Ventilation with high tidal volume induces inflammatory lung injury

Bueno, P.C.S.; Bueno, C.E.; Santos, M.L.; Oliveira-Júnior, I.; Salomão, R.; Pinheiro, B.V.; Beppu, O.S.

doi:10.1590/S0100-879X2002000200007

Abstract

Mechanical ventilation with high tidal volumes (V T) has been shown to induce lung injury. We examined the hypothesis that this procedure induces lung injury with inflammatory features. Anesthetized male Wistar rats were randomized into three groups: group 1 (N = 12): V T = 7 ml/kg, respiratory rate (RR) = 50 breaths/min; group 2 (N = 10): V T = 21 ml/kg, RR = 16 breaths/min; group 3 (N = 11): V T = 42 ml/kg, RR = 8 breaths/min. The animals were ventilated with fraction of inspired oxygen of 1 and positive end-expiratory pressure of 2 cmH2O. After 4 h of ventilation, group 3, compared to groups 1 and 2, had lower PaO2 [280 (range 73-458) vs 517 (range 307-596), and 547 mmHg (range 330-662), respectively, P<0.05], higher wet lung weight [3.62 ± 0.91 vs 1.69 ± 0.48 and 1.44 ± 0.20 g, respectively, P<0.05], and higher wet lung weight/dry lung weight ratio [18.14 (range 11.55-26.31) vs 7.80 (range 4.79-12.18), and 6.34 (range 5.92-7.04), respectively, P<0.05]. Total cell and neutrophil counts were higher in group 3 compared to groups 1 and 2 (P<0.05), as were baseline TNF-alpha concentrations [134 (range <10-386) vs 16 (range <10-24), and 17 pg/ml (range <10-23), respectively, P<0.05]. Serum TNF-alpha concentrations reached a higher level in group 3, but without statistical significance. These results suggest that mechanical ventilation with high V T induces lung injury with inflammatory characteristics. This ventilatory strategy can affect the release of TNF-alpha in the lungs and can reach the systemic circulation, a finding that may have relevance for the development of a systemic inflammatory response.

Lung injury; Mechanical ventilation; Inflammation; TNF-alpha

Braz J Med Biol Res, February 2002, Volume 35(2) 191-198

Ventilation with high tidal volume induces inflammatory lung injury

P.C.S. Bueno¹, C.E. Bueno¹, M.L. Santos¹, I. Oliveira-Júnior¹, R. Salomão², B.V. Pinheiro¹and O.S. Beppu¹

¹Laboratório de Pequenos Animais, Disciplina de Pneumologia, and ²Laboratório de Virologia, Disciplina de Doenças Infecciosas e Parasitárias, Escola Paulista de Medicina, Universidade Federal de São Paulo, São Paulo, SP, Brasil

References

Correspondence and Footnotes ^{Correspondence and Footnotes} Correspondence and Footnotes

Mechanical ventilation with high tidal volumes (V_T) has been shown to induce lung injury. We examined the hypothesis that this procedure induces lung injury with inflammatory features. Anesthetized male Wistar rats were randomized into three groups: group 1 (N = 12): V_T = 7 ml/kg, respiratory rate (RR) = 50 breaths/min; group 2 (N = 10): V_T = 21 ml/kg, RR = 16 breaths/min; group 3 (N = 11): V_T = 42 ml/kg, RR = 8 breaths/min. The animals were ventilated with fraction of inspired oxygen of 1 and positive end-expiratory pressure of 2 cmH₂O. After 4 h of ventilation, group 3, compared to groups 1 and 2, had lower PaO₂ [280 (range 73-458) vs 517 (range 307-596), and 547 mmHg (range 330-662), respectively, P<0.05], higher wet lung weight [3.62 ± 0.91 vs 1.69 ± 0.48 and 1.44 ± 0.20 g, respectively, P<0.05], and higher wet lung weight/dry lung weight ratio [18.14 (range 11.55-26.31) vs 7.80 (range 4.79-12.18), and 6.34 (range 5.92-7.04), respectively, P<0.05]. Total cell and neutrophil counts were higher in group 3 compared to groups 1 and 2 (P<0.05), as were baseline TNF-a concentrations [134 (range <10-386) vs 16 (range <10-24), and 17 pg/ml (range <10-23), respectively, P<0.05]. Serum TNF-a concentrations reached a higher level in group 3, but without statistical significance. These results suggest that mechanical ventilation with high V_T induces lung injury with inflammatory characteristics. This ventilatory strategy can affect the release of TNF-a in the lungs and can reach the systemic circulation, a finding that may have relevance for the development of a systemic inflammatory response.

