View clinical trials related to Hypoventilation.
Filter by:Patients requiring the use of artificial ventilation (also called mechanical ventilation) for more than 21 days account for more than 37% of all ICU costs. As such, these patients are now transferred to centers that specialize in weaning patients from the respirator; these units are referred to as long-term acute care (LTAC) facilities. Despite the increase of LTAC facilities, research on the fastest method for disconnecting the patient from the respirator is lacking. In addition, little information is available regarding the long-term survival and quality of life after a prolonged course of artificial ventilation. The purpose of this study is to determine the fastest method for disconnecting the patient from the respirator at a LTAC facility and its effect on long-term survival and quality of life.
Procedures performed under sedation have the same severity in regards to morbidity and mortality as procedures performed under general anesthesia1. The demand for anesthesia care outside the operating room has increased tremendously and it poses, according to a closed claim analysis, major risks to patients . Both closed claim analysis identified respiratory depression due to oversedation as the main risk to patients undergoing procedures under sedation. The major problem is that hypoventilation is only detected at very late stages in patients receiving supplemental oxygen. Besides the respiratory effects of hypoventilation, hypercapnia can also lead to hypertension, tachycardia, cardiac arrhythmias and seizures. The incidence of anesthetized patients with obstructive sleep apnea has increased substantially over the last years along with the current national obesity epidemic. These patients are at increased risk of hypoventilation when exposed to anesthetic drugs. The context of the massive increase in procedural sedation and the extremely high prevalence of obstructive sleep apnea poses major respiratory risks to patients and it may, in a near future, increase malpractice claims to anesthesiologists. The development of safer anesthesia regimen for sedation are, therefore, needed. The establishment of safer anesthetics regimen for sedation is in direct relationship with the anesthesia patient safety foundation priorities. It addresses peri-anesthetic safety problems for healthy patient's. It can also be broadly applicable and easily implemented into daily clinical care. Ketamine has an established effect on analgesia but the effects of ketamine on ventilation have not been clearly defined. The lack of validated and sensitive instruments to evaluate the effects of ketamine on ventilation is an important reason for the conflicting results.The investigators have demonstrated that the transcutaneous carbon dioxide monitor is accurate in detecting hypoventilation in patients undergoing deep sedation. Animal data suggest that when added to propofol in a sedation regimen, ketamine decreased hypoventilation when compared to propofol alone. It is unknown if ketamine added to a commonly used sedative agent (propofol) can decrease the incidence and severity of hypoventilation in patients undergoing deep sedation. It is also unknown if the effect of ketamine on ventilation are different in patients with and without obstructive sleep apnea. The investigators hypothesized that patients receiving ketamine and propofol will develop less intraoperative hypoventilation than patients receiving propofol alone. The investigators also hypothesized that this effect will be even greater in patients with obstructive sleep apnea than patients without obstructive sleep apnea. Significance: Respiratory depression due to oversedation was identified twice as the major factor responsible for claims related to anesthesia. The high prevalence of obstructive sleep apnea combined with more complex procedures done in outpatient settings can increase physical risks to patients and liability cases to anesthesiologists. The main goal of this project is to establish the effect of ketamine in preventing respiratory depression to patients undergoing procedures under sedation. If the investigators confirm the their hypothesis , their findings can be valuable not only to anesthesiologist but also to other specialties ( Emergency medicine, gastroenterologists, cardiologists, radiologists) that frequently performed procedural sedation. The research questions is;does ketamine prevent hypoventilation during deep sedation? The hypotheses is; ketamine will prevent hypoventilation during sedation cases.
Background: Congenital Central Hypoventilation Syndrome (CCHS) is a rare disorder of automatic control of breathing. This disease can manifest as early as birth. Patients with this disease have a fundamental lack of central drive breathing. They do not mount any responses to hypoxia or hypercapnia during sleep or wakefulness. This places them at risk of injury or death whenever they are not consciously breathing. They require lifelong assisted ventilation while sleeping, and some while awake. Progesterone is a known respiratory stimulant in normal individuals, and it has been shown in one study of 2 patients that this drug may improve CO2 responsiveness in patients with CCHS. However, this observation requires confirmation. Hypothesis: Exogenous progesterone (in oral contraception pills) will improve CO2 responsivity by hyperoxic hypercapnic ventilatory response testing, hypoxic responsivity using 5-breath nitrogen breathing, hyperoxic ventilatory response while breathing 100% oxygen, and improve spontaneous ventilation during sleep in CCHS females >15-years of age. The progesterone will also depress ventilatory response using a hyperoxia test. Study Methodology: Baseline measures of CO2 and oxygen responsivity, and spontaneous ventilation during sleep, will be performed at baseline and after 3-weeks of taking a progesterone containing oral contraceptive agent. CO2 responsivity will be measured using a hyperoxic hypercapnic ventilatory response test. Hypoxic responsivity will be measured using a 5-breath 100% nitrogen breathing test. Hyperoxic responsivity will be measured by having subjects breathe 100% oxygen for 2-minutes. Subjects will perform an overnight polysomnogram to assess adequacy of gas exchange during spontaneous breathing while asleep. A progesterone containing oral contraception pill will then be given for 3-weeks, and the above measures repeated. Serum progesterone will be measured at baseline and at the time of study.
The purpose of this study is to analyze whether the treatment of metabolic alkalosis with acetazolamide in intubated patients with chronic obstructive pulmonary disease (COPD) or with obesity hypoventilation syndrome (OHS) reduces the length of mechanical ventilation (MV).
