Relation of blood-free to blood-inclusive postmortem lung water measurements in sheep

Lung ultrasound to quantitatively evaluate extravascular lung water content and its clinical significance

BACKGROUND

As we all know, pulmonary edema can be diagnosed by lung ultrasound (LUS), but how to accurately and quantitatively evaluate lung water content by ultrasound is a difficult problem that needs to be solved urgently. B-line assessment with LUS has recently been proposed as a reliable, noninvasive semiquantitative tool for evaluating extravascular lung water (EVLW). To date, however, there has been no easy quantitative method to evaluate EVLW by LUS.

OBJECTIVE

(1) To explore the feasibility of establishing a rabbit model with increased EVLW by injecting warm normal saline (NS) into the lungs via the endotracheal tube. (2) To establish a simple, accurate and clinically operable method for quantitative assessment of EVLW using LUS. (3) To develop LUS into a resource for guiding the clinical treatment of patients with increased EVLW.

METHODS

Forty-five New Zealand rabbits were randomized into nine groups (n = 5). After anesthesia, each group of rabbits was injected with different amounts of warm sterile NS (0 ml/kg, 2 ml/kg, 4 ml/kg, 6 ml/kg, 8 ml/kg, 10 ml/kg, 15 ml/kg, 20 ml/kg, 30 ml/kg) via the endotracheal tube. Each rabbit was examined by LUS before and after NS injection. At the same time, the spontaneous respiratory rate (RR, breaths per minute), heart rate (HR, bpm) and arterial blood gas (ABG) of the rabbits were recorded. Then, both lungs were dissected to obtain the wet and dry weight and conduct a complete histological examination.

RESULTS

Injecting NS into the lungs through a tracheal tube can successfully establish a rabbit model with increased EVLW. The extent of EVLW increase is related to the volume of NS injected into the lungs. As the EVLW increases, three different types of B-lines can be seen in the LUS. When the NS injection volume is 2-6 ml/kg, comet-tail artifacts and B-lines are the main patterns found on LUS; as additional NS is injected into the lungs, the rabbits' RR gradually increases, while their HR gradually decreases, ABG remains normal or shows mild metabolic acidosis (MA). Confluent B-lines grow gradually but significantly, reaching a dominant position when the NS injection volume reaches 6-8 ml/kg and predominating almost entirely when the NS injection volume is 8-15 ml/kg; at that time, rabbits' RRs and HRs decrease sharply, and the ABG indicated type I respiratory failure (RF).Compact B-lines occur and predominate almost entirely when the NS injection volume reaches 10 ml/kg and 15-20 ml/kg, respectively. At that time, rabbits begin to enter cardiac and respiratory arrest, and ABG shows type II RF and MA.

CONCLUSION

In this study, the establishment of an animal model with increased EVLW confirmed that different lung water content had corresponding manifestations in ultrasound and was associated with different degrees of clinical symptoms, and the study results can be used to guide clinical practice.

Estimation of extravascular lung water using the transpulmonary ultrasound dilution (TPUD) method: a validation study in neonatal lambs

Increased extravascular lung water (EVLW) may contribute to respiratory failure in neonates. Accurate measurement of EVLW in these patients is limited due to the lack of bedside methods. The aim of this pilot study was to investigate the reliability of the transpulmonary ultrasound dilution (TPUD) technique as a possible method for estimating EVLW in a neonatal animal model. Pulmonary edema was induced in 11 lambs by repeated surfactant lavages. In between the lavages, EVLW indexed by bodyweight was estimated by TPUD (EVLWI_tpud) and transpulmonary dye dilution (EVLWI_tpdd) (n = 22). Final EVLWI_tpud measurements were also compared with EVLWI estimations by gold standard post mortem gravimetry (EVLWI_grav) (n = 6). EVLWI was also measured in two additional lambs without pulmonary edema. Bland–Altman plots showed a mean bias between EVLWI_tpud and EVLWI_tpdd of −3.4 mL/kg (LOA ± 25.8 mL/kg) and between EVLWI_tpud and EVLWI_grav of 1.7 mL/kg (LOA ± 8.3 mL/kg). The percentage errors were 109 and 43 % respectively. The correlation between changes in EVLW measured by TPUD and TPDD was r² = 0.22. Agreement between EVLWI measurements by TPUD and TPDD was low. Trending ability to detect changes between these two methods in EVLWI was questionable. The accuracy of EVLWI_tpud was good compared to the gold standard gravimetric method but the TPUD lacked precision in its current prototype. Based on these limited data, we believe that TPUD has potential for future use to estimate EVLW after adaptation of the algorithm. Larger studies are needed to support our findings.

