Large volume polymerized haemoglobin solution in a Jehovah's Witness following abruptio placentae.

Severe anaemia, with haemoglobin (Hb) levels < or =3 g dL(-1), is associated with mortality rates of 50-95%. Although accepted transfusion targets have been debated in the literature (Carson et al., 2002; Practice guidelines for blood component therapy. 1996; Consensus Conference. 1988; Hebert et al., 1999), few would argue the risks associated with Hb levels less than 5 g dL(-1) in critically ill patients. In patients who are unable to receive red blood cell transfusions, the utility of Hb solutions is an attractive solution. We describe a Jehovah's Witness patient who exemplifies the marked physiologic derangements of severe anaemia and subsequent clinical resolution with large volume polymerized human Hb transfusion. The Hb-based oxygen carrier, PolyHeme, provided adequate oxygen transport, acting as a bridge until endogenous production could compensate for red cell loss. Practicing physicians need to be aware of current therapeutic options for use in these complicated patients.

Mesenteric lymph is responsible for post-hemorrhagic shock systemic neutrophil priming.

BACKGROUND: Hemorrhagic shock-induced splanchnic hypoperfusion has been implicated as a priming event in the two event model of multiple organ failure (MOF). We have previously shown that early postinjury neutrophil (PMN) priming identifies the injured patient at risk for MOF. Recent in vitro studies have demonstrated that postshock mesenteric lymph primes isolated human neutrophils. We hypothesize that lymphatic diversion before hemorrhagic shock abrogates systemic PMN priming and subsequent lung injury. METHODS: Sprague-Dawley rats (n >or= 5 per group) underwent hemorrhagic shock (MAP 40 mm Hg x 30 min) and resuscitation (shed blood + 2x crystalloid) with and without mesenteric lymphatic duct diversion. Sham animals underwent anesthesia and laparotomy. Whole blood was taken 2 hours after resuscitation, heparinized, and incubated for 5 min at 37 degrees C. Surface expression of CD11b (a marker for PMN priming) was determined by flow-cytometry compared with isotype controls. In addition, lung myeloperoxidase (MPO) was measured for PMN sequestration, and Evans blue lung leak was assessed in the bronchoalveolar lavage fluid in sham, and shock +/- lymph diversion animals. RESULTS: Hemorrhagic shock resulted in increased surface expression of PMN CD11b relative to sham (23.8 +/- 6.7 vs. 9.9 +/- 0.6). Mesenteric lymphatic diversion before hemorrhagic shock abrogated this effect (8.0 +/- 2.6). Lung PMN accumulation, as assessed by MPO, was greater in the lungs of nondiverted (113 +/- 14 MPO/mg lung) versus sham (55 +/- 4 MPO/mg lung, p < 0.05); lymph diversion reduced lung PMNs to control levels (71 +/- 6.5 MPO/mg lung, p < 0.05). Evans blue lung leak was 1.6 times sham in the hemorrhagic shock group; this was returned to sham levels after lymph diversion (p < 0.05). CONCLUSION: Post-hemorrhagic shock mesenteric lymph primes circulating PMNs, promotes lung PMN accumulation, and provokes acute lung injury. Lymphatic diversion abrogates these pathologic events. These observations further implicate the central role of mesenteric lymph in hemorrhagic shock-induced lung injury. Characterizing the PMN priming agents could provide insight into the pathogenesis of postinjury MOF and ultimately new therapeutic strategies.

Hypertonic saline activation of p38 MAPK primes the PMN respiratory burst.