Key words: Lung injury, Mechanical ventilation, Inflammation, TNF-a

Abstract

Introduction

Mechanical ventilation is an important therapy in patients with acute respiratory failure, providing adequate gas exchange and rest to respiratory muscles. For this reason, it is widely used in intensive care units (1). In spite of its great importance, mechanical ventilatory support has its own risks. Since its introduction, the association between high airway pressures and barotrauma (pneumothorax, pneumomediastinum, pulmonary interstitial emphysema, subcutaneous emphysema, pneumoperitoneum, or pneumopericardium) has been demonstrated (2). Many studies have shown that mechanical ventilation can increase microvascular permeability and edema formation (3-6). These problems raised the question that mechanical ventilation may increase lung injury and hamper recovery, especially in patients with acute respiratory distress syndrome (ARDS), contributing to the development of infection, multisystem organ damage, and increased mortality (7).

In the early stages of ARDS there is a small number of working lung units, sometimes as little as 25% of normal (referred to some authors as "baby lung"), which receive all the adjusted tidal volume (V_T), resulting in high ventilation pressures (8). These high ventilation pressures, achieved with conventional V_T (e.g., 10 to 12 ml/kg), have been related to pulmonary injury in different experimental models (9,10). Despite the wide variations among different animal species, these results can be, at least in part, extrapolated to clinical practice, as shown by some studies that achieved good results with protective strategies during mechanical ventilation (11-13).

The ventilator-induced lung injury was initially attributed to the overdistension and repetitive opening and collapse of alveolar units. More recently, experimental studies suggested that mechanical ventilation increases pulmonary levels of inflammatory mediators and induces neutrophil accumulation (14-16). These studies suggest the hypothesis that ventilator-induced lung injury has an inflammatory component. The aim of the present study was to verify if mechanical ventilation with high V_T induces lung injury with inflammatory characteristics.

Material and Methods

Animal care was provided according to the Principles of Laboratory Animal Care published by the National Institutes of Health (Guide for the Care and Use of Experimental Animals, NIH Publication No. 86-23, 1985).

Experimental preparations

Male Wistar rats (Escola Paulista de Medicina, Universidade Federal de São Paulo, São Paulo, SP, Brazil), weighing 300 to 350 g were anesthetized by intraperitoneal (ip) injection of 50 mg/kg thiobarbital and placed in dorsal decubitus throughout the experiment. After tracheostomy a 14-gauge cannula was inserted into the trachea. The rats were ventilated for 20 min at a V_T of 7 ml/kg, respiratory rate (RR) of 50 breaths/min, positive end-expiratory pressure (PEEP) of 2 cmH₂O, and fraction of inspired oxygen (F_IO₂) of 1, with a ventilator for small animals (Inter-3, Intermed, São Paulo, SP, Brazil). The animals were kept paralyzed with 1 mg/kg pancuronium bromide ip throughout the experiments. A 24-gauge catheter was inserted into the left carotid artery for arterial blood sampling.

Experimental protocol

After 20 min, the baseline values were measured and the animals were randomly assigned to one of three groups. Group 1 (N = 12): ventilated at the same setting used during the baseline period for a total of 4 h. Group 2 (N = 10): ventilated at a V_T of 21 ml/kg, RR of 16 breaths/min, PEEP of 2 cmH₂O, and F_IO₂ of 1, for a total of 4 h. Group 3 (N = 11): ventilated at a V_T of 42 ml/kg, RR of 8 breaths/min, PEEP of 2 cmH₂O, and F_IO₂ of 1, for a total of 4 h.

