Rainer Kentner

Survival without brain damage after clinical death of 60-120 mins in dogs using suspended animation by profound hypothermia

ObjectivesThis study explored the limits of good outcome of brain and organism achievable after cardiac arrest (no blood flow) of 60–120 mins, with preservation (suspended animation) induced immediately after the start of exsanguination cardiac arrest. DesignProspective experimental comparison of three arrest times, without randomization. SettingUniversity research laboratory. SubjectsTwenty-seven custom-bred hunting dogs (17–25 kg). InterventionsDogs were exsanguinated over 5 mins to cardiac arrest no-flow of 60 mins, 90 mins, or 120 mins. At 2 mins of cardiac arrest, the dogs received, via a balloon-tipped catheter, an aortic flush of isotonic saline at 2°C (at a rate of 1 L/min), until tympanic temperature reached 20°C (for 60 mins of cardiac arrest), 15°C (for 60 mins of cardiac arrest), or 10°C (for 60, 90, or 120 mins of cardiac arrest). Resuscitation was by closed-chest cardiopulmonary bypass, postcardiac arrest mild hypothermia (tympanic temperature 34°C) to 12 hrs, controlled ventilation to 20 hrs, and intensive care to 72 hrs. Measurements and Main ResultsWe assessed overall performance categories (OPC 1, normal; 2, moderate disability; 3, severe disability; 4, coma; 5, death), neurologic deficit scores (NDS 0–10%, normal; 100%, brain death), regional and total brain histologic damage scores at 72 hrs (total HDS >0–40, mild; 40–100, moderate; >100, severe damage), and morphologic damage of extracerebral organs. For 60 mins of cardiac arrest (n = 14), tympanic temperature 20°C (n = 6) was achieved after flush of 3 mins and resulted in two dogs with OPC 1 and four dogs with OPC 2: median NDS, 13% (range 0–27%); and median total HDS, 28 (range, 4–36). Tympanic temperature of 15°C (n = 5) was achieved after flush of 7 mins and resulted in all five dogs with OPC 1, NDS 0% (0–3%), and HDS 8 (0–48). Tympanic temperature 10°C (n = 3) was achieved after flush of 11 mins and resulted in all three dogs with OPC 1, NDS 0%, and HDS 16 (2–18). For 90 mins of cardiac arrest (n = 6), tympanic temperature 10°C was achieved after flush of 15 mins and resulted in all six dogs with OPC 1, NDS 0%, and HDS 8 (0–37). For 120 mins of cardiac arrest (n = 7), three dogs had to be excluded. In the four dogs within protocol, tympanic temperature 10°C was achieved after flush of 15 mins. This resulted in one dog with OPC 1, NDS 0%, and total HDS 14; one with OPC 1, NDS 6%, and total HDS 20; one with OPC 2, NDS 13%, and total HDS 10; and one with OPC 3, NDS 39%, and total HDS 22. ConclusionsIn a systematic series of studies in dogs, the rapid induction of profound cerebral hypothermia (tympanic temperature 10°C) by aortic flush of cold saline immediately after the start of exsanguination cardiac arrest—which rarely can be resuscitated effectively with current methods—can achieve survival without functional or histologic brain damage, after cardiac arrest no-flow of 60 or 90 mins and possibly 120 mins. The use of additional preservation strategies should be pursued in the 120-min arrest model.

Rapid Hypothermic Aortic Flush Can Achieve Survival without Brain Damage after 30 Minutes Cardiac Arrest in Dogs