Investigation of hypertonic saline (HTS) modulation of neutrophils (PMN) cytotoxic responses has generated seemingly contradictory results. Clinically relevant levels of HTS attenuate receptor-mediated p38 MAPK signaling, whereas higher levels activate p38 MAPK. Concurrently, HTS exerts a dose-dependent attenuation of the PMN respiratory burst, most notably at concentrations where p38 MAPK is activated. We hypothesized that HTS-mediated p38 MAPK activation augments the PMN respiratory burst on return to normotonicity. We found that although clinically relevant levels of HTS (Na+ > or = 200 mM) did not activate p38 MAPK, higher concentrations (Na+ > or = 300 mM) resulted in activation comparable with that after PAF stimulation. Transient stimulation with high levels of HTS primed the PMN respiratory burst in response to fMLP and PMA. This effect was attenuated by pretreatment with SB 203580, a p38 MAPK specific inhibitor. We conclude that severe osmotic shock primes the respiratory burst via p38 MAPK signaling, further supporting the role of this signaling cascade in PMN priming.

Post-hemorrhagic shock mesenteric lymph lipids prime neutrophils for enhanced cytotoxicity via phospholipase A2.

Hemorrhagic shock induced mesenteric hypoperfusion has long been implicated as a key event in the pathogenesis of the adult respiratory distress syndrome (ARDS) and multiple organ failure (MOF). Previous work links post-hemorrhagic shock mesenteric lymph (PHSML) lipids and neutrophil (PMN) priming in the pathogenesis of ARDS. We hypothesize that gut phospholipase A2 (PLA2) liberates proinflammatory lipids following hemorrhagic shock, which are responsible for enhanced PMN cytotoxicity. Mesenteric lymph was collected from rats (n > or = 5) before hemorrhagic shock, during hemorrhagic shock (MAP 40 mm Hg x 30 min), and after resuscitation (shed blood + 2x lactated Ringers). PMNs were incubated with physiologic concentrations (1-5%, v:v) of (a) buffer control, (b) sham (c) pre-shock lymph, (c) PHSML, (d) PHSML lipid extracts, (e) heat-denatured PSHML, and (f) PHSML harvested after i.v. pretreatment with a known PLA2 inhibitor (quinacrine, 10 mg/kg). PMNs were activated with fMLP (1 micromol), and the maximal rate of superoxide production measured by reduction of cytochrome c. Gut morphology was assessed histologically using hematoxalin and eosin (HE) staining. PHSML and PHSML lipid extracts (5%, v:v) primed for enhanced superoxide production compared to buffer controls (2.5-fold and 3.6-fold), sham (2.5-fold) and pre-shock lymph (2.0-fold). Lymph collected after systemic PLA2 inhibition, in contrast, abrogated the PMN priming response. Gut mucosal morphology, at end-resuscitation, was intact on HE staining both with and without PLA2 inhibition. Heat denaturing the PHSML (eliminating cytokines and complement), on the other hand, did not reduce PMN priming. Physiologic concentrations of PHSML lipids prime the PMN respiratory burst. Lymph priming is diminished with systemic PLA2 inhibition, implicating gut PLA2 as a source of proinflammatory lipids that may be central in the pathogenesis of hemorrhagic shock induced ARDS/MOF.

Phospholipase A(2)--derived neutral lipids from posthemorrhagic shock mesenteric lymph prime the neutrophil oxidative burst.

BACKGROUND: Our previous work identified posthemorrhagic shock mesenteric lymph (PHSML) lipids as key elements in polymorphonuclear neutrophil (PMN)--provoked acute lung injury. We hypothesize that gut phospholipase A(2) (PLA(2)) is responsible for the generation of proinflammatory lipids in PHSML that primes circulating PMNs for enhanced oxidative burst. METHODS: Mesenteric lymph was collected from rats (n = 5) before (preshock), during the induction of hemorrhagic shock (mean arterial pressure, 40 mm Hg x 30 minutes), and at resuscitation (shed blood + 2x lactated Ringer's solution). PLA(2) inhibition (quinacrine, 10 mg/kg, intravenously) was given before shock was induced. Extracted lipids were separated by normal phase high-pressure liquid chromatography and resuspended in albumin. PMNs were exposed to a 5% vol:vol concentration of eluted lipids and activated with N-formyl-methionyl-leucyl-phenylalanine (1 micromol/L). Superoxide production was assessed by cytochrome C reduction. RESULTS: High-pressure liquid chromatography--extracted neutral lipids of lymph collected before hemorrhagic shock did not prime the PMN oxidase, whereas isolated neutral lipids of postshock lymph primed PMNs 2.6- +/- 0.32-fold above baseline (P <.05). PLA(2) inhibition returned PHSML neutral lipid priming to baseline levels. CONCLUSIONS: PLA(2) inhibition before hemorrhagic shock abrogates the neutrophil priming effects of PHSML through reduction of the accumulation of proinflammatory neutral lipids. Identification of these PLA(2)-dependent lipids provides a mechanistic link that may have therapeutic implications for postshock acute lung injury.

