Ultrastructure of the blood-air barrier of dog lungs during the treatment of acute hypoxia using extracorporeal membrane oxygenation

Electron microscopic studies of lung aerohematic barrier were performed in 10 dogs under condition of severe hypoventilation hypoxia, using membrane oxygenator "Sever-OMR". Acute hypoxia treated with extrapulmonary membrane oxygenation was characterized by less deep and disseminated ultrastructural changes in aerohematic barrier than that treated without membrane oxygenation. The data obtained show positive effect of extracorporeal membrane oxygenation on lung tissues.     

Metabolic and circulatory responses of normoxic skeletal muscle to whole-body hypoxia

Whole-body hypoxia may increase peripheral O2 demand because it increases catecholamine calorigenesis, an effect attributable to beta 2-adrenoceptors. We tested these possibilities by pump-perfusing innervated hindlimbs in eight dogs with autologous blood kept normoxic by a membrane oxygenator while ventilating the animals for 40 min with 9% O2 in N2 (NOB group). Similar periods of normoxic ventilation preceded and followed the hypoxic period. A second group (n = 8, beta B) was pretreated with the specific beta 2 blocker ICI 118,551. Hindlimb O2 uptake was elevated by 25 min of hypoxia in NOB, whereas whole-body O2 uptake was reduced. Limb O2 uptake remained elevated in recovery, but all effects on limb O2 uptake were absent in beta B. Hindlimb resistance and perfusion pressure increased in hypoxia in both groups, and there was little evidence of local escape from reflex vasoconstriction. These results clearly indicated that global hypoxia increased O2 demand in muscle when the local O2 supply was not limited and that beta 2-receptors were necessary for this response. Autoregulatory escape of limb muscle blood flow from centrally mediated vasoconstriction during whole-body hypoxia was also shown to be practically nil, if normoxia was maintained in the limb.     

Muscle perfusion and oxygenation during local hyperoxia

Ventilation with O2 was previously shown to decrease whole-body and hindlimb muscle O2 uptake (VO2) in anesthetized dogs, particularly during anemia. To determine whether this was a purely local effect of hyperoxia (HiOx), we pump perfused isolated dog hindlimb muscles with autologous blood made hyperoxic (PO2 greater than 500 Torr) in a membrane oxygenator while the animals were ventilated with room air. Both constant-flow and constant-pressure protocols were used, and half the dogs were made anemic by exchange transfusion of dextran to hematocrit (Hct) approximately 15%. Thus there were four groups of n = 6 dogs each. A 30-min period of HiOx was preceded and followed by similar periods of perfusion with normoxic blood. In HiOx all four groups showed increased leg hindrance, increased leg venous PO2, and no significant changes in leg O2 inflow. Limb blood flow and VO2 decreased approximately 20% in HiOx with constant-pressure perfusion, regardless of Hct. In the constant-flow protocol, leg VO2 in HiOx was maintained by the anemic animals and actually increased in the normocythemic group. We conclude that HiOx directly affected vascular smooth muscle to cause flow restriction and maldistribution. Constant flow offset these effects, but the increased limb VO2 may have been a toxic effect. Anemia appeared to exaggerate the microcirculatory maldistribution caused by HiOx.     

Strength of hypoxic vasoconstriction determines shunt fraction in dogs with atelectasis

We investigated the degree to which strength of pulmonary hypoxic vasoconstriction affects perfusion of pulmonary shunt pathways in acute atelectasis. In 17 intact supine dogs (anesthetized, paralyzed, and ventilated) we produced left lower lobe atelectasis by occluding the lobar bronchus during oxygen inhalation. Subsequently, shunt fraction (reflecting perfusion of that lobe) was measured using an SF6 infusion while the dogs breathed room air; the mean was 26% (range 14-40%). Pulmonary pressor response to hypoxia was assessed in 13 dogs using the increase in pulmonary end-diastolic gradient (PDG) produced by inhalation of 10% oxygen. Those animals with the largest increase in pulmonary diastolic gradient had the smallest shunt fraction while breathing room air, whereas those with the smallest response had the largest shunt fraction. The contribution of local hypoxia to vasoconstriction in the shunt pathway was assessed in 13 dogs breathing room air by measuring the increase in shunt fraction produced by infusing prostaglandin E1 (PGE1). Those with the largest increase in shunt fraction had the smallest pre-PGE1 shunt fraction. Thus the strength of pulmonary vascular reactivity to hypoxia markedly influences the degree of vasoconstriction in shunt pathways and is a major determinant of shunt pathway perfusion.     

