Adequate Gas Exchange Research Articles

Pulmonary function in aging

Aging generates four important changes in the structure and function of the respiratory system. There is a reduction in the elastic recoil of the lung causing "senile emphysema", a condition characterized by reduction in the alveolar surface area without alveolar destruction, which is associated with hyperinflation, increased lung compliance and reduction in alveolar-capillary diffusing capacity. There is a decrease in the compliance of the chest watt, due to calcification of its articulations, dorsal kyphosis and "barrel chest". There is a decrease in the strength of respiratory muscles which correlates with cardiac Index, nutritional status and hyperinflation, and there is a reduction in the ventilatory response to hypoxia and hypercapnia as well as in the perception of increased airway resistance. The increased static lung compliance combined with the decreased chest watt compliance leads to an increase in the functional residual capacity with aging. On the other hand, the loss of alveolar and airways elastic recoil combined with the reduction in the strength of the expiratory muscles, leads to an increase in residual volume and decreased maximal expiratory airflow rates and vital capacity. Despite these changes, the respiratory system maintains an adequate gas exchange at rest and during exercise during the whole life span, showing a normal PaCO2 and a slight decline in PaO2 (-0,3 mmHg per year) which is attenuated to become almost undetectable over the age of 70.

Función respiratoria en la senectud

Aging generates four important changes in the structure and function of the respiratory system. There is a reduction in the elastic recoil of the lung causing "senile emphysema", a condition characterized by reduction in the alveolar surface area without alveolar destruction, which is associated with hyperinflation, increased lung compliance and reduction in alveolar-capillary diffusing capacity. There is a decrease in the compliance of the chest watt, due to calcification of its articulations, dorsal kyphosis and "barrel chest". There is a decrease in the strength of respiratory muscles which correlates with cardiac Index, nutritional status and hyperinflation, and there is a reduction in the ventilatory response to hypoxia and hypercapnia as well as in the perception of increased airway resistance. The increased static lung compliance combined with the decreased chest watt compliance leads to an increase in the functional residual capacity with aging. On the other hand, the loss of alveolar and airways elastic recoil combined with the reduction in the strength of the expiratory muscles, leads to an increase in residual volume and decreased maximal expiratory airflow rates and vital capacity. Despite these changes, the respiratory system maintains an adequate gas exchange at rest and during exercise during the whole life span, showing a normal PaCO2 and a slight decline in PaO2 (-0,3 mmHg per year) which is attenuated to become almost undetectable over the age of 70.

Adaptive support ventilation for gynaecological laparoscopic surgery in Trendelenburg position: bringing ICU modes of mechanical ventilation to the operating room

The aim of the present study was to test the efficacy of adaptive support ventilation (ASV) to automatically adapt the ventilatory settings to the changes in the respiratory mechanics that occur during pneumoperitoneum and Trendelenburg position in gynaecological surgeries. We prospectively studied 22 ASA I women scheduled for gynaecological laparoscopic surgery in the Trendelenburg position. After intravenous induction of general anaesthesia, patients were ventilated with ASV, a closed-loop mode of mechanical ventilation based on the Otis formula, designed to automatically adapt the ventilatory settings to changes in the patient's respiratory system mechanics, while maintaining preset minute ventilation. Respiratory mechanics variables, ventilatory setting parameters and analysis of blood gases were recorded at three time points: 5 min after induction (baseline), 15 min after pneumoperitoneum and Trendelenburg positioning (Pneumo-Trend) and 15 min after pneumoperitoneum withdrawal (final). A reduction of 44.4% in respiratory compliance and an increase of 29.1% in airway resistance were observed during the Pneumo-Trend period. Despite these changes in respiratory mechanics, minute ventilation was kept constant. ASV adapted the ventilatory settings by automatically increasing inspiratory pressure by 3.2 +/- 0.9 cmH(2)O (+19%), P < 0.01, respiratory rate by 1.3 +/- 0.5 breaths per minute (+9%) and the inspiratory to total time ratio (T(i)/T(tot)) by 43.3%. At final time, these parameters returned towards their baseline values. Adequate gas exchange was maintained throughout all periods. PaCO(2) increased moderately (+13%) from 4.4 +/- 0.6 (baseline) to 5.0 +/- 0.9 kPa (Pneumo-Trend), P < 0.01; and decreased slightly at final time (4.7 +/- 0.8 kPa), P < 0.05. Clinician's intervention was needed in only one patient who showed a moderate hypercapnia (PaCO(2) 6.9 kPa) during pneumoperitoneum. In healthy women undergoing gynaecologic laparoscopy, ASV automatically adapted the ventilatory settings to the changes in the respiratory mechanics, keeping constant the preset minute ventilation, providing an adequate exchange of respiratory gases and obviating clinician's interventions.

