Human Acute Respiratory Distress Syndrome Research Articles

Heterogeneous expression of cell adhesion molecules by endothelial cells in ARDS.

ARDS (acute respiratory distress syndrome) can be associated with septic shock and multiple organ failure caused by an uncontrolled systemic inflammatory response to Gram-negative bacterial infection. While in animal models the key role of the endothelial adhesion molecules ICAM-1, E-selectin, and VCAM in ARDS has been extensively studied, there are scarcely any corresponding pathomorphological studies of human lung tissue. Hence, little is known about whether there is a comparable, or even heterogeneous, expression pattern of these molecules in the human pulmonary vasculature. This study was therefore undertaken to investigate the immunohistochemical expression of the constitutively expressed PECAM (CD31) and the inducible molecules ICAM-1, E-selectin, and VCAM in ARDS lungs from patients who had died in septic shock induced by Gram-negative bacteria. While in all specimens (ARDS and normal lungs) there was homogeneous strong expression of PECAM in all vessels, ICAM-1 was clearly up-regulated in ARDS lungs. E-selectin and VCAM were not expressed by endothelial cells (ECs) in normal lungs, but in ARDS lungs there was strong expression of both molecules in larger vessels, while in the capillaries there was only mosaic-like weak expression of a few ECs. This immunohistochemical investigation demonstrates the induction and up-regulation of adhesion molecules in human ARDS lungs, comparable to that described in animal models. There is also markedly heterogeneous expression of E-selectin and VCAM, indicating toporegional differences in the function of pulmonary ECs.

Respiratory Reovirus 1/L Induction of Diffuse Alveolar Damage: Pulmonary Fibrosis Is Not Modulated by Corticosteroids in Acute Respiratory Distress Syndrome in Mice

Acute respiratory distress syndrome (ARDS) is a clinical syndrome characterized by diffuse alveolar damage (DAD) secondary to an intense host inflammatory response of the lung to a pulmonary or extrapulmonary infectious or noninfectious insult. We have previously described a unique animal model in which CBA/J mice infected with reovirus 1/L develop ARDS. This model recapitulates the histopathological changes observed in human ARDS, which consist of the overlapping phases of exudation, including the formation of hyaline membranes, regeneration, and healing via repair with fibrosis. In this report, we show that the development of DAD in the acute phase of the disease and intraalveolar fibrosis in the late phase of the disease was not modulated by treatment with methylprednisolone (MPS). In the presence or absence of MPS, the majority of cells infiltrating the lungs after reovirus 1/L infection were polymorphonuclear leukocytes and macrophages. A number of key proinflammatory and anti-inflammatory cytokines/chemokines that are observed in the BAL fluid of ARDS patients were also found in the lungs of mice after reovirus 1/L infection and were not modulated by MPS. These include interferon-γ, interleukin-10, and monocyte chemoattractant protein. The histopathology, cytokine/chemokine expression, and response to corticosterids in reovirus 1/L-induced ARDS are similar to what is observed in human patients, making this a clinically relevant model.

Respiratory Reovirus 1/L Induction of Diffuse Alveolar Damage: A Model of Acute Respiratory Distress Syndrome

Acute respiratory distress syndrome (ARDS) is a clinical syndrome that is characterized by diffuse alveolar damage usually secondary to an intense host inflammatory response of the lung to a pulmonary or extrapulmonary infectious or noninfectious insult. In this report we describe a unique animal model in which CBA/J mice infected with reovirus serotype 1, strain Lang develop ARDS. This model recapitulates the histopathological changes observed in human ARDS, which consists of the overlapping phases of exudation including the formation of hyaline membranes, regeneration, and healing via resolution and/or repair with fibrosis. While the consequences of a number of infectious and noninfectious insults in various animal systems have been developed as models of human ARDS, they are models of acute lung injury and are of short-term duration. Therefore, they do not recapitulate all of the clinical and pathological phases observed in human ARDS. Thus, study of the cellular and molecular factors involved in these distinct phases of the disease have been limited. Reovirus 1/L infection of CBA/J mice will allow investigations of the pathophysiology of ARDS as it progresses from the initial stages of edema and neutrophilia to fibrotic lesion development in late stages.

Inducibility of the 70 kD Heat Shock Protein in Peripheral Blood Monocytes Is Decreased in Human Acute Respiratory Distress Syndrome and Recovers Over Time

