12 Clinical Trials for Various Conditions
This is a prospective observational study of patients with suspected Acute Compartment Syndrome. The primary objective of this work is to determine whether intensity changes associated with the NIRST signal, reflecting oxy- and deoxy-hemaglobin and water concentrations or ICG fluorescence signal, reflecting tissue perfusion, can be associated with development of Acute Compartment Syndrome and identification of at-risk soft tissue and muscle.
The purpose of this trial is to conduct a pilot study that will aid in the design of an evaluation of the clinical benefit of MY01, an FDA cleared device, that allows continuous monitoring of intracompartmental muscle pressure in patients at risk for developing acute compartment syndrome. MY01 has previously been successfully tested on animal and Human cadaver Acute Compartment Syndrome models within the RI MUHC through Department of Defense research Grant (Combat Casualty Care Research Program (CCCRP). This trial is supported by the same grant, as the next phase of the overall project. This is a multi-center, non-randomized, historically controlled, prospective trial of the MY01 device. A cohort of 50 participants will be prospectively enrolled with two weeks follow up to document clinical benefit of the device. Results from this study will be used to inform the design of a larger study designed to demonstrate the clinical benefit of the MY01 device in the early diagnosis of ACS. The role of each organisation within the trial are detailed below: * Research Institute of McGill University Health Centre (RI MUHC): study coordination and data analysis (no recruitment activity will take place in the MUHC). * Hennepin Healthcare: participants recruitment * Vanderbilt University Medical Centre: participants recruitment
The long-term objective is to develop a tool to aid in making a timely and accurate diagnosis of acute compartment syndrome (ACS). The immediate objective is to develop a model to accurately predict the likelihood of ACS based on data available to the clinician within the first 48 hours of injury (specific clinical findings supplemented by muscle oxygenation measured by near-infrared spectroscopy (NIRS), and continuous intramuscular pressure (IMP) and perfusion pressure (PP) monitoring). Our primary outcome is the retrospective assessment of the likelihood of compartment syndrome made by a panel of clinicians using the following data: * A physiologic "fingerprint" composed of continuous pressure versus time curve, continuous oximetry values, response of muscle to fasciotomy when performed, and serum biomarkers of muscle injury (CPK levels). * Clinical and functional outcomes at 6 months post-injury including: sensory exam, muscle function, presence/absence of myoneural deficit, and patient reported function using the Short Musculoskeletal Function Assessment (SMFA).
This is a study intended to evaluate a new device that uses light to measure the amount of oxygen in the muscles of injured and non-injured legs and forearms in specific situations. The name of this technology is NIRS (near-infrared spectroscopy). This is a prospective observational cohort study intended to gather data using NIRS among injured and noninjured extremities over time. Additionally, this data will help in establishing diagnostic perfusion value thresholds to be used in a subsequent interventional study confirming the efficacy of NIRS-based ACS monitoring.
This is a prospective observational study to determine the reliability and accuracy of Near Infrared Spectroscopy (NIRS) to detect oxygen flow in the extremities of injured and non-injured soldiers over time. This technology may be useful in the detection of acute compartment syndrome. We hypothesize that: * NIRS values will be well-correlated with intracompartmental pressure measurements * NIRS values will be significantly different between non-injured and injured extremities, and injured extremities treated with fasciotomy for acute compartment syndrome. * NIRS values of the upper extremity and feet will correlate to values from normal legs in critical control patients and patients with unilateral sever lower extremity injuries.
The purpose of this study is to define the reliability and accuracy of Near Infrared Spectroscopy (NIRS) in the detection of intra-compartmental tissue perfusion in injured and noninjured extremities over time. We hypothesize that this technology, combined with vital signs, intracompartmental pressures and clinical examinations, will be useful in diagnosing acute compartment syndrome (ACS), monitoring patients at risk for ACS, and evaluating the adequacy of fasciotomy in patients treated for ACS.
Acute compartment syndrome (ACS) is a complication of lower leg trauma that occurs when the pressure inside the leg due to swelling exceeds the body's ability to provide blood to the muscle of the leg. This condition cuts off blood flow to the leg. Left untreated, the condition can result in devastating consequences including complete loss of function of the lower extremity or amputation. Near-infrared spectroscopy (NIRS)-based tissue perfusion monitors are a non-invasive means of continuously monitoring the amount of oxygen in the tissues of an injured extremity. The device utilizes harmless red light to detect the proportion of hemoglobin saturated with oxygen up to 3 cm below the skin surface. The purpose of this study will be to launch the first stages of validation of this device as a diagnostic tool for compartment syndrome, by observing this device in uninjured subjects.
Near infrared spectroscopy (NIRS) provides a non-invasive means of continuously monitoring tissue oxygenation, which may be useful for diagnosis of acute compartment syndrome (ACS). Placement of these sensor pads on the surface of the skin must be such that light penetrates the intended compartment without inadvertently obtaining measurements of an adjacent compartment. The objective of this study is to examine whether the NIRS measurements of each compartment truly represent the tissue perfusion of the intended compartment, as indicated by the predictable decrease in muscle oxygenation of a given compartment in response to muscle fatigue. The investigators hypothesize that the tissue oxygenation values of the stimulated compartment will significantly decrease following muscle stimulation, indicating that the intended muscle compartment was successfully isolated. Additionally, the investigators hypothesize that NIRS values of unstimulated muscle compartments will not change from baseline.
The purpose of this study is to evaluate both genotypic differences and differences in local gene expression in individuals who develop acute traumatic compartment syndrome relative to control patients with at-risk lower extremity fractures who do not develop compartment syndrome.
The Accuryn Registry Study is an open-ended, global, multi-center, retrospective and prospective, single-arm data collection study with an FDA cleared device. The target population are cardiovascular surgery patients. Physiologic data measurements will be collected from enrolled subjects using electronic medical records and data streams via the Accuryn Monitoring System.
The Accuryn Registry Study is an open-ended, global, multi-center, retrospective and prospective, single-arm data collection study with an FDA cleared device. The target population are cardiovascular surgery patients. Physiologic data measurements will be collected from enrolled subjects using electronic medical records and data streams via the Accuryn Monitoring System.
The CAPSS Study is a retrospective and prospective, multi-center, single-arm post-market data collection study with an FDA cleared device. Physiologic data measurements will be collected from enrolled subjects using electronic health records and data streams via the Accuryn Monitoring System. Analysis of these data has the potential to be able to acutely guide resuscitation and monitor trends for emerging critical conditions.