94 Clinical Trials for Various Conditions
The purpose of this study is to compare oxygen saturation measurement readings from manufactured pulse oximetry devices to the oxygen saturation measurements of arterial blood samples drawn at the same time of measurements.
The overall purpose is to directly compare pulse rate (PR) acquisition and oxygen saturation performance between two pulse oximeters (PO) in newborns.
The objective of this study is to evaluate the performance of Masimo RD SET® SpO2 sensors in subjects with light and dark skin pigmentation in the intensive care therapeutic area.
The Lumerah System, developed and manufactured by Raydiant Oximetry, Inc., is a non-invasive fetal pulse oximeter that measures fetal arterial oxygen saturation using safe, non-invasive, transabdominal near-infrared spectroscopy. The Lumerah System is intended as an adjunct to cardiotocography. In this study, women in labor will also be simultaneously monitored with a re-engineered version of the previously approved transvaginal oximeter sensor connected to a Nellcor N-400 fetal oximetry monitor for the purposes of device development. The data obtained from the transabdominal sensor and the transvaginal sensor will be used for research purposes only and will not be used to guide or alter patient management.
This is a study of adult patients with a severe and sudden brain injury who have a drain placed in their brain to measure pressure. The purpose of the study is to monitor the pressure in the brain using a monitor placed on the forehead, and compare this to a drain placed in the brain.
Validate the performance of Philips FAST SpO2 with Masimo Pulse Oximetry Sensors in determining functional arterial oxygen saturation (SpO2) using arterial saturation (SaO2) as a reference in the range of 70-100% in subjects of varying skin pigmentation.
The goal of this clinical trial is to determine if pulse oximeters show an SaO2-SpO2 discrepancy that correlates with skin pigmentation such that pulse oximetry will overestimate oxygenation in newborns with darker skin. The main questions it aims to answer is if SaO2-SpO2 discrepancy varies with the degree of skin pigmentation among neonates, if gestational age has an influence on SaO2-SpO2 discrepancy, and if packed red blood cell (PRBC) transfusion has an influence on SaO2-SpO2 discrepancy in newborns with various degrees of light and dark skin. Researchers will compare SaO2 and SpO2 values in neonates of various skin pigmentation.
This is a prospective, non-randomized, non-blinded comparative study to evaluate the accuracy of pulse oximetry compared to co-oximetry in dark-skinned (Black) compared to lighter-skinned (White) children undergoing anesthesia, using standard FDA performance statistics as measured by mean bias and accuracy root mean squared to evaluate device performance.
This is a prospective study to evaluate the feasibility of obtaining a pulse oximetry ready from the oropharynx with a standard oximeter probe that has been attached to an oral airway or a tongue blade. The study will compare the values from the peripheral pulse oximeter on a finger, toe, foot or hand with the that from the oropharyngeal oximeter. The study will also compare the saturation from an arterial blood gas (ABG) collected as standard of care with that obtained from the oropharyngeal oximeter.
Finger pulse oximetry SpO2 is widely used to estimate arterial oxygen saturation SaO2. Current Spo2 targets do not take into consideration the many variables that affect that correlation in particular skin pigmentation. This study aims to evaluate different FDA approved pulse oximeters (Nonin co-pilot, massimo Radical 7, Philips-standard of care monitor, innovo premium iP900BP, nellcor PM1000N, Nano100) with SaO2 reference values obtained by an arterial blood gas in subjects with different skin pigments measured by a skin color scale as well as self-identification of race.
Validation study to compare the accuracy of non-invasive Philips SpO2 sensors in detecting blood oxygen levels compared to invasive methods requiring a blood draw and lab analysis.
In this prospective study, the investigators will enroll 154 children with arterial lines to determine the accuracy of pulse oximeters in children with darker skin pigmentation. Studies in adults suggest pulse oximeters may overestimate the true level of oxygenation in the blood as measured directly by co-oximetry. However, pediatric data are relatively limited. This study, which is funded by the FDA through the Stanford-UCSF (University of California San Francisco) Clinical Excellence in Regulatory Science and Innovation (CERSI) Program, will determine if the error/bias is associated with skin pigmentation and whether the error falls outside FDA standards. The broader purpose of the study is to work toward eliminating health disparities.
This is a prospective observational study designed to quantify and understand errors in pulse oximetry in hospitalized patients in relation to their skin pigmentation. It is driven by three recent retrospective studies showing missed diagnosis of hypoxemia in patients across a spectrum of skin pigmentation, defined as blood SaO2 \<90% when their pulse oximeter reads 92% or greater.
To validate the SpO2 accuracy, bias, and precision of Medline's reprocessed pulse oximetry sensors as compared to SaO2 in arterial blood samples as assessed by CO-oximetry in neonates.
The investigators' study aims to study how melanin index (mx) affects the deviation between SpO2 and SaO2, which becomes generally greater as hypoxia increases. The studies reviewed grouped individuals by race or have assigned individuals into groups like "dark", "intermediate", or "light" to describe pigmentation. Both of these methods are neither standardized nor objective, looking for race identifiers when it is more useful to be considering skin pigmentation identifiers. Skin pigmentation is a spectrum and it should be treated as such when trying to characterize relationships involving measurable factors such as melanin index. The investigators will similarly measure the deviation between SpO2 and SaO2 however novel in that the investigators will quantitatively measure skin pigmentation via a light reflectance measurement device by Photovault.
The Raydiant Oximetry Sensing System (Lumerah) is a non-invasive fetal pulse oximeter that measures fetal arterial oxygen saturation using safe, non-invasive, transabdominal near-infrared spectroscopy. Lumerah is intended as an adjunct to cardiotocography by detecting decreases in fetal oxygenation.
