Neuroprotection by Selective Nitric Oxide Synthase Inhibition at 24 Hours After Perinatal Hypoxia-Ischemia

Peeters-Scholte, Cacha; Koster, Johanna G.; Veldhuis, Wouter B.; Tweel, Evelyn van den; Zhu, Changlian; Kops, Nicole; Blomgren, Klas; Bär, Dop; Buul‐Offers, Sylvia van; Hagberg, Henrik; Nicolay, Klaas; Bel, Frank van; Groenendaal, Floris

doi:10.1161/01.str.0000028343.25901.09

Cited by 104 publications

(82 citation statements)

References 44 publications

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“…Elimination of nNOS neurons through injections of quisqualic acid into the cortex of P7 rats rendered these animals resistant to HI [195], and nNOS deficiency through genetic targeting was also neuroprotective [196]. Administration of the combined iNOS/nNOS inhibitor 2-iminobiotin reduced caspase-3 activation [197] and conferred tissue protection [198]. The iNOS inhibitor aminoguanidine [199] (IL-1) also reduced brain injury after HI, further indicating that NO production exerts cytotoxic effects in the developing brain such insults.…”

Section: Nitric Oxidementioning

confidence: 99%

Pathological apoptosis in the developing brain

2007

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More than half of the initially-formed neurons are deleted in certain brain regions during normal development. This process, whereby cells are discretely removed without interfering with the further development of remaining cells, is called programmed cell death (PCD). The term apoptosis is used to describe certain morphological manifestations of PCD. Many of the effectors of this developmental cell death program are highly expressed in the developing brain, making it more susceptible to accidental activation of the death machinery, e.g. following hypoxia-ischemia or irradiation. Recent evidence suggests, however, that activation and regulation of cell death mechanisms under pathological conditions do not exactly mirror physiological, developmentally regulated PCD. It may be argued that the conditions after e.g. ischemia are not even compatible with the execution of PCD as we know it. Under pathological conditions cells are exposed to various stressors, including energy failure, oxidative stress and unbalanced ion fluxes. This results in parallel triggering and potential overshooting of several different cell death pathways, which then interact with one another and result in complex patterns of biochemical manifestations and cellular morphological features. These types of cell death are here called "pathological apoptosis," where classical hallmarks of PCD, like pyknosis, nuclear condensation and caspase-3 activation, are combined with non-PCD features of cell death. Here we review our current knowledge of the mechanisms involved, with special focus on the potential for therapeutic intervention tailored to the needs of the developing brain.

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Section: Nitric Oxidementioning

confidence: 99%

Pathological apoptosis in the developing brain

2007

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“…The development of novel animal models of childhood stroke and the optimization of cerebral perinatal HI and MCAO models appear as the most important approaches to pursue this issue. As the majority of basic research studies have been focused on inflammation in perinatal HI model, a stronger scientific effort should be N-acetylcysteine Oxygen radical scavenger Reduction in cerebral oxidative stress and cerebral injury; improvement in myelin expression and neurological outcome in neonatal rats (combined with hypothermia) (HI model) [83] Melatonin Oxygen radical scavenger Reduction in white matter damage and promotion of repair by induction of axonal regrowth or sprouting in newborn mice (ibotenate-mediated excitotoxic brain injury) [84] Decrease in oxidative damage mediators in 7-day-old rats (HI model) [85] 2-iminobiotin Selective nNOS and iNOS inhibitor Improvement in cerebral energy state, reduction in vasogenic oedema and neuronal death (HI model) [60] 7-nitroindazole Selective nNOS inhibitor Suppression of both two peaks of NO metabolites (during hypoxia and during the re-oxygenation period) (HI model) [82] Aminoguanidine Selective iNOS inhibitor Suppression only the NO metabolites peak in the re-oxygenation period. Reduction in cerebral injury in a neonatal rats (HI model) [61,62] DETANONOate (Z)-1-[N-(2-amino-ethyl)-N-(2-ammonio-ethyl)amino] diazen-1-ium-1,2-diolate NO donor Reduction in neuropathologic injury score in newborn rats (HI model) [79] Hypothermia Nonselective anti-inflammatory effects Improvement in survival and neurologic outcomes in human neonates [89][90][91] More benefit in combined pharmacological hypothermia treatment (HI model) [92,93] Simvastatin Nonselective antioxidant and anti-inflammatory effects Reduction in cerebral damage in neonatal rats (HI model) [94] *HI, Hypoxia-ischaemia.…”