End-expiratory and tidal volumes measured in conscious mice using single projection x-ray images

The evaluation of airway resistance (R(aw)) in conscious mice requires both end-expiratory (V(e)) and tidal volumes (V(t)) (Lai-Fook SJ and Lai YL. J Appl Physiol 98: 2204-2218, 2005). In anesthetized BALB/c mice we measured lung area (A(L)) from ventral-to-dorsal x-ray images taken at FRC (V(e)) and after air inflation with 0.25 and 0.50 ml (DeltaV(L)). Total lung volume (V(L)) described by equation: V(L) = DeltaV(L) + V(FRC) = KA(L)(1.5) assumed uniform (isotropic) inflation. Total V(FRC) averaged 0.55 ml, consisting of 0.10 ml tissue, 0.21 ml blood and 0.24 ml air. K averaged 1.84. In conscious mice in a sealed box, we measured the peak-to-peak box pressure excursions (DeltaP(b)) and x-rays during several cycles. K was used to convert measured A(L)(1.5) to V(L) values. We calculated V(e) and V(t) from the plot of V(L) vs. cos(alpha - phi). Phase angle alpha was the minimum point of the P(b) cycle to the x-ray exposure. Phase difference between the P(b) and V(L) cycles (phi) was measured from DeltaP(b) values using both room- and body-temperature humidified box air. A similar analysis was used after aerosol exposures to bronchoconstrictor methacholine (Mch), except that phi depended also on increased R(aw). In conscious mice, V(e) (0.24 ml) doubled after Mch (50-125 mg/ml) aerosol exposure with constant V(t), frequency (f), DeltaP(b), and R(aw). In anesthetized mice, in addition to an increased V(e), repeated 100 mg/ml Mch exposures increased both DeltaP(b) and R(aw) and decreased f to apnea in 10 min. Thus conscious mice adapted to Mch by limiting R(aw), while anesthesia resulted in airway closure followed by diaphragm fatigue and failure.

Prevention of endotoxin-induced systemic response by bone marrow-derived mesenchymal stem cells in mice

Bone marrow-derived mesenchymal stem cells (BMDMSCs) appear to be important in repair of the chronic lung injury caused by bleomycin in mice. To determine effects of these BMDMSCs on an acute inflammatory response, we injected C57BL/6 mice intraperitoneally with 1 mg/kg endotoxin followed either by intravenous infusion of 5 x 10(5) BMDMSCs, the same number of lung fibroblasts, or an equal volume of normal saline solution. Lungs harvested 6, 24, and 48 h and 14 days after endotoxin showed that BMDMSC administration prevented endotoxin-induced lung inflammation, injury, and edema. Although we were able to detect donor cells in the lungs at 1 day after endotoxin, by 14 days no donor cells were detected. BMDMSC administration suppressed the endotoxin-induced increase in circulating proinflammatory cytokines without decreasing circulating levels of anti-inflammatory mediators. Ex vivo cocultures of BMDMSC and lung cells from endotoxemic animals demonstrated a bilateral conversation in which lung cells stimulated proliferation and migration of stem cells and suppressed proinflammatory cytokine production by lung cells. We conclude that BMDMSCs decrease both the systemic and local inflammatory responses induced by endotoxin. These effects do not require either lung engraftment or differentiation of the stem cells and are due at least in part to the production of stem cell chemoattractants by the lungs and to humoral and physical interactions between stem cells and lung cells. We speculate that mobilization of this population of BMDMSCs may be a general mechanism for modulating an acute inflammatory response.

New method for evaluation of lung lymph flow rate with intact lymphatics in anaesthetized sheep

AIM

Lung lymph has commonly been studied using a lymph fistula created by tube cannulation into the efferent duct of the caudal mediastinal node in sheep. In this method, the tail region of the caudal mediastinal node is resected and the diaphragm is cauterized to exclude systemic lymph contamination, and cannulation is performed into one of the multiple efferent ducts originating from the caudal mediastinal node. Moreover, the pumping activity of lymphatics might be diminished by cannulation. Therefore, the purpose of the study was to evaluate the flow rate of lung lymph with maintenance of intact lymphatic networks around the caudal mediastinal node to the thoracic duct in sheep.

METHODS

An ultrasound transit-time flow meter was used to measure lung lymph flow. The thoracic duct was clamped just above the diaphragm and the flow probe was attached to the thoracic duct just after the last junction with an efferent duct from the caudal mediastinal node. The lung lymph flow rate was measured at baseline and under conditions of lung-oedema formation.