BackgroundNeither exsanguination to pulselessness nor cardiac arrest of 30 min duration can be reversed with complete neurologic recovery using conventional resuscitation methods. Techniques that might buy time for transport, surgical hemostasis, and initiation of cardiopulmonary bypass or other resuscitation methods would be valuable. We hypothesized that an aortic flush with high-volume cold normal saline solution at the start of exsanguination cardiac arrest could rapidly preserve cerebral viability during 30 min of complete global ischemia and achieve good outcome. MethodsSixteen dogs weighing 20–25 kg were exsanguinated to pulselessness over 5 min, and circulatory arrest was maintained for another 30 min. They were then resuscitated using closed-chest cardiopulmonary bypass and had assisted circulation for 2 h, mild hypothermia (34°C) for 12 h, controlled ventilation for 20 h, and intensive care to outcome evaluation at 72 h. Two minutes after the onset of circulatory arrest, the dogs received a flush of normal saline solution at 4°C into the aorta (cephalad) via a balloon catheter. Group I (n = 6) received a flush of 25 ml/kg saline with the balloon in the thoracic aorta; group II (n = 7) received a flush of 100 ml/kg saline with the balloon in the abdominal aorta. ResultsThe aortic flush decreased mean tympanic membrane temperature (Tty) in group I from 37.6 ± 0.1 to 33.3 ± 1.6°C and in group II from 37.5 ± 0.1 to 28.3 ± 2.4°C (P = 0.001). In group I, four dogs achieved overall performance category (OPC) 4 (coma), and 2 dogs achieved OPC 5 (brain death). In group II, 4 dogs achieved OPC 1 (normal), and 3 dogs achieved OPC 2 (moderate disability). Median (interquartile range [IQR]) neurologic deficit scores (NDS 0–10% = normal; NDS 100% = brain death) were 69% (56–99%) in group I versus 4% (0–15%) in group II (P = 0.003). Median total brain histologic damage scores (HDS 0 = no damage; >100 = extensive damage; 1,064 = maximal damage) were 144 (74–168) in group I versus 18 (3–36) in group II (P = 0.004); in three dogs from group II, the brain was histologically normal (HDS 0–5). ConclusionsA single high-volume flush of cold saline (4°C) into the abdominal aorta given 2 min after the onset of cardiac arrest rapidly induces moderate-to-deep cerebral hypothermia and can result in survival without functional or histologic brain damage, even after 30 min of no blood flow.

Antioxidant Tempol Enhances Hypothermic Cerebral Preservation During Prolonged Cardiac Arrest in Dogs

The authors are systematically exploring pharmacologic preservation for temporarily unresuscitable exsanguination cardiac arrest in dogs. They hypothesized that the antioxidant Tempol improves cerebral outcome when added to aortic saline flush at the start of cardiac arrest. In study A, no drug (n = 8), Tempol 150 mg/kg (n = 4), or Tempol 300 mg/kg (n = 4) was added to 25 mL/kg saline flush at 24°C (achieving mild cerebral hypothermia) at the start of 20-minute cardiac arrest. In study B, no drug (n = 8) or Tempol 300 mg/kg (n = 7) was added to 50 mL/kg saline flush at 2°C (achieving moderate cerebral hypothermia) at the start of 40-minute cardiac arrest. Cardiac arrest was reversed with cardiopulmonary bypass. Mild hypothermia lasted for 12 hours, controlled ventilation was sustained to 24 hours, and intensive care was provided for up to 72 hours. In study A, overall performance category 1 or 2 (good outcome) was achieved in all eight dogs treated with Tempol compared with three of eight dogs in the control group (P = 0.03). In study B, good outcome was achieved in all seven dogs treated with Tempol versus only two of 8 dogs in the control group (P = 0.007). In both studies, neurologic deficit scores were significantly better in the Tempol group, but not total histologic damage scores. At 72 hours, electron paramagnetic resonance spectroscopy of Tempol revealed direct evidence for its presence in the brain. Single- and double-strand DNA damage, nitrotyrosine immunostaining, total antioxidant reserve, and ascorbate acid levels were similar between groups, and thiol levels were decreased after Tempol in study B. The authors conclude that when added to aortic saline flush at the start of prolonged cardiac arrest, the antioxidant Tempol can enhance mild or moderate hypothermic cerebral preservation in terms of improved functional outcome. The mechanisms involved in this beneficial effect need further clarification.