Short-term outcomes of cadaveric lung transplantation in ventilator-dependent patients

IntroductionSurvival after cadaveric lung transplantation (LTx) in respiratory failure recipients who were already dependent on ventilation support prior to transplantation is poor, with a relatively high rate of surgical mortality and morbidity. In this study, we sought to describe the short-term outcomes of bilateral sequential LTx (BSLTx) under extracorporeal membrane oxygenation (ECMO) support in a consecutive series of preoperative respiratory failure patients.MethodsBetween July 2006 and July 2008, we performed BSLTx under venoarterious (VA) ECMO support in 10 respiratory failure patients with various lung diseases. Prior to transplantation, 6 patients depended on invasive mechanical ventilation support and the others (40%) needed noninvasive positive pressure ventilation to maintain adequate gas exchange. Their mean age was 40.9 years and the mean observation period was 16.4 months.ResultsExcept for 1 ECMO circuit that had been set up in the intensive care unit for pulmonary crisis 5 days prior to transplantation, most ECMO (90%) circuits were set up in the operating theater prior to pneumonectomy of native lung during transplantation. Patients were successfully weaned off ECMO circuits immediately after transplantation in 8 cases, and within 1 day (1/10 patients) and after 9 days (1/10 patients) due to severe reperfusion lung edema following transplantation. The mean duration of ECMO support in those successfully weaned off in the operating theater (n = 8) was 7.8 hours. The average duration of intensive care unit stay (n = 10) was 43.1 days (range, 35 to 162 days) and hospital stay (n = 10) was 70 days (range, 20 to 86 days). Although 4 patients (40%) had different degrees of complicated postoperative courses unrelated to ECMO, all patients were discharged home postoperatively. The mean forced vital capacity and the forced expiratory volume in 1 second both increased significantly postoperatively. The cumulative survival rates at 3 months and at 12 months post-transplantation were 100% and 90%.ConclusionsAlthough BSLTx in this critical population has varied surgical complications and prolonged length of postoperative ICU and hospital stays, all the patients observed in this study could tolerate the transplant procedures under VA ECMO support with promising pulmonary function and satisfactory short-term outcome.

Prediction of Intubation after Bronchoscopy with Non-invasive Positive Pressure Ventilation Support in Patients with Acute Hypoxemic Respiratory Failure

Background: Non-invasive positive pressure ventilation (NPPV) ensures adequate gas exchange during bronchoscopy in spontaneously breathing, hypoxemic patients, thus avoiding endotracheal intubation. However, in some patients, endotracheal intubation is eventually required after bronchoscopy. This study investigated the incidence of intubation and predictors of a need for emergency intubation prior to NPPV bronchoscopy initiation. Methods: On a retrospective basis, we reviewed the medical records of 36 patients (median age, 55 years; interquartile range [IQR], 43∼65 years) with acute hypoxemic respiratory failure who required NPPV during bronchoscopy between January 2005 and October 2007. Results: All patients were hypoxemic (median PaO2/FiO2 ratio 155; IQR 90∼190), but tolerated bronchoscopy with NPPV support. SOFA score and SAPS II score immediately before NPPV initiation were 4 (3∼7) and 36 (30∼42), respectively. Seventeen (47%) patients needed endotracheal intubation at a median time of 22 (2∼50) hours after bronchoscopy. Patients who needed intubation after bronchoscopy had a higher in-hospital mortality (11 [65%] vs. 4 [21%], p=0.017). Upon multiple logistic regression analysis, the need for intubation after bronchoscopy was independently associated with a P aO2/FiO2 ratio (OR, 0.961; 95% CI, 0.924∼0.999; p=0.047) immediately before NPPV initiation for bronchoscopy. Conclusion: The severity of the hypoxemia immediately prior to NPPV initiation for bronchoscopy was associated with the need for intubation after bronchoscopy in patients with hypoxemic respiratory failure.

