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The Microcirculation in Trauma and Sepsis

The microcirculation plays a vital part for fluid-, gas- and solute-exchange, and changes in permeability during trauma or sepsis, that are in part necessary for the natural healing process, may also cause hypovolemia and edema formation, leading to disturbances in microvascular exchange. This thesis discusses changes is microvascular flow, permeability and plasma volume (PV) loss after experimental or surgical trauma and experimental sepsis. We evaluated the effect of blunt skeletal muscle trauma itself and thereafter treatment with prostacyclin (PGI2) on PV-loss, transcapillary escape rate (TER) of 125I-albumin and cytokine release. In experimental sepsis, we studied the importance of charge for microvascular permeability and observed the effectiveness of albumin versus Ringer's acetate compared to a hemorrhage model. Perioperatively, we evaluated changes in the sublingual microcirculation in patients undergoing major abdominal surgery, using Sidestream Darkfield-imaging (SDF) in relation to outcome. Skeletal muscle trauma caused PV-loss, increase in permeability and cytokine release and PGI2-treatment attenuated these changes. Sepsis led to a breakdown of the negatively charged glycocalix, which is probably important for the normally low permeability of albumin. The plasma volume expanding effect of albumin as compared to Ringer's acetate was independent of the state of permeability. Perioperative changes in the sublingual microcirculation during major abdominal surgery are minor with no correlation to outcome or parameters reflecting global oxygen delivery

Plasma Volume Expansion with 5% Albumin Compared to Ringer's Acetate during Normal and Increased Microvascular Permeability in the Rat.

It is believed that the effectiveness of colloids as plasma volume expanders is dependent on the endothelial permeability for macromolecules. The objective of this study was to test the hypothesis that the plasma volume expanding effect of 5% albumin relative to that of a crystalloid solution is reduced if microvascular permeability is increased

Changes in the sublingual microcirculation during major abdominal surgery and post-operative morbidity.

Little is known about perioperative microcirculatory changes during major abdominal surgery, and the main objectives of this study were to evaluate perioperative microcirculatory alterations in this setting, and if changes in microcirculatory parameters are associated with post-operative morbidity and/or with changes in parameters reflecting oxygen delivery

Effect of charge on microvascular permeability in early experimental sepsis in the rat.

A key feature of sepsis is hypovolemia due to increased microvascular permeability. It has been suggested that the negative charge of albumin and of the endothelial glycocalyx is important for maintenance of the normally low permeability for albumin. Here we tested the hypothesis that charge effects contribute to the increased permeability in sepsis. Transcapillary escape rate (TER) and initial distribution volume for (125)I-labeled bovine serum albumin (BSA, isoelectric point pH 4.6) and for (131)I-labeled charge modified BSA (cBSA, average isoelectric point, pH 7.1) was measured 3h after sepsis was induced by cecal ligation and incision (CLI) (n=11) and in control animals (n=12). The importance of charge for permeability in sepsis was estimated by comparing the ratio between TER for cBSA and TER for BSA during control conditions to that after CLI. Plasma concentration of the glycocalyx component glycosaminoglycans (GAGs) was measured in separate control and CLI animals. The initial distribution volume for BSA and cBSA in control animals was 38±3ml/kg and 47±4mL/kg and decreased by 17% and 19%, respectively, following CLI. TER for BSA increased from 16.7±4.1% in the controls to 20.1±1.9% following CLI. Corresponding values for cBSA were 26.7±5.6% and 29.8±3.5%, respectively. The ratio between TER for cBSA and TER for BSA was 1.62±0.1 in the control group and 1.49±0.1 following CLI (p<0.05). Plasma GAG concentrations were higher in CLI animals than in the control group. We conclude that CLI induce hypovolemia secondary to increased microvascular permeability. Negative charge contributes to the normally low permeability of albumin and the importance of charge is decreased in early experimental sepsis. The observed charge effects are associated with CLI-induced breakdown of the glycocalyx

Prostacyclin reduces plasma volume loss after skeletal muscle trauma in the rat.

BACKGROUND: Trauma induces transcapillary leakage of fluid and proteins because of increased microvascular permeability. Based on studies showing that prostacyclin (PGI2) has permeability-reducing properties, in the present study, we investigated whether PGI2 reduces plasma volume (PV) loss after a nonhemorrhagic trauma. METHODS: The study was performed on anesthetized Sprague-Dawley rats exposed to a controlled standardized blunt trauma to the abdominal rectus muscle. Thereafter, the animals were randomized to treatment with either PGI2 (2 ng/kg per minute) or 0.9% NaCl. PV was estimated before and 3 hours after the trauma using I-albumin as tracer. In separate experiments, the transcapillary escape rate of I-albumin was calculated and plasma concentrations of cytokines were measured after both treatments. RESULTS: Average PV at baseline was 41.6 mL/kg ± 2.5 mL/kg and 42.3 mL/kg ± 1.7 mL/kg in the PGI2 and NaCl animals, respectively. PV was decreased by 22% ± 8% in the NaCl animals and by 11% ± 9% in the PGI2 animals 3 hours after the trauma (p < 0.05). Trauma induced a decrease in mean arterial blood pressure and an increase in hematocrit in both groups. There were no differences in urine production and mean arterial blood pressure between the PGI2 and NaCl animals. The transcapillary escape rate for albumin was calculated for one hour starting 30 minutes after the trauma and was 15.1% ± 2.4% per hour in the PGI2 animals and 17.4% ± 3.3% per hour in the NaCl animals (p = 0.09). Interleukin 6 concentration 3 hours after the trauma was lower in the PGI2 animals than in the NaCl animals (p < 0.05). CONCLUSION: We conclude that PGI2 attenuates PV loss after blunt muscle trauma. The vascular effects of PGI2 are associated with a modulation of the trauma-induced inflammatory response

A Model for Evaluating the Effects of Blunt Skeletal Muscle Trauma on Microvascular Permeability and Plasma Volume in the Rat

The objective of the present study was to develop an experimental model suitable for studying the effects of a nonhemorrhagic soft tissue trauma on plasma volume (PV) and microvascular permeability. Anesthetized Sprague-Dawley rats were exposed to a sham procedure or a laparotomy followed by a standardized trauma to the abdominal rectus muscle. We evaluated the effects of trauma on transcapillary escape rate and on PV (3 h after trauma) using I-125-albumin as tracer and on edema formation in the traumatized muscle with a wet- versus dry- weight method. The effects of the trauma on the cytokines IFN-gamma, IL-4, IL-6, IL-10, and TNF-alpha were investigated 1 and 3 h after trauma in a separate group. Transcapillary escape rate was 13.9% per hour in the sham animals compared with 18.5% per hour in the traumatized animals (P < 0.05). Because arterial and venous blood pressures were not altered by the trauma, the change in transcapillary escape rate most likely reflects a change in microvascular permeability. Plasma volume decreased from 42 mL/kg at baseline to 31 mL/kg at the end of the experiments (P < 0.05) in the trauma group, whereas PV remained unchanged in the sham group. Only 15% of the PV loss could be referred to edema in the traumatized muscle. Trauma induced a significant increase in IL-6 and IL-10 after 1 h. We conclude that the present nonhemorrhagic trauma induces an increase in microvascular permeability in the traumatized tissue and in other parts of the body, resulting in hypovolemia. The model may be used for the evaluation of different therapeutic interventions aimed at the correction of hypovolemia