After 4 h, while the rat was still being ventilated, the abdomen was opened and a blood sample was obtained from the inferior vena cava for later cytokine analysis, before exsanguinating the animal by aortic section.

Measurements

Arterial blood gases were measured using an automatic analyzer (Radiometer ABL, 330, Copenhagen, Denmark) at baseline, and after 2 and 4 h. Airway pressure was measured through the tracheostomy tube using a transducer (Pneumotach, Hans Rudolph, Kansas City, KS, USA) and was continuously recorded. After the animal was sacrificed, a pressure-volume curve was determined by the stepwise injection of 1 ml room air every 2 min, measuring the pressures with a water column. The lungs were inflated until the measured pressure reached 35 cmH₂O, and then deflated in the same way, with measurements of the corresponding pressures.

The thorax of the animals was opened, and the lungs were removed and carefully dissected from mediastinal tissue. The wet weight of the left lung (WLW) was obtained (Marte, A200, São Paulo, SP, Brazil), the lung was then heated at 90ºC in a gravity convection oven (Fanem, 315SG, São Paulo, SP, Brazil) for 72 h, and the residue was weighed (dry lung weight, DLW). The right lung was washed three times with 28 ml/kg physiological saline. A small aliquot of the combined lavage was used for total cell count in a hemocytometer (Neubauer chamber), and the remaining washings were centrifuged at 1,500 g for 20 min to separate cellular from noncellular elements. The supernatant was separated, frozen at -80ºC, and subsequently used for protein concentration and TNF-a analysis. The cell pellet was suspended in 1 ml physiological saline, cytocentrifuged (LABHO, CT12, São Paulo, SP, Brazil), air dried and stained with May-Grünwald-Giemsa. A differential cell count was performed on a minimum of 200 cells. Concentrations of TNF-a at baseline and in serum were measured in duplicate by ELISA (Factor-test-x/RAT TNF-a, Genzyme Diagnostics, Cambridge, MA, USA). Total baseline protein concentrations were determined spectrophotometrically in duplicate by the method of Lowry et al. (17).

Statistical methods

Data are reported as mean ± SEM or median when appropriate. One-way analysis of variance was used for WLW and DLW. For all other variables, one-way rank analysis of variance was used. Scheffé's correction was used for multiple comparisons. A P value <0.05 was considered to be statistically significant.

Values of arterial blood gases (PaO₂ and PaCO₂) and pH for the three groups are listed in Table 1 and illustrated in Figure 1. During the baseline period and after 2 h of mechanical ventilation, all variables were similar among groups. After 4 h, PaO₂ was lower in group 3 compared with groups 1 and 2 (P<0.05). PaCO₂ and pH continued to be similar among groups after 4 h of experiment.

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Table 2 lists the lung volumes (ml) at pulmonary pressures of 10, 20, and 35 cmH₂O, achieved during inflation. The volumes were lower in group 3 compared with groups 1 and 2 at pulmonary pressures of 10 and 20 cmH₂O (P<0.05).

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The WLW and the WLW/DLW ratio were higher in group 3 (P<0.05). The baseline protein contents and the baseline proteins/DLW ratio were also higher in group 3 (P<0.05). These results are listed in Table 3.

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The total cell and neutrophil counts were higher in group 3 compared with groups 1 and 2 (P<0.05) (Figure 2). Baseline TNF-a was higher in group 3 compared with group 1 (P<0.05) (Figure 3). Although serum TNF-a reached a higher level in group 3, the difference was not statistically significant (Figure 4).

Figure 1.
PaO

₂, PaCO₂, and pH in the three groups at baseline and after 2 and 4 h of mechanical ventilation. After 4 h, PaO₂ was lower in group 3 (V_T = 42 ml/kg). PaCO₂ and pH were similar for all groups throughout the experiment. *P<0.05 compared to groups 1 and 2 (one-way rank analysis of variance). V_T = tidal volume.

[View larger version of this image (10 K GIF file)]

Figure 2.
Total cell and neutrophil counts and the percentage of baseline in the three groups. After 4 h, total cell count, neutrophil count and its percentage of baseline were higher in group 3 compared with groups 1 and 2. *P<0.05 (one-way rank analysis of variance).