An Interventional Study is planned with the primary purpose of screening for changes in end-tidal carbon dioxide (ETCO2), inspired carbon dioxide (ICO2), and other vital signs that may develop after donning a disposable surgical mask. Measurements will be taken and recorded during a 5-minute control period without a mask, recording non-invasive ETCO2 and ICO2 levels by way of a nasal cannula (NC), oxygen saturation (SpO2), breaths per minute (RR), and heart rate (HR) via anesthesia equipment. This will be followed by a 15-minute intervention of wearing a disposable surgical mask and repeating measurements of ETCO2, ICO2, SpO2, RR, and HR, recorded each minute. Data will be collected from adults and children as young as 2 years of age. Age groups will include children aged 2-14 and adults aged 18 to 80, as described in the details of the research protocol. Parents and their children are invited to participate together.
The overall purpose of this study is to evaluate maternal-fetal tissue light scattering properties. The objectives of the study are: (i) integrate established mathematical principles of oxygen saturation to model with increasing accuracy the "body in a body" problem of fetus in mother; similar to existing pulse oximeters, the calculations will be integrated into software in the final commercial product; (ii) obtain human measurements against which both computational models and animal data can be compared.
This is a randomized, prospective study to determine if there is a difference in hospital length of stay between patients receiving continuous hardwire cardiorespiratory monitoring and those receiving intermittent vital signs measurements among pediatric patients admitted for uncomplicated respiratory illness.
The primary purpose of this observational study was to determine if pRBC transfusions decrease the frequency of intermittent hypoxia events in very low birth weight infants (VLBW) during the first six weeks of life. The impact on non-pRBC transfusions on the frequency of intermittent hypoxia was also assessed.
The primary objective is to measure the feasibility, acceptability, and appropriateness of audit and feedback with educational outreach as a strategy to align continuous pulse oximetry use in stable bronchiolitis patients with evidence and guideline recommendations.
This project is set up to advance and integrate the established mathematical principles of oxygen saturation to model with increasing accuracy the "body in a body" problem of fetus in mother; similar to existing pulse oximeters,
This study is being conducted to study light scattering properties of maternal-fetal tissue.
The non-invasive measurement of dysfunctional hemoglobins allows physicians to monitor levels in affected individuals without requiring blood samples or laboratory testing. Nonin Medical Inc, has recently developed a multi-wavelength device that measures carboxyhemoglobin and methemoglobin non-invasively. The primary objective of this study is to validate %MetHb and SpO2 accuracy performance of the study device. Evaluations will be for the range of 0 to 15% MetHb with 95-100% SaO2 as assessed by CO-oximetry, and 0-15% MetHb accuracy under conditions of elevated HHb (SaO2 80-100%) as assessed by CO-oximetry, and SpO2 with 80-100% SaO2 during elevated MetHb as assessed by CO-oximetry.
The primary aim of this research is to determine the accuracy of smartphone pulse oximeters in detecting blood oxygen saturations, episodes of desaturations, and heart rate by comparing results to a Masimo© hospital-grade pulse oximeter.
This research study will help the investigators to learn more about a device used when children are sick called a pulse oximeter. The pulse oximeter measures how much oxygen is inside a child's blood without taking blood from the child. It is non-invasive meaning it does not enter the body. The device has a cable attached to it. At the end of the cable is a wrap that looks like a Band-Aid with a red light on it. This wrap is placed around a finger or toe. The red light gives the investigators a reading of how much oxygen is in the child's blood and the child's heart rate. Having a pulse oximeter connected to a child is painless. This device is used in many places. Besides hospitals, it is used in doctors' offices and in fitness centers. This study will help the investigators learn more about whether a partially wireless, more portable pulse oximeter that connects to a small device worn on the child's arm or leg will give the investigators a more reliable signal/reading while letting children move more easily. The investigators will compare this device with the traditional wall-connected unit. Movement of the cable or a child moving may give a false oxygen reading. The investigators will ask the child to do activities that create movement and will look at the readings when the child moves. The investigators think the partially wireless pulse oximeter will be more reliable during movement than the traditional wall-connected unit. Subjects will have two continuous pulse oximeter probes placed on them. These soft probes will go on a finger, toe, foot or hand and will be attached to two different pulse oximeter monitors. The child will then be asked to do common childhood activities based on their age for about 20 minutes. These activities will be play activities the child already does such as grabbing a toy, drawing with crayons or kicking a ball. Continuous pulse oximetry data will be recorded during the testing and will be stored in a way that it cannot be linked to the subject after the testing is complete.
Assess ability of Masimo SpHb sensor to demonstrate robust performance on various sensor application sites on neonates/infants
The purpose of the study is to assess device performance in the presence of carbon monoxide.
This study will evaluate the effectiveness of an automated voice prompting system on post operative hypoxia within the Postoperative Anesthesia Care Unit (PACU). This will be done to detect an improvement of the patient experience and provider care through a decrease in the number of peripheral capillary oxygen saturation (SpO2) monitor alarms via the patients own ability to follow the instruction and improve their SpO2 levels.
The purpose of this study is to conduct a SpO2 hypoxia evaluation of the Oxitone Medical Oxitone 1000 pulse oximeter. The Oxitone 1000 pulse oximeter will be evaluated during non-motion conditions over the range of 70-100% SpO2 in comparison to a Reference Pulse Oximeter. The study is observational in nature which quantifies device performance and accuracy in compassion to a Reference Pulse Oximeter.