Hypertonic saline attenuation of the neutrophil cytotoxic response is reversed upon restoration of normotonicity and reestablished by repeated hypertonic challenge.

BACKGROUND: Hypertonic saline (HTS) resuscitation, in addition to enhancing hemodynamic recovery, modulates postinjury hyperinflammation in the critically injured. The polymorphonuclear neutrophil (PMN) cytotoxic response, a key element in the pathogenesis of postinjury organ dysfunction, is attenuated under hypertonic conditions. Although plasma Na(+) rises to 180 mmol/L after HTS infusion, baseline levels are reestablished within 24 hours. We hypothesized that HTS attenuation of the PMN cytotoxic response (beta2-integrin expression, elastase release, and O2- production) is reversed upon return to normotonicity, but can be reestablished by repeated HTS challenge. METHODS: Isolated human PMNs were incubated in HTS (Na(+) = 180 mmol/L) for 5 minutes at 37 degrees C then returned to normotonicity by centrifugation and resuspension in isotonic buffer. Stimulated (PAF) beta2-integrin expression was measured by flow cytometry. Stimulated (PAF/fMLP) elastase release and O2- production were measured by cleavage of N-methoxysuccinyl-Ala-Ala-Pro-Val p-nitroanilide and reduction of cytochrome c (Cyt c). Protein tyrosine phosphorylation in PMN cell lysates was assessed by Western blot. RESULTS: Clinically relevant levels of HTS induced tyrosine phosphorylation in resting PMNs and attenuated cytotoxic responses. Reestablishment of normotonicity returned these functions to baseline. A repeated HTS challenge after restoration of normotonicity also induced tyrosine phosphorylation and suppressed the cytotoxic response. CONCLUSIONS: HTS attenuation of the PMN cytotoxic response is reversible but can be reestablished by repeated HTS treatment. This phenomenon may provide the unique opportunity to selectively and temporarily decrease the postinjury inflammatory response when patients are at greatest risk for PMN-mediated tissue damage.

Blood transfusion and the two-insult model of post-injury multiple organ failure.

Neutrophils (PMNs) have been implicated in the pathogenesis of multiple organ failure (MOF). The two-insult model of MOF is based on the fundamental concept that two sequential and independent insults that are individually innocuous against the host can cause overwhelming inflammation. The in vitro PMN priming/activation sequence simulates the two-insult model. Our work has demonstrated that transfusion is an early consistent risk factor for post-injury MOF and lysophosphatidylcholines (lyso-PCs) are generated in stored blood components. Additionally, platelet-activating factor (PAF) is a key inflammatory agent produced in severely injured patients. We therefore hypothesize that two events, trauma and transfusion, enhance PMN cytotoxicity irrespective of the sequence. Superoxide (O2-) production was measured by reduction of cytochrome c, adherence to fibrinogen was assessed by the radioactivity of adherent Na2(51)CrO4 (51Cr)-labeled PMNs, and endothelial cell (EC) damage by measuring the radioactivity released from 51Cr-labeled human umbilical vein endothelial cells monolayers. Isolated PMNs were primed with buffer, PAF (2 microM), or lyso-PCs (4.5, 15, and 30 microM) followed by activation with buffer, N-formyl-methionyl-leucyl-phenylalanine (fMLP) (1 microM), PAF (2 microM), or lyso-PCs (4.5, 15, and 30 microM). Neither PAF nor lyso-PCs alone stimulated O2- production. While PAF alone caused PMN adherence, lyso-PCs alone did not allowed PMNs to adhere to fibrinogen. However, both combinations of PAF/lyso-PCs and lyso-PCs/PAF significantly augmented O2- production and PMN adherence. Furthermore, these enhanced PMN cytotoxic responses significantly caused EC damage. These findings suggest that in the scenario of the two-insult model, early or late transfusion administered following trauma can provoke PMN cytotoxicity via priming or activation, thereby increasing the risk of post-injury MOF.