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Figure 3.
Baseline TNF-a levels in the three groups. After 4 h, the baseline TNF-a was higher in group 3 (V

_T = 42 ml/kg) compared with group 1 (V_T = 21 ml/kg) and group 2 (V_T = 7 ml/kg). *P<0.05 (one-way rank analysis of variance).

[View larger version of this image (4 K GIF file)]

Figure 4.
Serum TNF-a levels in the three groups. After 4 h, although serum TNF-a was higher in group 3 (V

_T = 42 ml/kg) compared with group 1 (V_T = 21 ml/kg) and group 2 (V_T = 42 ml/kg), it did not reach statistical significance (one-way rank analysis of variance).

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Results

The results of this study showed that mechanical ventilation with high V_T (42 ml/kg) induced lung injury in rats after 4 h compared to mechanical ventilation with a lower V_T (7 and 21 ml/kg). The lung injury was demonstrated by the decrease in PaO₂ and the increase in WLW, WLW/DLW ratio, baseline protein contents, and baseline protein contents/DLW ratio, and by the worsening of the pulmonary compliance measured at pulmonary pressures of 10 and 20 cmH₂O. The rats were ventilated with a V_T of 42 ml/kg because in ARDS, a clinical condition where lung injury induced by mechanical ventilation is critical, sometimes even less than 25% of the lungs are ventilated. So, in these cases, traditional adjustments of V_T to 10 to 12 ml/kg may correspond to a V_T as high as 42 ml/kg in a previously normal lung. In the groups ventilated with lower V_T, the RR were increased in order to keep the same minute volume, as can be seen by the same pH and PaCO₂ levels at baseline.

Discussion

Research in different species has shown that mechanical ventilation with high V_T can induce lung injury similar to that seen in ARDS. Webb and Tierney in 1974 (18) demonstrated that rats ventilated for 1 h with high inspiratory pressures (45 cmH₂O) developed hypoxemia, increased WLW, and histological findings of alveolar edema. Kolobow et al. (19), studying sheep ventilated for 4 h either with low inspiratory pressures (15 to 20 cmH₂O) or high inspiratory pressures (50 cmH₂O), found in the latter group development of hypoxemia, worsening of respiratory compliance, and histological findings indistinguishable from those seen in ARDS.

Lung injury induced by mechanical ventilation is multifactorial and includes the structural disruption generated by lung overdistension and by the shear forces created during repetitive opening and closing of atelectatic regions. Mechanical ventilation has also deleterious effects on the surfactant function, increasing the tendency of distal airways and alveoli to collapse, and increasing the pressure necessary to open the lung (20,21). Although the higher airway pressures achieved may result in increased transmural capillary pressure, facilitating the development of hydrostatic edema, the lung injury induced by high V_T includes alterations in the pulmonary capillary permeability and alveolar epithelium leaks (22). The increase in baseline protein contents and in the baseline protein contents/DLW ratio seen in this study excludes hydrostatic edema as the only hypothesis. DLW, another argument for a high protein content edema, did not differ among the three groups. This might have occurred because, during the experiments, the rats ventilated with 42 ml/kg presented with lung fluid that had to be aspirated from the trachea by a catheter. The loss of protein with this fluid aspiration may have avoided the increase in DLW. Other authors have demonstrated, also by experimental studies, defects in the blood-air barrier induced by mechanical ventilation with high V_T and inspiratory pressures. Egan et al. (22) demonstrated in sheep that epithelial pore radii increased, and leaks developed at static inflation pressures greater than 35 cmH₂O. Parker et al. (23) examined the effects of ventilation of open-chest dogs with high peak airway pressures (>60 cmH₂O), and showed a higher lung lymph protein clearance and higher lymph/plasma protein ratio, which indicate increases in microvascular permeability. Dreyfuss et al. (5) found that high positive pressure ventilation resulted in a dramatic increase in pulmonary microvascular permeability associated with parenchymal ultrastructural lesions. They showed an increase in DLW and fractional ¹²⁵I-labeled albumin uptake by the lungs in the group ventilated at 45 cmH₂O peak inspiratory pressure compared with those ventilated at 7 cmH₂O, and ultrastructural alterations such as damage of type I cells, denuding of the epithelial basement membrane, interstitial and alveolar edema and hyaline membranes. West et al. (24), using electron microscopy, demonstrated microvascular injury induced by high distending pressures. These authors detected a large number of endothelial and epithelial breaks, which they called stress fractures, at high lung volumes compared with low lung volumes.

