Enhanced resolution of experimental ARDS through IL-4-mediated lung macrophage reprogramming.

Despite intense investigation, acute respiratory distress syndrome (ARDS) remains an enormous clinical problem for which no specific therapies currently exist. In this study, we used intratracheal lipopolysaccharide or Pseudomonas bacteria administration to model experimental acute lung injury (ALI) and to further understand mediators of the resolution phase of ARDS. Recent work demonstrates macrophages transition from a predominant proinflammatory M1 phenotype during acute inflammation to an anti-inflammatory M2 phenotype with ALI resolution. We tested the hypothesis that IL-4, a potent inducer of M2-specific protein expression, would accelerate ALI resolution and lung repair through reprogramming of endogenous inflammatory macrophages. In fact, IL-4 treatment was found to offer dramatic benefits following delayed administration to mice subjected to experimental ALI, including increased survival, accelerated resolution of lung injury, and improved lung function. Expression of the M2 proteins Arg1, FIZZ1, and Ym1 was increased in lung tissues following IL-4 treatment, and among macrophages, FIZZ1 was most prominently upregulated in the interstitial subpopulation. A similar trend was observed for the expression of macrophage mannose receptor (MMR) and Dectin-1 on the surface of alveolar macrophages following IL-4 administration. Macrophage depletion or STAT6 deficiency abrogated the therapeutic effect of IL-4. Collectively, these data demonstrate that IL-4-mediated therapeutic macrophage reprogramming can accelerate resolution and lung repair despite delayed use following experimental ALI. IL-4 or other therapies that target late-phase, proresolution pathways may hold promise for the treatment of human ARDS.

Genetic variability of induction and emergence times for inhalational anaesthetics.

BACKGROUND AND OBJECTIVES: Anaesthetic requirements differ among inbred mouse strains. We tested the genetic influence on induction and arousal times to inhalational anaesthetics in two of these strains. METHODS: Five male C57BL/6J (B6) and five male C3H/HeJ (C3) mice were each exposed to five different concentrations of nitrous oxide (N2O) at five different levels of halothane. Time to sleep and arousal were assessed. Data were analysed by repeated measures of analysis of variance. RESULTS: Halothane, N2O and genetic strain, all were significant independent factors on the time to sleep, while only N2O was a significant independent factor on the time to arousal (P = 0.004). B6 mice took significantly longer to fall asleep compared to the C3 mice controlling for halothane and N2O concentrations (F-ratio = 36, P < 0.0001). The effect of N2O on time to arousal was only significant for the B6 strain (F-ratio = 10, P = 0.005), and not for the C3 strain (F-ratio = 0.8, P = 0.38). CONCLUSIONS: Genetics influences the time to sleep for anaesthetic agents in mice.

mTORC2 signalling regulates M2 macrophage differentiation in response to helminth infection and adaptive thermogenesis.

Alternatively activated macrophages (M2) have an important function in innate immune responses to parasitic helminths, and emerging evidence also indicates these cells are regulators of systemic metabolism. Here we show a critical role for mTORC2 signalling in the generation of M2 macrophages. Abrogation of mTORC2 signalling in macrophages by selective conditional deletion of the adaptor molecule Rictor inhibits the generation of M2 macrophages while leaving the generation of classically activated macrophages (M1) intact. Selective deletion of Rictor in macrophages prevents M2 differentiation and clearance of a parasitic helminth infection in mice, and also abrogates the ability of mice to regulate brown fat and maintain core body temperature. Our findings define a role for mTORC2 in macrophages in integrating signals from the immune microenvironment to promote innate type 2 immunity, and also to integrate systemic metabolic and thermogenic responses.

In vivo measurement of lung volumes in mice.

