Burn edema is accentuated by a moderate smoke inhalation injury in sheep.

We determined the lung and systemic response of a moderate smoke inhalation injury combined with a 15% total body surface third-degree burn compared with a burn alone and inhalation alone. Adult sheep were prepared with chronic lung and bilateral prefemoral soft tissue lymph fistula. The burn was confined to one side. Physiologic parameters, lymph flow (QL), and lymph/plasma protein ratio were monitored. Oxidant changes were measured as lipid peroxidation by circulating and lymph-conjugated dienes and lung tissue malondialdehyde. Animals were resuscitated with lactated Ringer's solution during the 24-hour study period to restore and maintain vascular filling pressures and cardiac index. We found net 24-hour fluid balance for burn-inhalation injuries to be 4.1 +/- 1.2 L compared with burn alone of 2.9 +/- 0.9 L and inhalation alone of 2.4 +/- 0.5 L, a significant difference. Protein-rich burn tissue QL increased by fivefold to sixfold with burn alone compared with more than tenfold with burn-inhalation injury. A twofold increase in both lung and nonburn soft tissue QL was also seen in the combined injury not seen with burn alone. Arterial blood gases decreased only at 12 hours. Plasma conjugated dienes were increased in all groups, whereas burn lymph values were increased only in combined insult. In addition, lung malondialdehyde content at 24 hours was 155 +/- 11 nmol/gm with burn-inhalation injury compared with 62 +/- 8 nmol/L for burn alone, 55 +/- 9 nmol/L in inhalation alone, and 45 +/- 4 nmol/L for controls. However, no alveolar flooding was noted in any group. We conclude that a modest smoke inhalation (carboxyhemoglobin of 25%) added to a 15% total body surface burn markedly increases the degree of burn edema, as well as nonburn soft tissue and lung QL, compared with burn alone, indicating increased plasma to interstitial fluid transport in these tissues as well. Increased burn tissue lipid peroxidation products corresponded with the increased burn fluid losses. The increased lung lipid peroxidation also indicates further lung oxidant activity as well.     

Effect of a body burn on endotoxin-induced lipid peroxidation: comparison with physiologic and histologic changes

We determined the effect of a 15% total body surface (TBS), full-thickness burn on the physiologic, histologic, and oxidant-induced lipid peroxidation changes produced by endotoxin. The endotoxin-burn response was compared with that of endotoxin alone. Twenty-two adult sheep with chronic lung and flank lymph fistulas were studied. In 11 sheep a burn was produced under anesthesia and 3 days later they were given 2 micrograms/kg of endotoxin. Data were also compared with those of control sheep and those that were given burns alone. Circulating conjugated dienes increased with endotoxin alone but remained at baseline with endotoxin and burn injury. The lung lymph flow response was increased significantly in the endotoxin-burn group (sixfold) compared with that of endotoxin alone (fourfold). Histologic quantitation of lung neutrophil count was comparable in both groups 6 hours after injury, although mononuclear cells were much more evident in lungs in the endotoxin-burn group. Lipid peroxidation measured by malondialdehyde was significantly increased in the endotoxin group compared with the endotoxin-burn group, despite the greater increase in lymph flow and lung water in the burned group. Oxygen consumption (VO2) remained constant after endotoxin alone compared with baseline. However, VO2 increased twofold immediately after endotoxin in the endotoxin-burn group. This marked increase was followed by a significant decrease in VO2 from baseline. Flank soft-tissue nonburned increased lung lymph flow twofold to threefold with endotoxin and burn, indicating increased soft-tissue permeability, whereas it remained unchanged with endotoxin alone. Liver malondialdehyde increased from a control of 110 +/- 20 to 210 +/- 80 mmol/gm tissue with endotoxin alone and to 450 +/- 54 nmol/gm tissue with endotoxin and burn. We can conclude that burn injury accentuates both the pulmonary and systemic physiologic response to endotoxin, possibly as a result of mediators released from mononuclear cells already activated in the presence of the burn. The increased lung physiologic response does not appear to be caused by greater oxidant-induced lipid peroxidation, as was seen in the liver with the combined injury.     

