26 Clinical Trials for Various Conditions
The study aim is to determine whether electrical impedance tomography (EIT) is equivalent in the detection of pulmomary emboli compared to Computed Tomographic Angiography (CTA). EIT is a non-invasive, non-ionizing functional imaging technique that can be performed at bedside. Electrical impedance tomography data will be collected on individuals undergoing a CTA scan of the chest at Medical Center of the Rockies (MCR). The primary outcome measure is to assess whether assessment by CTA corresponds with EIT in detection of pulmonary emboli. The study will include up to 63 participants. EIT data will be collected for up to 20 minutes during tidal breathing and for approximately five to ten seconds during breath-holding.
The purpose of this study is to determine the ability of electrical impedance tomography (EIT) to identify structural and functional physiological changes that occur with disease progression in cystic fibrosis patients. The investigators also aim to determine whether EIT can serve as an alternative for CT to identify regions of air trapping and consolidation, whether EIT can provide clinically useful information about response to treatment for an acute PE, and whether EIT can provide longitudinal information about structural changes in the lung.
This is an unblinded pilot study to investigate the technical feasibility of using an electrical impedance tomography device for noninvasive pulmonary function monitoring in ALS patients. The study will enroll patients with ALS in one cohort and healthy volunteers in a second cohort that will both undergo EIT imaging with the investigational device prior to and while performing a standard PFT procedure.
Overview of study. This is an observational study that is intended to provide the first in-human data using EIT as a biomarker of muscle health in neuromuscular conditions. We will seek patients with neurological disorders (both neuromuscular and other neurological conditions) as well as healthy subjects for study. EIT measurements will be performed on appendicular muscles (in the upper and lower extremities) depending on the condition, both at rest and with contraction. EIT measurements will be repeated on an intermittent basis to assess repeatability as well disease progression or improvement over time.
To validate the benefits of recognizing asymmetric lung disease like atelectasis and pneumothorax in neonatal respiratory distress syndrome using electrical impedance tomography
The purpose of this study is to evaluate the Genesis Electrical Impedance Tomography (EIT) imaging system for use in pediatric respiratory disease populations including neuromuscular and bronchopulmonary dysplasia, as well as in age and height matched controls. The EIT does not use radiation, and is read through electrodes.
Doctors follow a standard ventilator management strategy when making adjustments to the breathing machine to optimize the amount of oxygen into the lungs. The purpose of this study is to assess whether the EIT (electrical impedance tomography) device can be an additional useful tool for ventilator management and identifying the ideal positive end-expiratory pressure (PEEP).
Lung units that participate in gas exchange are known as 'recruited' lung. Patients with lung injury suffer from a proportion of units that do not participate in gas exchange (i.e. the derecruited lung), which results in impaired gas exchange and induces an inflammatory cascade. The level of PEEP is often coupled to indices of oxygenation such as PaO2, PaO2 to FIO2 ratio, or oxygen index. Currently, two strategies are widely accepted and considered equivocal, one strategy using a lower PEEP level coupled to a certain oxygen requirement, the other using a higher PEEP level. The primary purpose of this study is to demonstrate the safety and efficacy of an electrical impedance tomography (EIT) PEEP titration protocol designed to recruit collapsed lung in children with ARDS and properly maintain lung volumes by setting an optimal PEEP level. A safety system has been developed using the ARDSnet FIO2/PEEP High (upper threshold limit) and Low (lower threshold limit) algorithm. Efficacy will be defined as an improvement in lung volume as assessed by electrical impedance tomography, lung compliance and by an improvement in markers of gas exchange. Safety will be defined as the incidence of barotrauma and hemodynamic consequences that occur during the protocol. Those results will be compared to incidences of barotrauma and hemodynamic compromise within the ARDS literature. Knowledge gained from this pilot will be instrumental in developing an EIT imagine guided protocol which will allow us to conduct future RCTs utilizing EIT technology
Respiratory disorders are the leading cause of respiratory failure in children. Thousands of children are admitted to a pediatric intensive care unit each year and placed on mechanical ventilators. Despite over 40 years since the first pediatric-specific ventilator was designed, there has been no specific cardiopulmonary directed therapy that has proven superior. While mechanical ventilation is generally lifesaving, it can be associated with adverse events. There is evidence building to suggest that adopting a lung protective ventilation strategy by the avoidance of lung over-distension and collapse reduces death. Therefore, timely discovery of these two lung conditions is extremely important in order to mitigate the effects associated with positive pressure mechanical ventilation. The investigators research team has extensive research experience with a non-invasive and radiation free medical device called electrical impendence tomography (EIT). EIT is intended to generate regional information of changes in ventilation. Meaning it can detect this collapse and overdistension. This additional source of information could help fine tune the mechanical ventilator. A baseline of understanding of how often this occurs in the patients the investigators serve is required. Therefore the investigators propose an EIT observation study in their pediatric ICU patient population.