RESULTS

The baseline lung lymph flow rate in our model was three- to sixfold greater than values obtained with the cannulation method. With oedema-formation, the lung lymph flow rate was the same as that measured using cannulation.

CONCLUSION

The lung lymph flow was unexpectedly large under the conditions of the study, and our data suggest that the drainage effect of lymphatics is significant as a safety factor against pulmonary oedema formation.

Transdiaphragmatic transport of tracer albumin from peritoneal to pleural liquid measured in rats

In conscious Wistar-Kyoto rats, we studied the uptake of radioactive tracer (125)I-albumin into the pleural space and circulation after intraperitoneal (IP) injections with 1 or 5 ml of Ringer solution (3 g/dl albumin). Postmortem, we sampled pleural liquid, peritoneal liquid, and blood plasma 2-48 h after IP injection and measured their radioactivity and protein concentration. Tracer concentration was greater in pleural liquid than in plasma approximately 3 h after injection with both IP injection volumes. This behavior indicated transport of tracer through the diaphragm into the pleural space. A dynamic analysis of the tracer uptake with 5-ml IP injections showed that at least 50% of the total pleural flow was via the diaphragm. A similar estimate was derived from an analysis of total protein concentrations. Both estimates were based on restricted pleural capillary filtration and unrestricted transdiaphragmatic transport. The 5-ml IP injections did not change plasma protein concentration but increased pleural and peritoneal protein concentrations from control values by 22 and 30%, respectively. These changes were consistent with a small (approximately 8%) increase in capillary filtration and a small (approximately 20%) reduction in transdiaphragmatic flow from control values, consistent with the small (3%) decrease in hydration measured in diaphragm muscle. Thus the pleural uptake of tracer via the diaphragm with the IP injections occurred by the near-normal transport of liquid and protein.

Effect of core body temperature on ventilator-induced lung injury

OBJECTIVE

Ventilator-induced lung injury is a risk in patients requiring elevated ventilatory support pressures. We hypothesized that thermal stress modulates the development of ventilator-induced lung injury.

DESIGN

Experimental study.

SETTING

University laboratory.

SUBJECTS

Anesthetized rabbits.

INTERVENTIONS

Two experimental studies were designed to determine the role of temperature as a cofactor in ventilator-induced lung injury. In the first study, three groups of anesthetized rabbits were randomized to be ventilated for 2 hrs at core body temperatures of 33, 37, or 41 degrees C while ventilated with pressure control ventilation of 15/3 cm H2O (noninjurious settings-control) or 35/3 cm H2O (potentially injurious settings-experimental). To exclude effects arising from cardiac output fluctuations or from extrapulmonary organs, an isolated lung model was used for the second study, perfused at a fixed rate and studied at either 33 degrees C or 41 degrees C.

MEASUREMENTS AND MAIN RESULTS

In the first study, the hyperthermic group compared with the hypothermic animals had significantly reduced mean PaO2 (-114 vs. + 14 mm Hg, p <.05), increased lung edema formation (mean wet weight/dry weight ratio of 8.1 vs. 5.7), and altered pressure-volume curves. The hyperthermic isolated, perfused lungs had an increased ultrafiltration coefficient, formed more edema, and experienced greater alveolar hemorrhage than hypothermic lungs.

CONCLUSIONS

In two studies of ventilator-induced lung injury in rabbits, maintaining hyperthermia compared with hypothermia augmented the development of lung injury. Similar results from both the in vivo and isolated, perfused lung studies suggest that the observed effects were not due to cardiovascular factors or consequences of heating nonpulmonary organs.

Interstitial exclusion of albumin in rabbit lung during development of pulmonary oedema

The modifications of the macromolecular sieving properties of the pulmonary extracellular tissue matrix were studied in adult anaesthetized rabbits (n = 10) exposed to increased tissue hydration. Exclusion of albumin from the perivascular pulmonary interstitial space was determined by using the continuous infusion method coupled with direct sampling of interstitial fluid performed through the wick technique. The rabbits underwent an intravenous infusion of saline amounting to 10 (n = 5) or 20 % (n = 5) body weight. Extracellular albumin distribution volume was derived from the steady state tissue concentration of radioactive rabbit serum albumin (125I-RSA). Pulmonary extracellular and intravascular fluid volumes (Vx and Vv, respectively) were measured as distribution volumes of 51Cr-EDTA and 131I-RSA, respectively, and interstitial fluid tracer concentrations were determined in interstitial fluid collected through implanted wicks. At the highest degree of hydration, interstitial fluid volume (Vi = Vx - Vv) and extravascular albumin distribution volume (Va,w) significantly increased by 38.5 and 240.2 %, respectively, compared to control. Albumin-excluded volume (Ve,a = Vi - Va,w) was 398.9 +/- 17 microl (g dry tissue weight)-1; the albumin-excluded volume fraction (Fe,a = Ve,a/Vi) was 0.23 +/- 0.01, 33.2 % of the control value. Data indicate that, at variance with what is observed in tissues like skin and muscle, pulmonary Fe,a is highly sensitive to tissue fluid content.

