Cerebral Protection in Experimental Cardiopulmonary Resuscitation : With Special Reference to the Effects of Methylene Blue

Miclescu, Adriana

January 2009

Although survival rates are increasing, brain injury continues to be a leading cause of death after cardiac arrest (CA). Permanent brain damage after CA is determined by limited tolerance to ischemia from CA and cardiopulmonary resuscitation (CPR), as well as the unique cerebral response to reperfusion after return of spontaneous circulation (ROSC). A major pathway leading to neurotoxic cascade and neuronal injury after CA involves the increased presence of reactive oxygen and nitrogen species generated during ischemia and reperfusion. The magnitude of cerebral oxidative injury induced by free radicals increased with the duration of CA (Paper I). Nitric oxide (NO), a free radical responsible for the formation of reactive nitrogen species, is increased during global ischemia from CA and reperfusion (Paper IV). Hypothetically, the administration of a drug that counteracts the overproduction of NO and also acts as a scavenger of oxygen free radicals might be warranted in order to reduce the damage caused by nitrosative and oxidative stress. For these purposes we used methylene blue (MB), an old dye that has been used in medicine for almost half a century, and an experimental pig model of 20 min of ventricular fibrillation (VF) to reflect a clinical scenario of ischemia/reperfusion injury. Administration of MB added to a hypertonic-hyperoncotic solution (MBHSD) that was started during CPR and continued for 50 min after ROSC increased short-term survival by decreasing myocardial damage, as well as cerebral peroxidation and inflammatory injury (Paper II). Immunostaining of cerebral tissue collected at different time points after CA and ROSC (Paper IV) provided experimental evidence that cortical blood-brain barrier (BBB) disruption begins as early as  during the initial phase of untreated as well as treated CA. The results indicated that MB administration reduced the neurologic injury and BBB disruption considerably, but did not reverse the ongoing detrimental processes. The demonstrated positive effects of MB were related to a decrease of nitrite/nitrate tissue content, and thus to a decrease of excess NO due to the MB inhibitory effects on NOS isoforms. A mixture of MB in hypertonic sodium lactate (MBL) was investigated to facilitate administration of MB in “the field.” Based on findings that MBL cardio- and neuroprotective properties were similar to those of MBHSD, there is reason to believe that the use of MBL might be extended during ongoing CPR and after ROSC (Paper III). It would therefore make sense to try using MB as a pharmacological neuroprotectant during or after clinical CPR in order to expand the temporal therapeutic window before other measures for neuroprotection such as hypothermia are available.

Cardiac arrest

cardiopulmonary resuscitation

reperfusion injury

methylene blue

nitric oxide

nitric oxide synthases

blood-brain barrier

Anaesthetics and intensive care

Anestesiologi och intensivvård

Endogenous Nitric Oxide Production and Pulmonary Blood Flow : during different experimental lung conditions