Many studies are producing evidence that mechanical ventilation has significant effects on lung levels of inflammatory cells and mediators. Valenza et al. (25) have shown that mechanical ventilation at 15 ml/kg and low levels of PEEP increased the levels of interleukin-1ß compared with ventilation at 7 ml/kg. Tremblay et al. (26) have also shown that mechanical ventilation with excessive end-inspiratory lung volume and without PEEP increased the concentration of lung lavage cytokines. The results of our study are in agreement with this evidence. The group ventilated at 42 ml/kg had a larger number of cells and neutrophils at baseline compared with the other groups (Figure 2). Also, baseline TNF-a levels were higher in these animals (Figure 3). We hypothesize that ventilating the rats with high V_T induced an increase in the production and release of TNF-a by the lung macrophages and that TNF-a induced neutrophil accumulation and activation in the lungs, contributing to their injury.

More recently, some studies have shown results suggesting that lung injury induced by mechanical ventilation may initiate and propagate a systemic inflammatory response that may play an important role in the development of multiple system organ failure in critically ill patients. von Bethman et al. (27) reported, in an isolated perfused lung model, that ventilation with high transpulmonary pressures leads to a significant increase in concentrations of TNF-a and interleukin-6 in the perfusate, indicating the loss of compartmentalization of the inflammatory process within the lungs. Chiumello et al. (28) demonstrated in rats that ventilation at high V_T and without PEEP for 4 h increased the release of inflammatory mediators into the systemic circulation in a lung injury model using hydrochloric acid instillation. In the present study, the serum TNF-a levels in the group ventilated at 42 ml/kg were higher compared with the other two groups, although without statistical significance (Figure 4). This could be explained by the fact that even ventilation with lower V_T can release some amount of mediators. We sampled serum from unventilated rats and no TNF-a was detected (data not shown).

In conclusion, the results of the present study provide further evidence that strategies of mechanical ventilation at high V_T lead to lung injury at least in part by an inflammatory mechanism. We speculate that this inflammatory response may not be compartmentalized within the lungs because of the epithelial and endothelial damage, and may propagate a systemic inflammatory response.

Address for correspondence: O.S. Beppu, Disciplina de Pneumologia, Escola Paulista de Medicina, UNIFESP, Rua Botucatu, 740, 3º andar, 04023-062 São Paulo, SP, Brasil. E-mail: hsbvp@zaz.com.br

Research supported by CAPES. Publication supported by FAPESP. Received March 22, 2001. Accepted September 14, 2001.