We describe longitudinal measurements of functional residual capacity (FRC) in breathing mice using a clinical computed tomography (CT) scanner. Lungs of anesthetized mice from the A/J and C3H/HeJ strains were scanned over a 10-s period. Using a fixed threshold for CT density, we could accurately and reproducibly obtain the amount of air in the lungs at FRC, with a 10% coefficient of variation. Total lung volume, and the fractions in left and right lungs, were measured in the two strains from 4 to 12 wk of age. Results show that in both strains the FRC increases only up to 6 wk of age and then remains stable despite a steady increase in body weight. Over this time period, FRC was consistently about 50% greater in the C3H/HeJ strain compared with the A/J strain. The C3H/HeJ strain also has a significantly smaller fraction of the total lung volume in the left lung. We conclude that accurate measurements of FRC in breathing mice can be made using a standard clinical CT scanner. This method may be useful for repeated noninvasive assessment of both structural and functional changes in the lungs of experimental and genetically manipulated mice.

Assessment of cellular profile and lung function with repeated bronchoalveolar lavage in individual mice.

In this study, we sought to develop procedures that would enable repeated bronchoalveolar lavage (BAL) in individual mice on multiple occasions. To achieve this objective, we first developed the procedures that would allow individual mice to survive a whole lung lavage, and then tested whether, on subsequent days, there was an effect of this initial BAL on the cell profile, lung permeability, and baseline respiratory function. Our results demonstrate that the repeated lavage procedure can be readily carried out in individual mice of different strains on multiple occasions. The lavage procedure itself results in immediate increases in respiratory system resistance and concomitant decreases in compliance, but these parameters return to prelavage values by the 2nd or 3rd day postlavage. Lavage also induces variable increases in inflammatory cells depending on the strain used. However, in all three strains examined here (A/J, BALB/c, and C3H/HeJ), inflammatory cell numbers returned to baseline values within 3 days after an initial lavage procedure. The ability to perform repeated BAL in individual mice should prove to be an extremely useful tool in a variety of functional genomic studies in the lung.

Spontaneous airways constrict during breath holding studied by high-resolution computed tomography.

Airway constriction during a breath hold could not be examined previously using standard methods. We used high-resolution computed tomography (HRCT) in vivo to assess the temporal changes in airway area and the effects of a deep inspiration with and without vagal suppression. Five dogs were anesthetized, intubated, and their lungs ventilated with 100 percent oxygen. Fifteen HRCT slices were obtained at functional residual capacity (FRC) either immediately after stopping ventilation at end expiration after either a tidal volume breath or three deep inspirations. Subsequently the dogs were given atropine, 0.2 mg/kg, and the scans were repeated. The cross-sectional areas of 33 airways ranging in size from 1.6 to 9.7 mm in diameter were measured. Airways were separated in three groups based on size: small (< 3 mm in diameter); medium (3 to 6-mm in diameter); and large (> 6 mm in diameter). The small, medium, and large airways showed a spontaneous constriction over time to 49 +/- 8 percent, 83 +/- 4 percent, and 82 +/- 4 percent of initial airway size, respectively (p < 0.01), (p < 0.0001). The deep inspiration caused an initial dilation only in the smallest airways to 133.3 +/- 4 percent. The subsequent constrictions were even greater than after the tidal volume breath averaging 67 +/- 15 percent, 61 +/- 6 percent, and 60 +/- 9 percent of initial airway area in the small, medium, and large airways, respectively (p = 0.001). Atropine caused an average increase in baseline airway area of 115 +/- 5 percent and 121 +/- 6 percent after a tidal volume breath and deep inspiration, respectively, compared with the preatropine controls, with no difference between the three groups. Atropine also completely abolished the spontaneous airway constriction observed after either a tidal volume breath or a deep inspiration in all three groups equally. In conclusion, using direct airway imaging in vivo, we found that airways spontaneously constrict during a prolonged expiratory pause, and a deep inspiration significantly augments this airway constriction. These responses are mediated via vagal afferent pathways, likely arising from progressively decreasing slow-adapting receptor activity.

A species comparison of alveolar size and surface forces.