Effect of dobutamine infusion on endotoxin-induced lipid peroxidation in awake sheep.

beta-agonists are known to not only increase oxygen delivery, but also attenuate the inflammatory response. We studied the effect of infusing the beta-agonist, dobutamine, on the oxidant-induced lung and liver tissue lipid peroxidation seen after endotoxemia. Twelve unanesthetized adult sheep with lung and soft tissue (prefemoral) lymph fistulae were given 5 micrograms/kg of Escherichia coli endotoxin intravenously. In six sheep, dobutamine 10 to 15 micrograms/kg/min was infused beginning 3 hours after endotoxin to increase oxygen delivery by 75% above baseline. Animals were killed at 6 hours, and lung and liver lipid peroxidation, measured as malondialdehyde, was obtained. Data were compared to six control sheep. Endotoxin alone produced increased lung and soft tissue vascular permeability as evidenced by a twofold increase in protein-rich lymph flow. Lung and liver malondialdehyde increased to 116 +/- 40 nmol/gm and 202 +/- 64 nmol/gm, respectively, compared to control values of 42 +/- 7 nmol/gm and 110 +/- 20 nmol/gm, respectively. Dobutamine infusion after endotoxin increased oxygen delivery by 75%, although changes in total oxygen consumption were not different from those seen with endotoxin alone. Lung and soft tissue lymph flow did not change with dobutamine. However, lung malondialdehyde was 41 +/- 17 nmol/gm, not different from controls. Liver malondialdehyde remained elevated at 164 +/- 26 nmol/gm. We conclude that dobutamine infusion prevents further oxidant-induced lung tissue lipid peroxidation but does not reverse the increased permeability already present. Liver lipid peroxidation was not decreased, suggesting the liver oxidant process may not be caused by the same mechanism as the lung lipid peroxidation.     

The lung inflammatory response to thermal injury: relationship between physiologic and histologic changes

We studied the effect of a body burn on lung physiologic, biochemical, and histologic changes in a 2-day postburn period. A 15% of total-body-surface third-degree burn was produced in 24 adult sheep with lung and burn lymph fistulas. Eight sheep were killed at 12 hours and eight at 48 hours. At 12 hours we noted increased lung tissue lipid peroxidation, lung congestion, and neutrophil sequestration, in addition to a 30% decrease in lung compliance. Lung permeability and water content were not increased. Increased release of lipid peroxides and prostanoids were noted from burn tissue, as evidenced by increased plasma levels of malondialdehyde and conjugated dienes that remained elevated for about 8 hours and were decreased with wound removal. The lung inflammatory response was still present at 48 hours, the cells being primarily neutrophils. Nevertheless, the lipid peroxidation process, as measured by lung tissue malondialdehyde, had resolved. There was no evidence of burn tissue infection, measured by quantitative culture, to explain the persistent increase in lung inflammatory cells. Excision and closure of the burn wound at 3 hours postburn in eight sheep attenuated the lipid peroxidation and compliance changes but did not decrease the neutrophil sequestration. We conclude that burn injury results in a local wound oxidant release that leads to lipid peroxidation, both in wounds and in lung, as well as lung inflammation. The lipid peroxidation process may be attenuated by removal of the wound. The neutrophil sequestration is not altered, however, indicating this response occurs very early after injury, probably as a result of oxidant-initiated complement activation.     