1. Esteban A, Anzueto A, Alía I, Gordo F, Apezteguía C, Pálizas F, David C, Goldwasser R, Soto L, Bugedo G, Rodrigo C, Pimentel J, Raimondi G & Tobin M (2000). How is mechanical ventilation employed in the intensive care unit? An international utilization review. American Journal of Respiratory and Critical Care Medicine, 161: 1450-1458.
2. Parker JC, Hernandez LA & Peevy KJ (1993). Mechanisms of ventilator-induced lung injury. Critical Care Medicine, 21: 131-143.
3. Parker JC, Townsley MI, Rippe B, Taylor AE & Thigpen J (1984). Increased microvascular permeability in dog lungs due to high peak airway pressures. Journal of Applied Physiology, 57: 1809-1816.
4. Woo SW & Hedley-Whyte J (1972). Macrophage accumulation and pulmonary edema due to thoracotomy and lung overinflation. Journal of Applied Physiology, 33: 14-21.
5. Dreyfuss D, Basset G, Soler P & Saumon G (1985). Intermittent positive-pressure hyperventilation with high inflation pressures produces pulmonary microvascular injury in rats. American Review of Respiratory Disease, 132: 880-884.
6. Dreyfuss D & Saumon G (1993). Role of tidal volume, FRC, and end-inspiratory volume in the development of pulmonary edema following mechanical ventilation. American Review of Respiratory Disease, 148: 1194-1203.
7. Slutsky AS & Tremblay LN (1998). Multiple system organ failure. Is mechanical ventilation a contributing factor? American Journal of Respiratory and Critical Care Medicine, 157: 1721-1725.
8. Pelosi P, Crotti S, Brazzi L & Gattinoni L (1996). Computed tomography in adult respiratory distress syndrome: what has it taught us? European Respiratory Journal, 9: 1055-1062.
9. Argiras EP, Blakeley CR, Dunnil MS, Otremski S & Sykes MK (1987). High PEEP decreases hyaline membrane formation in surfactant deficient lungs. British Journal of Anaesthesia, 5: 1278-1285.
10. Muscedere JG, Mullen JBM, Gan K, Bryan AC & Slutsky AS (1994). Tidal ventilation at low airway pressures can augment lung injury. American Journal of Respiratory and Critical Care Medicine, 149: 1327-1334.
11. Hickling KG, Walsh J, Henderson S & Jackson R (1994). Low mortality rate in adult respiratory distress syndrome using low-volume, pressure-limited ventilation with permissive hypercapnia: a prospective study. Critical Care Medicine, 22: 1568-1578.
12. Amato MBP, Barbas CSV, Medeiros DMM, Magaldi RB, Schettino GPP, Lorenzi-Filho G, Kairalla RA, Deheinzelin D, Munoz C, Oliveira R, Takagaki TY & Carvalho CRR (1998). Effect of a protective-ventilation strategy on mortality in the acute respiratory distress syndrome. New England Journal of Medicine, 338: 347-354.
13. The Acute Respiratory Distress Syndrome Network (2000). Ventilation with lower tidal volumes as compared with traditional tidal volumes for acute lung injury and the acute respiratory distress syndrome. New England Journal of Medicine, 342: 1301-1308.
14. Kawano T, Mori S, Cybulsky M, Burger R, Ballin A, Cutz E & Bryan AC (1987). Effect of granulocyte depletion in a ventilated surfactant-depleted lung. Journal of Applied Physiology, 62: 27-33.
15. Imai YT, Kawano T, Miyasaka K, Takata M, Imai T & Okuyama K (1994). Inflamatory chemical mediators during conventional ventilation and during high frequency oscillatory ventilation. American Journal of Respiratory and Critical Care Medicine, 150: 1550-1554.
16. Takata M, Abe J, Tanaka H, Kitano Y, Doi S, Kohsaka T & Miysaka K (1997). Intraalveolar expression of tumor necrosis factor-alpha gene during conventional and high-frequency ventilation. American Journal of Respiratory and Critical Care Medicine, 156: 272-279.
17. Lowry O, Rosebrough NJ, Farr AL & Randall RJ (1951). Protein measurement with the Folin phenol reagent. Journal of Biological Chemistry, 193: 265-275.
18. Webb HH & Tierney DF (1974). Experimental pulmonary edema due to intermittent positive pressure ventilation with high inflation pressures. Protection by positive end-expiratory pressure. American Review of Respiratory Disease, 110: 556-565.
19. Kolobow T, Moretti MP, Fumagalli R, Mascheroni D, Prato P, Chen V & Joris M (1987). Severe impairment in lung function induced by high peak airway pressure during mechanical ventilation. An experimental study. American Review of Respiratory Disease, 135: 312-315.
20. Tierney DF & Johnson RP (1965). Altered surface tension of lung extracts and lung mechanics. Journal of Applied Physiology, 20: 1253-1260.
21. Ito Y, Veldhuizen RAW, Yao L, McCaig LA, Bartlett AJ & Lewis JF (1997). Ventilation strategies affect surfactant aggregate conversion in acute lung injury. American Journal of Respiratory and Critical Care Medicine, 155: 493-499.
22. Egan EA, Nelson RM & Oliver RE (1976). Lung inflation and alveolar permeability to nonelectrolytes in the adult sheep in vivo Journal of Physiology, 260: 409-424.
23. Parker JC, Hernandez LA, Longenecker GL, Peevy K & Johnson W (1990). Lung edema caused by high peak inspiratory pressure in dogs. Role of increased microvascular filtration pressure and permeability. American Review of Respiratory Disease, 142: 321-328.
24. West JB, Tsukimoto K & Mathieu-Costello O (1991). Stress failure in pulmonary capillaries. Journal of Applied Physiology, 70: 1731-1742.
25. Valenza F, Ribeiro SP & Slutsky AS (1995). High volume-low pressure mechanical ventilation upregulates IL-1ß production in an ex vivo lung model. American Journal of Respiratory and Critical Care Medicine, 151: A552 (Abstract).
26. Tremblay L, Valenza F, Ribeiro SP, Li J & Slutsky AS (1997). Injurious ventilatory strategies increase cytokines and c-fos mRNA expression in an isolated rat lung model. Journal of Clinical Investigation, 99: 944-952.
27. von Bethman AN, Brasch F, Nusing R, Vogt K, Volk HD, Muller KM, Wendel A & Uhlig S (1998). Hyperventilation induces release of cytokines from perfused mouse lung. American Journal of Respiratory and Critical Care Medicine, 157: 263-272.
28. Chiumello D, Pristine G & Slutsky AS (1999). Mechanical ventilation affects local and systemic cytokines in an animal model of acute respiratory distress syndrome. American Journal of Respiratory and Critical Care Medicine, 160: 109-116.

