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.

Restoring microcirculatory perfusion in a preclinical model of severe hemorrhagic shock: The role of microcirculatory function.

BACKGROUND: No reflow in capillaries (no reflow) is the lack of tissue perfusion that occurs once central hemodynamics are restored. This prevents oxygen transfer and debt repayment to vital tissues after shock resuscitation. Since metabolic swelling of cells and tissues can cause no reflow, it is a target for study in shock. We hypothesize no reflow secondary to metabolic cell swelling causes the problem not addressed by current strategies that increase central hemodynamics alone. METHODS: Anesthetized swine were bled until plasma lactate reached 7.5 mM to 9 mM. Intravenous low volume resuscitation solutions were administered (6.8 mL/kg over 5 minutes) consisting of; (1) lactated Ringer (LR), (2) autologous whole blood, (3) high-dose vitamin C (200 mg/kg), or (4) 10% PEG-20k, a polymer-based cell impermeant that corrects metabolic cell swelling. Outcomes were macrohemodynamics (MAP), plasma lactate, capillary flow in the gut and tongue mucosa using orthogonal polarization spectral imaging (OPSI), and survival to 4 hours. RESULTS: All PEG-20k resuscitated swine survived 240 minutes with MAP above 60 mm Hg compared with 50% and 0% of the whole blood and LR groups, respectively. The vitamin C group died at just over 2 hours with MAPs below 40 and high lactate. The LR swine only survived 30 minutes and died with low MAP and high lactate. Capillary flow positively correlated ( p < 0.05) with survival and MAP. Sublingual OPSI correlated with intestinal OPSI and OPSI was validated with a histological technique. DISCUSSION: Targeting micro-hemodynamics in resuscitation may be more important than macrohemodynamics. Fixing both is optimal. Sublingual OPSI is clinically achievable to assess micro-hemodynamic status. Targeting tissue cell swelling that occurs during ATP depletion in shock using optimized osmotically active cell impermeants in crystalloid low volume resuscitation solutions improves perfusion in shocked tissues, which leverages a primary mechanism of injury.

Superior Survival Outcomes of a Polyethylene Glycol-20k Based Resuscitation Solution in a Preclinical Porcine Model of Lethal Hemorrhagic Shock.

OBJECTIVE: To compare early outcomes and 24-hour survival after LVR with the novel polyethylene glycol-20k-based crystalloid (PEG-20k), WB, or hextend in a preclinical model of lethal HS. BACKGROUND: Posttraumatic HS is a major cause of preventable death. current resuscitation strategies focus on restoring oxygen-carrying capacity (OCC) and coagulation with blood products. Our lab shows that PEG-20k is an effective non-sanguineous, LVR solution in acute models of HS through mechanisms targeting cell swelling-induced microcirculatory failure. METHODS: Male pigs underwent splenectomy followed by controlled hemorrhage until lactate reached 7.5-8.5 mmol/L. They were randomized to receive LVR with PEG-20k, WB, or Hextend. Surviving animals were recovered 4 hours post-LVR. Outcomes included 24-hour survival rates, mean arterial pressure, lactate, hemoglobin, and estimated intravascular volume changes. RESULTS: Twenty-four-hour survival rates were 100%, 16.7%, and 0% in the PEG-20k, WB, and Hextend groups, respectively (P= 0.001). PEG-20k significantly restored mean arterial press, intravascular volume, and capillary perfusion to baseline, compared to other groups. This caused complete lactate clearance despite decreased OCC. Neurological function was normal after next-day recovery in PEG-20k resuscitated pigs. CONCLUSION: Superior early and 24-hour outcomes were observed with PEG-20k LVR compared to WB and Hextend in a preclinical porcine model of lethal HS, despite decreased OCC from substantial volume-expansion. These findings demonstrate the importance of enhancing microcirculatory perfusion in early resuscitation strategies.