Mitochondrial respiratory function and reperfusion injury during pulmonary preservation

Early organ-specific mitochondrial dysfunction of jejunum and lung found in rats with experimental acute pancreatitis

INTRODUCTION

Multiple organ dysfunction is the main cause of death in severe acute pancreatitis. Primary mitochondrial dysfunction plays a central role in the development and progression of organ failure in critical illness. The present study investigated mitochondrial function in seven tissues during early experimental acute pancreatitis.

METHODS

Twenty-eight male Wistar rats (463 ± 2 g; mean ± SEM) were studied. Group 1 (n= 8), saline control; Group 2 (n= 6), caerulein-induced mild acute pancreatitis; Group 3 (n= 7) sham surgical controls; and Group 4 (n= 7), taurocholate-induced severe acute pancreatitis. Animals were euthanased at 6 h from the induction of acute pancreatitis and mitochondrial function was assessed in the heart, lung, liver, kidney, pancreas, duodenum and jejunum by mitochondrial respirometry.

RESULTS

Significant early mitochondrial dysfunction was present in the pancreas, lung and jejunum in both models of acute pancreatitis, however, the Heart, liver, kidney and duodenal mitochondria were unaffected.

CONCLUSIONS

The present study provides the first description of early organ-selective mitochondrial dysfunction in the lung and jejunum during acute pancreatitis. Research is now needed to identify the underlying pathophysiology behind the organ selective mitochondrial dysfunction, and the potential benefits of early mitochondrial-specific therapies in acute pancreatitis.

Influence of Inflated Lung Pressure on Lung Mechanical Properties during Cold Storage in Rats

The degree of lung inflation pressure during cold storage has a deep connection with lung functions after reperfusion. However, the change of the lung mechanical properties during cold storage at the different lung inflation pressure is unknown. We investigated the change of the mechanical properties both at the organ and the tissue level under different inflated lung pressure soon after the cold storage. In group I, the lungs were not preserved. In group II, the lungs were preserved in deflated condition. In groups III and IV, the lungs were inflated with room air at pressures of 14 and 25 cm H2O. After 24-hour storage, the input impedance (Z) was measured by a computer-controlled small animal ventilator (n = 8 each group). All data were analyzed using a homogeneous linear model, which includes airway resistance (R(aw)), tissue elastance (H), and tissue damping (G). Hysteresivity (eta) was calculated as G/H. After Z measurement, the tissue elasticity (Eqs) obtained from the quasi-static stress-strain curve was compared. We also analyzed the biochemical changes of surfactant in bronchoalveolar lavage (BAL) fluid. R(aw )was significantly lower in groups III and IV than in group I (p < 0.01). Hysteresivity (eta) was significantly lower in group IV than in groups I and III (p < 0.05). Eqs was significantly higher in groups III and IV than in groups I and II (p < 0.01). The total protein level in the BAL fluid of the preserved groups was significantly higher compared with group I (p < 0.01). We conclude that hyperinflated storage would deteriorate lung tissue mechanical properties.

Effects of Cold Preservation on the Lung Mechanical Properties in Rats

In lung transplantation, cold preservation is an important process. However, the mechanical changes in the airway and tissue during cold preservation, especially before reperfusion, are unknown. To test the hypothesis that the mechanical changes in the airway and lung parenchyma start during cold preservation, we investigated the mechanical properties of the rat lung as a whole organ and in excised lung strips. In the 0 h group, the lungs were not preserved. In the 9 and 24 h group, the lungs were preserved for 9 and 24 h at 4 degrees C. After preservation, we evaluated the static compliance (Csta) of the whole lung as obtained from the pressure volume curves (n=5 in each group). Also, we measured the input impedance taken by a computer-controlled small-animal ventilator (n=9 in each group). All data were analyzed using a homogeneous linear model, which includes airway resistance (Raw), tissue elastance (H), and tissue resistance (G). Hysteresivity (eta) was calculated as G/H. Moreover, the tissue elasticity (Eqs) obtained from the quasi-static stress-strain curves was compared. There was no significant difference in Csta among the three groups. Raw was significantly lower in the 24 h group than in the 0 h group (p<0.01). Eqs was significantly higher in the preserved groups than in the 0 h group (p<0.01). These results demonstrated that the changes in the three mechanical properties of the airway and the tissue started within 9 h of preservation.