Ventilatory responses to specific CNS hypoxia in sleeping dogs.

Our study was concerned with the effect of brain hypoxia on cardiorespiratory control in the sleeping dog. Eleven unanesthetized dogs were studied; seven were prepared for vascular isolation and extracorporeal perfusion of the carotid body to assess the effects of systemic [and, therefore, central nervous system (CNS)] hypoxia (arterial PO(2) = 52, 45, and 38 Torr) in the presence of a normocapnic, normoxic, and normohydric carotid body during non-rapid eye movement sleep. A lack of ventilatory response to systemic boluses of sodium cyanide during carotid body perfusion demonstrated isolation of the perfused carotid body and lack of other significant peripheral chemosensitivity. Four additional dogs were carotid body denervated and exposed to whole body hypoxia for comparison. In the sleeping dog with an intact and perfused carotid body exposed to specific CNS hypoxia, we found the following. 1) CNS hypoxia for 5-25 min resulted in modest but significant hyperventilation and hypocapnia (minute ventilation increased 29 +/- 7% at arterial PO(2) = 38 Torr); carotid body-denervated dogs showed no ventilatory response to hypoxia. 2) The hyperventilation was caused by increased breathing frequency. 3) The hyperventilatory response developed rapidly (<30 s). 4) Most dogs maintained hyperventilation for up to 25 min of hypoxic exposure. 5) There were no significant changes in blood pressure or heart rate. We conclude that specific CNS hypoxia, in the presence of an intact carotid body maintained normoxic and normocapnic, does not depress and usually stimulates breathing during non-rapid eye movement sleep. The rapidity of the response suggests a chemoreflex meditated by hypoxia-sensitive respiratory-related neurons in the CNS.     

Role of the carotid bodies in chemosensory ventilatory responses in the anesthetized mouse.

We examined the effects of carotid body denervation on ventilatory responses to normoxia (21% O2 in N2 for 240 s), hypoxic hypoxia (10 and 15% O2 in N2 for 90 and 120 s, respectively), and hyperoxic hypercapnia (5% CO2 in O2 for 240 s) in the spontaneously breathing urethane-anesthetized mouse. Respiratory measurements were made with a whole body, single-chamber plethysmograph before and after cutting both carotid sinus nerves. Baseline measurements in air showed that carotid body denervation was accompanied by lower minute ventilation with a reduction in respiratory frequency. On the basis of measurements with an open-circuit system, no significant differences in O2 consumption or CO2 production before and after chemodenervation were found. During both levels of hypoxia, animals with intact sinus nerves had increased respiratory frequency, tidal volume, and minute ventilation; however, after chemodenervation, animals experienced a drop in respiratory frequency and ventilatory depression. Tidal volume responses during 15% hypoxia were similar before and after carotid body denervation; during 10% hypoxia in chemodenervated animals, there was a sudden increase in tidal volume with an increase in the rate of inspiration, suggesting that gasping occurred. During hyperoxic hypercapnia, ventilatory responses were lower with a smaller tidal volume after chemodenervation than before. We conclude that the carotid bodies are essential for maintaining ventilation during eupnea, hypoxia, and hypercapnia in the anesthetized mouse.     

A respiratory venous chemoreceptor in the young puppy.

An extracorporeal venovenous shunt system utilizing a membrane oxygenator to alter venous blood gases was used to study the regulation of ventilation in 28 newborn and 4 adult dogs. There was no effect of the extracorporeal circuit per se (without the oxygenator in the system) on essential cardiovascular or respiratory function. When the puppies were placed on the extracorporeal circuit with the oxygenator in the system to effect changes in mixed venous blood gas composition there was a significant increase in venous P02 (Pv02), a decrease in venous Pco2 (Pvco2), a rise in venous pH (PHv), and a marked fall in minute ventilation (VE). There were no significant changes in cardiovascular function or arterial blood gases to account for the depression of ventilation. Acute changes in Pvo2 produced appropriate directional changes of VE under conditions where other arterial and venous blood gases were held constant. At a low Pvco2/Paco2 ratio, ventilation was depressed compared to those conditions with a high ratio. At any Pvc02/Paco2 ratio, ventilation could be depressed by raising the Pvo2. In adult animals ventilation could not be altered by changing venous blood gases. These experiments support the existence of a respiratory chemoreceptor sensitive to both PO2 and PCO2 in the prepulmonary or venous circulation of the newborn animal.     