Nilsson, Manja

January 2011

Nitric oxide (NO) is an important regulator of pulmonary blood flow and attenuates hypoxic pulmonary vasoconstriction (HPV). Nitric oxide is synthesized enzymatically in a number of tissues, including the lungs, and can also be generated from reduction of nitrite during hypoxia and acidosis. Inhaled nitric oxide (INO) is a selective pulmonary vasodilator, with no effects on systemic arterial blood pressure due to inactivation by hemoglobin in the blood. INO has distant effects both within the lungs and in other organs, since NO can be transported to remote tissues bound to proteins, or as more stable molecules of nitrite and nitrate. In healthy pigs, INO causes vasoconstriction and down regulation of endogenous NO production in lung regions not reached by INO, and predominantly so in hypoxic lung regions, i.e. augmentation of HPV. In this thesis, distant effects of INO in pigs with endotoxemic- and lavage-induced lung injuries were studied. INO increased the NO production in lung regions not reached by INO in endotoxemic pigs, whereas endogenous NO production was unaffected in pigs with lavage-induced injury. Metabolic and/or hypercapnic acidosis frequently occurs in critically ill patients, but whether acidosis affects the endogenous pulmonary NO production is unclear. The regional NO production and blood flow in hyperoxic and hypoxic lung regions, were studied during metabolic and hypercapnic acidosis. Neither metabolic, nor hypercapnic acidosis changed the endogenous NO production in hyperoxic or hypoxic lung regions. Metabolic acidosis potentiated HPV, whereas hypercapnic acidosis transiently attenuated HPV. In conclusion, the present thesis has demonstrated that INO in experimental sepsis increases the endogenous NO production in lung regions not reached by INO, which may cause increased shunt and poor response to INO. This distant effect is not seen in lavage injuried lungs, an experimental model with less inflammation. Acidosis does not affect the endogenous pulmonary NO production in hyperoxic or hypoxic lung regions. Whereas metabolic acidosis potentiates HPV, hypercapnic acidosis transiently attenuates HPV, due to a combination of hypercapnia-induced increase in cardiac output and a probable vasodilating effect of the CO2-molecule.

Nitric oxide

pulmonary blood flow

endotoxin

nitric oxide inhalation

endothelin

hypercapnia

acidosis

lavage-induced lung injury

Anaesthetics and intensive care

Anestesiologi och intensivvård

Intestinal effects of lung recruitment maneuvers

Claesson, Jonas

January 2007

Background and aims: Lung recruitment maneuvers (brief episodes of high airway pressure) are a modern treatment alternative to achieve open lung conditions under mechanical ventilation of patients with acute lung injury. It is well known that positive pressure ventilation with high airway pressures cause negative circulatory effects, and that the effects on regional vascular beds can be even more pronounced than the systemic effects. Hypoperfusion of the mesenteric vascular bed can lead to tissue ischemia and local inflammation. This intestinal inflammation has been associated with subsequent development of multiple organ dysfunction syndrome, a syndrome that still carries a high mortality and is a leading cause of death for intensive care patients. The aim of this thesis was therefore to investigate whether lung recruitment maneuvers would cause negative effects on mesenteric circulation, oxygenation or metabolism. Methods and results: In an initial study on ten patients with acute lung injury, we could demonstrate a trend towards a decreased gastric mucosal perfusion during three repeated lung recruitment maneuvers. To more closely examine this finding, we set up an oleic acid lung injury model in pigs, and in our second study we established that this model was devoid of inherent intestinal effects and was adequate for subsequent studies of intestinal effects of lung recrutiment maneuvers. In the acute lung injury model, we also tested the effect of an infusion of a vasodilating agent concurrent with the recruitment maneuvers, the hypothesis being that a vasodilating agent would prevent intestinal vasoconstriction and hypoperfusion. We could show that three repeated lung recruitment maneuvers induced short term negative effects on mesenteric oxygenation and metabolism, but that these findings were transient and short lasting. Further, the effects of prostacyclin were minor and opposing. These findings of relative little impact on the intestines of lung recruitment maneuvers, lead us to investigate the hypothesis that repeated recruitment maneuvers maybe could elicite a protective intestinal preconditioning response, a phenomenon previously described both in the rat and in the dog. However, in our fourth study, using both classical ischemic preconditioning with brief periods of intestinal ischemia or repeated lung recrutiment maneuvers, we could not demonstrate the phenomenon of intestinal preconditioning in the pig. Conclusions: We conclude, that from a mesenteric point of view, lung recruitment maneuvers are safe, and only induce transient and short lasting negative effects. We also conclude that the cause of the minor effects of lung recruitment maneuvers is not dependent on intestinal preconditioning.

acute lung injury

oleic acid lung injury

ischemia

reperfusion injury

swine

mechanical ventilation

lung recruitment

splanchnic circulation

laser Doppler flowmetry

tissue oxygen tension

microdialysis

lactate

glycerol

Anaesthetics and intensive care

Anestesiologi och intensivvård