Is smaller high enough? Another piece in the puzzle of stress, strain, size, and systems

Extracorporeal lung-supporting procedures open the possibility of staying within widely accepted margins of 'protective' mechanical ventilation (tidal volume of less than 6 mL per kg of predicted ideal body weight and plateau pressure of less than 30 cm H2O) in most any case of respiratory failure or even of further reducing ventilator settings while still providing adequate gas exchange. There is evidence that, at least in some patients, a further reduction in tidal volumes might be beneficial. Extracorporeal procedures to support the lungs have undergone tremendous technical developments, thus reducing the procedure-related risks. However, what is true for ventilator settings should also be true for extracorporeal procedures: studies will have to demonstrate a convincing risk-benefit ratio. In addition, a simple reduction of the tidal volume will certainly not be the right answer. If extracorporeal support largely influences gas exchange, the 'optimal' tidal volume/positive end-expiratory pressure ratio keeping stress and strain low and avoiding alveolar derecruitment will still have to be individually defined.

Oxygen diffusivity of biologic and synthetic scaffold materials for tissue engineering

Scaffolds for tissue engineering and regenerative medicine applications are commonly manufactured from synthetic materials, intact or isolated components of extracellular matrix (ECM), or a combination of such materials. After surgical implantation, the metabolic requirements of cells that populate the scaffold depend upon adequate gas and nutrient exchange with the surrounding microenvironment. The present study measured the oxygen transfer through three biologic scaffold materials composed of ECM including small intestinal submucosa (SIS), urinary bladder submucosa (UBS), and urinary bladder matrix (UBM), and one synthetic biomaterial, Dacron. The oxygen diffusivity was calculated from Fick's first law of diffusion. Each material permitted measurable oxygen diffusion. The diffusivity of SIS was found to be dependent on the direction of oxygen transfer; the oxygen transfer in the abluminal-to-luminal direction was significantly greater than the luminal-to-abluminal direction. The oxygen diffusivity of UBM and UBS were similar despite the presence of an intact basement membrane on the luminal surface of UBM. Dacron showed oxygen diffusivity values seven times greater than the ECM biomaterials. The current study showed that each material has unique oxygen diffusivity values, and these values may be dependent on the scaffold's ultrastructure.

Reducing Lung Injury during Neonatal Resuscitation of Preterm Infants

Neonatologists are familiar with the concept of ventilator-induced lung injury (VILI) 1,2 and are increasingly careful in the neonatal intensive care unit (NICU) to apply positive-pressure ventilation (PPV) strategies that are gentle to the lungs. 3 Although PPV also is commonly used in the delivery room (DR), clinicians appear less aware that the same gentle approach should be applied to reduce lung injury during the first few minutes of life. To achieve adequate gas exchange after delivery, lung fluid is cleared and replaced with air, and functional residual capacity (FRC) is established. Mechanical ventilation requires an appropriate minute volume to achieve adequate gas exchange. Clinical signs are used to evaluate the response to ventilation during neonatal resuscitation. The tidal volume (V T ) delivered is rarely measured; thus, airway pressure is not adjusted to optimize V T and reduce volutrauma or underventilation. 4,6 The use of end-expiratory pressure, considered essential to avoid lung injury in the NICU, is still not uniformly applied in the DR. PPV may cause lung injury through various mechanisms, including high airway pressure (barotrauma), high V T and overdistention (volutrauma), repeated alveolar collapse and reexpansion (atelectrauma), and infection and inflammation (bio-trauma).1 These injuries cause leakage of proteinaceous fluid and blood into the airways, alveoli, and lung interstitium, inhibiting surfactant function, interfering with lung mechanics, and contributing to lung injury.1 In this review, we describe what is known about the causes of neonatal lung injury, based on animal and human research. Although human data are scanty, and randomized control trials are needed, we suggest ways in which current practice might be changed to help minimize lung injury during neonatal resuscitation.