Early postburn lipid peroxidation: effect of ibuprofen and allopurinol

We measured lipid peroxidation of plasma, lung, and liver in anaesthetized sheep after third-degree burns involving 30% of total body surface. Animals were resuscitated to baseline filling pressures with lactated Ringer's solution and killed 10 hours after burn. Six sheep were pretreated with ibuprofen (12.5 mg/kg) and five with allopurinol (50 mg/kg). We used conjugated dienes and malondialdehyde as measures of lipid peroxidation. Circulating conjugated dienes increased from a baseline of 0.48 +/- 0.06 to 0.64 +/- 0.05 after burn, while protein-rich burn tissue lymph flow increased up to eightfold. We also noted a significant increase in lung tissue malondialdehyde from 45 +/- 4 to 60 +/- 6 nmol/gm and liver malondialdehyde from 110 +/- 20 to 271 +/- 34 nmol/gm along with increased tissue neutrophil sequestration. Ibuprofen attenuated lung-tissue malondialdehyde but had no effect on lung inflammation, circulating lipid peroxides or burn edema, indicating that ibuprofen most likely decreased O2 radical release in lung tissue by the already-sequestered neutrophils. Allopurinol, possibly via xanthine oxidase inhibition, markedly attenuated burn QL and circulating lipid peroxides and prevented all pulmonary lipid peroxidation and inflammation, indicating that release of oxidant from burn tissue was in part responsible for local burn edema, as well as distant inflammation and oxidant release, the latter most likely from complement activation. Neither antioxidant decreased lipid peroxidation in the liver; this indicates that its mechanism of production was different from that seen in burn tissue, in plasma, or in the lung. An ischemic event resulting from a selective decrease in splanchnic blood flow may be the cause of the liver changes.     

Systemic lipid peroxidation and inflammation induced by thermal injury persists into the post-resuscitation period

We determined the time course of the oxidant-induced systemic lipid peroxidation seen after burn injury. Twelve sheep were given a 15% of total body surface third-degree burn and monitored for 3 or 5 days. Circulating lipid peroxides were monitored by both malondialdehyde (MDA) and conjugated dienes (CD). Lung and liver tissue MDA was also measured and compared to controls. A significant but transient increase in circulating MDA and CD was noted several hours after burn. Venous plasma levels increased again 3-5 days postburn with onset of wound inflammation. Oxygen consumption, VO2, also increased by 35 +/- 12% at this time. Lung MDA, which increased to 64 +/- 5 from a control of 45 +/- 4 nMol/gm, at 12 hours after burn was still increased 3 days after injury. Marked lung inflammation was present early after injury and persisted for the 5-day study period. Liver MDA also increased from control value of 110 +/- 20 to 252 +/- 25 at 12 hours and remained increased over the 5-day period. Serum alkaline phosphatase was also increased. Burn biopsies revealed no infection to explain the ongoing lipid peroxidation process, i.e., bacterial content was less than 10(5) organisms/gram burn tissue. We conclude that an initial system lipid peroxidation occurs immediately after burn injury, and that this process continues well into the post-resuscitation period, corresponding in time with increased VO2, lung inflammation, and evidence of liver dysfunction. The ongoing oxidant changes with the presence of a burn may explain the accentuated organ dysfunction seen with an additional septic insult in burned patients.     

Tissue inflammation without bacteria produces increased oxygen consumption and distant organ lipid peroxidation

An inflammatory focus was produced by implantation of gauze below the hide in the flanks of six sheep with flank lymph fistulas. Physiologic and metabolic parameters were monitored in the unanesthetized animals for 7 days, after which the gauze was removed and monitoring continued for another 5 days. Animals were then killed. Lung and liver tissue was inspected and analyzed for lipid peroxide content. Data were compared with those of six controls in which gauze was not implanted. We noted a transient significant increase (on day 1 only) in wound lymph, thromboxane B2, and 6-keto-PGF1 alpha from baseline values of 190 +/- 70 and 20 +/- 10 pg/ml to 1000 +/- 240 and 420 +/- 70 pg/ml, respectively. Plasma values were also significantly increased on day 1. Body temperature increased by 1 degree C and cardiac index increased by 30% during this period, whereas oxygen consumption, VO2, was not significantly increased. The VO2 and cardiac index increased by 50% over baseline, beginning on day 5, whereas systemic vascular resistance decreased. Body temperature was not increased. These changes corresponded with an increase in wound lymph monocyte count from 0% to 15% of total. The VO2 and cardiac index remained increased after gauze removal. No bacteria were found in the wound. Postmortem analysis revealed a marked monocyte-macrophage infiltration in both lung and liver. Lung water, represented as water content over dry weight, was normal. Lung and liver lipid peroxidation, measured by the by-product malondialdehyde content, increased 300% and 90% over control values, respectively. We conclude that a local, nonbacteria-induced wound inflammation increases VO2, with the increase not corresponding to increase in body temperature. Distant organ changes, namely, changes in lung and liver, were also evident 5 days after gauze removal.     