The independent roles of alveolar size and surface tension in relation to lung stability were investigated in 11 different mammalian species whose body weight ranged from 0.03 to 50 kg. This range in species provided a wide variation in subgross anatomy as well as a fourfold range in alveolar diameter. Alveolar diameter was estimated from the mean linear intercept (Lm) of fixed lungs. Quasi-static pressure-volume curves were determined in excised lungs and the percent volume remaining on deflation from total lung capacity at 30 cmH2O to 10 cmH2O (%V10) provided an index of deflation stability related to functional surfactant. Surface tension of lung extract was measured in the Wilhelmy balance, and the minimum surface tension measured provided an index of surface tension lowering capacity of surfactant. Relationships of %V10 with alveolar diameter and surface tension with alveolar diameter were examined for correlations. Our results indicated that despite a range in Lm between 31 and 133 micron (mouse to pig), %V10 did not change in proportion with Lm across species. Similarly, minimum surface tension was about the same (6.1 to 8.8 dyn/cm) across a threefold difference in alveolar diameter. These results suggest that a stable alveolar configuration is maintained by both surface and tissue forces in a complex manner yet to be analyzed.

On the purported discovery of the bronchial circulation by Leonardo da Vinci.

Among modern physiologists and anatomists, there has been a nearly universal acceptance that Leonardo da Vinci was the first to identify the anatomy of the bronchial circulation. However, because of certain ambiguities in both his anatomic drawing that was supposed to have shown this circulation and the accompanying descriptive text, we questioned whether he really could have been the first to discover this small but important vasculature. To address this question, we set out to repeat Leonardo's dissections in the ox. We reasoned that perhaps the normally tiny bronchial vessels would be considerably more noticeable in this very large species. Our dissections, however, failed to provide any evidence that Leonardo's drawing was that of the bronchial circulation. Furthermore we observed a set of distinct small pulmonary veins to the left upper and right middle lobes that Leonardo, given his lack of understanding of the function of the lung and its circulation, could have easily mistaken for a separate circulation. We thus conclude that Leonardo da Vinci did not describe the anatomy of the bronchial circulation. We believe that the first person to clearly and unequivocally describe the anatomy of this circulation was the Dutch Professor of Anatomy and Botany, Frederich Ruysch.

Effects of tidal volume stretch on airway constriction in vivo.

Tidal stresses are thought to be involved in maintaining airway patency in vivo. The present study examined the effects of normal stresses exerted by the lung parenchyma during tidal ventilation on recovery from agonist-induced airway constriction. In seven anesthetized dogs, one lung was selectively ventilated with a Univent endotracheal tube (Vitaid, Lewiston, NY). Airway tone was increased either transiently (intravenous bolus) or continuously (intravenous infusion) with methacholine (MCh). During one-lung ventilation, changes in the airway size of both lungs were measured for up to 40 min during recovery from constriction by using high-resolution computed tomography. After recovery to baseline, the alternate lung was ventilated, and the protocol was repeated. The absence of tidal stresses led to an attenuated recovery from either transient or steady-state airway constriction. The effectiveness or lack thereof of normal tidal stress in stabilizing airway size may be one factor that contributes to the lack of reversal with tidal breathing and deep inspiration seen in asthmatic subjects.

Osmotic stimuli induce epithelial-dependent relaxation in the guinea pig trachea.