Neutral and DEAE dextrans as tracers for assessing lung microvascular barrier permeability and integrity

Steady-state lymph-to-plasma concentration ratios (L/Ps) of neutral dextrans, cationic DEAE dextrans, and endogenous proteins were determined under normal and increased permeability conditions in six unanesthetized yearling sheep prepared with chronic lung lymph fistulas. Fluorescent dextrans with radii ranging from 1 to 30 nm were intravenously infused, and after 24 h, perilla ketone (PK) was given to alter permeability while the dextran infusion was maintained. Plasma and lymph samples were collected before and after PK administration and analyzed for dextran and protein concentrations after high-performance liquid chromatography size separation. Under both baseline and increased permeability conditions, DEAE dextrans had higher L/Ps than neutral dextrans of similar size but lower L/Ps than proteins of similar size. Comparison of L/Ps before and after PK revealed that the percentage change in permeability for neutral and DEAE dextrans was significantly larger than that for proteins. These results suggest that 1) the pulmonary microvascular barrier behaves as a net negative barrier, 2) some transport mechanisms for proteins and dextrans are different, and 3) neutral and cationic dextrans are more sensitive markers than proteins of the same size for assessing changes in pulmonary capillary permeability.

Correlation between increased airway responsiveness and severity of pulmonary edema

To determine whether the severity of the pulmonary edema in sheep models of cardiogenic and non-cardiogenic pulmonary edema correlate with concomitant alterations in airway responsiveness using three separate measures of pulmonary edema: post-mortem wet-to-dry lung weight ratio (W/D), chest radiograph (CXR) scores, and small airway wall area. Cardiogenic pulmonary edema was induced by increasing left atrial pressure (increase PLA) and non-cardiogenic pulmonary edema was induced by intravenous administration of Perilla ketone (PK). There was a significant negative correlation between changes in airway responsiveness and changes in CXR grade (r=-0.749, P<0.05), W/D (r=-0.662, P<0.05), airway wall areas (r=0.784, P<0.05) after increases in both PLA and PK. Chest radiograph score, W/D, and airway wall area correlated with each other (CXR score and W/D r=0.657, P<0.05; CXR score and airway wall area r=0.678, P<0.05; airway wall area and W/D r=0.704, P<0.05). We speculate that the increased airway responsiveness observed during pulmonary edema may result from the mechanical effects of edema formation within the airways.

Lidocaine attenuates acute lung injury induced by a combination of phospholipase A2 and trypsin

OBJECTIVE

Acute severe pancreatitis is often associated with acute lung injury, including acute respiratory distress syndrome. Acute lung injury induced by phospholipase A2 (PLA2) or trypsin, a pancreatic enzyme, is an experimental model resembling acute respiratory distress syndrome. Neutrophils and platelets are thought to play a pivotal role in the pathogenesis of acute respiratory failure. Lidocaine inhibits some aspects of neutrophil and platelet functions. We conducted the current study to assess the effects of pretreatment with lidocaine on acute lung injury induced by a combination of PLA2 and trypsin.

DESIGN

Prospective, randomized animal study.

SETTING

University research laboratory.

SUBJECTS

Twenty-one adult male Japanese White rabbits (weight range, 2.0-2.4 kg).

INTERVENTIONS

The animals were mechanically ventilated with a tidal volume of 10 mL/kg and an Fio2 of 0.4, and thereafter, they were randomly assigned to three groups. Acute lung injury was induced by a combination of PLA2 (1000 units/kg/hr) and trypsin (5000 units/kg/hr) infused intravenously for 4 hrs. Immediately before induction of the acute lung injury, the lidocaine treatment group received intravenous lidocaine (2 mg/kg bolus followed by 2 mg/kg/hr) until they were killed. In the nontreatment group, saline was given instead of lidocaine. Rabbits in the nonlung-injury group received saline infusion instead of the pancreatic enzymes.

