INSULIN ATTENUATES THE SYSTEMIC INFLAMMATORY RESPONSE IN AN ANIMAL TRAUMA MODEL

Abstract

Introduction: The beneficial effects of insulin in the maintenance of normoglycaemia in non-diabetic myocardial infarct and intensive care patients have recently been reported. Hyperglycaemia and neutrophilia have been shown to be independent prognostic indicators of poor outcome in the traumatised patient. The role of insulin and the maintenance of normoglycaemia in the trauma patient have as yet not been explored. We hypothesised that through the already described anti-inflammatory effects of insulin and the maintenance of normoglycaemia, that the systemic inflammatory response would be attenuated, in the injured patient. This might result in less adult respiratory distress syndrome (ARDS) and multi-organ dysfunction and therefore less morbidity and mortality in trauma patients.

Materials and Methods: We used a previously validated rodent trauma model. There were 3 groups, two groups underwent bilateral femur fracture and 15% blood loss via cannulation and aspiration of the external jugular vein. The third group were anaesthetised only. The treatment group immediately receive subcutaneous insulin according to a recently identified sliding scale, and thereafter subcutaneous boluses, dependent on ½ hourly blood sugar estimations. The control groups received the same volume of normal saline ½ hourly, subcutaneously. The animals were maintained under anaesthetic for 4 hours from injury via inhaled isoflurane and oxygen. Core temperature and O2 saturations were recorded throughout. At 4 hours, each animal underwent midline laparotomy and cannulation of the IVC for blood sampling for full blood counts and lactate levels. Serum was also taken for flow cytometric analysis of neutrophil activation via respiratoy burst and CD11b levels. Broncho-alveolar lavage (BAL) was performed for neutrophil content and total protein estimation. The left lower lobe was harvested for wet-dry lung weight ratios.

Results: While O2 saturations were equal throughout in both groups, respiratory rates were persistently elevated in the controls. Wet:Dry lung weight ratios (p< 0.05) and lactate levels were reduced in the insulin treated animals compared to controls. There were similiarly fewer neutrophils in the BAL specimens of the insuliln treated animals compared to injured controls (p< 0.05).

Conclusions: Insulin reduces leukocyte lung sequestration in the injured animal model. This work confirms that insulin may have a role in reducing ARDS in the trauma patient, be that as an anti-inflammatory agent or anti-hyperglycaemic agent, or both, indicating that outcomes might be improved by treating hyperglycaemic trauma patients with insulin. Further work needs to done to elucidate its exact mechanism of action and role in the injured patient.