Obesity is an escalating problem in the UK and a proportion of these patients have a condition known as Obesity Hypoventilation Syndrome (OHS). This syndrome is associated with symptoms of breathlessness, reduction in exercise capacity, fatigue and headaches. Previous research has shown that patients with this condition tend to use healthcare services more frequently and are often at risk of other diseases such as diabetes mellitus and high blood pressure. Currently, the mainstay of treatment is noninvasive ventilation (NIV), this is a mask ventilator that patients use overnight to improve oxygen levels and remove carbon dioxide (the waste gas of breathing), however this does not fully treat the underlying problem. The research group has shown that NIV helps improve activity and contributes to weight loss in this group of patients. The aim of this research will be to investigate the effect of an exercise and nutrition programme in addition to NIV on weight loss and activity levels compared to NIV alone.
The investigators hypothesize that the addition of capnography during moderate sedation will improve recognition of hypoventilation and apnea. This will lead to an increased frequency of staff interventions such as verbal or physical stimulation for these events in order to improve ventilation which will in turn lead to a reduction in the frequency of oxygen desaturations. If capnography proves to be effective in creating earlier detection and intervention for hypoventilation and apnea during moderate sedation provided by non-anesthesiologists, this device can be used in a variety of clinical settings to enhance patient safety.
Weaning protocols that include the use of noninvasive ventilation (NIV), decreases the incidence of re-intubation and ICU length of stay. However, the role of NIV in post-extubation failure is still not clear. Impaired airway clearance is associated with NIV failure. Mechanical Insufflation-Exsufflation (MI-E) is an assisted coughing technique that has been proven to be very effective in patients under NIV. In this study the investigators assess the efficacy of MI-E as part of a protocol for patients that develop respiratory failure after extubation.
Primary objectives: evaluate the efficacy of noninvasive ventilation (NIV) treatment versus continuous positive airway pressure (CPAP) and life style modification treatment in Obesity Hypoventilation Syndrome (OHS), with PCO2 (first phase) and days of hospitalization (second phase) analyzed as a primary variables and percentage of dropouts for medical reasons and mortality as operative variables. As secondary variables: Measure functional and clinical improvement during sleep and wakefulness, quality of life, echocardiography and the incidence and blood pressure and evolution of cardiovascular events. Objectives secondaries:role of apneogenic sleep events on molecular inflammation, endothelial damage and the genesis of diurnal hypercapnia. Methods:prospective, randomized controlled trial. Patients with OHS will be divided initially into two groups based on their apnea-hypopnea index (AHI) score, >=30 and < 30, using conventional polysomnography. The AHI >=30 group will be randomized to CPAP, NIV or life style modification treatments. The AHI <=30 groups will be randomized to NIV or life style modification treatments. Treatment efficacy at the medium- and long-term will be analyzed by comparing groups. The role of apneic events and leptin in the genesis of daytime alveolar hypoventilation will be analyzed by comparing the daytime PCO2/AHI coefficient between responders and non-responders to CPAP treatment, and the evolution of leptin levels in the four branches of the study. The role of apneic events in metabolic and biochemical alterations and endothelial dysfunction will be analyzed by comparing basal and post-treatment levels of related substances between groups, with and without significant AHI.
Some overweight individuals develop problems with their breathing such that they gradually breathe less and less. This leads to a lack of oxygen and a buildup of carbon dioxide in the blood, called ventilatory failure. As a consequence, if such a person develops a chest infection, they are more likely to become seriously ill and need intensive care. In addition they are much more likely to develop severe complications during and following operations. This problem can be treated with a machine at home used overnight to help breathing. It is interesting that ventilatory failure only happens in some overweight individuals, and the investigators do not understand what factors make this complication develop. There are a number of theories: for example the distribution of the fat, additional lung disease (such as asthma), the addition of obstructive sleep apnoea, a condition when there are periods of cessation of breathing overnight (which is more common in obese individuals), weak muscles of breathing (perhaps due to fatty infiltration of muscles or vitamin D deficiency), and other hormonal changes. The investigators intend to measure many potential factors in a range of overweight individuals, some who have ventilatory failure, and some who do not, to try and work out which are the important factors that cause this problem. If the investigators can identify such factors, then this will help predict in advance who is at risk from chest infections and during operations; thus allowing for earlier provision of an overnight breathing machine. This should reduce complications and potentially deaths in such individuals.
Noninvasive ventilation (NIV) is a form of ventilation delivered by a mask and is an important mode of treatment in patients with both acute and chronic respiratory (breathing) failure. Humidification is widely accepted as an essential part of the ventilation strategy in patients receiving invasive ventilation (i.e. via a tube inserted into the mouth), but its role during NIV use is not proven. Consequently, there is a variation in practice with regard to humidification during NIV. Humidification is important in maintaining upper and lower airway mucosal function and patients requiring NIV often report symptoms, such as throat dryness, due to a lack of airway humidity. Success of NIV in the acute setting is dependent on many factors including, patient tolerance of NIV during the acute phase. In patients with chronic obstructive airways disease (COPD), poor tolerance results in NIV failure, which necessitates endotracheal intubation or treatment failure. Furthermore, invasive ventilation increases the risk of a hospital acquired pneumonia, which is associated with a worse outcome. In the long term setting of NIV use, again patients frequently report symptoms due to drying of the airways and adherence to NIV can be highly variable. Adherence in these patients is important in improving both quality and length of life. Humidification devices may be technically effective, but clinicians have concerns regarding potential negative effects of these devices. There is a requirement to evaluate the use of humidification in both the acute and long term use of NIV, particular, in terms of patient ventilator interaction, which will impact on comfort and adherence to NIV. This will effect the overall effectiveness of ventilation. The investigators propose a randomised controlled trial to investigate the effects of a humidification system during noninvasive ventilation.