MEASUREMENTS AND MAIN RESULTS

During the experimental period (4 hrs), arterial blood gases, lung mechanics, and peripheral neutrophil and platelet counts were measured. Immediately after killing, the wet weight/dry weight ratio of the lung was recorded. Light microscopic findings (lung injury score and number of neutrophils) were compared between the three groups. The combination of PLA2 and trypsin decreased Pao2, lung compliance, and peripheral counts of neutrophils and platelets and increased alveolar/arterial oxygen tension difference, lung resistance, wet weight/dry weight ratio, and the number of neutrophils in the lung. Lidocaine treatment attenuated these changes. The two pancreatic enzymes caused extensive morphologic lung damage, which was lessened by lidocaine.

CONCLUSIONS

We conclude that pretreatment with intravenous lidocaine attenuated the lung injury induced by the pancreatic enzymes. However, further studies are required to determine whether this drug has a therapeutic effect once the lung injury has developed.

Evaluation of 18-hour lung preservation with oxygenated blood for optimal oxygen delivery

BACKGROUND

Previous studies have shown that availability of oxygen during lung preservation to maintain aerobic metabolism may be essential for the optimal viability of preserved lung tissue. The purpose of this study was to evaluate lung preservation with oxygenated blood for optimal oxygen delivery to the lung graft in a rabbit model.

METHODS

Eighteen excised rabbit lungs were flushed and stored for 18 hours at 10 degrees C with one of the following: Euro-Collins solution (EC; n=6), oxygenated homologous blood (OB; n=6), or low-potassium dextran solution (LPD; n=6). Poststorage lung functions were evaluated with isolated, blood-perfused lung model for 10 minutes.

RESULTS

The mean oxygen tensions after reperfusion for the EC, OB, and LPD groups (47.0+/-2.8, 76.9+/-13.1, 96.2+/-10.9 mm Hg at 10 minutes, respectively) were significantly different throughout the perfusion period (EC < OB < LPD, p < 0.05; EC < LPD, p < 0.01). Pulmonary artery pressure during the reperfusion period in the EC group (35.8+/-4.4 mm Hg at 10 minutes) was higher than that in the OB and LPD groups (29.8+/-4.3 and 22.4+/-2.2 mm Hg, respectively) (EC > OB, EC > LPD, p < 0.05). However, the E-selectin level in the reperfused blood in the OB group (5.04+/-0.24 ng/mL) was significantly elevated compared with that in other groups (EC, 3.56+/-0.54; LPD, 2.92+/-0.35 ng/mL, p < 0.05), which indicated enhanced neutrophil recruitment in the OB group. Comparisons of thrombomodulin and endothelin among the three groups did not reach statistical significance.

CONCLUSIONS

We conclude that OB may enhance lung preservation as compared with EC solution, probably through its enriched oxygen delivery during storage and extracellular composition. However, the availability of oxygenated blood does not exceed that of LPD solution because of augmented neutrophil recruitment, which may activate neutrophil-endothelial interactions.

Optical measurement of isolated canine lung filtration coefficients after alloxan infusion

In this study, lung filtration coefficient (Kfc) was measured in eight isolated canine lung preparations by using three methods: standard gravimetric (Std), blood-corrected gravimetric (BC), and optical. The lungs were held in zone III conditions and were subjected to an average venous pressure increase of 8.79 +/- 0.93 (mean +/- SD) cmH2O. The permeability of the lungs was increased with an infusion of alloxan (75 mg/kg). The resulting Kfc values (in milliliters . min-1 . cmH2O-1 . 100 g dry lung weight-1) measured by using Std and BC gravimetric techniques before vs. after alloxan infusion were statistically different: Std, 0.527 +/- 0.290 vs. 1. 966 +/- 0.283; BC, 0.313 +/- 0.290 vs. 1.384 +/- 0.290. However, the optical technique did not show any statistical difference between pre- and postinjury with alloxan, 0.280 +/- 0.305 vs. 0.483 +/- 0. 297, respectively. The alloxan injury, quantified by using multiple-indicator techniques, showed an increase in permeability and a corresponding decrease in reflection coefficient for albumin (sigmaf). Because the optical method measures the product of Kfc and sigmaf, this study shows that albumin should not be used as an intravascular optical filtration marker when permeability is elevated. However, the optical technique, along with another means of measuring Kfc (such as BC), can be used to calculate the sigmaf of a tracer (in this study, sigmaf of 0.894 at baseline and 0.348 after injury). Another important finding of this study was that the ratio of baseline-to-injury Kfc values was not statistically different for Std and BC techniques, indicating that the percent contribution of slow blood-volume increases does not change because of injury.