Nonperipheral chemoreceptor stimulation of ventilation by cyanide.

To assess the ventilatory responses elicited by changes of tissue hypoxia, sodium cyanide (0.12 mg/kg-min for 10 min) was infused into the upper abdominal aorta of anesthetized dogs. These infusions produced decreases in oxygen consumption, increases in arterial lactate concentration, and increases in arterial lactate/pyruvate ratio. Coincident with these metabolic changes of hypoxia, minute ventilation (VE) increased 228 +/- SE 36% and arterial PCO2 decreased 21 +/- SE 2 mmHg; therefore, pH increased both in arterial blood in and cisternal cerebrospinal fluid. Following infusion of cyanide into the abdominal aorta, small quantities of cyanide (48 +/- SE 14 mumol/liter) appeared in carotid arterial blood. To evaluate the possibility that the observed increases in VE were due to stimulation of peripheral arterial chemoreceptors by the recirculating cyanide, the carotid and aortic chemoreceptors were denervated in four dogs. Nonetheless, after intra-aortic infusion of sodium cyanide (1.2 mg/kg), ventilation in these chemodenervated animals again increased considerably (154 +/- SE 36%). In order to explore the possibility that cyanide infusion can stimulate ventilation by an extracranial mechanism, heads of vagotomized dogs (including the carotid bodies) were perfused entirely by donor dogs. The intra-aortic infusion of sodium cyanide (0.9 mg/kg) into these head-perfused animals still caused large increases in VE (163 +/- SE 19%). It is concluded that intra-aortic cyanide infusions stimulate VE by an extracranial mechanism other than the carotid and aortic chemoreceptors.     

Pulmonary circulation in different gaseous media

The ultrasonic method was used in acute experiments on cats with an open (under artificial lung ventilation) and closed chest to explore lung circulation in a changed gaseous medium. Moderate hypoxia (10% O2) and hypercapnia (5, 10% CO2) induce a 10-15% decrease in the lung blood flow in the inferolobular pulmonary artery in the presence of unchanged or slightly elevated minute volume of the heart. The higher hypoxia (5% O2) provokes inconclusive changes in the lung blood flow: biphasic response or increase. It is assumed that considerable elevation of blood pressure in the common pulmonary artery in all the cases points to vasoconstriction that occurs under the effect of hypoxia and hypercapnia.     

Effects of oxygenation and flow on the viability and function of rat hepatocytes cocultured in a microchannel flat-plate bioreactor

The goal of this study was to investigate the viability and synthetic function of rat hepatocytes cocultured with 3T3-J2 fibroblasts in a small-scale microchannel flat-plate bioreactor with and without an internal membrane oxygenator under flow. Bioreactor channel heights ranged between 85 and 500 microm and medium flow rates ranged between 0.06 and 4.18 mL/min. The results showed that the bioreactor without the oxygenator resulted in significantly decreased viability and function of hepatocytes, whereas hepatocytes in the bioreactor with internal membrane oxygenator were able to maintain their viability and function. The shear stress calculations showed that, at lower wall shear stresses (0.01 to 0.33 dyn/cm(2)), hepatocyte functions, measured as albumin and urea synthesis rates, were as much as 2.6- and 1.9-fold greater, respectively, than those at higher wall shear stresses (5 to 21 dyn/cm(2)). Stable albumin and urea synthesis rates for 10 days of perfusion were also demonstrated in the bioreactor with internal membrane oxygenator. These results are relevant in the design of hepatocyte bioreactors and the eventual scaling-up to clinical devices.     