Optimal Positive End‐Expiratory Pressure During Pumpless Extracorporeal Lung Membrane Support

The aim of this study was to determine the optimal positive end-expiratory pressure (PEEP) required during extracorporeal lung membrane support (interventional lung assist [iLA]; Novalung GmbH, Hechingen, Germany). Twenty healthy pigs were initially (4 h) mechanically ventilated with a tidal volume (V(T)) of 10 mL/Kg, respiratory rate (RR) of 20 breaths/min, PEEP of 5 cm H(2)O, and fraction of inspired O(2) (FiO(2)) of 1.0. Thereafter, the iLAs were placed arteriovenously transfemorally and settings reduced to reach near static ventilation (V(T) < or = 2 mL/Kg, RR 4 breaths/min, PEEP of 5, FiO(2) 1.0). Then, animals were assigned to four study groups evaluating 5 cm H(2)O increasing levels of PEEP for 8 h. Gas exchanges with PEEP < or = 10 cm H(2)O were significantly worse than those with PEEP > 12 cm H(2)O, and this without hemodynamical imbalance. This study suggests that the iLA may provide adequate gas exchange during static ventilation only with PEEP levels > 10 cm H(2)O, and this without pulmonary or systemic hemodynamic imbalance.

M634: Airway Management for the OMS

Successful airway management is the cornerstone of safe anesthesia practice. The fundamental responsibility of the anesthesia provider is to maintain adequate gas exchange. Morbidity and mortality studies overwhelmingly conclude that respiratory events are the most common emergent anesthetic events and result in the worst outcomes when not properly treated. We will review the airway management tools available to the oral and maxillofacial surgeon. These will include the endotracheal tube, laryngeal mask airway, combitube, and cricothyroidotomy.

Alternative Invasive Positive Pressure Ventilatory Strategies

In Brief Conventional modes of mechanical ventilation often cause patient-ventilatory asynchrony and may fail to assure adequate gas exchange while attempting to adhere to lung protective ventilatory strategies. Airway pressure release ventilation, partial liquid ventilation, and high-frequency ventilation are alternative ventilatory strategies used for acute respiratory distress syndrome that aim to protect the lung while providing adequate gas exchange. The closed-loop ventilatory strategies use computer algorithm and feedback monitoring of respiratory system mechanics to improve patient-ventilator interaction and comfort. A vast array of mechanical ventilatory modes is available at the disposal of the clinician. In this article, we discuss the basic principles and review the available clinical evidence for the common alternative invasive ventilatory modes and closed loop ventilatory systems.

Apneic Oxygenation Combined With Extracorporeal Arteriovenous Carbon Dioxide Removal Provides Sufficient Gas Exchange in Experimental Lung Injury

We hypothesized that apneic oxygenation, using an open lung approach, combined with extracorporeal CO2 removal, would provide adequate gas exchange in acute lung injury. We tested this hypothesis in nine anesthetized and mechanically ventilated pigs (85-95 kg), in which surfactant was depleted from the lungs by repeated lung lavage. After a lung recruitment maneuver, the tracheal tube was connected to 20 cm H2O continuous pressure (100% O2) for oxygenation of the blood. A pumpless membrane ventilator (interventional lung assist by Novalung) was connected in an arteriovenous shunt for CO2 removal. PaO2 and PaCO2 were recorded for 3.5 hours. PaO2 was 464 (403, 502) mm Hg (median and interquartile range) throughout the experiment. The O2 uptake through the lungs was 185 (164, 212) ml/min. PaCO2 increased asymptotic towards 60 mm Hg. The CO2 removal through the membrane ventilator was 180 (150, 180) ml/min. Thus, the method provided adequate gas exchange in this experimental model, suggesting that it might have potential as an alternative treatment modality in acute lung injury.