Optical measurement of isolated canine lung filtration coefficients at normal hematocrits

In this study, lung filtration coefficient (Kfc) values were measured in eight isolated canine lung preparations at normal hematocrit values using three methods: gravimetric, blood-corrected gravimetric, and optical. The lungs were kept in zone 3 conditions and subjected to an average venous pressure increase of 10.24 +/- 0.27 (SE) cmH2O. The resulting Kfc (ml . min-1 . cmH2O-1 . 100 g dry lung wt-1) measured with the gravimetric technique was 0.420 +/- 0.017, which was statistically different from the Kfc measured by the blood-corrected gravimetric method (0.273 +/- 0.018) or the product of the reflection coefficient (sigmaf) and Kfc measured optically (0. 272 +/- 0.018). The optical method involved the use of a Cellco filter cartridge to separate red blood cells from plasma, which allowed measurement of the concentration of the tracer in plasma at normal hematocrits (34 +/- 1.5). The permeability-surface area product was measured using radioactive multiple indicator-dilution methods before, during, and after venous pressure elevations. Results showed that the surface area of the lung did not change significantly during the measurement of Kfc. These studies suggest that sigmafKfc can be measured optically at normal hematocrits, that this measurement is not influenced by blood volume changes that occur during the measurement, and that the optical sigmafKfc agrees with the Kfc obtained via the blood-corrected gravimetric method.

Blood volume distribution in lung injury

Mild hydrochloric acid was used to induce injury in the caudal section of one lung in each of 10 dogs. 99mTc-red blood cells were injected intravenously. Blood samples were drawn prior to sacrifice. Lung and blood samples were weighed, assayed for radioactivity and dried to constant weight. Assuming a uniform hematocrit, and hence a constant density, we computed blood volumes in terms of mass. The control lung had 4.32 +/- 0.62 g of extravascular lung water (EVLW) per g of bloodless dried weight (BLDW). Injury in the other lung was characterized by an elevated average of 7.08 +/- 0.79 g of EVLW per g of BLDW. The control lung contained 2.49 +/- 0.43 g of blood per g of BLDW and the injured lung contained a reduced amount of 1.69 +/- 0.55 g of blood per g of BLDW. In 8 subjects, injured portions retained the least blood volume per g of BLDW (a limiting value of 1.43 +/- 0.47 g per g). These results support a thesis of a reduction of blood volume in an injured area.

Methylprednisolone does not protect the lung from inhalation injury

Most clinical studies suggest that corticosteroids are contraindicated in the treatment of acute smoke inhalation. However, they are still used in critical situations with the hope that they might reverse the acute pathophysiological responses to smoke inhalation and thus reduce the severity of the illness or make survival possible. These experiments were done to study the effect of methylprednisolone on the response to smoke inhalation in anaesthetized mongrel dogs. Three experimental protocols were followed: (I) haemodynamics, gas exchange, lung compliance, and lung water were evaluated; (II) pulmonary vascular permeability was assessed by cannulating the afferent tracheobronchial lymphatic and calculating the osmotic reflection coefficient (sigma d) at high lung lymph flows; (III) pulmonary surfactant function was studied using a Wilhelmy balance. Methylprednisolone alone did not alter any measured values compared with those seen in control animals. Treatment with methylprednisolone (30 mg/kg) prior to smoke exposure did not attenuate any of the adverse responses typically seen after smoke inhalation. These data indicate that methylprednisolone does not protect the lung from the acute physiological consequences of inhalation injury.

Simultaneous exposure of sheep to endotoxin and 100% oxygen

The purpose of this study was to determine the effect of endotoxin on the development of vascular and airway dysfunction during O2 toxicity. Sheep were prepared for chronic measurement of vascular pressures, cardiac output, gas exchange, and collection of lung lymph. Tracheostomies were made for accurate delivery of gas mixtures. Sheep were placed in one of three experimental groups: those receiving endotoxin (n = 9), those breathing 100% O2 and receiving endotoxin (n = 7), and those exposed to 100% O2 alone (n = 6). Sheep had daily measurements of hypoxic vasoconstriction (FIO2 = 0.12), gas exchange, circulating white blood cell counts, lymph flow, and lymph and plasma protein concentrations. Lung neutrophils were counted, and copper-zinc superoxide dismutase and manganous superoxide dismutase were measured in lung samples from some sheep biopsies taken at baseline surgery and postmortem. Endotoxin markedly prolonged survival time and partially protected against the increased lung vascular permeability in sheep breathing 100% oxygen, but impairment of gas exchange, loss of hypoxic pulmonary vasoconstriction, and ultimate progression of respiratory failure were not prevented. Induction of MnSOD occurred in sheep breathing 100% O2, in sheep receiving endotoxin alone, and in those exposed to 100% O2 plus endotoxin. We conclude that endotoxin markedly increases tolerance to O2 toxicity but that some of the pathophysiology of O2 toxicity is unaltered. The role of superoxide dismutase in the observed protection is unclear.