The immediate effect of burn wound excision on pulmonary function in sheep: the role of prostanoids, oxygen radicals, and chemoattractants

Pulmonary dysfunction is a well-recognized complication of burn wound excision. It remains unclear whether this is caused by bacteria or inflammatory mediators released during excision of the wound. We produced a 15% full-thickness burn in 18 sheep, and between days 5 and 7 completely excised the wound under general anesthesia. Pulmonary parameters of static and dynamic lung compliance (CSTAT and CDYN), PaO2/FiO2, and pulmonary artery pressure (Ppa) were measured, as well as burn lymph, venous and aortic thromboxane B2 (TxB2), chemotactic index (chemotaxis/chemikinesis), and oxygen radical activity reflected in the level of lipid peroxidation in lung tissue. We noted a transient increase in burn lymph and venous TxB2 during excision, increasing from a preburn value of 200 and 220 +/- 50 pg/ml to 950 +/- 210 and 980 +/- 280 pg/ml, respectively. In 13 of 18 sheep, chemotactic activity and lung tissue lipid peroxidation, measured as malondialdehyde (MDA) content, were not increased. In this group only a very transient decrease in CDYN, PaO2/FiO2, and a 3 mm Hg increase in mean Ppa was seen with excision, with these parameters returning rapidly to baseline. Five of the 13 sheep had wound biopsy specimens that were greater than 10(6) organisms/gm tissue. In the remaining five sheep, plasma chemotactic index was also significantly increased with excision, as was lung MDA content, while decreases in CDYN, CSTAT, and PaO2/FiO2 and an increase in Ppa were more protracted. Three of these five sheep had wound biopsy specimens greater than 10(6) organisms/gm. We conclude that a release of thromboxane occurs during excision, which corresponds in time to transient lung dysfunction. If there is also a release of chemotactic factors, a more protracted pulmonary response occurs with evidence of O2 radical-induced lung changes.     

A comparison of effects of thermal injury and smoke inhalation on bacterial translocation

Thermal injury as well as smoke inhalation injury results in serious morbidity and high mortality. In a chronic ovine model, we studied the development of bacterial translocation to the mesenteric lymph node, liver, spleen, kidney, and lung following: 1) sham injury (N = 6), 2) cutaneous thermal injury (N = 5), 3) cotton smoke inhalation injury (N = 4), 4) combined thermal injury and smoke inhalation injury (N = 7). Cardiac output, mean arterial pressure, and plasma protein concentration were maintained within 10% of preinjury values. Urine output was maintained above 1 ml/kg/hour with fluid and plasma resuscitation. A wide-beam ultrasonic flow probe was chronically implanted to allow serial measurement of cephalic mesenteric arterial blood flow throughout the 48-hour experimental period. Sheep were sacrificed 48 hours following injury for quantitative organ culture of mesenteric lymph node, liver, spleen, kidney, and lung. Measurements of mesenteric blood flow demonstrated a decrease to 48 +/- 8%, 80 +/- 5%, and 64 +/- 9% of preinjury levels in sheep receiving thermal injury, smoke inhalation injury, and combination injury, respectively. The sham animals maintained mesenteric blood flow at 102 +/- 7% of control levels. Thermal injury, as well as combination thermal and smoke inhalation injury, resulted in higher levels of translocation than smoke inhalation injury alone.     