Independent lung ventilation in a newborn with asymmetric acute lung injury due to respiratory syncytial virus: a case report

IntroductionIndependent lung ventilation is a form of protective ventilation strategy used in adult asymmetric acute lung injury, where the application of conventional mechanical ventilation can produce ventilator-induced lung injury and ventilation-perfusion mismatch. Only a few experiences have been published on the use of independent lung ventilation in newborn patients.Case presentationWe present a case of independent lung ventilation in a 16-day-old infant of 3.5 kg body weight who had an asymmetric lung injury due to respiratory syncytial virus bronchiolitis. We used independent lung ventilation applying conventional protective pressure controlled ventilation to the less-compromised lung, with a respiratory frequency proportional to the age of the patient, and a pressure controlled high-frequency ventilation to the atelectatic lung. This was done because a single tube conventional ventilation protective strategy would have exposed the less-compromised lung to a high mean airways pressure. The target of independent lung ventilation is to provide adequate gas exchange at a safe mean airways pressure level and to expand the atelectatic lung. Independent lung ventilation was accomplished for 24 hours. Daily chest radiograph and gas exchange were used to evaluate the efficacy of independent lung ventilation. Extubation was performed after 48 hours of conventional single-tube mechanical ventilation following independent lung ventilation.ConclusionThis case report demonstrates the feasibility of independent lung ventilation with two separate tubes in neonates as a treatment of an asymmetric acute lung injury.

Feasibility of very high-frequency ventilation in adults with acute respiratory distress syndrome*

To assess the feasibility of using respiratory frequencies up to 15 Hz during high-frequency oscillatory ventilation (HFO) of adults with acute respiratory distress syndrome (ARDS). Observational study. Medical intensive care unit at a tertiary care university hospital. Thirty adult patients receiving HFO at the discretion of their physicians for management of severe ARDS. Clinical management algorithm for HFO that minimized delivered tidal volumes by encouraging the use of the highest frequency that allowed acceptable clearance of carbon dioxide. This contrasts with the typical use of HFO in adults, in which frequencies generally do not exceed 6 Hz. Patients were 42 +/- 15 yrs old, weighed 83 +/- 25 kg, and had failed conventional lung-protective ventilation due to refractory hypoxia or respiratory acidosis and high plateau airway pressures. During HFO, 25 of 30 patients maintained acceptable gas exchange at frequencies > 6 Hz; 12 reached maximal frequencies of > or = 10 Hz. Among patients whose maximal frequencies exceeded 6 Hz, mean maximal frequency was 9.9 +/- 2.1 Hz, at a mean oscillation pressure amplitude of 81 +/- 11 cm H2O. At those settings, blood gases were pH 7.31 +/- 0.06, PaCO2 was 58 +/- 21 mm Hg, and PaO2 was 82 +/- 33 mm Hg. Survival to hospital discharge among this severely ill cohort was 37%. Most adults can maintain adequate gas exchange using HFO frequencies well above 5-6 Hz. Use of higher frequencies should minimize tidal volume and we speculate might thereby reduce ventilator-associated lung injury.