Kinetics of pulmonary platelet deposition and clearance during thrombin-induced microembolism in rabbits

Using 111In-labeled autologous platelets, we studied the kinetics of pulmonary platelet deposition and clearance in relation to hemodynamic and structural events during thrombin-induced pulmonary microembolism in rabbits. Autologous platelets were radiolabeled and returned to animals prior to infusion of thrombin (100 units/kg over 15 min) (n = 20) or saline (n = 6). All animals were pretreated with tranexamic acid, an inhibitor of fibrinolysis. Thrombin-treated animals manifested progressive increases in mean pulmonary platelet activity, reaching a maximum of 38% above baseline (p less than .0001), whereas no change was observed in saline-treated controls. Animals that died during, or immediately following, thrombin infusion manifested significantly greater increases in pulmonary platelet uptake (mean 1.55 +/- 0.47 times baseline), compared to surviving animals (1.14 +/- 0.16; p less than .05 survivors vs. nonsurvivors). In surviving animals, following cessation of thrombin, pulmonary platelet activity cleared gradually, with a half-time of approximately 12 min. Thrombin reduced circulating platelet counts (p less than .001), increased mean pulmonary artery pressure (13 +/- 3 mm Hg to 18 +/- 6 mm Hg; p less than .0001), and reduced mean systemic arterial pressure (55 +/- 10 mm Hg to 44 +/- 7 mm Hg; p less than .001). The time courses of these events approximated that of thrombin-induced pulmonary platelet uptake. Furthermore, the increase in pulmonary artery pressure occurred predominantly in the group of animals in which the increase in pulmonary radiolabeled platelet activity exceeded the median value of 20%. Postmortem histology showed extensive pulmonary thrombus extending from small arterial to capillary levels in animals that died during, or immediately following, thrombin infusion, but not in surviving animals. Our findings suggest that platelet aggregation plays an important role in the pathogenesis of hemodynamic change following thrombin-induced pulmonary embolization.

Polyamine synthesis in rat lungs injured with alpha-naphthylthiourea

The diamine, putrescine, and polyamines, spermidine and spermine, are low molecular weight organic cations with documented regulatory roles in cell growth and differentiation. Multiple lines of direct and indirect evidence suggest that these organic cations also may function in stimulus-response coupling processes regulating cellular injury and repair. For example, recent studies in monocrotaline-treated rats, hyperoxic rats, and in cultured pulmonary endothelial cells suggest that polyamines regulate pulmonary endothelial integrity and may thus participate in development and/or regression of acute edematous lung injury. To determine if the polyamines are involved in a well-characterized animal model of acute lung injury, the present experiments assessed the relation between changes in polyamine synthesis and development of edema in lungs from rats treated with alpha-naphthylthiourea (ANTU). ANTU caused dose- and time-dependent increases in the lung activity of the initial and rate-limiting enzyme in polyamine biosynthesis, ornithine decarboxylase (ODC) and in the lung contents of the polyamines putrescine, spermidine, and spermine. ANTU also caused dose- and time-dependent increases in the lung wet-to-dry weight ratio indicative of pulmonary edema formation. Changes in lung polyamine biosyntheic activity after ANTU did not relate temporally to changes in the lung wet-to-dry weight ratio: ODC activity was depressed during the 3-h period immediately following ANTU administration, a period when the wet-to-dry weight ratio was increasing, and markedly elevated at 18 h after ANTU administration when the wet-to-dry weight ratio had returned to control levels. Pretreatment of the animals with alpha-difluoromethylornithine, a highly specific inhibitor of ODC, failed to attenuate ANTU-induced increases in lung wet-to-dry weight ratio. These observations indicate polyamine synthesis is enhanced in rat lungs with ANTU-induced pulmonary edema but, unlike certain other models of lung injury and pulmonary edema, accumulation of polyamines probably is not essential for development of edematous lung injury. It is conceivable that in this animal model polyamines play a role in lung repair processes or some longer-term consequence of lung injury.