Electrical impedance tomography (EIT) monitoring has been researched as a method to determine the spatial impedance distribution in a body cross section, but has yet to become an established clinical tool. EIT monitoring gives a dynamic, breath-to-breath measurement of both global and regional ventilation. Recently, there has been evidence that EIT monitoring has great potential to become a non-invasive bedside tool for assessment of regional lung ventilation without documented hazards. Potential applications include any adult patients in acute respiratory failure. Data collected from this research may contribute to improved patient safety outcomes. PURPOSE: The purpose of this pilot study is to examine the feasibility of using the EIT monitor in intensive care unit (ICU) setting on patients with acute respiratory failure and to compare the EIT monitor data to standard of care patient assessments. It is hypothesized that the EIT monitor, when applied to adults in acute respiratory failure, will correlate with conventional standard of care assessments for these patients.
Aim of this study is to better understand pathophysiology of the alteration of respiratory mechanics and cardiovascular function in obese volunteer subjects. The investigators plan to test this hypothesis with a physiological, interventional study conducted on volunteers by using Electrical Impedance Tomography in a group of patients and magnetic resonance imaging (MRI) in another group.
The goal of this clinical trial is to perform a PEEP titration protocol and use EIT to identify the optimal PEEP at which lung overdistention and collapse are most effectively balanced. The primary and secondary aims of the study are as follows: Identify the difference between the optimal PEEP recommended by EIT metrics and the current guideline recommended approach to identifying optimal PEEP in PARDS. There will be a statistically significant difference in the recommended optimal PEEP identified using the EIT PEEP titration tool and that of the PEEP/FiO2 grid recommendations. Determine the difference in physiologic metrics between EIT optimal PEEP and the PEEP/FiO2 recommended PEEP. Participants will undergoing EIT monitoring while being subjected to PEEP titration protocol.
Electrical Impedance Tomography (EIT) is a non-invasive imaging technique that can measure lung function in real time. This study will follow premature infants to see if EIT can help predict which infants will be successful in weaning off respiratory support by 32-33 weeks gestational age. If successful, EIT could be used to develop new guidelines for respiratory support in premature infants.