Effect of breathing of a helium-oxygen mixture on adaptation to effort in humans during high-altitude hypoxia

The study was carried out on 17 healthy males aged 20-27 years subjected for 15 minutes to submaximal effort on a cycle ergometer (Elema-Schonander) under conditions of breathing ambient atmospheric air or a helium-oxygen mixture (20% O2 + 80% He) and under hypobaric pressure simulating an altitude of 3500 m above sea level. During the experiment the heart rate was recorded with ECG, and determinations were performed of the minute volume, respiratory rate, tidal volume and systolic arterial blood pressure. In the serum of venous blood obtained before and 3 minutes after the exercise the concentrations were measured of lactate (LA), pyruvate (PA) and glucose. High-altitude hypoxia caused unifavourable changes in the adaptation to effort manifesting themselves as an increase of the values of the determined physiological and biochemical indices. On the other hand, favourable changes were observed of the reaction to exercise while the subjects were breathing the helium-oxygen mixture during high-altitude hypoxia. The minute volume increased owing to increased tidal volume, and the exercise-induced rise of lactate (LA), pyruvate (PA) and the LA/PA ratio was lower. This may suggest reduced energy cost of respiration and reduced anaerobic metabolism under these conditions.     

Evaluation of the efficacy of extracorporeal membrane oxygenation of animals with acute respiratory insufficiency

The efficiency of extracorporeal membrane oxygenation was studied for 2-3 hours in experiments on dogs with severe ventilatory respiratory failure. Extracorporeal oxygenation led to the decrease in arterial hypoxaemia and hypercapnia in animals. However, the variables did not reach the initial levels and were closer to normal values during veno-venous and not veno-arterial perfusion. During extracorporeal membrane oxygenation total systemic blood flow exceeded the initial level irrespective of the means of perfusion and total oxygen transport did not decline lower than the initial level. At the same time during veno-arterial perfusion oxygen delivery provided by the cardiac output decreased almost two-fold by the second hour of perfusion. This might be the reason for inadequate oxygen delivery to the brain and heart. 67% and 71% of animals survived after veno-arterial and veno-venous perfusion, respectively.     

Increased normoxic ventilation induced by repetitive hypoxia in conscious dogs.

To determine if a long-lasting increase in normoxic ventilatory drive is induced in conscious animals by repetitive hypoxia, we examined the normoxic [arterial O2 saturation (SaO2) > 93%] ventilatory response following successive episodes of 2-min eucapnic hypoxic challenges (SaO2 = 80%) in awake tracheotomized dogs. End-tidal CO2 was maintained at the resting level during and after repetitive hypoxia. The experimental protocol was performed twice in each of five dogs on separate days. To determine if changes in normoxic ventilation occurred between episodes of repetitive hypoxia, data were compared from six periods (epochs) for all experiments. The mean minute ventilation (VI) during three normoxic periods between episodes of intermittent hypoxia was 135, 154, and 169% of control (P < 0.05). VI during a 30-min recovery period was still higher at 183 and 172% of control (P < 0.05). Normoxic VI between hypoxic and recovery periods was significantly higher than the corresponding values in sham experiments. Our results indicate that a long-lasting increase in normoxic ventilation can be evoked in an awake unanesthetized dog by a short exposure to repetitive hypoxia.     

Renal preservation by hypothermic perfusion: 2. The influence of oxygenator design and oxygen tension

Rabbit kidneys have been perfused for 24 hr at 5 °C and tested by autotransplantation with immediate contralateral nephrectomy. The perfusate contained an extracellular balance of ions with dextran and bovine serum albumin. The circuit included a nonpulsatile pump, a 0.22-μm membrane filter, and an oxygenator.The efficiency of membrane, film, and bubble oxygenators was compared. Flat membrane oxygenators were found to be more efficient than tubing oxygenators, and although the bubble oxygenator was the most efficient it created problems with foaming. A simple film oxygenator provided the best compromise.Ten kidneys were perfused and transplanted in each of three experimental groups; a film oxygenator was used to provide partial pressures of oxygen of 676 mmHg, 137 mmHg, and 9 mmHg, respectively.There were no significant differences in behavior during perfusion, function after transplantation, or histology of transplanted kidneys in the three groups.The similarity of the results using a film oxygenator with those previously obtained with a membrane oxygenator indicates that complex membrane oxygenators are not necessary for preservation in our system. Moreover, the similarity of the results with oxygen tensions from 9 mmHg to 676 mmHg shows that deliberate oxygenation is also unnecessary.     