Plasma from aged stored red blood cells delays neutrophil apoptosis and primes for cytotoxicity: abrogation by poststorage washing but not prestorage leukoreduction.

BACKGROUND: Blood transfusion-particularly that of older stored red blood cells (RBCs)--is an independent risk factor for postinjury multiple organ failure. Immunomodulatory effects of RBC transfusion include neutrophil (PMN) priming for cytotoxicity, an effect exacerbated by longer RBC storage times. We have found that delayed PMN apoptosis in trauma patients is provoked by transfusion, independent of injury severity. We hypothesized that aged stored RBCs delay PMN apoptosis, but that prestorage leukodepletion or poststorage washing could abrogate the effect. METHODS: Healthy volunteers each donated 1 unit of blood. One half was leukodepleted, and RBC units were processed in the usual fashion and stored at 4 degrees C. Aliquots were removed on days 1, 14, 21, and 42 and the plasma fraction isolated. Selected aliquots were washed with normal saline before plasma isolation. PMNs harvested from healthy controls were incubated (5% CO2, 37 degrees C) with unmodified, leukoreduced, or washed RBC plasma (20% plasma/80% RPMI 1640), and apoptosis assessed by morphology after 24 hours. Apoptotic index (apoptotic PMNs/total PMNs) was compared. PMN priming for superoxide release was also assessed after plasma exposure. RESULTS: PMN apoptosis was delayed by RBCs stored for 21 or 42 days. Prestorage leukodepletion did not alter the effect. However, washing 42-day-old RBCs abrogated the effect. PMN priming for superoxide was provoked by stored packed RBCs in an identical pattern to delayed apoptosis. CONCLUSION: Plasma from stored RBCs-even if leukoreduced-delays apoptosis and primes PMNs. The effect becomes evident at 21 days and worsens through product outdate (42 days), but may be prevented by poststorage washing. Inflammatory agents contaminating stored blood likely mediate the effect. Modification of transfusion practices (e.g., giving fresher or washed RBCs or blood substitutes) may attenuate adverse immunomodulatory effects of transfusion in trauma patients.

Hypertonic saline alteration of the PMN cytoskeleton: implications for signal transduction and the cytotoxic response.

BACKGROUND: Recognition that hypertonic saline (HTS) modulates the inflammatory response has renewed interest in this agent for postinjury resuscitation. Changes in extracellular tonicity alter cell shape and are accompanied by cytoskeletal reorganization. Recent evidence suggests that cytoskeletal reorganization is critical for receptor-mediated signal transduction. We hypothesized that HTS-induced changes in the cytoskeleton interfere with cytotoxic signal transduction. METHODS: Isolated neutrophils (PMNs) were incubated in HTS (Na+ = 180 mmol/L) and activated with N-formyl-methionyl-leucyl-phenylalanine (receptor-mediated) or phorbol myristate (receptor independent). Actin polymerization was assessed by digital image microscopy and flow cytometry. PMN superoxide anion (O2-) production and p38 MAPK activation was measured by reduction of cytochrome c and Western blot. Pretreatment with cytochalasin B was used to disrupt HTS-induced actin reorganization. RESULTS: HTS inhibited receptor-mediated cytoskeletal reorganization and attenuated p38 MAPK activation and O2- production. HTS had no effect on receptor-independent O2- production. Cytoskeletal disruption (cytochalasin B) prevented HTS attenuation of receptor-mediated p38 MAPK activation. CONCLUSION: HTS attenuates the PMN cytotoxic response by interfering with intracellular signal transduction. Changes in the actin cytoskeleton appear to modulate receptor-mediated p38 MAPK signaling.