Figure 1. PaO₂, PaCO₂, and pH in the three groups at baseline and after 2 and 4 h of mechanical ventilation. After 4 h, PaO₂ was lower in group 3 (V_T = 42 ml/kg). PaCO₂ and pH were similar for all groups throughout the experiment. *P<0.05 compared to groups 1 and 2 (one-way rank analysis of variance). V_T = tidal volume.

Figure 3. Baseline TNF-a levels in the three groups. After 4 h, the baseline TNF-a was higher in group 3 (V_T = 42 ml/kg) compared with group 1 (V_T = 21 ml/kg) and group 2 (V_T = 7 ml/kg). *P<0.05 (one-way rank analysis of variance).

Figure 4. Serum TNF-a levels in the three groups. After 4 h, although serum TNF-a was higher in group 3 (V_T = 42 ml/kg) compared with group 1 (V_T = 21 ml/kg) and group 2 (V_T = 42 ml/kg), it did not reach statistical significance (one-way rank analysis of variance).

Correspondence and Footnotes

Publication Dates

Publication in this collection
08 Feb 2002
Date of issue
Feb 2002

History

Received
22 Mar 2001
Accepted
14 Sept 2001

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1. Esteban A, Anzueto A, Alía I, Gordo F, Apezteguía C, Pálizas F, David C, Goldwasser R, Soto L, Bugedo G, Rodrigo C, Pimentel J, Raimondi G & Tobin M (2000). How is mechanical ventilation employed in the intensive care unit? An international utilization review. American Journal of Respiratory and Critical Care Medicine, 161: 1450-1458.

[2] 2. Parker JC, Hernandez LA & Peevy KJ (1993). Mechanisms of ventilator-induced lung injury. Critical Care Medicine, 21: 131-143.

[3] 3. Parker JC, Townsley MI, Rippe B, Taylor AE & Thigpen J (1984). Increased microvascular permeability in dog lungs due to high peak airway pressures. Journal of Applied Physiology, 57: 1809-1816.

[4] 4. Woo SW & Hedley-Whyte J (1972). Macrophage accumulation and pulmonary edema due to thoracotomy and lung overinflation. Journal of Applied Physiology, 33: 14-21.

[5] 5. Dreyfuss D, Basset G, Soler P & Saumon G (1985). Intermittent positive-pressure hyperventilation with high inflation pressures produces pulmonary microvascular injury in rats. American Review of Respiratory Disease, 132: 880-884.

[6] 6. Dreyfuss D & Saumon G (1993). Role of tidal volume, FRC, and end-inspiratory volume in the development of pulmonary edema following mechanical ventilation. American Review of Respiratory Disease, 148: 1194-1203.

