Massroor Pourcyrous scite author profile

The extended postictal state is characterized by neurological problems in patients. Inadequate blood supply to the brain and impaired cerebral autoregulation may contribute to seizure-induced neuronal damage. Recent evidence in newborn pigs indicates that activation of the antioxidative enzyme heme oxygenase (HO) at the onset of seizures is necessary for increased cerebral blood flow during the ictal episode and for normal cerebral vascular functioning during the immediate postictal period. We hypothesized that seizures cause prolonged postictal cerebral vascular dysfunction that can be accentuated by HO inhibition and rescued by HO overexpression. Cerebral vascular responses to endothelium-dependent (hypercapnia, bradykinin) and -independent (isoproterenol, sodium nitroprusside) stimuli were assessed 48 h after bicuculline-induced seizures in: 1) saline-control newborn piglets, 2) HO-inhibited animals (HO was inhibited by tin protoporphyrin, SnPP, 3 mg/kg iv), and 3) HO-overexpressing piglets (HO-1 was upregulated by cobalt protoporphyrin, CoPP, 50 mg/kg ip). Extended alterations of HO expression in cerebral microvessels were confirmed by measuring CO production and inducible HO (HO-1) and constitutive HO (HO-2) proteins. Our data provide evidence that seizures cause a severe, sustained, postictal cerebral vascular dysfunction as reflected by impaired vascular reactivity to physiologically relevant dilators. During the delayed postictal state, vascular reactivity to all dilator stimuli was reduced in saline control and, to a greater extent, in HO-inhibited animals. In CoPP-treated piglets, no reduction in postictal cerebral vascular reactivity was observed. These findings may indicate that CoPP prevents postictal cerebral vascular dysfunction by upregulating HO-1, a finding that might have implications for preventing postictal neurological complications. cerebral circulation; epilepsy; postictal state; heme oxygenase; cobalt protoporphyrin THE POSTICTAL STATE as a consequence of epileptic seizures is associated with serious neurological problems and contributes to morbidity in patients. Debilitating effects of seizures are often extended to several days or even weeks of the postictal period (18). The multifactorial mechanisms of the postictal state are poorly understood. Human status epilepticus is consistently associated with cognitive problems and with widespread neuronal necrosis in the brain. Inadequate blood supply to the brain may contribute to seizure-induced neuronal damage and to the overall postictal state. During seizures, blood flow to the brain increases in patients (7, 9) and in animal models (11,34). In newborn piglets, neuronal activation at the onset of bicuculline-induced seizures is accompanied by the immediate increase in diameter of pial arterioles, major resistance vessels of the brain that determine the cerebral blood flow (30). The increase in the cerebral blood flow is required to match increased metabolic demands of activated neurons during the ictal episode and to prevent subsequent n...

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Endogenous heme oxygenase prevents impairment of cerebral vascular functions caused by seizures

Carratù

Pourcyrous

Fedinec

et al. 2003

American Journal of Physiology-Heart and Circulatory Physiology

101

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In newborn pigs, the mechanism of seizure-induced cerebral hyperemia involves carbon monoxide (CO), the vasodilator product of heme catabolism by heme oxygenase (HO). We hypothesized that seizures cause cerebral vascular dysfunction when HO activity is inhibited. With the use of cranial window techniques, we examined cerebral vascular responses to endothelium-dependent (hypercapnia and bradykinin) and endothelium-independent (isoproterenol and sodium nitroprusside) dilators during the recovery from bicuculline-induced seizures in saline controls and in animals pretreated with a HO inhibitor, tin protoporphyrin (SnPP). SnPP (3 mg/kg iv) blocked dilation to heme and reduced the CO level in cortical periarachnoid cerebrospinal fluid, indicating HO inhibition in the cerebral microcirculation. In saline control piglets, seizures increased the CO level, which correlated with the time-dependent cerebral vasodilation; during the recovery (2 h after seizure induction), responses to all vasodilators were preserved. In SnPP-treated animals, cerebral vasodilation and the CO responses to seizures were greatly reduced, and cerebral vascular reactivity was severely impaired during the recovery. These findings suggest that HO in the cerebral microcirculation is rapidly activated during seizures and provides endogenous protection against seizure-induced vascular injury.

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C-Reactive Protein in the Diagnosis, Management, and Prognosis of Neonatal Necrotizing Enterocolitis

et al. 2005

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