Patients undergoing general anesthesia require mechanical ventilation (artificial delivery of air and oxygen to their lungs). It is well known that during mechanical ventilation, so-called atelectasis formation occurs. This is a condition characterized by partial or complete collapse of lung tissue that can result in a reduction in oxygen uptake through the lung. A known risk factor for atelectasis formation during mechanical ventilation is the utilization of high oxygen concentration, as the oxygen molecules are absorbed in the lung, which then can lead to collapse of the tissue. Despite the proven association, standard operating procedure at the end of anesthesia still requires utilization of 100% oxygen. Its justification is the goal to ensure sufficient oxygenation throughout the extubation phase. However, clinical observation doesn't show a lack of oxygenation in this phase, but the patient is still exposed to the risk of atelectasis formation. This study aims to investigate the hypothesis of whether the utilization of reduced inspiratory oxygen concentration before extubation (70% or 40% compared to 100%) reduces atelectasis formation. The study was originally planned to randomize 24 patients to either 70% or 100% inspiratory oxygen concentration at the end of anaesthesia. After completion of this first phase, the study was amended to enroll another 24 patients randomized to 40% or 100% inspiratory oxygen concentration at the end of anaesthesia. Of note, both concentrations are still higher than when breathing room air in, which has of 21% oxygen. During the intervention, parameters such as the oxygen content in the blood (oxygen saturation, SpO₂), heart rate, and blood pressure are recorded, and atelectasis formation is measured using a technique called electrical impedance tomography (EIT). EIT measurements are performed at designated time points during the procedure. Anesthesia care providers are asked to document procedural, patient, and ventilator data in a questionnaire. Secondary outcomes are the homogeneity and distribution of air measured with EIT, as well as some clinical outcomes including post-extubation desaturation (\<90% SpO₂), incidence of re-intubation or non-invasive ventilation, and the Post-anesthesia Care Unit (PACU) length of stay.
Premature infants commonly have desaturation episodes due to different reasons such as cessation of breathing or loss of lung volume. The purpose of this study is to differentiate the mechanisms of desaturation episodes with continuous lung volume monitoring. As we better understand the mechanisms underlying the desaturation episodes, newer strategies directed at underlying pathophysiology can potentially by evaluated for mitigation of these episodes.
The purpose of this study is to determine whether the Enlight 2100 electrical impedance tomography (EIT) belt can optimize positive end-expiratory pressure (PEEP) during surgery better than standard anesthesia machines.
Acute respiratory distress syndrome (ARDS) is when a person's lungs become inflamed, which can be caused by infection, trauma, surgery, blood transfusion, or burn. ARDS often leads to a situation where the person cannot breathe independently and needs machines' help. Once the lungs are inflamed, the small air sacs responsible for exchanging gases (i.e., ventilation) and the blood flow in the lungs (i.e., perfusion) can be affected. In the past, most research focused on studying ventilation physiology and how to help people breathe with machines. Less was done on perfusion because it requires imaging techniques such as computed tomography with intravenous contrast and radiation. One treatment option for low oxygen levels is inhaled nitric oxide (iNO), a gas that can dilate the lung blood vessels and improve oxygenation; however, it is not always clear whether this treatment will work. Electrical Impedance Tomography (EIT) is a bedside and accessible imaging technique that is radiation-free and non-invasive and can potentially detect changes in lung perfusion. EIT can perform multiple measurements; it is portable and accessible. This prospective interventional study aims to assess changes in regional blood perfusion in the lungs of patients with ARDS in response to iNO utilizing EIT. The main questions it aims to answer are: 1. If EIT can measure lung regional perfusion response to an iNO challenge of 20ppm for 15 minutes. 2. If EIT is comparable to dual-energy computed tomography (DECT), the gold-standard method to detect changes in regional lung perfusion. 3. If EIT can be an imaging marker to identify ARDS severity Participants will be divided into two cohorts: 1. Cohort 1 (n=60): Participants will be asked to be monitored by EIT before, during, and after the administration of iNO (20 ppm) for 15 minutes (OFF-ON-OFF) 2. Cohort 2 (N=10): Participants will be asked to be monitored by EIT and DECT before and during the administration of iNO (20 ppm) for 15 minutes (OFF-ON).
The primary objective of this study is to demonstrate a significant difference in electrical impedance between normal, benign, premalignant, and malignant oral lesions using a custom device. The secondary study objective is to create a database of in vivo electrical impedance spectra and images of oral lesions. This will be achieved by collecting Electrical Impedance sensing data and images from two cohorts of patients: Cohort I will consist of 200 patients undergoing oral lesion biopsies and Cohort II will be comprised of 50 patients scheduled for oral cancer resection. A maximum of 5 additional subjects will be initially enrolled in each Cohort to optimize data acquisition.