Mild hypothermia increases survival from severe pressure-controlled hemorrhagic shock in rats

BACKGROUND In previous studies, mild hypothermia (34 degrees C) during uncontrolled hemorrhagic shock (HS) increased survival. Hypothermia also increased mean arterial pressure (MAP), which may have contributed to its beneficial effect. We hypothesized that hypothermia would improve survival in a pressure-controlled HS model and that prolonged hypothermia would further improve survival. METHODS Thirty rats were prepared under light nitrous oxide/halothane anesthesia with spontaneous breathing. The rats underwent HS with an initial blood withdrawal of 2 mL/100 g over 10 minutes and pressure-controlled HS at a MAP of 40 mm Hg over 90 minutes (without anticoagulation), followed by return of shed blood and additional lactated Ringers solution to achieve normotension. Hemodynamic monitoring and anesthesia were continued to 1 hour, temperature control to 12 hours, and observation without anesthesia to 72 hours. After HS of 15 minutes, 10 rats each were randomized to group 1, with normothermia (38 degrees C) throughout; group 2, with brief mild hypothermia (34 degrees C during HS 15-90 minutes plus 30 minutes after reperfusion); and group 3, with prolonged mild hypothermia (same as group 2, then 35 degrees C [possible without shivering] from 30 minutes after reperfusion to 12 hours). RESULTS MAP during HS and initial resuscitation was the same in all three groups, but was higher in the hypothermia groups 2 and 3, compared with the normothermia group 1, at 45 and 60 minutes after reperfusion. Group 1 required less blood withdrawal to maintain MAP 40 mm Hg during HS and more lactated Ringers solution for resuscitation. At end of HS, lactate levels were higher in group 1 than in groups 2 and 3 (p < 0.02). Temperatures were according to protocol. Survival to 72 hours was achieved in group 1 by 3 of 10 rats, in group 2 by 7 of 10 rats (p = 0.18 vs. group 1), and in group 3 by 9 of 10 rats (p = 0.02 vs. group 1, p = 0.58 vs. group 2). Survival time was longer in group 2 (p = 0.09) and group 3 (p = 0.007) compared with group 1. CONCLUSION Brief hypothermia had physiologic benefit and a trend toward improved survival. Prolonged mild hypothermia significantly increased survival after severe HS even with controlled MAP. Extending the duration of hypothermia beyond the acute phases of shock and resuscitation may be needed to ensure improved outcome after prolonged HS.

Effects of mild hypothermia on survival and serum cytokines in uncontrolled hemorrhagic shock in rats.

Previous studies have suggested benefit of mild hypothermia during hemorrhagic shock (HS). This finding needs additional confirmation and investigation into possible mechanisms. Proinflammatory cytokines are mediators of multiple organ failure following traumatic hemorrhagic shock and resuscitation. We hypothesized that mild hypothermia would improve survival from HS and may affect the pro- and anti-inflammatory cytokine response in a rat model of uncontrolled HS. Under light halothane anesthesia, uncontrolled HS was induced by blood withdrawal of 3 mL/100 g over 15 min followed by tail amputation. Hypotensive (limited) fluid resuscitation (to prevent mean arterial pressure [MAP] from decreasing below 40 mmHg) with blood was started at 30 min and continued to 90 min. After hemostasis and resuscitation with initially shed blood and Ringers solution, the rats were observed for 72 h. The animals were randomized into two HS groups (n = 10 each): normothermia (38°C ± 0.5°C) and mild hypothermia (34°C ± 0.5°C) from HS 30 min until resuscitation time (RT) 60 min; and a sham group (n = 3). Venous blood samples were taken at baseline, RT 60 min, and days 1, 2, and 3. Serum interleukin (IL)-1&bgr;, IL-6, IL-10, and tumor necrosis factor (TNF)-&agr; concentrations were quantified by ELISA. Values are expressed as median and interquartile range. Survival time by life table analysis was greater in the hypothermia group (P = 0.04). Survival rates to 72 h were 1 of 10 vs. 6 of 10 in the normothermia vs. hypothermia groups, respectively (P = 0.057). All cytokine concentrations were significantly increased from baseline at RT 60 min in both HS groups, but not in the shams. At RT 60 min, in the normothermia vs. hypothermia groups, respectively, IL-1&bgr; levels were 185 (119–252) vs. 96 (57–135) pg/mL (P = 0.15); IL-6 levels were 2242 (1903–3777) vs. 1746 (585–2480) pg/mL (P = 0.20); TNF-&agr; levels were 97 (81–156) vs. 394 (280–406) pg/mL (P = 0.02); and IL-10 levels were 1.7 (0–13.3) vs. 15.8 (1.9–23.0) pg/mL (P = 0.09). IL-10 remained increased until day 3 in the hypothermia group. High IL-1&bgr; levels (>100 pg/mL) at RT 60 min were associated with death before 72 h (odds ratio 66, C.I. 3.5–1255). We conclude that mild hypothermia improves survival time after uncontrolled HS. Uncontrolled HS induces a robust proinflammatory cytokine response. The unexpected increase in TNF-&agr; with hypothermia deserves further investigation.