Endotoxin causes hydrogen peroxide-induced lung lipid peroxidation and prostanoid production

We studied the role of hydrogen peroxide release on endotoxin-induced lung injury in unanesthetized sheep with chronic lung lymph fistulas. We also further defined the relationship between endotoxin injury, lipid peroxidation, and prostaglandin production. Sheep were given endotoxin alone (1 microgram/kg) or pretreated with catalase (32,500 U/kg) or ibuprofen (12.5 mg/kg). Endotoxin alone resulted in an early prostanoid release, lipid peroxidation measured as circulating conjugated dienes both one and four hours after the administration of endotoxin, pulmonary hypertension, hypoxia, and increased protein permeability. Permeability was monitored by lymph flow and lymph protein content. Catalase pretreatment significantly attenuated all of these aspects of the endotoxin response. Ibuprofen prevented the early lung changes and blocked prostanoid release but did not attenuate the increased permeability. In addition, cyclo-oxygenase inhibition had a dual effect on lipid peroxidation, increasing initial conjugated diene levels while suppressing the later release. The initial effect was clearly related to cyclo-oxygenase blockade. The early conjugated diene release appears to be related to arachidonic acid metabolism and does not correspond to the degree of increased permeability. We conclude that H2O2 plays a major role in lung injury after endotoxin.     

The pulmonary and systemic response to recurrent endotoxemia in the adult sheep

The pulmonary and systemic hemodynamic effects of recurrent endotoxemia were studied in the adult sheep with lung lymph fistulas. Six sheep were given 1 mu/kg Escherichia coli endotoxin every 12 hours for 5 days, after which animals were monitored for another 3 days. The pulmonary response to the first three injections was characterized by an initial severe pulmonary hypertension, hypoxia, and a two- to threefold increase in lymph flow, QL. Lymph and plasma thromboxane A2 (TxB2) and prostacyclin (6-keto-PGF1 alpha) levels increased from baseline values of nearly 200 pg/ml to values exceeding 2000 pg/ml. The systemic response to initial doses was characterized by an increase in systemic vascular resistance, a decrease in cardiac index, and a transient 20% increase in oxygen consumption. With later endotoxin doses, the pulmonary response was markedly attenuated, with only modest changes in pulmonary artery pressure, lymph flow, and arterial oxygen tension noted. TxB2 increases were less than 800 pg/ml, and 6-keto-PGF1 alpha levels remained unchanged. However, we noted the progressive onset of a hyperdynamic state characterized by a sustained increase in cardiac index and body temperature, and a 50% increase in oxygen consumption, whereas systemic vascular resistance decreased by 45%. Three days after endotoxin injections were discontinued, the hyperdynamic state (including leukocytosis) was still present, whereas pulmonary variables returned to baseline levels. We conclude that a hyperdynamic state can be produced by repeated doses of endotoxin that will present even after the endotoxin insult is discontinued, which is a characteristic of the multisystem organ failure syndrome.     

Fluid resuscitation with deferoxamine prevents systemic burn-induced oxidant injury.

We studied the effect of deferoxamine (DFO) infused after burns on hemodynamic stability as well as local and systemic inflammation and oxidant-induced lipid peroxidation. Eighteen anesthetized sheep were given a 40% of total body surface burn and fluid resuscitated to restore oxygen delivery (DO2) and filling pressures to baseline values. Animals were resuscitated with lactated Ringer's (LR) alone or LR plus 1,500 ml of a 5% hetastarch complexed with DFO (8 mg/ml). Animals were killed 6 hours postburn. The sheep resuscitated with LR and LR plus hetastarch demonstrated significant lung inflammation and significant increases in lung and liver malondialdehyde (MDA) from controls of 47 +/- 6 and 110 +/- 7 nMol/gm to 63 +/- 13 and 202 +/- 59 for LR and 67 +/- 4 and 211 +/- 9 for LR + hetastarch, respectively. The group resuscitated with hetastarch alone required 15% less fluid. VO2 returned to baseline values in both groups by 2 hours. Resuscitation with the 5% hetastarch-DFO decreased total fluids by 30% over LR and prevented the increase in lung and liver MDA. In addition, postburn VO2 increased by 25% above baseline values. Burn tissue edema, measured as protein-rich lymph flow, was significantly increased with the administration of DFO compared with the other groups. We conclude that DFO used for burn resuscitation prevents systemic lipid peroxidation and decreases the vascular leak in nonburn tissues while also increasing O2 utilization. Resuscitation with hetastarch-DFO may accentuate burn tissue edema, possibly by increased perfusion of burn tissue.     

