pulmonary mechanics and is a risk factor for obstructive sleep apnea (OSA). However, our understanding of these elements is limited even in the general population. The investigators plan to use various validated methods to assess control of breathing, respiratory drive, distribution of ventilation and gas exchange to obtain a better understanding of underlying physiologic signatures in patients with and without obesity and the role of posture/position, with a secondary analysis comparing participants with and without obstructive sleep apnea.
Background: The COVID-19 outbreak has strained the health care system. New tools are needed for diagnostic testing and monitoring of people who have the virus. Researchers want to test a device they hope can screen, detect, and monitor symptoms linked to respiratory diseases like COVID-19. Objective: To evaluate and validate a device that measures breathing, body temperature, heart rate, and tissue oxygenation. Eligibility: Healthy adults ages 18 and older with no flu-like symptoms and no current signs of infection, cough, fever, or sneezing. Design: Participants will have a physical exam. Their vital signs will be taken. Participants will sit in a chair. They will be monitored for 60 to 80 minutes while they do the following tasks: Rest for 10 minutes. They will repeat this after each task. Hold their breath for up to 2 minutes and then rest for 2 minutes. They will do this task 3 times. Pace-breathe with breathing rates of 10, 20, and 30 breaths per minute. They will do this task 2 times. Breathe air that has 5% of carbon dioxide for 5 minutes. During these tasks, data will be collected and recorded with a pulse oximeter, thermometer, respiratory belt, and spirometer. Participants will fill out questionnaires related to their daily activity (medication intake, exercise, smoking, and drinking). Participation will last for 2 to 3 hours.
Individuals susceptible to SARS-CoV-2 and the illness it causes (COVID-19) are comprised of heterogeneous populations with a large risk spectrum for more severe disease. Pre-existing risk factors for a more severe course include respiratory and cardiovascular disease, morbid obesity, diabetes, underlying kidney or liver disease, and immunocompromised status. Whether children and young adults with inflammatory bowel disease (IBD) or juvenile idiopathic arthritis (JIA) receiving immunomodulating biologic and other therapies which are known to increase risk of viral infection are at increased risk of complications from COVID-19 or post-infectious co-morbidities, including the recently described multi inflammatory syndrome (MISC), is entirely unclear. This research focuses on the heretofore uncharacterized immune response to SARS-CoV-2 infection in children and young adults with IBD or JIA who are receiving maintenance immunosuppressive biologic therapies. Given the large Connecticut based infusion program, in a region of the United States with a recent large outbreak of COVID-19, the investigators have a unique opportunity to address a glaring knowledge gap in this unique pediatric, adolescent, and young adult population. The investigators will longitudinally determine antibody development and durability to SARS-CoV-2 in approximately 450-500 children and young adults with IBD or JIA receiving biologic therapy using a highly sensitive and specific quantitative assay utilizing novel technology. This period will include a return to school or work for many with likely resurgent infections, as well as the possible introduction of anti-SARS CoV-2 vaccines. The specific aim is to study the acute and convalescent antibody responses to SARS-CoV-2 infection in a cohort of children and young adults receiving infusions of biologic therapies for IBD and JIA.
Ventilator associated events (VAE) is a quality metric defined by 48 hours of stability followed by 48 hours of escalation of ventilator settings within the ICU. VAE have been associated with poor outcomes and increases the cost of care, yet is not easy to avoid. Operationalizing all the standards of care known to improve outcomes of those requiring mechanical ventilation in the critical care environment requires a comprehensive approach. ICU teams are encouraged to follow best practice protocols to help liberate and prevent VAEs. Yet, compliance with protocols in most ICUs is suboptimal for multiple reasons. With the advent of computerized mechanical ventilators capable of streaming data from breath to breath and biomedical integration systems (BMDI) such as Capsule (UTMB's BMDI system), software systems have been developed to help identify variances in the standard of care. Automation in near real-time ventilator data feedback has been shown to reduce the incidences of VAEs. This quality improvement project will leverage Vyaire's Respiratory Knowledge Portal (RKP) to collect and store meaningful data regarding ventilator-associated events (VAE), alarm policy compliance, ventilator weaning, and lung protective analytics. Goals: 1. To collect quality metrics utilizing RKP from patients requiring mechanical ventilation over a 3-4-month period for a retrospective baseline analysis. 2. Provide the RKP tool to the ICU team to determine if the use of RKP's webportal and Messenger Zebra phone app improves quality of mechanical ventilation and outcomes. 3. To determine a return on investment (ROI) for a software system like RKP.
