View clinical trials related to Respiratory Insufficiency.
Filter by:The investigators in this study are concerned about the harmful effects of oxygen exposure in newborn infants, particularly at high concentrations. Inhaled nitric oxide (iNO) is an FDA approved drug for the treatment of hypoxic respiratory failure (HRF) in term and late-preterm babies greater than 34 weeks gestation. Hypoxic respiratory failure occurs when a patient's lungs cannot get enough oxygen into their bloodstream. This condition is traditionally treated with high concentrations of oxygen and most often requires the patient be placed on a ventilator (breathing machine). The administration of inhaled nitric oxygen directly into the lungs often improves blood oxygen levels and allows caretakers to reduce the amount of oxygen given to the baby. The purpose of this research study is to evaluate if giving the inhaled nitric oxide earlier in the course of disease improves the effectiveness of the drug, reduces the amount of cellular injury from oxygen exposure, and decreases the total amount of time a patient requires supplemental oxygen. This study uses an FDA approved drug in a new manner.
The purpose of this study is to determine whether two modes of artificial (i.e. mechanical) ventilation have an impact on patient synchrony with the ventilator (breathing machine) and on the patient's work of breathing.
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.
Newborn infants with severe respiratory failure are treated with extracorporeal membrane oxygenation (ECMO), a modified form of cardiopulmonary bypass. These infants as at risk for brain injury as a result of hypoxia and blood flow changes in the brain prior to and during ECMO. The investigators propose a clinical trial of a novel treatment (cooling during ECMO) and novel diagnostic tool (advanced MRI techniques) that will lead to improved outcomes, early diagnosis and intervention for brain injury, decreased cost and duration of clinical trials, decrease in the burden of chronic neurologic disease and disability in society, thus improving the health and quality of life of these infants as they progress through childhood into adulthood.
Patients who are on mechanical ventilation in an intensive care unit often require diursis as part of their pre-extubation regimen. The drug of choice for diuresis has traditionally been furosemide. However, this drug cause hypernatremia (a rise in serum sodium) in a significant proportion of patients. Hypernatremia is traditionally treated by providing free water supplementation to the patient. This strategy creates a vicious and unproductive cycle of giving free water, and then diuresing it off. We propose a strategy for breaking this cycle by using a second diuretic-- metolazone-- which has a tendency to rid the body of more sodium, thereby minimizing hypernatremia.
Neurally adjusted ventilatory assist (NAVA) is a new concept of mechanical ventilation. NAVA delivers assistance to spontaneous breathing based on the detection of the electrical activity of the diaphragm. The investigators will study the effects of non-invasive NAVA on respiratory muscle unloading critically ill patients.
The aim of the study is to compare the efficacy and tolerance of autotitrating non-invasive ventilation (NIV) versus standard NIV in patients admitted to hospital with acute exacerbation of chronic respiratory failure. The investigators hypothesise that autotitrating NIV will ventilate patients with acute exacerbations of chronic respiratory failure as effectively as standard NIV.
Acute hypoxaemic respiratory failure (AHRF) refers to pathological states in which arterial blood oxygenation is severely impaired,and which need invasive positive pressure ventilation (IPPV) as respiratory support technique in most cases.However,IPPV carries well-known risks of complications such as ventilator induced lung injury (VILI) or ventilator associated pneumonia (VAP),and the incidence of which is increased as the prolongation of IPPV so as to lead to higher mortality rate. Consequently,early extubation is extraordinarily necessary. More recently, NPPV has shown to shorten the duration of IPPV,reduce the mortality and morbidity rates in patients with chronic obstructive pulmonary disease (COPD). Despite this evidence, the efficacy of NPPV in patients with AHRF has not been evidenced. However,NPPV has been shown to provide adequate ventilation and oxygenation,and reduce inspiratory muscle effort,neuromuscular drive,and dyspnea scores. Moreover,to some patints,NPPV is similar with IPPV in providing oxygenation. The duration of weaning is from the first day a patient met standard criteria for weaning readiness to the time of successful extubation (lasting at least 48 h),which represents 40-50% of the total duration of IPPV.As a result,duration of IPPV would be shortened if that of weaning was shortened. The investigators hypothesized that in mechanical ventilated patients with AHRF who met standard criteria for weaning readiness and suffer failure of spontaneous breathing trial, use of NPPV for early extubation, providing adequate ventilation and oxygenation, would shorten the duration of IPPV as the primary end-point variable, thereby reduce the incidence of complication and mortality rates. Accordingly, the investigators conducted a prospective,randomized clinical trial to assess the efficacy of this strategy compared with the conventional-weaning approach.
The primary objective of the proposed work is development of a high resolution pharmacokinetic-pharmacodynamic (PK-PD) model of hydromorphone for experimental pain stimuli, ventilatory depression, and surrogate biomarkers of opioid effect that will allow the fingerprinting of hydromorphone. This fingerprint will serve as the basis for the development of dosing strategies that efficiently maximize analgesia while minimizing ventilatory depression and sedation. For example, this high-resolution fingerprint will allow precise estimation of an initial hydromorphone target effect site concentration (Ce) from those of effectively administered synthetic opioids with previously determined high-resolution fingerprints (i.e., remifentanil or fentanyl), thereby minimizing underdosing of hydromorphone for analgesia and minimizing side effects.
The aim of this study is to see if the Vapotherm High Flow Therapy (HFT) device is effective to provide breathing support to patients with Chronic Obstructive Pulmonary Disease or COPD. The investigators believe that patients using HFT will not require as much use of therapies that provide pressure through a face mask, and are already recognized by FDA as support therapies for respiratory insufficiency.