Hypertonic saline inhibits neutrophil (PMN) priming via attenuation of p38 MAPK signaling.

Priming of the neutrophil cytotoxic response is central to the pathogenesis of early postinjury multiple organ failure (MOF). Platelet-activating factor (PAF) has been implicated as a key inflammatory mediator in postinjury neutrophil priming and requires p38 MAPK signaling to produce its biologic effects. Hypertonic saline (HTS) resuscitation decreases the postinjury inflammatory response following shock in animals and decreases receptor-mediated neutrophil (PMN) cytotoxic functions in vitro. We hypothesized that HTS attenuates PAF priming of the PMN cytotoxic response by interfering with PAF-mediated p38 MAPK signal transduction. Isolated PMNs were preincubated in isotonic buffer or HTS (Na+ = 180 mM), then primed with PAF. Neutrophil CD11b/CD18 expression was measured by flow cytometry. Receptor-dependent (fMLP), N-formyl-methionyl-leucyl-phenylalanine, fMLP) and receptor-independent (PMA) O2- production was measured by reduction of cytochrome c in resting and PAF primed PMNs. Total p38 MAPK protein PAF-mediated p38 MAPK activation was assessed by western blot of PMN lysates. Clinically relevant levels of HTS attenuated PAF-mediated beta2-integrin expression. While HTS attenuated receptor-dependent (fMLP and PAF/fMLP) O2- production, receptor-independent (PMA) O2- production was unaffected. Conversely, HTS attenuated PAF priming of PMA-mediated O2- production. PAF and HTS did not alter total cellular p38 MAPK content. Clinically relevant levels of HTS alone did not activate p38 MAPK but inhibited PAF mediated p38 MAPK activation. HTS attenuates PAF priming of the PMN cytotoxic response by altering intracellular signal transduction. Therefore, HTS resuscitation may attenuate postinjury PMN priming and ultimately the risk of developing MOF.

The lipid fraction of post-hemorrhagic shock mesenteric lymph (PHSML) inhibits neutrophil apoptosis and enhances cytotoxic potential.

Dysfunctional neutrophil (PMN) apoptosis facilitates hyperinflammatory tissue injury. Previous work has demonstrated that post-hemorrhagic shock mesenteric lymph (PHSML) provokes PMN-mediated acute lung injury in animal models, but the mechanism remains unclear. We have documented that the lipid fraction of PHSML is responsible for PMN priming of the respiratory burst. In this study, we hypothesized that PHSML lipids delay PMN apoptosis and thereby further enhance PMN cytotoxic potential. Mesenteric lymph was collected from rats (n = 5) before (control), during non-lethal hemorrhagic shock (MAP 40 mmHg, 30 min), and during resuscitation (shed blood + 2x crystalloid). Human PMNs were incubated with control, PHSML, PHSML lipid extracts, and heat-treated PHSML (60 degrees C, 30 min.) at 1-10% (v:v) in RPMI 1640 for 24 h. Apoptosis was assessed using acridine orange/ethidium bromide staining and fluorescence microscopy. Priming of the respiratory burst was evaluated by incubating PMNs with (a) control PHSML or (b) PHSML lipid extracts for 24 h and by activating with fMLP (1 micromol/L). PHSML and PHSML lipid extracts (5-10%) inhibited PMN apoptosis. Heat denaturing the PHSML (to eliminate cytokines and complement) had no effect on the inhibition of PMN apoptosis. Similarly, incubation with polymixin B at a concentration that binds endotoxin had no effect. Both the PHSML and PHSML lipids (5%) following 24-h incubation primed the fMLP-activated oxidase. At physiologic concentrations, both PHSML and the lipid fraction of PHSML delay PMN apoptosis and prime the NADPH oxidase. These data further implicate the lipid components of mesenteric lymph as central in the pathogenesis of hemorrhagic shock induced PMN-mediated acute lung injury.

