View clinical trials related to Primary Graft Dysfunction.
Filter by:Proning manoeuvre as an early treatment for acute severe hypoxic respiratory failure has been implemented recently during the COVID-19 pandemic. This method was proposed more than fifty years ago to improve gas exchange : Proning Severe ARDS (PROSEVA) trial, however, was the milestone which demonstrated mortality benefit in patients with severe ARDS. Nevertheless, few analysis were performed on the effects of the prone position after lung transplantion (LT). The aim of the study is therefore to relate LT primary graft dysfunction (PGD) pathophysiology, which occurs in postoperative setting, to prone-positioning effects on ventilation-perfusion matching, improved lung compliance and clinical outcomes of impairedorgan patients.
The purpose of this study is to assess whether TNFa antibody use before lung transplant can prevent kidney injury after lung transplant.
Lung Transplantation (LuTX) is the curative treatment for selected patients with end-stage lung disease. Primary Graft Dysfunction (PGD), a specific form of respiratory failure occurring within the first 72 hours after graft reperfusion, represents the most common complication after LuTX. Actual recommendation regarding management of mechanical ventilation of the lung graft immediately after LuTX are based only on opinion experts and not on clinical trials. Optimization of Positive End-Expiratory Pressure might contribute to both prevention and treatment of PGD. In this interventional single-center non-pharmacological study (with medical device), in the immediate postoperative period of patients who are undergone LuTX, we will evaluate the effects of varying levels of PEEP upon: - lung and chest wall mechanics, - intrapulmonary shunt fraction; - distribution of ventilation and perfusion; - gas exchange. The final aim is to find the optimal level of PEEP in this patient's cohort
Lung transplantation (LTx) is the only effective treatment for patients with end stage lung disease. Of the major organs transplanted, survival following LTx is the lowest with a mean of 5 years. Despite improvements, primary graft dysfunction (PGD) remains the leading cause of early mortality and contributes to the development of chronic lung allograft dysfunction (CLAD) that remains the leading cause of late mortality. Earlier detection of rejection after LTx is of substantial importance as it would improve the possibilities of treatment and could increase survival. The investigators have shown in previous work that exhaled breath particles (EBP) reflect the composition of respiratory tract lining fluid (RTLF). EBP and particle flow rate (PFR) can be used as non-invasive methods for early detection and monitoring of airway diseases such as acute respiratory distress syndrome (ARDS). It has also been shown that the particle flow prolife after lung transplantation differs between patients who develop PGD and those who do not and that the composition of EBP differs between patients with and without bronchiolitis obliterans syndrome (BOS), an obstructive form of CLAD. Samples of EBP and measurements of PFR will be collected from lung transplanted patients. Membranes with EBP will be saved for molecular analysis. The investigators aim to identify potential particle flow patterns and biomarkers for earlier detection of rejection after lung transplantation.
Lung transplantation is the ultimate treatment for end stage lung diseases. Survival after lung transplantation is limited mainly due to the development of chronic allograft dysfunction (CLAD). Both acute cellular rejection and primary grade dysfunction (PGD) have been associated with the development of CLAD. In this study we will investigate multiple prognostic factors that influence long term survival after lung transplantation with a specific interest in PGD, acute rejection and the development of CLAD.
This study is being done to determine if parenterally administered ascorbic acid (Vitamin C) given at the time of lung transplant is safe. Vitamin C may be an effective intervention towards primary graft dysfunction (PGD). The study will enroll 69 participants who consent to the intervention. Participants who do not consent to the intervention will be treated according to standard-of-care, but may choose to be consented to have their data retrospectively reviewed. Based on our consent rate, this group may include 40-70 participants. Participants will be on study for up to 12 months.
Pulmonary transplantation is a very demanding surgical procedure, often accompanied by coagulopathy and severe perioperative bleeding. The most common complication that develops within the first 72 hours after surgery is primary graft dysfunction (PGD), up to 30% in the most severe form. The etiology of PGD is multifactorial. One of the causes may be the amount of perioperative blood loss. Intravascular volume is normally maintained by the administration of crystalloid and colloid solutions and fresh frozen plasma, which is also used to treat coagulopathy, however it is administered at the discretion of the anaesthetist and his experience, practically meaning ,,blindly". In the field of the allogeneous ischemic organ, these substitution solutions essentially become another allogeneous material and can cause undesired immunomodulation and contribute to the development of PGD. In our prospective randomized trial (120 patients), two patient groups will be investigated. In the first group, the coagulopathy and perioperative blood loss will be treated by the current standard approach, by ,,blind" administration of fresh frozen plasma, crystalloids and colloids. In the second group, the cause of coagulopathy will be diagnosed and treated according to the point-of-care (POC) results of ROTEM, PFA 200 and Multiplate. A colloidal solution of 5% albumin will be used to replace the circulating volume and maintain the oncotic pressure. Investigators assume that the POC management of coagulopathy and bleeding in the second group will lead to a reduction in perioperative bleeding, to reduced administration of infusion solutions, and thus to a reduction of the incidence of PGD.
The validity of several functional parameters, which could be included in a new PGD scoring system, will be tested in a prospective pilot study of 80 consecutive bilateral lung transplant recipients in high volume lung transplant centers. Functional parameters will be collected at different time points within the first 72hrs after lung transplantation and their accuracy in predicting clinical outcome as well as their correlation with lung water content (measured by PiCCO) will be tested. Insights will serve to generate a hypothesis (a novel PGD score), which can then be tested in future prospective trials.
Among the complications of heart transplant, primary dysfunction of the graft (PDG) is the most feared with a net impact on early morbidity and mortality. The all-cause mortality rate at the international level is 10% at 30 days and 34% at one year. Mortality at 30 days is secondary in 66% of cases with DPG or multi-organ failure. The treatment of choice for the more severe PDG remains ECMO-type circulatory mechanical assistance or ventricular assistance. According to several studies, this could reduce early mortality. Early placement and short-term (<30 days) of support appear to improve survival in the first year after transplantation. The haemodynamic parameters revealing this DPG are not clearly described in the literature. hypothesis of this research is that: - DPG risk factors in strasbourg's hospital center are comparable to other European and international centers. - Simple hemodynamic parameters can be used to detect PDG earlier in order to set up assistance more quickly.
PGD is a syndrome characterized by alveolocapillary barrier structural and functional alterations with surfactant inactivation and vascular permeability increase, which cause lung edema, parenchymal infiltrate and progressive hypoxemia. PGD may be enhanced in lung donor. Inflammatory and structural changes may be present in the lungs before organ recovery and/or after organ preservation. The investigators aim to identify the surfactant protein, inflammatory and structural changes in lung donor before and after cold ischemia, and biomarkers to PGD in lung recipients.