Progress in Resuscitation

THERE WAS A TIME NOT LONG AGO WHEN THE QUALity and quantity of chest compressions did not seem that important during resuscitation—at least not in comparison with early defibrillation. A ventricular tachyarrhythmia is the initiating event in more than 80% of patients who develop out-of-hospital, primary cardiac arrest during ambulatory electrocardiographic monitoring. Survival declines rapidly if defibrillation is not performed in the first few minutes (defibrillation phase) because myocardial adenosine triphosphate (ATP) levels begin to decrease as fibrillating myocardial cells continue to consume ATP at a nearly normal rate. As a result, ventricular fibrillation (VF) is the presenting rhythm in only 22% to 35% of out-of-hospital cardiac arrest cases when emergency medical services (EMS) personnel arrive on scene. By this time, myocardial ATP stores have often declined to critical levels and a defibrillation shock will usually terminate VF but frequently results in either asystole or pulseless electrical activity as cells run out of high-energy phosphate “fuel.” During this circulatory phase, a brief period of effective chest compression before defibrillation can boost myocardial ATP stores and increase the likelihood that a perfusing rhythm will follow defibrillation. Thus, the strategy for resuscitation from cardiac arrest has evolved from “shock first and often” to a time-critical, orchestrated approach of high-quality cardiopulmonary resuscitation (CPR), defibrillation, and postresuscitation care. This new approach highlights the importance of highquality, minimally interrupted chest compressions to maximize tissue oxygen delivery and intracellular high-energy phosphate levels. Conventional, closed-chest CPR is at best imperfect, producing hemodynamic change similar to that observed in cardiogenic shock. Minimal interruption of chest compression helps to maximize tissue oxygen delivery and, hence, myocardial high-energy phosphate levels. Aufderheide et al showed that both high-quality chest compression (adequate depth, force, and duration) and complete chest wall decompression are needed to maximize stroke volume and improve venous filling during the upstroke, respectively. The odds of survival from cardiac arrest increase when continuous, or nearly continuous, high-quality chest compressions are performed during resuscitation. Abella et al used a monitor/defibrillator with additional sensing capabilities to measure CPR quality (chest compression rate and depth, ventilation rate, and the fraction of cardiac arrest time without chest compressions) during resuscitation in 67 patients who experienced in-hospital cardiac arrest. The authors found that the quality of chest compression was inconsistent and often did not meet published guideline recommendations, even when performed by well-trained hospital staff. In a follow-up study, the same authors used a handheld recording device to measure chest compression rate as a surrogate for CPR quality in 3 different hospitals and found that higher chest compression rates correlated significantly with initial return of spontaneous circulation in 97 in-hospital patients with cardiac arrest. Thus, chest compression quantity and quality are critical determinants of survival from cardiac arrest. Positive pressure ventilation may not be necessary during the first few minutes of CPR because spontaneous agonal respirations often contribute to respiratory exchange of gases. Chest compression alone with a patent airway generates significant minute ventilation and the quantity of oxygen needed is reduced significantly during low blood flow states. Chandra et al assessed the time course of change in arterial blood gases during resuscitation in a canine experimental VF model and found that chest compression alone during CPR can maintain adequate gas exchange to sustain the oxygen saturation level above 90% for at least 4 minutes. Survival from out-of-hospital cardiac arrest is as good in humans when bystanders perform only chest compressions compared with when bystanders perform both chest compressions and mouth-to-mouth ventilation. In this issue of JAMA, Bobrow and colleagues provide an analysis based on a before and after comparison as well as a protocol compliance analysis of out-of-hospital

Cardiac Metabolism in the Fetus and Newborn

The heart undergoes marked changes in energy substrate availability, utilization, and metabolic activity during the transition from the fetal to postnatal environment. Availability of these substrates to the newborn is dependent on adequate gas exchange in the lungs, coronary blood flow, and, after a period of time, enteral or parenteral intake of nutrients. At birth, a rapid shift from carbohydrate to fatty acid utilization occurs. However, in the presence of oxygen insufficiency, the neonatal heart retains the capacity to maintain anaerobic energy production and, thus, cardiac function. Despite the importance of adequate cardiac function and the frequency of neonatal hypoxemic conditions, relatively little is known about how the lack of oxygen affects neonatal cardiac function. More studies are required to discern the optimal nutritional management of infants at risk of suffering from myocardial injury related to oxygen deprivation or other alterations of the fetal and postnatal environment.

Gas exchange during perfluorocarbon liquid immersion: Life-support for the ex utero fetus

Respiratory mortality and morbidity remain major consequences of extreme prematurity. Percutaneous transfer of oxygen and carbon dioxide is possible in the newborn human. Perfluorocarbon (PFC) liquids have excellent oxygen and carbon dioxide carrying capacity. Animals can breath immersed in perfluorocarbon liquids and maintain adequate gas exchange. Our hypothesis is that the combination of spontaneous tidal perfluorocarbon breathing and respiration through the skin immersed in perfluorocarbon will allow adequate gas exchange in the preterm newborn. In this pilot study we aimed to observe the effects of immersion in FC-77 perfluorocarbon liquid on the preterm lamb. PILOT DATA: Four preterm lambs at 100-115 days gestation were delivered using a modified EXIT procedure. Immediately after complete delivery, the catheterised lamb was immersed in warm, oxygenated FC-77 perfluorocarbon liquid. Physiological monitoring was done for up to 60 min. All lambs were warmed adequately and seemed to have centrally intact circulation initially. All had little or no respiratory effort and there was no appreciable lung expansion. All had severe respiratory acidosis. For the provision of immediate ex utero care to the 'fetus' there are three requirements: adequate gas exchange surfaces and sufficient oxygen and carbon dioxide gradients, a functioning circulation, and an environment capable of keeping the lamb warm (thus minimising metabolic demand, oxygen consumption and carbon dioxide production). In this pilot study the greatest initial problem was the severe and rapidly worsening respiratory acidosis. The major problem was a lack of respiratory drive. No lung expansion from the outset would yield zero contribution to gas exchange from the lungs. An intact central circulation does not necessarily mean that the pulmonary circulation, respiratory drive and/or the skin circulation are adequate. For adequate gas exchange to occur it will require a 'breathing' animal with expanded alveoli. If the transition from the normal in utero state to immersion in PFC was immediate, and lung expansion was achieved, it could still be possible to achieve adequate gas exchange through the skin and lungs of the extremely preterm newborn. Given the potential for gas exchange across the skin of the extremely preterm infant we hypothesise that the immersion of extremely preterm infants in PFC liquid will allow optimal percutaneous gas exchange to occur. Given some lung gas exchange with less injurious liquid ventilation (spontaneous or mechanical) we hypothesise that the combination of skin and lung gas exchange will provide sufficient gas exchange to support life.