This study is Phase 3 of a three-phase DOD CDMRP funded project for the development of a multi-technology poly-anatomic noninvasive system for early detection of occult hemorrhage. Early detection of ongoing hemorrhage (OH) before onset of shock is a universally acknowledged great unmet need, and particularly important after trauma. Delays in the detection of OH are associated with a "failure to rescue" and a dramatic deterioration in prognosis once the onset of clinically frank shock has occurred. An early alert to the presence of OH with an acceptable rate of false-positives and false-negatives would save countless lives. Additionally, such technology would save significant time, money and effort by allowing medical resources to be applied more accurately - the essence of precision medicine. An automated system would monitor currently stable patients continuously, leaving clinicians free to care for patients in need of attention.
Early detection of ongoing hemorrhage (OH) before onset of hemorrhagic shock is a universally acknowledged great unmet need, and particularly important after traumatic injury. Delays in the detection of OH are associated with a "failure to rescue" and a dramatic deterioration in prognosis once the onset of clinically frank shock has occurred. An early alert to the presence of OH would save countless lives. This is a single site study, enrolling 48 patients undergoing liver resection in a "no significant risk" prospective clinical trial to: 1) further identify a minimal subset of noninvasive measurement technologies necessary for the desired diagnostic performance, 2) validate the performance of our Phase I algorithm, and 3) re-train the algorithm to a Phase II human iteration. The main outcome variables are non-invasive measurements that will be used for machine learning, not real-time patient management. The data generated will be used later for discovery and validation in traditional and innovative machine learning.
The investigators will assess the feasibility and validity of esophageal pressure measurements during one-lung ventilation in the lateral position for surgery by comparing to lung collapse estimated from electrical impedance tomography during a PEEP trial.
The purpose of the study is to use a new method of high-density electroencephalogram (HD-EEG) recording to map brain areas important for movement, sensation, language, emotion, and cognition.
The primary purpose of this study is to determine if there is a significant difference in regional distribution of ventilation when comparing eupneic tidal ventilation with Incentive Spirometry (I.S.) and EzPAP® lung expansion therapy in healthy adult human subjects. Electrical impedance tomography (EIT) will be used to measure regional distribution of ventilation during resting tidal ventilation and during lung expansion therapy.
The purpose of this study is to better understand how air is spread throughout study participants' lungs after abdominal surgery by comparing two lung inflation treatments: 1. Incentive Spirometry (I.S.) lung expansion therapy 2. EzPAP® lung expansion therapy. Lung expansion therapy is routinely used after upper abdominal surgery. Taking deep breaths after surgery helps lungs to stay inflated. At the University of Virginia, it is at the physician's discretion as to which treatment will be used to help with deep breathing lung inflation therapy after surgery. The investigators would like to know which of the lung inflation therapies is better at helping inflate participants' lungs. The investigators will be using a device called Electrical Impedance Tomography (EIT) to measure how effectively air spreads in participants' lungs. This device is not currently approved by the Food and Drug Administration (FDA) for the purpose used in this study, and therefore, it is considered investigational. Investigators are inviting eligible participants to consider participating in this study because doctors order Incentive Spirometry as a standard of care following upper abdominal surgery. Information gained from monitoring how air is spread throughout participants' lungs will help investigators to determine if there is a clinical difference and benefit when comparing Incentive Spirometry and EzPAP lung expansion therapies.
The purpose of this research study is to measure current flow inside the head using magnetic resonance imaging (MRI). The data from this study will be used to map the current flow caused from the electrical stimulation inside the head. The methods develop will be used to map and better control delivery of the current for electrical stimulation to modify a psychiatric condition such as depression; or other conditions such as epilepsy, Parkinson's disease or autism.
The goal of this study is to evaluate the sensitivity and specificity of Electrical Impedance Tomography (EIT) as a bedside diagnostic tool for lung pathologies in patients who are mechanically ventilated. In electrical impedance tomography low amplitude, low frequency current is applied on electrodes, and the resulting voltage is measured and used to computed the electrical properties of the interior of the chest as they change in time. The computed properties are used to form an image, which can then be used for monitoring and diagnosis.