Metabolic Tissue Swelling and Local Microcirculation in Splanchnic Artery Occlusion Shock: Implications for Critical Illness.

Trauma is a leading cause of death in the United States. Advancements in shock resuscitation have been disappointing because the correct upstream mechanisms of injury are not being targeted. Recently, significant advancements have been shown using new cell-impermeant molecules that work by transferring metabolic water from swollen ischemic cells to the capillary, which restores tissue perfusion by microcirculatory decompression. The rapid normalization of oxygen transfer improves resuscitation outcomes. Since poor resuscitation and perfusion of trauma patients also causes critical illness and sepsis and can be mimicked by ischemia-reperfusion of splanchnic tissues, we hypothesized that inadequate oxygenation of the gut during trauma drives development of later shock and critical illness. We further hypothesized that this is caused by ischemia-induced water shifts causing compression no-reflow. To test this, the superior mesenteric artery of juvenile anesthetized swine was occluded for 30 minutes followed by 8 hours of reperfusion to induce mild splanchnic artery occlusion (SAO) shock. One group received the impermeant polyethylene glycol 20,000 Da (PEG-20k) that prevents metabolic cell swelling, and the other received a lactated Ringer's vehicle. Survival doubled in PEG-20k-treated swine along with improved macrohemodynamics and intestinal mucosal perfusion. Villus morphometry and plasma inflammatory cytokines normalized with impermeants. Plasma endotoxin rose over time after reperfusion, and impermeants abolished the rise. Inert osmotically active cell impermeants like PEG-20k improve intestinal reperfusion injury, SAO shock, and early signs of sepsis, which may be due to early restoration of mucosal perfusion and preservation of the septic barrier by reversal of ischemic compression no-reflow. SIGNIFICANCE STATEMENT: Significant advancements in treating shock and ischemia have been disappointing because the correct upstream causes have not been targeted. This study supports that poor tissue perfusion after intestinal ischemia from shock is caused by capillary compression no-reflow secondary to metabolic cell and tissue swelling since selectively targeting this issue with novel polyethylene glycol 20,000 Da-based cell-impermeant intravenous solutions reduces splanchnic artery occlusion shock, doubles survival time, restores tissue microperfusion, and preserves gut barrier function.

Effects of polyethylene glycol-20k IV solution on donor management in a canine model of donor brain death.

BACKGROUND: Traditionally, vasopressors and crystalloids have been used to stabilize brain dead donors; however, the use of crystalloid is fraught with complications. This study aimed to investigate the effectiveness of a newly developed impermeant solution, polyethylene glycol-20k IV solution (PEG-20k) for resuscitation and support of brain dead organ donors. METHODS: Brain death was induced in adult beagle dogs and a set volume of PEG-20k or crystalloid solution was given thereafter. The animals were then resuscitated over 16 h with vasopressors and crystalloid as necessary to maintain mean arterial pressure of 80-100 mmHg. The kidneys were procured and cold-stored for 24 h, after which they were analyzed using the isolated perfused kidney model. RESULTS: The study group required significantly less crystalloid volume and vasopressors while having less urine output and requiring less potassium supplementation than the control group. Though the two groups' mean arterial pressure and lactate levels were comparable, the study group's kidneys showed less preservation injury after short-term reperfusion indexed by decreased lactate dehydrogenase release and higher creatinine clearance than the control group. CONCLUSIONS: The use of polyethylene glycol-20k IV solution for resuscitating brain dead donors decreases cell swelling and improves intravascular volume, thereby improving end organ oxygen delivery before procurement and so preventing ischemia-reperfusion injury after transplantation.

Effects of a novel low volume resuscitation solutions on coagulation and platelet function.

BACKGROUND: Novel crystalloid solutions containing polyethylene glycol polymers (PEG-20k) produce dramatic resuscitation effects but dose-dependently produce a hypocoagulative state. The objective of this study was to examine possible mechanisms of this effect. Based on previous thromboelastography data, we hypothesize the effect is largely due to platelet interactions with the polymers. METHODS: Whole citrated blood from healthy volunteers was diluted ex-vivo 10% with crystalloids and tested for coagulation and platelet function. The specific tests included prothrombin time (PT), activated partial thromboplastin time (aPTT), fibrinogen and von Willebrand factor (vWf) activity, thrombin generation, thromboelastography with and without platelet mapping, platelet flow cytometry, and erythrocyte sedimentation rate. FINDINGS: Fibrinogen and vWF activities, PT, and aPTT were not affected by PEG-20k dilutions. Thrombin activity was mildly suppressed with PEG-20k (TTP- 20%). Platelet mapping demonstrated significantly greater % inhibition of both ADP and arachidonic acid-induced platelet aggregation with PEG-20k, but direct ADP-activated gpIIa/IIIb (PAC1) and P-selectin (CD62P) binding site expression was not altered. Mild dose-dependent suppression of TEG-MA was seen with PEG-20k using platelet poor plasma. Erythrocyte Sedimentation Rates (ESR) were dramatically accelerated after dilution with 10% PEG-20k, which was competitively blocked by smaller PEG polymers, suggesting nonspecific PEG-20k cell binding effects. CONCLUSIONS: PEG-20k creates a mild hypocoagulative state in whole blood at concentrations ≥10%, which may be due to platelet-PEG interactions at the IIb/IIIa interface with lesser effects on fibrin polymerization. This interaction may cause a functional thrombasthenia induced by nonspecific platelet surface passivation by the PEG polymer.

Thromboelastographic analysis of novel polyethylene glycol based low volume resuscitation solutions.

BACKGROUND: Low volume resuscitation (LVR) in shock prevents deleterious effects of crystalloid loading in pre-hospital settings. Polyethylene glycol 20,000 (PEG-20k) based LVR solutions are 20-fold more effective at maintaining perfusion and survival in shock compared to conventional crystalloids. The aim of this study was to determine coagulation and platelet function of whole blood treated with 10% PEG-20k. METHODS: Citrated blood from volunteers (n = 25) or early admission severely injured trauma patients (n = 9) were diluted 10% with various LVR solutions in a matched design with a paired volume control (saline), and studied using thromboelastography (TEG). FINDINGS: In healthy volunteers and patients, 10% PEG-20k significantly increased clot amplification time (k), decreased propagation (angle), maximal clot size and strength (MA), and the overall coagulation index (CI), but not clot initiation (R) or fibrinolysis (Ly30), relative to paired saline dilutional controls. Clinically, K, angle, and MA were just outside of the normal limits in volunteers but not in patients. No statistical differences existed between PEG-20k and Hextend (HES) in either patient population. In a dose response series using volunteer blood, all effects of 10% PEG-20k on TEG were reversed and normalized by lower concentrations (7.5% and 5%). Furthermore, 7.5% PEG-20k produced similar resuscitation effects as 10% PEG in rodent hemorrhagic shock models (n = 5). CONCLUSIONS: In conclusion, PEG-20k based LVR solutions produced a dose-dependent minor hypocoagulative state, possibly associated with changes in clot propagation and platelet function, which can be reversed by dose reduction in concentration while providing superior LVR, microvascular rescue, and lactate clearance compared to saline or starch.