Hypertonic saline attenuation of polymorphonuclear neutrophil cytotoxicity: timing is everything.

BACKGROUND: The potential to modulate the inflammatory response has renewed interest in hypertonic saline (HTS) resuscitation of injured patients. However, the effect of the timing of HTS treatment with respect to polymorphonuclear neutrophil (PMN) priming and activation remains unexplored. We hypothesized that HTS attenuation of PMN functions requires HTS exposure before priming and activation. METHODS: Isolated PMN were incubated in HTS (180 mM Na+) before L-alpha-phosphatidylcholine, beta-acetyl-gamma-O-alkyl (PAF)/N-formylmethionyl-leucyl-phenylalanine (fMLP) priming/activation, after priming, or after priming/activation. Superoxide production was measured by the reduction cytochrome c, elastase release by cleavage of AAPV-pNA, and beta2-integrin expression by flow cytometry. RESULTS: HTS before priming or activation decreased beta2-integrin expression, superoxide production, and elastase release. In contrast, HTS after priming/activation augmented superoxide production and elastase release. CONCLUSION: The timing of HTS is a key variable in the attenuation of PMN cytotoxic functions. Maximal attenuation of cytotoxicity is achieved before priming, whereas HTS exposure after activation augments cytotoxicity.

Stored red blood cells selectively activate human neutrophils to release IL-8 and secretory PLA2.

Packed red blood cell (PRBC) transfusion has been invoked previously with immunosuppression and increased infections, but it has now been demonstrated that stored PRBCs (>14 days) can prime PMNs and provoke multiple organ failure. Recently, the role of PMNs in the genesis of MOF has been extended to their release of inflammatory cytokines, notably IL-1, IL-8, TNFalpha, and secretory phospholipase A2 (sPLA2). We hypothesize that stored PRBCs can act as a second event via stimulating the release of inflammatory cytokines from PMNs. Isolated human PMNs were incubated for 24 h in RPMI with either 20% fresh plasma or plasma from 42 day old PRBC (day of outdate) and release of IL-8, IL-1beta, TNFalpha, and sPLA2 were measured. Plasma from stored PRBCs contained small amounts of IL-8, sPLA2, and TNFalpha (102.1 +/-5.6 pg/ml, 87.6+/-6.0 pg/ml and 9.7+/-.7 pg/ml). Levels of IL-1beta were below detection (<1 pg/ml). Day 42 PRBC plasma stimulated significant PMN release of both IL-8 and sPLA2 as compared to both control and day 0 plasma (*P < .05), but PRBC plasma did not stimulate PMN release of either IL-1beta or TNFalpha. Transfused blood is emerging as an inflammatory agent that is capable of producing PMN priming. In this study we have demonstrated that PRBC plasma selectively activates PMNs to release both IL-8 and sPLA2. Thus, transfusion of PRBCs may represent a preventable inflammatory insult via modification of both blood banking and transfusion practices.

Posthemorrhagic shock mesenteric lymph primes circulating neutrophils and provokes lung injury.