Respiratory failure and extracorporeal membrane oxygenation

Conventional treatment of respiratory failure involves positive pressure ventilation with high concentrations of inspired oxygen. If adequate gas exchange still cannot be achieved extracorporeal membrane oxygenation (ECMO) may be an option. The general indication for ECMO for respiratory insufficiency is a reversible pulmonary disease, which cannot be managed by conventional means. ECMO is a modified heart-lung machine. Blood is withdrawn from a central vein in the patient and pumped through an artificial oxygenator back to the patient, either to a central artery (veno-arterial ECMO) or to a central vein (veno-venous ECMO). Total gas exchange can be achieved through the extracorporeal system, and the lungs do not have to be subjected to high-pressure ventilation. To date over 21,500 neonates have been treated with ECMO with an overall survival to hospital discharge of 76%. Meconium aspiration syndrome carries the highest survival (94%), whereas congenital diaphragmatic hernia on ECMO only has a survival of 52%. A total of 3500 pediatric patients (30 days to 18 years) have been treated with ECMO with a survival of 56%. Aspiration and viral pneumonia are the pediatric diagnoses with the highest survival rates. Randomized controlled studies have shown a significant advantage of ECMO with regard to survival in neonates. In the pediatric age group, nonrandomized studies have shown lower mortality in ECMO-treated patients.

Acute airway obstruction by a sheared endotracheal intubation stylet sheath in a premature infant

Airway obstruction by foreign bodies is rarely encountered in the neonatal intensive care unit. The majority of those cases reported are iatrogenic. This paper reports a case of acute airway obstruction in a preterm infant caused by a sheared plastic sheath of an endotracheal intubation stylet used during tracheal intubation. The small airway of this premature infant posed a challenge to retrieve the foreign body and to ensure adequate gas exchange at the same time. The risks and benefits of available therapeutic options for this rare, but serious complication are reviewed.

Effect of Repeated Induced Airway Collapse During Total Liquid Ventilation

Negative pressure generated during the expiratory phase of total liquid ventilation (TLV) may induce airway collapse. Evaluation of the effect of repeated airway collapse is crucial to optimize this technique. A total of 24 New Zealand White rabbits were randomly divided into four groups. Ventilation was performed for 6 hours with different strategies: conventional gas ventilation, TLV without airway collapse, and TLV with collapse induced in either 75 or 150 sequential breaths. In the treated groups, airway collapse was induced by increasing the perfluorocarbon drainage velocity while maintaining the minute ventilation constant. Airway pressure, gas exchange, and blood pressure were monitored at 30-minute intervals. At the end of the experiment, airway and lung parenchyma specimens were processed for light microscopy. No evidence of fluorothorax was noticed in any of the four groups at autopsy examination. Minimal signs of inflammation were noticed in all airway and lung parenchyma specimens, but no evident structural alteration was visible. Adequate gas exchange and systemic blood pressure were maintained during all the studies. Repeated airway collapse is not associated with structural changes in the respiratory system and does not alter the gas exchange ability of the lungs.