The protective profile of argon, helium, and xenon in a model of neonatal asphyxia in rats.

OBJECTIVE: Xenon provides neuroprotection in multiple animal models; however, little is known about the other noble gases. The aim of the current study was to compare xenon, argon, and helium neuroprotection in a neonatal asphyxia model in rats. DESIGN: Randomized controlled trial. SETTING: Laboratory. SUBJECTS: Seven-day-old postnatal Sprague-Dawley rats. INTERVENTIONS: Seventy percent argon, helium, xenon, or nitrogen balanced with oxygen after hypoxic-ischemic brain injury. MEASUREMENTS AND MAIN RESULTS: Control animals undergoing moderate hypoxic-ischemia endured reduced neuronal survival at 7 days with impaired neurologic function at the juvenile age compared with naïve animals. Severe hypoxic-ischemic damage produced a large cerebral infarction in controls. After moderate hypoxic-ischemia, all three noble gases improved cell survival, brain structural integrity, and neurologic function on postnatal day 40 compared with nitrogen. Interestingly, argon improved cell survival to naïve levels, whereas xenon and helium did not. When tested against more severe hypoxic-ischemic injury only, argon and xenon reduced infarct volume. Furthermore, postinjury body weight in moderate insult was lower in the helium-treated group compared with the naïve, control, and other noble gas treatment groups, whereas in the severe injurious setting, it is lower in both control and helium-treated groups than other groups. In the nondirectly injured hemisphere, argon, helium, and xenon increased the expression of Bcl-2, whereas helium and xenon increased Bcl-xL. In addition, Bax expression was enhanced in the control and helium groups. CONCLUSIONS: These studies indicate that argon and xenon provide neuroprotection against both moderate and severe hypoxia-ischemic brain injury likely through prosurvival proteins synthesis.

Systemic inflammation enhances surgery-induced cognitive dysfunction in mice.

The activation of the immune system, by either lipopolysaccharide (LPS) administration or surgical trauma, has been shown to be capable of affecting hippocampal function, causing memory impairment. Here, we examined the extent to which LPS-induced infection may aggravate impairment of memory function following orthopaedic surgery. Hippocampal memory function impairment was assessed using fear-conditioning tasks, while IL-1ß levels in plasma and hippocampus were measured using ELISA. LPS-induced inflammation disrupted hippocampal memory consolidation as evidenced by reduced contextual freezing time exhibited by infected mice. Likewise, surgery caused hippocampal-dependent memory impairment, which was associated with increased levels of IL-1ß both in plasma and hippocampus. However, a sub-pyrogenic dose of LPS alone failed to impair memory function. This dose of LPS, when administered prior to surgery, exacerbated surgery-induced cognitive dysfunction as evidenced by further reduction of contextual freezing time. Also, it caused a concomitant additional increase in the levels of IL-1ß in both plasma and hippocampus of those animals. Our data suggest that sub-clinical infection may sensitise the immune system augmenting the severity of post-operative cognitive dysfunction.

Severe burn injury induces a characteristic activation of extracellular signal-regulated kinase 1/2 in spinal dorsal horn neurons.

We have studied scalding-type burn injury-induced activation of extracellular signal-regulated kinase 1/2 (ERK1/2) in the spinal dorsal horn, which is a recognised marker for spinal nociceptive processing. At 5min after severe scalding injury to mouse hind-paw, a substantial number of phosphorylated ERK1/2 (pERK1/2) immunopositive neurons were found in the ipsilateral dorsal horn. At 1h post-injury, the number of pERK1/2-labelled neurons remained substantially the same. However, at 3h post-injury, a further increase in the number of labelled neurons was found on the ipsilateral side, while a remarkable increase in the number of labelled neurons on the contralateral side resulted in there being no significant difference between the extent of the labelling on both sides. By 6h post-injury, the number of labelled neurons was reduced on both sides without there being significant difference between the two sides. A similar pattern of severe scalding injury-induced activation of ERK1/2 in spinal dorsal horn neurons over the same time-course was found in mice which lacked the transient receptor potential type 1 receptor (TRPV1) except that the extent to which ERK1/2 was activated in the ipsilateral dorsal horn at 5 min post-injury was significantly greater in wild-type animals when compared to TRPV1 null animals. This difference in activation of ERK1/2 in spinal dorsal horn neurons was abolished within 1h after injury, demonstrating that TRPV1 is not essential for the maintenance of ongoing spinal nociceptive processing in inflammatory pain conditions in mouse resulting from at least certain types of severe burn injury.

