Active clinical trials for "Pulmonary Atelectasis"

Laparoscopic surgeries require carbon-dioxide into the abdomen which may occasionally lead to atelectasis. The extent of this atelectasis is not well documented in peri-operative period although it has been extensively researched in critical care set up. In this study, it is aimed to observe the ultrasonographic condition of lungs in laparoscopic pediatric surgeries. The hypothesis was the Lung Ultrasound Scores would worsen in those surgeries by the end of the operation. Aged between 1-18 years pediatric patients who are scheduled for laparoscopic surgeries will be included in the study to observe the changes in the lung visuals throughout the operation. For that, after safe endotracheal intubation first ultrasonography will be performed for the first (T1) time, and the second ultrasonography will be performed once the surgery is finished and before extubation (T2). Lastly, the third evaluation will be performed after 30 minutes in post anesthesia care unit (T3). Lung Ultrasound Score (LUS) is calculated as follows: Both hemi-thoraxes are divided into 6 different zones, and depending on the number of B-lines, which happens due to aeration loss in lung tissue, every zone is scored. If there is no B-line, it is zero points. If the B-lines in the visual lower than 4, the area is scored as 1 point. The areas with B-lines more than 3 is scored as 2 points. Furthermore, if there is any disruption on the pleural face, then the area is scored as 3 points. Accordingly, the worst case scenario refers 36 points, meaning the less the points the better the lung aeration. Primary outcome is defined as T2 LUS which will show the actual condition of at the end of the surgery. For that, T1 scores and T2 scores will be compared. The secondary outcomes include T3 LUS, (T3-T1)LUS, intraoperative hemodynamics, length of stay in Post Anesthesia Care Unite, postoperative aldrete scores for discharging to ward, and intraoperative ventilation variables.

This study has been added as a sub study to the Simulation Training for Emergency Department Imaging 2 study (ClinicalTrials.gov ID NCT05427838). The Lunit INSIGHT CXR is a validation study that aims to assess the utility of an Artificial Intelligence-based (AI) chest X-ray (CXR) interpretation tool in assisting the diagnostic accuracy, speed, and confidence of a varied group of healthcare professionals. The study will be conducted using 500 retrospectively collected inpatient and emergency department CXRs from two United Kingdom (UK) hospital trusts. Two fellowship trained thoracic radiologists will independently review all studies to establish the ground truth reference standard. The Lunit INSIGHT CXR tool will be used to analyze each CXR, and its performance will be measured against the expert readers. The study will evaluate the utility of the algorithm in improving reader accuracy and confidence as measured by sensitivity, specificity, positive predictive value, and negative predictive value. The study will measure the performance of the algorithm against ten abnormal findings, including pulmonary nodules/mass, consolidation, pneumothorax, atelectasis, calcification, cardiomegaly, fibrosis, mediastinal widening, pleural effusion, and pneumoperitoneum. The study will involve readers from various clinical professional groups with and without the assistance of Lunit INSIGHT CXR. The study will provide evidence on the impact of AI algorithms in assisting healthcare professionals such as emergency medicine and general medicine physicians who regularly review images in their daily practice.

This study evaluates the influence of alveolar recruitment maneuver, protocolized liberation from respiratory support and monitoring of Integrated Pulmonary Index on the duration of the mechanical ventilation and the number of pulmonary complications in the early postoperative period after cardiac surgery.

Laparoscopy and robotic techniques are widespread procedures for pelvic gynecologic, urologic and abdominal surgery often performed in Trendelenburg position, with the application of pneumoperitoneum by inflating carbon dioxide. The rise in abdominal pressure following pneumoperitoneum and the head down body position have been shown to impair the respiratory function during the procedure, mainly inducing atelectasis formation in the dependent lung regions, worsening stress and strain of the alveolar structure. The application of a ventilator strategy providing positive end-expiratory pressure (PEEP) has been shown to reduce the diaphragm cranial shift, increasing functional residual capacity and decreasing respiratory system elastance. Furthermore, the application of recruiting maneuver followed by the subsequent application of PEEP improved oxygenation. These results are in accordance with finding by Talmor et al, evaluating the effect of a mechanical ventilation guided by esophageal pressure in acute lung injury patients. However a comparison between an esophageal pressure piloted mechanical ventilation and a conventional low tidal ventilator strategy with adjunct of PEEP and recruitment maneuvers according to clinical judgment has never been investigated in patients undergoing robotic gynecologic, abdominal or urologic surgery. The investigators aim to compare the conventional ventilation strategy (i.e. with application of PEEP and recruitment manoeuvre) with a ventilation driven by transpulmonary pressure assessed through an esophageal catheter, in patients undergoing to robotic surgery, with respect to oxygenation, expressed in terms of arterial oxygen tension - inspired oxygen fraction ratio (PaO2/FiO2) (primary endpoint), intraoperative respiratory mechanics indexes, number of lung recruitment maneuvers, rate and type of perioperative complications until hospital discharge (additional endpoint).

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.

