Joanne Favuzza

Neutrophil mediated remote organ injury after lower torso ischemia and reperfusion is selectin and complement dependent

BACKGROUND Lower torso ischemia and reperfusion leads to remote organ leukosequestration and injury. We now examine the intermediary role of selectins and complement in mediating lung and liver injury after hindlimb ischemia. METHODS Mice underwent a 2-hour bilateral tourniquet hind-limb ischemia followed by 3 hours of reperfusion. RESULTS Neutrophil depletion significantly decreased lung vascular permeability index (PI), measured by the extravasation of 125I-albumin, and liver injury as assessed by serum alanine aminotransferse levels. Lung PI and serum alanine aminotransferse levels were also reduced in mice treated with recombinant soluble P-selectin glycoprotein ligand-immunoglobulin fusion protein. Complement inhibition with soluble complement receptor type 1 decreased lung PI and serum alanine aminotransferse levels. C5-deficient mice exhibited a similar decrease in lung PI and liver injury. Lung and liver injury were restored in C5-deficient mice reconstituted with wild-type serum. CONCLUSION Remote organ injury after lower torso reperfusion is selectin and complement dependent.

Skeletal muscle reperfusion injury is mediated by neutrophils and the complement membrane attack complex

The relative inflammatory roles of neutrophils, selectins, and terminal complement components are investigated in this study of skeletal muscle reperfusion injury. Mice underwent 2 h of hindlimb ischemia followed by 3 h of reperfusion. The role of neutrophils was defined by immunodepletion, which reduced injury by 38%, as did anti-selectin therapy with recombinant soluble P-selectin glycoprotein ligand-immunoglobulin (Ig) fusion protein. Injury in C5-deficient and soluble complement receptor type 1-treated wild-type mice was 48% less than that of untreated wild-type animals. Injury was restored in C5-deficient mice reconstituted with wild-type serum, indicating the effector role of C5-9. Neutropenic C5-deficient animals showed additive reduction in injuries (71%), which was lower than C5-deficient neutrophil-replete mice, indicating neutrophil activity without C5a. Hindlimb histological injury was worse in ischemic wild-type and C5-deficient animals reconstituted with wild-type serum. In conclusion, the membrane attack complex and neutrophils act additively to mediate skeletal muscle reperfusion injury. Neutrophil activity is independent of C5a but is dependent on selectin-mediated adhesion.

Intestinal ischemia-reperfusion injury is mediated by the membrane attack complex.

BACKGROUND The dependence of intestinal ischemia-reperfusion injury on the classical complement pathway has been shown with the complement antagonist (sCR1) and complement-specific knockout mice. Using C5 deficient mice, we show that the membrane attack complex mediates local injury. METHODS Mice underwent intestinal ischemia-reperfusion. Albumin leak and histologic evidence were compared in wildtype mice, wildtypes treated with sCR1, neutrophil-depleted wildtypes, C5-deficient mice, and C5-deficient mice reconstituted with wildtype serum. Neutrophil tissue levels in injured C5-deficient and wildtype intestines were compared. RESULTS C5-deficient mice had a reduction in injury similar to mice treated with sCR1. Injury was restored by reconstitution with wildtype serum. Wildtype injury was unaffected by neutrophil depletion. Injured intestines of C5-deficient and wildtype mice had similar neutrophil levels. Immunohistochemistry of wildtype and reconstituted C5-deficient mice demonstrated injured intestinal epithelium although C5-deficient mice and sCr1-treated mice were similar to sham mice. CONCLUSIONS C5-deficient animals are protected from local injury. Injury is unaffected by neutrophil depletion, and the presence of neutrophils in injured tissue is independent of C5. Local injury is C5 dependent, but the action of C5a on granulocytes is not required. Therefore the membrane attack complex mediates local injury.