Bronchial blood flow and eicosanoid blockade following airway acid aspiration

The systemic circulation to the lung is thought to be an important microvascular exchange region which may contribute to pulmonary edema resulting from airway injury. In a chronic sheep model, we have evaluated the flow through the bronchial artery after airway injury caused by the aspiration of 2.5 ml/kg of 0.1 N hydrochloric acid with and without inhibition of thromboxane synthetase and cyclooxygenase. Cyclooxygenase inhibition with ibuprofen resulted in no rise in bronchial artery blood flow associated with airway acid aspiration (9.8 +/- 1.72 ml/min to 63.7 +/- 8.9 ml/min in the control group versus 11.3 +/- 2.5 ml/min to 10.3 +/- 3.4 ml/min in the ibuprofen group). No difference in bronchial artery blood flow was noted between control acid aspiration and acid aspiration with thromboxane synthetase inhibition. Significant early reduction in lung lymph flow was noted in the cyclooxygenase inhibition group compared to control. These data suggest that inhibition of the cyclooxygenase pathway of eicosanoid production may lessen the injury caused by airway acid aspiration. The decrease in airway blood flow with associated reduction in lymph flow suggests that airway blood flow may be important in the generation of pulmonary edema in this model.     

Oxygen consumption early postburn becomes oxygen delivery dependent with the addition of smoke inhalation injury.

We determined the relationship between oxygen delivery, DO2, and oxygen consumption, VO2, in sheep after a moderate smoke inhalation injury and 15% TBSA third-degree burn compared with burn alone and controls. Comparison was made beginning three hours after injury when carboxyhemoglobin levels were back to baseline values. We decreased DO2 between three and eight hours by 25% by either removing blood (controls) or decreasing the resuscitation fluid infusion rate. Lung oxidant, measured as tissue malondialdehyde (MDA) levels, and histologic changes were also assessed. Animals were killed at 24 hours. We found that in controls and animals with a burn alone, a 25% decrease in DO2 was compensated for by an increase in O2 extraction, maintaining VO2 constant. Correlation of DO2 to VO2 was r2 = 0.3, indicating independence of VO2 from DO2. With the combined injury, VO2 decreased in proportion to DO2, since O2 extraction did not increase. The correlation of DO2 to VO2 was r2 = 0.9, indicating delivery-dependent consumption, a pathologic process most likely caused by increased inflammatory mediators from the combined injury. Lung lipid peroxidation was markedly increased in the combined injury, 148 +/- 18 nmol MDA/gram of tissue compared with burn alone, 64 +/- 5 nmol/g, or controls, 45 +/- 4 nmol/g. However, no decrease in arterial O2 tension or increase in lung water was noted, i.e., the sheep did not have ARDS, which is known to impair O2 extraction. We conclude that a pathologic O2 delivery-dependent consumption develops with the combination of burn and inhalation injury, increasing the potential for tissue hypoxemia. This change corresponds with increased lung tissue oxidant change.     

The effect of leukocyte depletion on smoke inhalation injury in sheep

Leukocytes and the production of oxygen radicals and proteolytic enzymes have been implicated in the pathogenesis of lung injury after smoke inhalation. We investigated the mechanism responsible for this form of pulmonary damage in chronically prepared sheep previously made leukopenic with intra-arterial infusions of nitrogen mustard (mechlorethamine hydrochloride). A control air insufflated group (sham: n = 6), a cotton smoke insufflated group (smoke: n = 12), and a leukopenic cotton smoke insufflation group (smoked + depleted: n = 6) were compared. Although both smoke insufflation groups had equivalent smoke exposure, which was indexed by carboxyhemoglobin, the smoked + depleted group had significant attenuation in the increases in pulmonary artery pressure, pulmonary vascular resistance, and pulmonary lymph flow. The PaO2 to FiO2 ratio (P:F) did not fall to the same extent, nor was there a fall in PaO2. The production of oxygen radicals, which was measured as plasma-conjugated dienes, and the consumption of antiprotease, as measured by alpha 2-macroglobulin levels in lung lymph, were not changed in the smoked + depleted group, whereas it was elevated in the smoked group. We conclude that circulating leukocytes and the release of oxygen radicals and proteolytic enzymes contribute to the lung injury, pulmonary microvascular permeability increase, and pulmonary edema seen after smoke inhalation.     