Pulmonary arterial distension does not cause pulmonary vasoconstriction

Distension of the main pulmonary artery or its major branches with an intraluminal balloon has been reported to cause pulmonary vasoconstriction by an unknown mechanism. This study was an attempt to confirm the pressor response and explore its cause. Several balloon distension methods were tried and discarded because they caused unintentional obstruction. Ultimately, I inflated a balloon placed retrogradely and confined to the left main pulmonary artery of six anesthetized open-chest dogs after ligating left lobar arterial branches. Blood flow and systemic gas composition were controlled by interposing an external pump oxygenator between the left ventricle and aorta. Pressures in the aorta, main pulmonary artery, and left atrium were recorded. Alveolar hypoxia was used as an independent test of pulmonary vasoreactivity. Although hypoxic pressor responses occurred, challenges with arterial distension did not change lung perfusion pressure. Silicone rubber casts were made of the arteries of six dogs used in pilot experiments. These revealed the limited lengths in which distenders can be placed without unintentional encroachment on flow. I could not support the conclusion that arterial distension causes vasoconstriction and am suspicious that the perfusion pressure increases reported by others may have been caused by undetected obstruction of a major arterial branch.     

Effect of aortic balloon inflation on ventilation and brain stem blood flow in piglets

Increases in brain stem blood flow (BBF) during hypoxia may decrease tissue PCO2/[H+], causing minute ventilation (VE) to decrease. To determine whether an increase in BBF, isolated from changes in arterial PO2 and PCO2, can affect respiration, we obstructed the thoracic aorta with a balloon in 31 intact and 24 peripherally chemobarodenervated, anesthetized, spontaneously breathing newborn piglets. Continuous measurements of cardiorespiratory variables were made before and during 2 min of aortic obstruction. Radiolabeled microspheres were used to measure BBF before and approximately 30 s after balloon inflation in eight intact and five denervated animals. After balloon inflation, there was a rapid increase in mean blood pressure in both the intact and denervated animals, followed within 10 s by a decrease in tidal volume and VE. In the intact animals, the decrease in VE after acute hypertension can be ascribed to a baroreceptor-mediated reflex. After peripheral chemobarodenervation, however, acute hypertension continued to produce a decrease in VE, which cannot be explained by baroreceptor stimulation. In these denervated animals, aortic balloon inflation was associated with an increase in BBF (13.1 +/- 2.7%; P less than 0.05). We speculate that the increase in BBF during hypoxia may contribute to the decrease in ventilation observed after carotid body denervation.     

Brain glutamate metabolism during hypoxia and peripheral chemodenervation

Glutamate stimulates resting ventilation by altering neural excitability centrally. Hypoxia increases central ventilatory drive through peripheral chemoreceptor stimulation and may also alter cerebral perfusion and glutamate metabolism locally. Therefore the effect of hypoxia and peripheral chemodenervation on cerebrospinal fluid (CSF) transfer rate of in vivo tracer amidated central nervous system glutamate was studied in intact and chemodenervated pentobarbital-anesthetized dogs during normoxia and after 1 h of hypoxia induced with 10 or 12% O2 in N2 breathing at constant expired ventilation and arterial CO2 tension. Chemodenervation was performed by bilateral sectioning of the carotid body nerves and cervical vagi. CSF transfer rates of radiotracer 13NH4+ and [13N]glutamine synthesized via the reaction, glutamate + NH4(+)----glutamine, in brain glia were measured during normoxia and after 1 h of hypoxia. At normoxia, maximal glial glutamine efflux rate jm = 103.3 +/- 11.2 (SE) mumol.l-1.min-1 in all animals. After 1 h of hypoxia in intact animals, jm = 78.4 +/- 10.0 mumol.l-1.min-1. In denervated animals, jm was decreased to 46.3 +/- 4.3 mumol.l-1.min-1. During hypoxia, mean cerebral cortical glutamate concentration was higher in denervated animals (9.98 +/- 1.43 mumol/g brain tissue) than in intact animals (7.63 +/- 1.82 mumol/g brain tissue) and corresponding medullary glutamate concentration tended to be higher in denervated animals. There were no differences between mean glutamine and gamma-aminobutyric acid concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ventilatory responses to increased blood flow and decreased lung volume in awake dogs