Epithelium in airways, like endothelium in blood vessels, may regulate responses of adjacent smooth muscle. To study the intact trachea from guinea pigs we developed an in vitro preparation that permits independent stimulation from either the inner epithelial surface or the outer serosal surface. The whole guinea pig trachea was excised, cannulated, and perfused at a constant flow with Krebs-Henseleit (KH) solution that was in direct contact with the inner epithelial-lined surface. The outer serosal surface of the trachea was immersed in a separate system (bath) containing KH solution. Tracheal responses were assessed by measuring the pressure drop between the tracheal inlet and the outlet under conditions of constant flow. When the trachea was precontracted with carbachol or KCl, hyperosmolar stimuli (KCl, mannitol, urea, or NaCl) produced concentration-dependent relaxation when applied to the inner epithelial surface. Relaxation was not produced when the hyperosmolar stimulus was applied to the serosal surface and was markedly reduced or abolished when the epithelial surface had been physically damaged or removed. These results indicate that hyperosmotic stimuli induce epithelial-dependent relaxation of trachea. A defect in this mechanism may be partially responsible for the bronchoconstriction seen in asthmatic subjects after exercise.

Lymph flow and lung weight in isolated sheep lungs.

To study the relationship between lung weight and lymph flow, we used an in situ, isolated sheep lung preparation that allowed these two variables to be measured simultaneously. All lungs were perfused for 4.5 h at a constant rate of 100 ml X min-1 X kg-1. In control lungs, the left atrial pressure (Pla) was kept at atmospheric pressure. In experimental lungs, Pla was kept atmospheric except for a 50-min elevation to 18 mmHg midway through the perfusion. During this period of left atrial hypertension, pulmonary arterial pressure rose from 18 to 31 mmHg, lymph flow rose from 3 to 12 ml/h, and the lymph-to-plasma oncotic pressure ratio (pi L/pi P) fell from 0.7 to 0.48. After left atrial pressure was returned to control, pulmonary arterial pressure, lymph flow, and pi L/pi P all returned to control levels. The rate of weight gain after the return of left atrial pressure to control was also the same as that in the control group. However, during the period of left atrial hypertension 135 ml of fluid were filtered into the lung, and this large increase in lung weight remained after the pressure was lowered. The presence of this substantial excess lung water despite control values for vascular pressures, lymph flow, rate of weight gain, and pi L/pi P suggests that the absolute amount of lung water has little influence on the dynamic aspects of lung fluid balance. These results are consistent with a two-compartment model of the interstitial space, where only one of the compartments is readily drained by the lymphatics.

Respiratory system mechanics in mice measured by end-inflation occlusion.

Characterization of pulmonary function parameters in mice will facilitate the dissection of genetic mechanisms underlying airway hyperresponsiveness. We evaluated acetylcholine (ACh)-induced respiratory system resistance (Rrs) and elastance (Ers) in A/J and C3H/HeJ mice and compared these results with the previously used airway pressure-time index (APTI). A low-dead-space ventilatory system was designed to ventilate anesthetized mice with constant inspiratory flow. The end-inflation occlusion method was used to measure Rrs and Ers at baseline and after intravenous ACh (12.5-75.0 micrograms/kg) challenge. ACh induced a dose-dependent rise in Rrs and Ers in A/J mice, whereas minimal changes were observed in C3H/HeJ mice. A/J mice had a higher baseline Rrs, yet the response to ACh was independent of baseline Rrs. Additionally, sequential ACh challenges led to augmented responses. Rrs, Ers, and APTI were strongly correlated, and each was useful to detect differences in interstrain cholinergic-induced airway responsiveness. The Rrs detected the smallest differences between the strains of mice studied.

Contribution of pulmonary versus systemic perfusion of airway smooth muscle.

Recent studies suggest a significant contribution of the pulmonary circulation to the perfusion of large airways. In this study we used anesthetized ventilated sheep (n = 19) to determine the functional contribution of the pulmonary circulation to airway smooth muscle. We performed sequential intravenous challenge with methacholine chloride (MCh; 0.25-2.5 mg/ml) to determine airway resistance (Raw) changes in the intact animal, after bronchial artery cannulation that essentially removed bronchial arterial delivery of MCh, and in an isolated lung preparation. After blocking the vagal reflex component of this response, we found that intravenous MCh in the intact preparation resulted in an average 2.2 +/- 0.5 cmH2O.l-1.s increase (181%) in Raw. After prevention of bronchial arterial delivery of MCh, Raw increased by 0.8 +/- 0.3 cmH2O.l-1.s (64%; P < 0.01 compared with intact preparation). In the isolated lung preparation, Raw increased by 0.6 +/- 0.2 cmH2O.l-1.s (63%; P < 0.01 compared with intact preparation). These results demonstrate that in sheep, the bronchial artery provides the major route for delivery of intravenously administered agonists to airway smooth muscle. Considering the large dilutional effect of an intravenously administered agonist by the time it reaches the bronchial artery, we conclude that the pulmonary component of agonist delivery to large airways is < 10% and unlikely to play a major physiological role.