Measurement of extravascular lung water in sheep during colloid and crystalloid resuscitation from smoke inhalation

The pathophysiology of pulmonary inhalation injury, a major cause of morbidity and mortality from fires, is poorly understood. To examine the effects of colloid and crystalloid resuscitation on extravascular lung water (EVLW) during a standard smoke inhalation injury, we subjected 12 sheep to 8 minutes of cool pine smoke inhalation. The animals were then resuscitated to a pulmonary capillary wedge pressure (PCWP) of 10 +/- 1.5 mm Hg with either lactated Ringer's solution or plasma protein derivative. EVLW, cardiac output, vascular resistance, colloid oncotic pressure (COP), arterial and pulmonary artery pressures, PCWP, and blood gases were monitored during 4 hours of resuscitation. In colloid-treated animals, EVLW increased from 8.3 +/- 1.2 to 11.1 +/- 0.9 ml/kg with injury; it increased only to 12.5 +/- 1.3 ml/kg during resuscitation. In crystalloid-treated animals, EVLW increased from 8.0 +/- 1.0 to 10.3 +/- 0.8 ml/kg with injury and further increased to 17.4 +/- 1.6 ml/kg during resuscitation, a level significantly higher than that in the colloid group (P less than 0.05). The increases in EVLW were associated with progressive hypoxia, which was worse in the crystalloid group. In the crystalloid group, COP decreased from 27.3 +/- 0.9 to 14.2 +/- 0.4 mm Hg and intravascular driving force (COP-PCWP) dropped from 17.6 to 3.26 +/- 1.5 mm Hg; COP and COP-PCWP were maintained in the colloid group. These data demonstrate that supporting serum COP minimizes the increase in EVLW with smoke inhalation injury and suggests that smoke inhalation does not lead to a dramatic increase in alveolar capillary membrane permeability to protein.     

The effect of ketamine on endotoxin-induced lung injury

We investigated the effects of ketamine HCl on endotoxin-induced pulmonary injury in 20 chronically instrumented sheep with lung lymph fistulas. The caudal mediastinal lymph node was cannulated in 20 ewes (45-55 kg). The catheter was externalized and the lymph allowed to drain freely. Pulmonary injury was induced by an intravenous infusion of Escherichia coli endotoxin (1.0-1.5 micrograms/kg body wt) over a 5-min period in 11 animals. The injury was characterized by an increase in pulmonary arterial pressure, pulmonary arterial wedge pressure, and lung lymph flow. There was no change in mean systemic arterial pressure. These changes were significantly attenuated by intravenous administration of ketamine HCl (5 mg/kg) following endotoxin injury in 9 other animals. When ketamine was given, the pulmonary arterial pressure decreased 32%, lung lymph flow decreased 27%, and systemic blood pressure increased 22%. Potential mechanisms for the hemodynamic effects of ketamine HCl in sepsis are discussed with particular reference to the pulmonary microvasculature.     