Section: Resultsmentioning

confidence: 99%

“…In 7-day-oldrats, HIprotocol up regulated themRNAexpressionofseveralchemokines(suchasmacrophage [60]. Increase frequency of polymorphisms )308 G ⁄ A in children with sickle-cell anaemia and stroke [61] Up regulation in ischaemic brain in perinatal rats (HI model) [35].…”

Section: Chemokinesmentioning

confidence: 99%

“…Nitric oxide (NO) is a free radical gas, mainly mediating neuroprotection (when produced by endothelial nitric oxide synthase [eNOS]) or neurotoxic effects (when produced by neuronal [nNOS] and inducible NOS [iNOS]) [59][60][61][62]. In particular, both genetic and pharmacological inhibition of iNOS reduced cerebral injury in HI animal protocols [59][60][61][62].…”

Section: Oxidative Compoundsmentioning

confidence: 99%

“…In particular, both genetic and pharmacological inhibition of iNOS reduced cerebral injury in HI animal protocols [59][60][61][62]. Moreover, NO produced by iNOS has been shown to increase the activity of cyclooxygenase-2 (COX-2, an enzyme expressed in neurons at the border of ischaemic regions) in an adult rat model of transient MCAO [63].…”

Section: Oxidative Compoundsmentioning

confidence: 99%

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Pathophysiological role of inflammatory molecules in paediatric ischaemic brain injury

Mirabelli-Badenier

Braunersreuther²,

Lenglet³

et al. 2012

Eur J Clin Investigation

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Ischaemic stroke is one of the major causes of death and lifelong disability also in the paediatric population. Strong scientific effort has been put to clarify the pathophysiology of this disease in adults. However, only few studies have been performed in children. Preliminary results indicate that pathophysiological processes might differently affect the poststroke neuronal injury in neonates as compared to children. During the neural development, selective molecular mechanisms might be differently triggered by an ischaemic insult, thus potentially resulting in defined postischaemic clinical outcomes. Basic research studies in neonatal animal models of cerebral ischaemia have recently shown a potential role of soluble inflammatory molecules (such as cytokines, chemokines and oxidants) as pivotal players of neuronal injury in both perinatal and childhood ischaemic stroke. Although larger clinical trials are still needed to confirm these preliminary results, the potential benefits of selective treatments targeting inflammation in perinatal asphyxia encephalopathy might represent a promising investigation field in the near future. In this review, we will update evidence on the pathophysiological role of soluble inflammatory mediators in neonatal and childhood ischaemic stroke. Recent evidence on potential anti-inflammatory treatments to improve paediatric stroke prognosis will be discussed.

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Inflammation in white matter: Clinical and pathophysiological aspects

Pleasure

Soulika

Singh

et al. 2006

Ment. Retard. Dev. Disabil. Res. Rev.

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While the central nervous system (CNS) is generally thought of as an immunopriviledged site, immune-mediated CNS white matter damage can occur in both the perinatal period and in adults, and can result in severe and persistent neurological deficits. Periventricular leukomalacia (PVL) is an inflammatory white matter disease of premature infants that frequently results in cerebral palsy (CP). Clinical and experimental studies show that both hypoxic/ischemic and innate immune mechanisms contribute to the destruction of immature oligodendroglia and of axons in the deep cerebral white matter in PVL. No data are yet available as to whether there is any genetic predisposition to PVL or to its neurological sequelae. Multiple sclerosis (MS) is an inflammatory white matter disease that often begins in young adulthood, causes multifocal destruction of mature oligodendroglia and of axons, and eventually leads to substantial cumulative neurological disability. Certain genetic polymorphisms contribute to susceptibility to MS, and adaptive immune responses to myelin-associated self antigens, or to exogenous antigens that mimic these self antigens, play a central role in the pathophysiology of this disease.

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Neuroprotection by Selective Nitric Oxide Synthase Inhibition at 24 Hours After Perinatal Hypoxia-Ischemia

Cited by 104 publications

References 44 publications

Pathological apoptosis in the developing brain

Pathological apoptosis in the developing brain

Pathophysiological role of inflammatory molecules in paediatric ischaemic brain injury

Inflammation in white matter: Clinical and pathophysiological aspects

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