Extracellular signal-regulated kinases in pain of peripheral origin.

Activation of members of the family of enzymes known as extracellular signal-regulated kinases (ERKs) is now known to be involved in the development and/or maintenance of the pain associated with many inflammatory conditions, such as herniated spinal disc pain, chronic inflammatory articular pain, and the pain associated with bladder inflammation. Moreover, ERKs are implicated in the development of neuropathic pain signs in animals which are subjected to the lumbar 5 spinal nerve ligation model and the chronic constriction injury model of neuropathic pain. The position has now been reached where all scientists working on pain subjects ought to be aware of the importance of ERKs, if only because certain of these enzymes are increasingly employed as experimental markers of nociceptive processing. Here, we introduce the reader, first, to the intracellular context in which these enzymes function. Thereafter, we consider the involvement of ERKs in mediating nociceptive signalling to the brain resulting from noxious stimuli at the periphery which will be interpreted by the brain as pain of peripheral origin.

Role of interleukin-1beta in postoperative cognitive dysfunction.

OBJECTIVE: Although postoperative cognitive dysfunction (POCD) often complicates recovery from major surgery, the pathogenic mechanisms remain unknown. We explored whether systemic inflammation, in response to surgical trauma, triggers hippocampal inflammation and subsequent memory impairment, in a mouse model of orthopedic surgery. METHODS: C57BL/6J, knock out (lacking interleukin [IL]-1 receptor, IL-1R(-/-)) and wild type mice underwent surgery of the tibia under general anesthesia. Separate cohorts of animals were tested for memory function with fear conditioning tests, or euthanized at different times to assess levels of systemic and hippocampal cytokines and microglial activation; the effects of interventions, designed to interrupt inflammation (specifically and nonspecifically), were also assessed. RESULTS: Surgery caused hippocampal-dependent memory impairment that was associated with increased plasma cytokines, as well as reactive microgliosis and IL-1beta transcription and expression in the hippocampus. Nonspecific attenuation of innate immunity with minocycline prevented surgery-induced changes. Functional inhibition of IL-1beta, both in mice pretreated with IL-1 receptor antagonist and in IL-1R(-/-) mice, mitigated the neuroinflammatory effects of surgery and memory dysfunction. INTERPRETATION: A peripheral surgery-induced innate immune response triggers an IL-1beta-mediated inflammatory process in the hippocampus that underlies memory impairment. This may represent a viable target to interrupt the pathogenesis of postoperative cognitive dysfunction.

Xenon pretreatment attenuates anesthetic-induced apoptosis in the developing brain in comparison with nitrous oxide and hypoxia.

BACKGROUND: Administration of certain general anesthetics to rodents during the synaptogenic phase of neurodevelopment produces neuronal injury. Preconditioning (pretreatment) can reduce tissue injury caused by a severe insult; the authors investigated whether pretreatment strategies can protect the developing brain from anesthetic-induced neurotoxicity. METHODS: Seven-day-old Sprague-Dawley rats were pretreated with one of the following: 70% xenon, 70% nitrous oxide, or 8% hypoxia for 2 h; 24 h later, rats were exposed to the neurotoxic combination of 70% nitrous oxide and 0.75% isoflurane for 6 h. Cortical and hippocampal neuroapoptosis was assessed using caspase-3 immunostaining. Separate cohorts were maintained for 40 days at which time cognitive function with trace fear conditioning was performed. In other pretreated cohorts, rat cortices were isolated for immunoblotting of caspase-3, Bcl-2, cytochrome C, P53, and mitogen-activated protein kinases. To obviate physiologic influences, organotypic hippocampal slices harvested from postnatal rat pups were cultured for 5 days and exposed to the same conditions as obtained for the in vivo studies, and caspase-3 immunostaining was again the measured outcome. RESULT: Xenon pretreatment prevented nitrous oxide- and isoflurane-induced neuroapoptosis (in vivo and in vitro) and cognitive deterioration (in vivo). Contrastingly, nitrous oxide- and isoflurane-induced neuroapoptosis was exacerbated by hypoxic pretreatment. Nitrous oxide pretreatment had no effect. Xenon pretreatment increased Bcl-2 expression and decreased both cytochrome C release and P53 expression; conversely, the opposite was evident after hypoxic pretreatment. CONCLUSIONS: Although xenon pretreatment protects against nitrous oxide- and isoflurane-induced neuroapoptosis, hypoxic pretreatment exacerbates anesthetic-induced neonatal neurodegeneration.