[7] 7. Slutsky AS & Tremblay LN (1998). Multiple system organ failure. Is mechanical ventilation a contributing factor? American Journal of Respiratory and Critical Care Medicine, 157: 1721-1725.

[8] 8. Pelosi P, Crotti S, Brazzi L & Gattinoni L (1996). Computed tomography in adult respiratory distress syndrome: what has it taught us? European Respiratory Journal, 9: 1055-1062.

[9] 9. Argiras EP, Blakeley CR, Dunnil MS, Otremski S & Sykes MK (1987). High PEEP decreases hyaline membrane formation in surfactant deficient lungs. British Journal of Anaesthesia, 5: 1278-1285.

[10] 10. Muscedere JG, Mullen JBM, Gan K, Bryan AC & Slutsky AS (1994). Tidal ventilation at low airway pressures can augment lung injury. American Journal of Respiratory and Critical Care Medicine, 149: 1327-1334.

[11] 11. Hickling KG, Walsh J, Henderson S & Jackson R (1994). Low mortality rate in adult respiratory distress syndrome using low-volume, pressure-limited ventilation with permissive hypercapnia: a prospective study. Critical Care Medicine, 22: 1568-1578.

[12] 12. Amato MBP, Barbas CSV, Medeiros DMM, Magaldi RB, Schettino GPP, Lorenzi-Filho G, Kairalla RA, Deheinzelin D, Munoz C, Oliveira R, Takagaki TY & Carvalho CRR (1998). Effect of a protective-ventilation strategy on mortality in the acute respiratory distress syndrome. New England Journal of Medicine, 338: 347-354.

[13] 13. The Acute Respiratory Distress Syndrome Network (2000). Ventilation with lower tidal volumes as compared with traditional tidal volumes for acute lung injury and the acute respiratory distress syndrome. New England Journal of Medicine, 342: 1301-1308.

[14] 14. Kawano T, Mori S, Cybulsky M, Burger R, Ballin A, Cutz E & Bryan AC (1987). Effect of granulocyte depletion in a ventilated surfactant-depleted lung. Journal of Applied Physiology, 62: 27-33.

[15] 15. Imai YT, Kawano T, Miyasaka K, Takata M, Imai T & Okuyama K (1994). Inflamatory chemical mediators during conventional ventilation and during high frequency oscillatory ventilation. American Journal of Respiratory and Critical Care Medicine, 150: 1550-1554.

[16] 16. Takata M, Abe J, Tanaka H, Kitano Y, Doi S, Kohsaka T & Miysaka K (1997). Intraalveolar expression of tumor necrosis factor-alpha gene during conventional and high-frequency ventilation. American Journal of Respiratory and Critical Care Medicine, 156: 272-279.

[17] 17. Lowry O, Rosebrough NJ, Farr AL & Randall RJ (1951). Protein measurement with the Folin phenol reagent. Journal of Biological Chemistry, 193: 265-275.

[18] 18. Webb HH & Tierney DF (1974). Experimental pulmonary edema due to intermittent positive pressure ventilation with high inflation pressures. Protection by positive end-expiratory pressure. American Review of Respiratory Disease, 110: 556-565.

[19] 19. Kolobow T, Moretti MP, Fumagalli R, Mascheroni D, Prato P, Chen V & Joris M (1987). Severe impairment in lung function induced by high peak airway pressure during mechanical ventilation. An experimental study. American Review of Respiratory Disease, 135: 312-315.

[20] 20. Tierney DF & Johnson RP (1965). Altered surface tension of lung extracts and lung mechanics. Journal of Applied Physiology, 20: 1253-1260.

[21] 21. Ito Y, Veldhuizen RAW, Yao L, McCaig LA, Bartlett AJ & Lewis JF (1997). Ventilation strategies affect surfactant aggregate conversion in acute lung injury. American Journal of Respiratory and Critical Care Medicine, 155: 493-499.

[22] 22. Egan EA, Nelson RM & Oliver RE (1976). Lung inflation and alveolar permeability to nonelectrolytes in the adult sheep in vivo Journal of Physiology, 260: 409-424.

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