Fructose-1,6-bisphosphate and MK-801 by aortic arch flush for cerebral preservation during exsanguination cardiac arrest of 20 min in dogs. An exploratory study

In our exsanguination cardiac arrest (CA) outcome model in dogs we are systematically exploring suspended animation (SA), i.e. preservation of brain and heart immediately after the onset of CA to enable transport and resuscitative surgery during CA, followed by delayed resuscitation. We have shown in dogs that inducing moderate cerebral hypothermia with an aortic arch flush of 500 ml normal saline solution at 4 degrees C, at start of CA 20 min no-flow, leads to normal functional outcome. We hypothesized that, using the same model, but with the saline flush at 24 degrees C inducing minimal cerebral hypothermia (which would be more readily available in the field), adding either fructose-1,6-bisphosphate (FBP, a more efficient energy substrate) or MK-801 (an N-methyl-D-aspartate (NMDA) receptor blocker) would also achieve normal functional outcome. Dogs (range 19-30 kg) were exsanguinated over 5 min to CA of 20 min no-flow, and resuscitated by closed-chest cardiopulmonary bypass (CPB). They received assisted circulation to 2 h, mild systemic hypothermia (34 degrees C) post-CA to 12 h, controlled ventilation to 20 h, and intensive care to 72 h. At CA 2 min, the dogs received an aortic arch flush of 500 ml saline at 24 degrees C by a balloon-tipped catheter, inserted through the femoral artery (control group, n=6). In the FBP group (n=5), FBP (total 1440 or 4090 mg/kg) was given by flush and with reperfusion. In the MK-801 group (n=5), MK-801 (2, 4, or 8 mg/kg) was given by flush and with reperfusion. Outcome was assessed in terms of overall performance categories (OPC 1, normal; 2, moderate disability; 3, severe disability; 4, coma; 5, brain death or death), neurologic deficit scores (NDS 0-10%, normal; 100%, brain death), and brain histologic damage scores (HDS, total HDS 0, no damage; >100, extensive damage; 1064, maximal damage). In the control group, one dog achieved OPC 2, one OPC 3, and four OPC 4; in the FBP group, two dogs achieved OPC 3, and three OPC 4; in the MK-801 group, two dogs achieved OPC 3, and three OPC 4 (P=1.0). Median NDS were 62% (range 8-67) in the control group; 55% (range 34-66) in the FBP group; and 50% (range 26-59) in the MK-801 group (P=0.2). Median total HDS were 130 (range 56-140) in the control group; 96 (range 64-104) in the FBP group; and 80 (range 34-122) in the MK-801 group (P=0.2). There was no difference in regional HDS between groups. We conclude that neither FBP nor MK-801 by aortic arch flush at the start of CA, plus an additional i.v. infusion of the same drug during reperfusion, can provide cerebral preservation during CA 20 min no-flow. Other drugs and drug-combinations should be tested with this model in search for a breakthrough effect.