Mesenteric lymph has recently been invoked as an avenue for gut-derived factors that may result in distant organ injury following hemorrhagic shock. We demonstrate that posthemorrhagic shock mesenteric lymph primes neutrophils (PMNs) and causes lung injury. Methods. Mesenteric lymph was collected from Sprague-Dawley rats from their mesenteric lymph duct prior to, during, and following hemorrhagic shock (MAP 40 for 90 min). The rats were then resuscitated with shed blood plus lactated Ringers (2X shed blood) over 3 h. Lung leak was assessed by transudation of Evan's blue dye into the alveolus as measured by bronchoalveolar lavage. Isolated human PMNs were incubated with 1 and 10% lymph; priming was measured by the fMLP (1 microM)-stimulated production of superoxide and surface expression of CD11b determined by flow cytometry. Results. Mesenteric lymph flow increased significantly during resuscitation: preshock 144.4 microl/h, shock 44.5 microl/h, resuscitation 566.6 microl/h. Furthermore, diversion of this lymph abrogated lung injury as compared to rats without lymph diversion. Finally, mesenteric lymph from postshock animals primed PMNs for superoxide production (nearly three times control cells) as well as increased surface expression of CD11b (2-fold over control). Conclusion. Mesenteric lymph primes PMNs and causes lung injury following hemorrhagic shock. Mesenteric lymph provides a conduit for proinflammatory mediators that may participate in the pathogenesis of MOF.

Age of transfused blood is an independent risk factor for postinjury multiple organ failure.

BACKGROUND: Blood transfusion has repeatedly been demonstrated to be an independent risk factor for postinjury multiple organ failure (MOF). Previously believed to represent a surrogate for shock, packed red blood cell (PRBC) transfusion has recently been shown to result in neutrophil priming and pulmonary endothelial cell activation. We have previously observed that the generation of inflammatory mediators is related to the length of PRBC unit storage. The purpose of this study was to determine if age of transfused PRBC is a risk factor for the development of postinjury MOF. METHODS: Using our prospective database of trauma patients at risk for developing MOF, we identified patients who developed MOF (MOF+) and received 6 to 20 units of PRBCs in the first 12 hours following injury. A similar cohort of patients, matched for ISS and transfusion requirement, who did not develop MOF (MOF-) were also identified. The age of each unit of PRBC transfused in the first 6 hours was determined. Multiple logistic regression was performed to determine if age of transfused blood is an independent risk factor. RESULTS: Sixty-three patients were identified, 23 of whom were MOF+. There was no difference in ISS and transfusion requirement between MOF+ and MOF- groups. MOF+ patients, however, were significantly older (46+/-4.7 years versus 33+/-2.3 years). Moreover, mean age of transfused blood was greater in the MOF+ patients (30.5+/-1.6 days versus 24+/-0.5 days). Similarly, the mean number of units older than 14 and 21 days old were greater in the MOF+ patients. Multivariate analysis identified mean age of blood, number of units older than 14 days, and number of units older than 21 days as independent risk factors for MOF. CONCLUSION: The age of transfused PRBCs transfused in the first 6 hours is an independent risk factor for postinjury MOF. This suggests that current blood bank processing and storage technique should be reexamined. Moreover, fresh blood may be more appropriate for the initial resuscitation of trauma patients requiring transfusion.

Solution structure of the calcium channel antagonist omega-conotoxin GVIA.

The three-dimensional solution structure is reported for omega-conotoxin GVIA, which is a potent inhibitor of presynaptic calcium channels in vertebrate neuromuscular junctions. Structures were generated by a hybrid distance geometry and restrained molecular dynamics approach using interproton distance, torsion angle, and hydrogen-bonding constraints derived from 1H NMR data. Conformations of GVIA with low constraint violations converged to a common peptide fold. The secondary structure in the peptide is an antiparallel triple-stranded beta-sheet containing a beta-hairpin and three tight turns. The NMR data are consistent with the region of the peptide from residues S9 to C16 being more dynamic than the rest of the peptide. The peptide has an amphiphilic structure with a positively charged hydrophilic side and an opposite side that contains a small hydrophobic region. Residues that are thought to be important in binding and function are located on the hydrophilic face of the peptide.

Changes in double quantum filtered sodium intensity during prolonged ischemia in the isolated perfused heart.

Intracellular sodium (Nai) concentrations rose immediately and progressively during ischemia in the isolated heart. The intracellular double quantum filtered sodium coherence (DQ) intensity also increased during ischemia. However, when normalized for Nai, the DQ intensity began to fall after 40 min of ischemia, and remained depressed during reperfusion.