Antagonists of EDRF attenuate acetylcholine-induced vasodilation in isolated hamster lungs.

To evaluate the role of endothelium-dependent relaxing factor (EDRF) in acetylcholine- (ACh) induced vasodilation in the intact pulmonary circulation, we examined the effects of atropine and three EDRF antagonists that have been shown to be effective in vitro: nitro-L-arginine (NOARG), hemoglobin (Hb), and methylene blue (MB). We studied ACh-induced dilation after preconstriction with angiotensin II and prostaglandin F2 alpha (PGF2 alpha) in hamster lungs perfused with Krebs solution containing Ficoll (4 g/dl) and indomethacin (10 microM). In the constricted lungs with no blockers, infusion of ACh (1 microM) decreased the constriction by 67%, and this effect was completely abolished by atropine pretreatment (1 microM). Treatment of hamster lungs with each of the three EDRF blockers, NOARG (30 microM), Hb (10 microM), and MB (250 microM), augmented the pressor responses to angiotensin II and PGF2 alpha. However, NOARG and MB inhibited the ACh-induced dilation by 49 and 60%, respectively, without affecting vasodilatory responses to isoproterenol, an agent that relaxes vascular smooth muscle independent of EDRF synthesis. In contrast, Hb significantly inhibited both ACh- and isoproterenol-induced vasodilations. Because all these EDRF antagonists attenuated ACh-induced vasodilation in intact hamster lungs, we conclude that EDRF plays a role in this response. Nonselective inhibitory effects of Hb in hamster lungs, however, suggest that mechanisms other than inhibition of EDRF by this agent are also involved.

Effect of hypoxia on bronchial circulation.

We studied the effect of systemic hypoxia on the bronchial vascular pressure-flow relationship in anesthetized ventilated sheep. The bronchial artery, a branch of the bronchoesophageal artery, was cannulated and perfused with a pump with blood from a femoral artery. Bronchial blood flow was set so bronchial arterial pressure approximated systemic arterial pressure. For the group of 25 sheep, control bronchial blood flow was 22 ml/min or 0.7 ml.min-1.kg-1. During the hypoxic exposure, animals were ventilated with a mixture of N2 and air to achieve an arterial PO2 (PaO2) of 30 or 45 Torr. For the more severe hypoxic challenge, bronchial vascular resistance (BVR), as determined by the slope of the linearized pressure-flow curve, decreased acutely from 3.8 +/- 0.4 mmHg.ml-1.min to 2.9 +/- 0.3 mmHg.ml-1.min after 5 min of hypoxia. However, this vasodilation was not sustained, and BVR measured at 30 min of hypoxia was 4.2 +/- 0.8 mmHg.ml-1.min. The zero flow intercept, an index of downstream pressure, remained unaltered during the hypoxic exposure. Under conditions of moderate hypoxia (PaO2 = 45 Torr), BVR decreased from 4.6 +/- 0.3 to 3.8 +/- 0.4 mmHg.ml-1.min at 5 min and remained dilated at 30 min (3.6 +/- 0.5 mmHg.ml-1.min). To determine whether dilator prostaglandins were responsible for the initial bronchial vascular dilation under conditions of severe hypoxia (PaO2 approximately equal to 30 Torr), we studied an additional group of animals with pretreatment with the cyclooxygenase inhibitors indomethacin (2 mg/kg) and ibuprofen (12.5 mg/kg).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of bronchial vascular engorgement on airway dimensions.