The heat shock/stress proteins (HSP), and, in particular, the inducible, cytosolic Hsp70, represent an extremely conserved response to many different cellular injuries, including reactive oxygen species (ROS). Hsp70 has been shown to confer to cells and tissues protection against the deleterious effects of ROS or cytokines, both in vitro and in animal models of acute respiratory distress syndrome (ARDS). We hypothesized that Hsp70 expression levels in peripheral blood monocytes (PBM) of patients with ARDS, would correlate with disease severity. We prospectively included 13 patients with previous ARDS (50 +/- 17 yr; range, 20 to 76 yr), nine ventilated patients with non-ARDS/ALI disease (45 +/- 20 yr; range, 19 to 76 yr), and 14 healthy volunteers (45 +/- 20 yr; range, 22 to 77 yr). PBM activation state was evaluated according to their membrane expression of CD16, and oxidative status according to plasma lipid peroxidation products. Both baseline expression and Hsp70 inducibility (after in vitro heat shock) were examined in PBM, using flow cytometric analysis. We found that basal expression of Hsp70 in PBM was similar for patients and control subjects, whereas Hsp70 inducibility- a reflection of the ability to mount a stress response-was significantly reduced in the patients with ARDS (p = 0. 02). Among all correlation analyses we considered between Hsp70 inducibility on the one hand, clinical and laboratory biomarkers for disease severity and outcome in the patients with ARDS on the other, only the duration of ventilatory support was significant (p < 0.003). As an approach to distinguish between disease and ventilation, we also analyzed a group of, ventilated patients without ARDS. Our results indicate that in patients with ARDS, Hsp70 inducibility in PBM is decreased, but it recovers over time with duration of ventilatory support.

Aerosolized endotoxin is immediately bound by pulmonary surfactant protein D in vivo

Collectins are carbohydrate binding proteins that are implicated in innate host defense. The lung collectins, surfactant proteins A and D (SP-A and SP-D), bind a variety of pathogens in vitro and influence phagocytosis by alveolar macrophages. In this report we show that SP-D binds endotoxin (lipopolysaccharide, LPS) in vivo in a rat model of acute respiratory distress syndrome (ARDS). Intratracheal aerosolization of LPS in rats resulted in the typical features of human ARDS. Total amounts of SP-D, as well as the carbohydrate binding properties of SP-D were measured in lung lavage as a function of time. The amount of SP-D did not change during 24 h. Interestingly, SP-D in lung lavage isolated from rats during the first 2 h after LPS treatment, was not able to bind to carbohydrate. Further analysis revealed that the carbohydrate binding sites of SP-D were occupied by LPS, suggesting that SP-D is an LPS scavenging molecule in vivo. Electron microscopic analysis indicated that, 1 h after LPS aerosolization, aggregates of SP-D with LPS were found in lysosomal structures in alveolar macrophages. We conclude that the lung collectin SP-D binds inhaled endotoxin in vivo, which may help to protect the lung from endotoxin-induced disease.

Human circulating eosinophils secrete macrophage migration inhibitory factor (MIF). Potential role in asthma.

Macrophage migration inhibitory factor (MIF) is a potent proinflammatory mediator that has been shown to potentiate lethal endotoxemia and to play a potentially important regulatory role in human acute respiratory distress syndrome (ARDS). We have investigated whether eosinophils are an important source of MIF and whether MIF may be involved in the pathophysiology of asthma. Unstimulated human circulating eosinophils were found to contain preformed MIF. Stimulation of human eosinophils with phorbol myristate acetate in vitro yielded significant release of MIF protein. For example, eosinophils stimulated with phorbol myristate acetate (100 nM, 8 h, 37 degreesC) released 1,539+/-435 pg/10(6) cells of MIF, whereas unstimulated cells released barely detectable levels (< 142 pg/10(6) cells, mean+/-SEM, n = 8). This stimulated release was shown to be (a) concentration- and time-dependent, (b) partially blocked by the protein synthesis inhibitor cycloheximide, and (c) significantly inhibited by the protein kinase C inhibitor Ro-31,8220. In addition, we show that the physiological stimuli C5a and IL-5 also cause significant MIF release. Furthermore, bronchoalveolar lavage fluid obtained from asthmatic patients contains significantly elevated levels of MIF as compared to nonatopic normal volunteers (asthmatic, 797.5+/-92 pg/ml; controls, 274+/-91 pg/ml). These results highlight the potential importance of MIF in asthma and other eosinophil-dependent inflammatory disorders.

Aspects actuels du syndrome de détresse respiratoire aiguë de l'enfant

Acute respiratory distress syndrome (ARDS) is a frequent condition in pediatric intensive care units. The mortality remains high despite advances in conventional mechanical ventilation and aetiological treatment. Several animal studies have documented lung injury during mechanical ventilation with high tidal volume, and clinical investigations have shown that in human ARDS, most ventilation is distributed to the small areas of remaining aerated lung resulting in overdistension of these areas and lung injury (“baby lung” theory). Nevertheless the usefulness of extrapulmonary gas exchange remains much debated. New ventilatory strategies have been developped in order to reduce ventilator-induced lung injury and to improve systemic oxygenation but multicentric randomized clinical trials are needed before these strategies can be validated.

Clinical lessons from an experimental model of ARDS.

The oleic acid (OA) lung injury model is one of the most common laboratory methods for studying the acute respiratory distress syndrome (ARDS) in experimental animals. Many features of the model mimic the pathophysiology of ARDS in humans, despite obvious differences in pathogenesis. Thus, the OA lung injury model has been used extensively to study the consequence of lung injury and to evaluate potential new treatment strategies.