The effect of decreased lung volume on ventilatory responses to arteriovenous fistula-induced increased cardiac output was studied in four chronic awake dogs. Lung volume decreases were imposed by application of continuous negative-pressure breathing of -10 cmH2O to the trachea. The animals were surgically prepared with chronic tracheostomy, indwelling carotid artery catheter, and bilateral arteriovenous femoral shunts. Control arteriovenous blood flow was 0.5 l/min, and test flow level was 2.0 l/min. Arterial blood CO2 tension (PaCO2) was continuously monitored using an indwelling Teflon membrane mass spectrometer catheter, and inhaled CO2 was given to maintain isocapnia throughout. Increased fistula flow alone led to a mean 52% increase in cardiac output (CO), whereas mean systemic arterial blood pressure (Psa) fell 4% (P less than 0.01). Negative-pressure breathing alone raised Psa by 3% (P less than 0.005) without a significant change in CO. Expired minute ventilation (VE) increased by 27% (P less than 0.005) from control in both of these conditions separately. Combined increased flow and negative pressure led to a 50% increase in CO and 56% increase in VE (P less than 0.0025) without any significant change in Psa. Effects of decreased lung volume and increased CO appeared to be additive with respect to ventilation and to occur under conditions of constant PaCO2 and Psa. Because both decreased lung volume and increased CO occur during normal exercise, these results suggest that mechanisms other than chemical regulation may play an important role in the control of breathing and contribute new insights into the isocapnic exercise hyperpnea phenomenon.     

Gravity is a minor determinant of pulmonary blood flow distribution

Regional pulmonary blood flow in dogs under zone 3 conditions was measured in supine and prone postures to evaluate the linear gravitational model of perfusion distribution. Flow to regions of lung that were 1.9 cm3 in volume was determined by injection of radiolabeled microspheres in both postures. There was marked perfusion heterogeneity within isogravitational planes (coefficient of variation = 42.5%) as well as within gravitational planes (coefficient of variation = 44.2 and 39.2% in supine and prone postures, respectively; P = 0.02). On average, vertical height explained only 5.8 and 2.4% of the flow variability in the supine and prone postures, respectively. Whereas the gravitational model predicts that regional flows should be negatively correlated when measured in supine and prone postures, flows in the two postures were positively correlated, with an r2 of 0.708 +/- 0.050. Regional perfusion as a function of distance from the center of a lung explained 13.4 and 10.8% of the flow variability in the supine and prone postures, respectively. A linear combination of vertical height and radial distance from the centers of each lung provided a better-fitting model but still explained only 20.0 and 12.0% of the flow variability in the supine and prone postures, respectively. The entire lung was searched for a region of contiguous lung pieces (22.8 cm3) with high flow. Such a region was found in the dorsal area of the lower lobes in six of seven animals, and flow to this region was independent of posture. Under zone 3 conditions, neither gravity nor radial location is the principal determinant of regional perfusion distribution in supine and prone dogs.     

Expiratory abdominal muscle activity during ventilatory chemostimulation in piglets

We examined abdominal muscle minute electromyographic (EMG) activity (peak moving time average EMG x respiratory rate) during eupnea, hyperoxic hypercapnia (8% CO2-40% O2-balance N2), and hypoxia (13% O2) in 12 anesthetized (0.5% halothane) newborn piglets. In addition, we assessed the role of vagal afferent pathways in the abdominal muscles' response to ventilatory chemostimulation by examining abdominal EMG activity (EMGab) before and after bilateral cervical vagotomy in five animals. Phasic expiratory EMGab was observed in 11 of 12 piglets during eupnea. Hypercapnia was associated with a sustained augmentation of minute EMGab (444 +/- 208% control). In contrast, hypoxia consistently augmented (1 min, 193 +/- 33% control) then diminished (5 min, 126 +/- 39% control) minute EMGab. Vagotomy resulted in a decline in peak moving time average EMGab by approximately one-half (48 +/- 18% control); the abdominal muscles' response to ventilatory chemostimulation, however, was qualitatively unchanged. We conclude that 1) expiration during eupnea in anesthetized newborn piglets is associated with phasic EMGab; 2) both hypercapnia and hypoxia augment minute EMGab; however, only hypercapnia is associated with sustained augmentation; and 3) although vagal afferents have a role in modulating the base-line level of EMGab, other extravagal mechanisms appear to determine the pattern of EMGab in response to ventilatory chemostimulation.