Intraperitoneal, but not enteric, adenosine administration improves survival after volume-controlled hemorrhagic shock in rats

ObjectiveTo circumvent the potential adverse systemic side effects of adenosine, this study explored the potential benefit of intraperitoneal or enteric adenosine on survival and inflammatory responses after volume-controlled hemorrhagic shock. DesignProspective, randomized, and blinded. A three-phase, volume-controlled hemorrhagic shock model was used: hemorrhagic shock phase (120 mins), resuscitation phase (60 mins), and observation phase (72 hrs). Three groups were compared: controls, intraperitoneal adenosine, and enteric adenosine. SettingAnimal research facility. SubjectsMale Sprague-Dawley rats. InterventionsStarting at 20 mins of hemorrhagic shock and continuing through the resuscitation phase, all three groups received both intraperitoneal lavage and repeated bolus injections into the ileum of vehicle (normal saline) or adenosine. In the intraperitoneal adenosine group (n = 10), adenosine solution (0.1 mM) was used for intraperitoneal lavage. In the enteric adenosine group (n = 10), adenosine (1.0 mM) was injected into the ileum. Blood cytokine concentrations and leukocyte infiltration in lungs and liver were studied in 12 separate rats (control and intraperitoneal adenosine, n = 6 each) with the same hemorrhagic shock model at resuscitation time 1 hr or 4 hrs. Measurements and Main Results Mean arterial pressure and heart rate were similar between the three groups during hemorrhagic shock and resuscitation. Potassium, lactate, and blood urea nitrogen concentrations were lower and arterial pH was higher in the intraperitoneal and enteric adenosine groups compared with the control group (both p < .05). Survival time to 72 hrs was longer in the intraperitoneal adenosine group than in the control group (p < .05). Neither plasma interleukin-1&bgr;, interleukin-6, interleukin-10, and tumor necrosis factor-&agr; concentrations nor leukocyte infiltration in the lungs and liver was different between the control and intraperitoneal adenosine groups. ConclusionsThe administration of adenosine via the intraperitoneal route improves survival time after severe volume-controlled hemorrhagic shock in rats without worsening hypotension or bradycardia. This beneficial effect may not be attributable to effects of adenosine on the inflammatory response.

Gut damage during hemorrhagic shock: effects on survival of oral or enteral interleukin-6.

It has been reported that oral interleukin (IL)-6, without deleterious systemic side effects, prevents bacteremia and gut epithelial apoptosis after hemorrhagic shock (HS) in rodents. The goal of this study was to explore potential benefit of oral or enteral IL-6 on the gut and, consequently, on survival in a long-term outcome model of HS in rats. In Study A, 20 rats (control and IL-6, n = 10 per group) were anesthetized by spontaneous breathing of halothane and N2O. The left femoral vein and artery were cannulated. HS was initiated with withdrawal of 3 mL of blood per 100 g body weight over 15 min, and mean arterial pressure was maintained at 40 to 50 mmHg for another 75 min (total HS 90 min) by blood withdrawal or infusion of Ringers solution. At HS 90 min, resuscitation included reinfusion of shed blood and additional Ringers solution to restore normotension for 30 min. After awakening at resuscitation time 30 min, the rats received either 300 units IL-6 or the same volume of vehicle (controls) injected into the stomach via a feeding cannula. In Study B, 20 rats (control and IL-6, n = 10 per group), fasted overnight, were prepared and treated as in Study A, except that HS was initiated with withdrawal of 2 mL blood per 100 g over 10 min, and mean arterial pressure was maintained at 35-40 mmHg. IL-6 rats received 3,000 units IL-6 in 5 mL of normal saline injected directly into the ileum lumen 20 min after induction of shock and again at resuscitation time 60 min. Control rats received normal saline alone. In both studies, survival was observed to 72 h. In Study A, 7 of 10 rats in the control group and 5 of 10 in the IL-6 group survived to 72 h (NS). Macroscopic assessment of gut injury was not different between the two groups. In Study B, 6 of 10 rats survived to 72 h in each group. Frequency of bacteria growth in liver tissue of 72 h survivors was not different between the two groups. IL-6, administered into the stomach or directly injected into the small intestine lumen, did not protect the gut from ischemic injury, nor did it improve survival following severe HS in rats.