Lung isolation technique and one-lung ventilation (OLV) are the mainstays of thoracic anesthesia. Two principal lung isolation techniques are mainly use by clinicians, the double lumen tubes (DLT) and the bronchial blockers (BB). The physiology of lung collapse during OLV is not well described in the literature. Few publications characterized scant aspects of lung collapse, only with the use of DLT and sometime in experimental animals. Two phases of lung collapse have been described. The first phase is a quick and partial secondary to the intrinsic recoil of the lung. The second phase is the reabsorption of gas contained in the alveoli by the capillary bed. The investigators plan to describe the physiology of the second phase of lung deflation using of DLT or BB, in a human clinical context.

Pulmonary atelectasis is a frequent respiratory postoperative complication in cardiac surgery. Classically, the treatment of these patients is based on manual chest physiotherapy. Our objective is to evaluate the interest of association of positive end expiratory delivery sessions with the EzPAP® device. We perform a prospective monocentric, open label trial. Patients with atelectasis after scheduled cardiac surgery with cardiopulmonary bypass are included. They benefit from manual chest therapy and are randomised to receive or not positive end expiratory pressure sessions twice a day. The primary endpoint is the effect of this treatment on atelectasis radiological score after 2 days of treatment. The secondary endpoints are: oxygen saturation(SpO2)/inspired oxygen(FiO2) ratio, qualitative evaluation of ventilatory function, respiratory & cardiac rate, pain, inspiratory pressure (sniff test), patient satisfaction, duration of intensive care unit (ICU) and hospital stay.

Lung isolation is frequently used during thoracic surgery. Two techniques are principally used: the double lumen tube (DLT) and the bronchial blocker (BB). BB is easy to use but its reputation is darken by the need of multiple repositioning during surgery and especially by a slower lung collapse than the DLT. Reading recent literature on the subject and according to the vast experience of numerous hospital centers, it seems that the slowness of lung collapse remains without any solution. This slowness in lung deflation is detrimental to the initiation of video-assisted thoracoscopy surgery (VATS) and could be exacerbated in chronic obstructive disease (COPD) patients. For this reason, BB use is discredited in numerous centers. However, at IUCPQ, the investigators rarely observe slow lung collapse when BB are used. For many years, the investigators have used a systematic denitrogenation of the lung before the initiation of one lung ventilation (OLV). Furthermore, when the patient is positioned in lateral decubitus, the investigators impose an apnea period of about 30 seconds to favor collapse of the isolated lung before inflating the cuff. This apnea is always limited by the occurrence of oxygen desaturation (≤97%). The investigators also proceed to a second period of apnea of 30 seconds associated to a deflated BB's cuff at the pleural opening. Subsequently, the investigators inflate the BB's cuff to obtain definitive lung isolation. The investigators hypothesis is that the use of two apnea periods, when isolating the lung with a BB, will allow the same quality of surgical exposure at 0, 5, 10 and 20 minutes post opening of the pleura, compared to the one obtained with a DLT. The main objective of this study is first to compare the delay between the initiation of OLV and complete lung collapse obtained with BB and DLT, in two groups of patients undergoing VATS. Secondary objectives are: 1) to evaluate the quality of surgical exposure associated to the level of lung collapse, 2) to evaluate the quality of surgical exposure through the video camera, 3) to collect surgeons' opinion regarding the device (BB or DLT) that they thought was used during surgery. After obtaining institutional review board (IRB) approval, the investigators propose a study of 40 patients undergoing an elective VATS at the Institut universitaire de cardiologie et pneumologie de Québec (IUCPQ) involving an one lung ventilation. They will have to be 18 years old or more, to read, understand and sign an informed consent at their pre-operative evaluation. This study will be prospective, randomized, and blind to thoracic surgeons.

Atelectasis and redistribution of ventilation towards non-dependent lung zones are a common side effects of general anesthesia. Spontaneous breathing activity (SBA) during mechanical ventilation may avoid or reduce atelectasis, improving arterial oxygenation; however, it is unclear whether these effects play a significant role during general anesthesia in patients with healthy lungs. Earlier studies on ventilation during general anesthesia had to rely on computed tomography (CT) findings. Recent advances in lung imaging technology allow to assess the regional aeration of the lungs continuously and non-invasive by electrical impedance technology (EIT). In this work, we will use the EIT to assess ventilation changes from the time before induction of anesthesia until discharge from the post-anesthesia care unit. Our main focus is the difference caused by pure positive pressure ventilation (PCV) and assisted spontaneous breathing (pressure support ventilation, PSV). Our findings would improve our understanding of the physiology of the lungs during general anesthesia and would help to improve the standards of respiratory care during anesthesia

Effects of the high frequent chest wall oscillation technique applied on the patients who were intubated in intensive care unit were investigated. A total of 30 patients who were intubated and under the mechanical ventilator supplied, were included in the study. While the control group (n=15) received routine pulmonary rehabilitation technique, the study group (n=15) was administered high frequency chest wall oscillation for 72 hours as 4 times of 15-minute intervals, in addition to the pulmonary rehabilitation technique. Patients 'APACHE-II scores, dry sputum weight, Lung Collapse Index and blood gas values were measured at the hours 24th, 48th and 72nd, and endotracheal aspirate culture was studied at initial and 72nd. In addition, patient outcomes were evaluated at the end of the first week.