Airway vascular engorgement has been suggested to cause luminal narrowing and airflow obstruction. To determine the extent to which changes in bronchial vascular volume could influence airway dimensions, we studied the effects of left atrial pressure elevation on airway morphometry in sheep (n = 17). The bronchial branch of the bronchoesophageal artery was cannulated and perfused with autologous blood (0.6 ml.min-1.kg-1). A balloon-tipped catheter was inserted into the left atrial appendage to elevate left atrial pressure by 10 mmHg, and papaverine was infused into the bronchial artery to eliminate airway smooth muscle tone. Morphological measurements were made from rapidly frozen lungs excised in vivo. Left atrial pressure elevation caused a 79% increase in total vascular area (P = 0.0002). Average airway luminal area was significantly decreased from 86 to 71% of the airway maximal area (P < 0.0001). Noteworthy were the prominent bronchial vessels located within mucosal folds. However, when papaverine was infused during left atrial pressure elevation, despite a comparable total vascular area, luminal narrowing did not occur and remained at 87% of the maximal area (P = 0.6267). In conclusion, we found that engorgement of the bronchial vasculature leads to an increase in the vascular area in regions inside and outside the smooth muscle layer. The associated decrease in luminal area only occurs in the presence of airway smooth muscle tone. This suggests a reflex effect on the airway caused by the vascular engorgement. We conclude that vascular engorgement of the airway wall per se has a negligible effect on airway obstruction.

Airway closure with high PEEP in vivo.

When airway smooth muscle is contracted in vitro, the airway lumen continues to narrow with increasing concentrations of agonist until complete airway closure occurs. Although there remains some controversy regarding whether airways can close in vivo, recent work has clearly demonstrated that, if the airway is sufficiently stimulated with contractile agonists, complete closure of even large cartilaginous conducting airways can readily occur with the lung at functional residual capacity (Brown RH and Mitzner W. J Appl Physiol 85: 2012-2017, 1998). This result suggests that the tethering of airways in situ by parenchymal attachments is small at functional residual capacity. However, at lung volumes above functional residual capacity, the outward tethering of airways should increase, because both the parenchymal shear modulus and tethering forces increase in proportion to the transpulmonary pressure. In the present study, we tested whether we could prevent airway closure in vivo by increasing lung volume with positive end-expiratory pressure (PEEP). Airway smooth muscle was stimulated with increasing methacholine doses delivered directly to airway smooth muscle at three levels of PEEP (0, 6, and 10 cmH(2)O). Our results show that increased lung volume shifted the airway methacholine dose-response curve to the right, but, in many airways in most animals, airway closure still occurred even at the highest levels of PEEP.

The myth of maximal airway responsiveness in vivo.

A sine qua non of hyperresponsive airway disease in asthmatic subjects is the lack of a maximal response with increasing doses of aerosol agonist challenge. Normal subjects, however, often appear to exhibit an airway response plateau effect even when challenged with high concentrations of agonist. To investigate this question of maximal narrowing in individual airways in vivo, we used high-resolution computed tomography to visualize canine airways narrowed by two routes of agonist challenge. We compared airway narrowing induced by methacholine (MCh) via the conventional aerosol route to that caused by local atomization of MCh directly to individual airways. Our results showed that, with aerosol challenge, airway responses never reached a truly flat plateau even at the highest possible nebulizer concentrations. Airway closure was never observed. However, when MCh was delivered directly to the airway luminal surface, airways could be easily narrowed to complete closure at modest (10 mg/ml) agonist concentrations. Thus neither the elastic recoil of the lung nor limitations of smooth muscle shortening can be responsible for the apparent plateauing of dose-response curves. We suggest that the plateau results from limitations associated with the delivery of high concentration of agonists via the aerosol route.