Investigators will enroll 320 patients who will undergo non-cardiac surgery, receive supplemental oxygen via face mask, and will be on a continuous pulse oximetry monitor in the Post Anesthesia Care Unit (PACU). The enrollment criteria were adapted from a previous study that showed SpO2 values seriously underestimated the severity of post-operative hypoxemia in patients with and without specific risk factors for hypoxemia. Research personnel will screen and ensure that each subject meets the enrollment criteria, and the informed consent is properly executed. Upon arrival to the PACU, each subject will be fitted with oxygen mask containing the Linshom sensor, which will be connected to a Linshom monitor for data collection. A side stream capnography line will be connected to the same face mask and the capnography data will be collected on the Zoe Medical 740 SELECT™ monitor. Additionally, two pulse oximeters will be applied to the same hand (non- NIBP arm), one of which will be connected to a hospital monitor (SoC) and the other to a Zoe Medical 740 SELECT™ monitor. The Linshom and 740 SELECT™ monitors will collect data once every second. Research personnel will then initiate the Linshom CPRM baseline mode and begin recording any clinical intervention (e.g., medications, oxygen delivery change, and stimulation upon detection of changes in patient's condition) that is performed by the PACU staff, paying close attention to, and recording of time at which those interventions occurred. Data collection will be performed throughout the subject's entire PACU stay. The CPRM data collection will be performed passively while the patient is monitored via SoC and will not interfere with clinical interventions that may take place during the data collection. Clinical staff in the PACU will be blinded to the Linshom CPRM data as well as pulse oximetry (non-SOC monitor) and capnography data collected.
This goal of this study is to assess the suitability of the HealthBeacon Injection Care Management System (ICMS) as a Remote Therapeutic Monitoring (RTM) device for patients on injectable medications in the home-setting, for the management of respiratory disorders. The HealthBeacon ICMS is composed of the Smart Sharps Bin, Companion App and Care Team support. The Smart Sharps Bin a digitally connected sharps container and is pre-programmed with a patient's injection schedule. It creates a time-stamped record of each used injection deposited into it to calculate a patients' adherence to treatment. Following disposal, the next date of injection and rotating injection site is updated without requiring any extra work on behalf of the patient. The system also proactively supports enhanced compliance through a series of smart dose reminders and intervention calls, to help patients stay on track. Clinical teams can then review patient adherence data remotely via an online platform. The main aims of this study include the following: * To demonstrate the suitability of the HealthBeacon ICMS as an RTM device for respiratory patients through successful billing and reimbursement for physicians * To provide data to support the reimbursement of the HealthBeacon ICMS by Private Payors in the future Participants prescribed injectable medication for the treatment of a diagnosed respiratory condition will be enrolled by the Principal Investigator (PI) and referred to HealthBeacon. Participants will then be provided with access to the HealthBeacon ICMS to remotely track and support their adherence to treatment in the home-setting. Participants will use the system for 6 months and their adherence data during this time will be collected, which the PI and clinical team involved will be able to remotely access and review. At various stages of the study, the applicable RTM codes will be billed for, for each participant. These stages include when providing each participant with access to the HealthBeacon system, including the Smart Sharps Bin, when providing each participant with education on how to use the device, and when the clinical team monitors each individual patients' adherence data collected by the HealthBeacon system on a monthly basis.