Hemostasis in the Absence of Clotting Factors

BACKGROUND This study tests whether the hemostatic action of poly-N-acetyl glucosamine (p-GlcNAc) fiber material involves vasoconstrictor release leading to closure of an aortic laceration. METHODS A 22-gauge cannula was inserted into an infrarenal aortic segment of a rat. Surrounding ligatures were tied, and the aorta was flushed with 60 mL of saline from a reservoir held at 80 cm. A 23-gauge aortic puncture was made. The time taken to empty the reservoir was recorded. RESULTS Control patches led to an emptying time of 295 seconds, whereas p-GlcNAc patches increased this time to greater than 600 seconds. Ten minutes after patch removal, the emptying time decreased to 330 seconds. The rats were treated intravenously with endothelin receptor antagonists BQ-485 or JKC-301. The emptying time shortened to control values, despite the use of the p-GlcNAc fiber-based patch. CONCLUSION The mechanism of hemostasis by poly-N-acetyl glucosamine involves endothelin release independent of formed elements of blood.

Comparison of the effects of a 50% exchange-transfusion with albumin, hetastarch, and modified hemoglobin solutions

We compared the hemodynamic effects of replacing 50% of the blood volume of anesthetized rats with an equal volume of five solutions: human serum albumin (HSA), hetastarch, unmodified hemoglobin, diaspirin-crosslinked hemoglobin, and o-raffinose-crosslinked hemgolobin. Control rats were exchange-transfused with their own blood. HSA and hetastarch caused a severe reduction in systemic vascular resistance (SVR), hypotension, and acute renal failure immediately after the exchange-transfusion. Unmodified and diaspirin-crosslinked hemoglobins caused comparable and severe increases in SVR, whereas vasoconstriction induced by o-raffinose-crosslinked hemoglobin was minimal. The increased SVR induced by all hemoglobin solutions resolved over a 2-day period as the hemoglobin was cleared from plasma. Body weight was monitored for 5 days after the exchange transfusion as a measure of the relative long-term efficacy of the exchange solutions tested and increased substantially in control rats (that received blood). Rats that received both crosslinked hemoglobin solutions gained a comparable amount of weight as the control group. By contrast rats that received HSA, hetastarch and unmodified hemoglobin failed to gain weight or lost weight over the same period. In i) HSA and hetastarch are relatively ineffective as resuscitative fluids when administered after the loss of a large volume of blood; ii) diaspirin-crosslinked hemoglobin causes severe vasoconstriction, comparable in intensity to that induced by unmodified hemoglobin; iii) o-raffinose-crosslinked hemoglobin induces minimal vasoconstriction; iv) the vasoactive effects of all hemoglobin solutions are reversible. We conclude, that of all solutions tested, both the short- and long-term effects of an exchange-transfusion with whole blood are most closely reproduced by an exchange with o-raffinose-crosslinked hemoglobin.

Mast cells mediate complement activation after acid aspiration.

A significant role for the alternative complement pathway in acid aspiration has been demonstrated by the observation that C3 but not C4 genetic knockout mice are protected from permeability edema. Using mast cell-deficient mice (W/Wv), we tested the hypothesis that mast cells mediate complement activation after acid aspiration. Tracheostomy tubes were placed in anesthetized mice and 2 mL/kg 0.1 N HCL was instilled in the trachea. After 4 h, extravasation of 125I-albumin was used to calculate lung vascular permeability. The serum alternative complement pathway hemolytic activity was examined, and lung immunohistochemistry was performed. Lung permeability in W/Wv mice was 62% less than that of mast cell sufficient (+/+) animals and similar to +/+ mice treated with the chymase inhibitor chymostatin (65% decrease). Treatment of +/+ mice with D-PRO2,D-TRP(7,9)-Substance P, an antagonist to the neuropeptide substance P, reduced injury by 66%. Serum complement hemolytic activity was intact in injured w/wv mice and +/+ animals treated with chymostatin or dpdt-sp, but was decreased to 65% in the injured untreated +/+ group. Alveolar C3 deposition was intense in injured untreated +/+ mice but absent in the other groups. We interpret these data to indicate that mast cells mediate complement activation, via chymase degranulation, after acid aspiration. This mast cell activity likely is regulated by the release of substance P.