Monokine-induced lung injury in rats: similarities to monocrotaline-induced pneumotoxicity

Previous studies have shown that abnormal alveolar macrophages and biological activity resembling the macrophage-derived mediator interleukin-1 (IL-1) can be detected in bronchoalveolar lavage fluid from rats with monocrotaline-induced lung injury and pulmonary hypertension. To determine if monokines might play a pathogenic role in this model, the present study evaluated the effects of a murine monokine preparation enriched in IL-1 bioactivity on selected events characterizing the early pneumotoxic response to monocrotaline, including pulmonary edema and protein extravasation, pulmonary vascular hyperreactivity, and enhanced lung tissue activity of the rate-limiting enzyme in polyamine biosynthesis, ornithine decarboxylase (ODC). Intravenous injection of the monokine preparation containing 200 units/kg IL-1 (quantified by lymphocyte activating factor assay) into intact rats produced pulmonary edema within 3 hr manifested by increases in the lung wet-to-dry weight ratio and in the extent of pulmonary albumin extravasation. The edema had resolved within 24 hr of monokine administration as indicated by a return to control levels of the wet-to-dry weight ratio and albumin extravasation index. The monokine preparation also increased the transfer of albumin across monolayers of cultured porcine pulmonary vascular endothelial cells. While salt solution-perfused rat lungs isolated from animals treated 3 hr previously with the monokine preparation were hyporesponsive to angiotensin II, preparations derived from animals treated 24 hr previously were markedly hyperresponsive to the vasoconstrictor actions of the peptide. Pressor responses to potassium chloride and prostaglandin F2a were unaffected by exposure to the monokine preparation. Lung ODC activity in monokine-exposed animals did not differ from control at 3, 6, or 24 hr after treatment. In contrast, a 24-hr exposure of cultured pulmonary vascular endothelial cells to the monokine preparation increased ODC activity approximately 100-fold. These observations indicate that a monokine preparation containing IL-1 bioactivity causes transient pulmonary edema and pulmonary vascular hyperreactivity and increases ODC activity in pulmonary vascular endothelial cells. Because the monokine preparation mimics certain aspects of monocrotaline-induced pneumotoxicity in the rat, it is reasonable to postulate that monokines could play a pathogenic role in this and similar animal models of lung injury and pulmonary hypertension.

Smoke inhalation

An attempt has been made to review the characteristics of fire and smoke and the epidemiology of smoke inhalation to identify some of the many variables which interact to control the severity of the injury. An experimental model appropriate to study the pulmonary injury of smoke victims who survive to enter the health care system is described. Experiments which define how smoke damages the lung are reviewed in an effort to explain why the smoke-damaged lung is vulnerable to additional stress and why those with an injured lung and a burn have such a high mortality rate.

Lung water measurements with iodo-antipyrine

131I labeled iodo-antipyrine and 99mTc labeled erythrocytes were used to measure water content in lungs. These radioactive tracers were injected into 10 rabbits with normal lungs and 11 rabbits with injured lungs. Blood samples were drawn and the subjects were killed. The lungs were removed, weighed and homogenized. Samples of blood and lung homogenate were assayed for 131I and 99mTc. Samples were also weighed before and after drying to a constant weight at 70-75 degrees C. Extravascular lung water was determined by the dual isotope technique and again by gravimetric analysis. The average ratio of the results from the 2 different methods is 1.03 +/- 0.15. The 2 methods were compared by regression analysis and the correlation coefficient was 0.92 +/- 0.09. Our investigation suggests the possibility of measurement of lung water with equilibrium distribution of iodo-antipyrine.

Effects of crystalloid on lung fluid balance after smoke inhalation

Inhalation injury occurs in 21% of flame burn victims who require large fluid volumes for resuscitation and have a mortality rate greater than 30%. This study was done to determine how vulnerable the smoke-injured lung is to fluid accumulation when crystalloids are infused rapidly. Mongrel dogs were exposed to smoke and 10% body-weight Ringer's lactate in three groups: (I) fluid only, (II) smoke only, and (III) smoke and fluid. The increase in wet-dry lung weight ratio was 2% in Group I, 28% in Group II, and 42% in Group III, consistent with pulmonary edema present only in Group III. The decrease in colloid oncotic pressure was similar in both of the groups that were given fluid, and the rise in the surface tension minimum of lung extracts was similar in both of the groups that were exposed to smoke. The smoke-injured lung loses the ability to protect itself when challenged with fluid. Reduced oncotic pressure is not responsible. Changes in microvascular pressure, endothelial and epithelial damage, and surfactant inactivation interact to cause this increase in extravascular lung water.