Inhibition of neuronal nitric oxide synthase-mediated activation of poly(ADP-ribose) polymerase in traumatic brain injury: neuroprotection by 3-aminobenzamide.

Focal traumatic injury to the cerebral cortex is associated with early activation of the neuronal isoform of nitric oxide synthase (nNOS), where high concentrations of nitric oxide-derived free radicals elicit extensive DNA damage. Subsequent activation of the nuclear repair enzyme poly(ADP-ribose) polymerase (PARP) causes a severe energy deficit leading to the ultimate demise of affected neurons. Little is known about the temporal relationship of nNOS and PARP activation and the neuroprotective efficacy of their selective blockade in traumatic brain injury. To determine the relationship of nNOS and PARP activation, brain injury was induced by cryogenic lesion to the somatosensory cortex applying a pre-cooled cylinder after trephination for 6 s to the intact dura mater. Pre-treatment with 3-bromo-7-nitroindazole (BrNI; 25 mg/kg, i.p.), and pre- or combined pre- and post-treatment with 3-aminobenzamide (AB; 10 mg/kg (i.c.v.) or 10 mg/kg/h (i.p.)) were used to inhibit nNOS and PARP, respectively. Cold lesion-induced changes in the somatosensory cortex and neuroprotection by BrNI and AB were determined using immunocytochemistry and immunodot-blot for detection of poly(ADP-ribose; PAR), the end-product of PARP activation, and the triphenyltetrazolium-chloride assay to assess lesion volume. PAR immunoreactivity reached its peak 30 min post-lesion and was followed by gradual reduction of PAR immunolabeling. BrNI pre-treatment significantly decreased the lesion-induced PAR concentration in damaged cerebral cortex. Pre-treatment by i.c.v. infusion of AB markedly diminished cortical PAR immunoreactivity and significantly reduced the lesion volume 24 h post-injury. In contrast, i.p. AB treatment remained largely ineffective. In conclusion, our data indicate early activation of PARP after cold lesion that is, at least in part, related to nNOS induction and supports the relevance of nNOS and/or PARP inhibition to therapeutic approaches of traumatic brain injury.

Bradykinin B2, but not B1, receptor antagonism has a neuroprotective effect after brain injury.

The aim of the present study was to measure the therapeutic effects of bradykinin antagonists on lesion volume and brain swelling induced by cold injury in the parietal cortex of rat and mouse, respectively. Cold lesion was induced by application of a precooled (-78 degrees C) copper cylinder (3 mm diameter) to the intact dura of rat and mouse for 6 and 30 sec, respectively. At 24 h after the injury, the brains were removed and lesion volume was determined by the triphenyltetrazolium chloride method in rats. In the mouse, brain swelling was expressed as percentage increase in weight of the injured hemisphere which is compared to the contralateral side. After a subcutaneous priming dose of 18 microg/kg, a 1-h pretreatment and 24-h posttreatment using osmotic minipumps (300 ng/kg x min) was applied. Hoe140, a bradykinin receptor 2 antagonist, revealed a 19% reduction of lesion volume (p < 0.05) in the rat and a 14% diminution of brain swelling (p < 0.05) in the mouse. In contrast, the bradykinin receptor 1 antagonist, B 9858, had no effect on lesion volume compared to sham treated rats. When B 9858 was given in combination with Hoe140, a significant reduction in lesion volume was seen which was equivalent to and not different from that seen with Hoe140 alone in the rat. We conclude that brain injury after cold lesion is partially mediated by bradykinin and can be successfully treated with B2 antagonists.

Inhibition of endothelin-1 by the competitive ET(A) receptor antagonist Ro 61-1790 reduces lesion volume after cold injury in the rat.