Pulmonary dysfunction secondary to soft-tissue endotoxin

Our purpose was to determine whether peripheral soft tissues produce and release prostanoids in response to local sepsis, and whether this mediator release can produce pulmonary dysfunction. Escherichia coli endotoxin (2 micrograms/kg in 100 mL of saline) was injected below the hide of the flank in seven unanesthetized sheep. In three additional sheep, ibuprofen (12.5 mg/kg of body weight) was injected with the endotoxin. Thromboxane B2 and 6-keto-PGF1 alpha (prostacyclin) levels were measured in tissue lymph draining the flank, lung lymph, pulmonary artery (Ppa), and aortic plasma. One hour after endotoxin administration, mean PaO2 decreased from 90 to 74 mm Hg and Ppa increased from 22 to 35 mm Hg. Lung lymph flow (QL) increased only 50% with QL being protein poor. No increase in lung or peripheral soft-tissue vascular permeability was noted. Tissue lymph (TxB2) increased from 220 +/- 114 to greater than 10,000 pg/mL with levels in Ppa plasma increasing from 300 +/- 128 to 595 +/- 124 pg/mL and aortic plasma from 270 +/- 141 to 410 +/- 104 pg/mL. Lung lymph TxB2 paralleled aortic values. Peak levels of 6-keto-PGF1 alpha in systemic lymph exceeded 2,000 pg/mL while levels in lung lymph remained relatively constant. The pulmonary injury and the increase in TxB2 was prevented by ibuprofen. We conclude that the response of soft tissue to local endotoxin is to release thromboxane in quantities sufficient to raise plasma levels and to produce hypoxia and pulmonary hypertension. The lung dysfunction is not produced by an increase in lung water or vascular permeability.     

Effect of thermal injury on endotoxin-induced lung injury

We studied the effects of a burn injury on the response of the lung to endotoxin. Seventeen unanesthetized sheep with lung lymph fistulas were studied. Eight were given Escherichia coli endotoxin (1.5 micrograms/kg) alone and nine were given the same dose 72 hours after a 25% total body surface burn injury. At this time after burn, all physiologic parameters were at baseline levels. A characteristic two-phase lung injury was seen after administration of endotoxin with an initial hypertension phase, characterized by pulmonary artery hypertension, and a second or permeability phase, characterized by an increase in protein-rich lymph flow. all eight animals that underwent only endotoxin administration survived, whereas four of the nine burned animals died during the permeability phase in pulmonary edema. Major physiologic differences between the groups were noted during the permeability phase, including a more severe hypoxia, pulmonary hypertension, and increased postburn lymph flow. Major biochemical changes included significant increases in lymph thromboxane, thromboxane B2, and beta-glucuronidase activity in the burn group. We conclude that the lung is more sensitive to endotoxin after burn, probably as a result of an increased release of products of arachidonic acid metabolism and products of leukocyte activation caused by the body burn.     

Early pulmonary and hemodynamic effects of a chest wall burn (effect of ibuprofen)

The cardiopulmonary effects of a third-degree scald burn involving the anterolateral chest wall was compared with a burn of equal size (30% of total body surface) to the flanks in anesthetized sheep with lung lymph fistulas. The chest-burn group was characterized by immediate decreases in cardiac output (6.5 to 3.0 L/min), central venous pressure (5 mm Hg to 0 mm Hg), pulmonary wedge pressure (10 mm Hg to 6 mm Hg), and urine output 1.5 ml/kg/hr to less than 0.5 ml/kg/hr. The temperature of pulmonary artery blood increased from 38 to 42 degrees C and plasma prostacyclin increased from 20 to 200 pg/ml. These changes were significantly different from those seen in the body sheep with burns. Initial fluid requirements necessary to restore filling pressures were 50% greater in the sheep with chest burns than in the sheep with body burns. An early decrease in static lung compliance was also seen after chest burn that was not the result of increased lung edema. A progressive decrease in compliance, urine output, and stroke output was also seen in the later postburn period (6 to 7 hours), which was significantly improved by a chest wall escharotomy. Postmortem analysis in the chest-burn group revealed a significantly increased malondialdehyde content, a reflection of increased oxygen radical-induced lipid peroxidation relative to the body burn. Pretreatment of the chest burn with ibuprofen, 12.5 mg/kg, prevented the initial vasodilator and lung compliance changes so that early cardiopulmonary status was identical to that seen with a body burn alone. Ibuprofen also decreased the lung tissue malondialdehyde content. We conclude that a burn involving the chest wall results in cardiopulmonary abnormalities, not seen after a body burn of a comparable size, which appear to be due to hyperthermia and an increased release of prostacyclin and O2 radicals.