The aim of the present study was to investigate whether endothelin-1 (ET-1) in cerebral arteries is inhibited by the new, non-peptidergic ET(A) receptor antagonist Ro 61-1790 and, if it is, whether that inhibition reduces the lesion volume induced by cold injury in the parietal cortex. In vitro experiments were performed by measuring the isometric contractions of the rat middle cerebral and basilar arteries. A cold lesion was induced in vivo by the application of a pre-cooled (-78 degrees C) copper cylinder (diameter 3 mm) to the intact dura of rats for 6 s. After 24 h, lesion volume was determined by the triphenyltetrazolium method. In vitro, ET-1 (10(-12) - 3x10(-7) M) caused a dose-dependent contraction under resting conditions in the middle cerebral and basilar arteries of control rats. Ro 61-1790 (3x10(-9) M, 10(-7) M) shifted the concentration-effect curves for ET-1 in a parallel fashion (Emax unaltered). Post-treatment with Ro 61-1790 (10(-7)-10(-5) M) also inhibited the prior contraction elicited by ET-1 (3x10(-9) M) significantly. In vitro ET-1 application 3 h after the intracerebroventricular in vivo administration of Ro 61-1790 showed that the antagonist had reached the arteries and was bound to their ET(A) receptors. Intracerebroventricular pre-treatment of Ro 61-1790 reduced significantly the lesion volume by 23% after the injury. We conclude that ET-1 is involved in the development of secondary brain damage and that intracerebroventricular treatment with Ro 61-1790 reduces the size of the brain lesion caused by cold injury.

A novel brain trauma model in the mouse: effects of dexamethasone treatment.

We describe a novel methodological approach for inducing cold lesion in the mouse as a model of human cortical contusion trauma. To validate its reproducibility and reliability, dexamethasone (Dxm) was repeatedly applied to demonstrate possible antioedematous drug effects. Following the induction of anaesthesia with halothane, the dura was exposed via trephination. Using a micromanipulator a pre-cooled (-78 degrees C) copper cylinder, 3 mm in diameter, was pressed down to a depth of 1 mm onto the dura for 30 s under microscopic control. The body temperature was held constant at 37 degrees C throughout the procedure. Blood pressure (BP), measured by a modified photosensor-monitored tail-cuff method, and acid-base status were not significantly different when analysed before and after cold lesion and prior to sacrifice. However, there was a marginal mixed respiratory and metabolic acidosis. The antioedematous action of Dxm was studied in four standard pre-and post-treatment paradigms: 2x0.5 mg/kg (II), 2x12.5 mg/kg (III) and 4x6.25 mg/kg (IV: 3x pre-, 1x post-treatment: V: 1x pre-, 3x post-treatment). Physiological saline injections served as controls. High doses of Dxm (III-V) significantly attenuated the cold-lesion-induced loss of body mass. Dxm treatment also resulted in a reduction of brain water content (III; P<0.05), and brain swelling (IV; P<0.05) in the lesioned hemisphere, relative to controls. In conclusion, we have characterized a novel cold lesion model in the mouse to mimic traumatic brain injury and the beneficial effect of Dxm treatment on the extent of brain oedema.

Neuronal nitric oxide synthase inhibitor has a neuroprotective effect in a rat model of brain injury.

PURPOSE: The aim of the present study was to assess the effects of neuronal nitric oxide synthase (NOS I) inhibitors and a combination of NOS I and NOS II inhibitors on lesion volume after experimental brain injury. METHODS: Cold lesion of the brain was induced by application of a precooled (.... 78 °C) copper cylinder to the intact dura of the rat for 6 s. Brains were removed 24 h after the injury and lesion volume determined using the triphenyltetrazolium-chloride method. RESULTS: The specific NOS I inhibitor 3-bromo-7-nitroindazole (Br-7-NI) reduced lesion volume significantly by 21 % compared with the vehicle control. In contrast, 7-nitroindazole had no effect on lesion volume. When aminoguanidine, a specific NOS II inhibitor, was adminis-tered after Br-7-NI, lesion volume was significantly reduced but not significantly more than with either compound alone. CONCLUSION: Brain injury after cold lesion is partly mediated by NOS I activity and can be attenuated successfully with Br-7-NI, while coin-hibition of NOS II does not improve the outcome significantly.