Brain research
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Azotemia (48 h) decreases the risk of brain damage in rats after correction of chronic hyponatremia.
Brain myelinolysis complicates excessive correction of chronic hyponatremia in man. Myelinolysis appear in rats for correction levels deltaSNa) > 20 mEq/l/24 h. We previously showed in rats that when chronic hyponatremia was corrected with urea, the incidence and the severity of brain lesions were significantly reduced compared to hypertonic saline. ⋯ Similar catastrophic outcome was observed in the non-azotemic controls (control 2, no HgCl2 administration, n = 15, urea: 5 mmol/l). All of them developed myelinolysis-related neurologic symptoms and only four of them survived with severe brain lesions (survival 12/15 in Group I vs. 5/24 in pooled controls 1 and 2, p < 0.001). In conclusion, we showed for the first time that chronic hyponatremic rats with azotemia (48 h) tolerated large increases in SNa (approximately 30 mEq/l/24 h) without significant brain damage.
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The role of nitric oxide in cerebrovascular response to hypotension was analyzed by evaluating the changes in cerebrovascular resistance after inhibition of nitric oxide synthesis with Nw-nitro-L-arginine methyl ester (L-NAME) during three types of hypotension in conscious goats. Blood flow to one brain hemisphere was electromagnetically measured, hypotension was induced by controlled bleeding, and by i.v. administration of hexametonium (ganglionic blocker) or of diazoxide (vasodilator drug), and L-NAME was injected by i.v. route (35 mg kg-1). Under control conditions (13 goats), L-NAME increased arterial pressure from 98 +/- 3 to 123 +/- 4 mmHg and decreased cerebral blood flow from 65 +/- 3 to 40 +/- 3 ml min-1 (all P < 0.001); cerebrovascular resistance increased from 1.52 +/- 0.04 to 3.09 +/- 0.013 mmHg ml-1 min-1 (P < 0.01) (delta = 1.59 +/- 0.12 mmHg ml-1 min-1). ⋯ During this hypotension, L-NAME increased arterial pressure to 87 +/- 6 mmHg (P < 0.05) and did not affect the hypotensive values for cerebral blood flow (P > 0.05); cerebrovascular resistance increased from the hypotensive values to 1.53 +/- 0.13 mmHg ml-1 min-1 (P < 0.05) (delta = 0.36 +/- 0.06 mmHg-1 ml-1 min-1), and this increment was lower than under control conditions (P < 0.01). Therefore, the role of nitric oxide in cerebrovascular response to hypotension may differ in each type of hypotension, as this role during hemorrhagic hypotension may not change and during hypotension by ganglionic blockade or diazoxide may decrease. These differences may be related to changes in nitric oxide release as stimuli on the endothelium (shear stress and sympathetic activity) may vary in each type of hypotension.
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The neurophysiological mechanisms involved in diffuse noxious inhibitory controls (DNIC) have been investigated extensively, but information is lacking about the effect of different stimulus modalities and somatic locations on the effectiveness of DNIC. This study is the first to examine the hypoalgesic effects on a deep, tonic and painful test stimulus (TS) of both painful and non-painful conditioning stimuli (CS) applied to different sites of the body. Two separate experiments were performed using painful electrical stimulation of the left anterior tibialis muscle as the TS. ⋯ Compared with TS alone, the perceived pain intensity of the TS increased (4.5 +/- 1.8%; P = 0.019) in combination with the painful CS applied to the same muscle (ipsilateral homotopic site), but decreased (-25.3 +/- 1.4%; P < 0.001) in combination with non-painful CS at the same site. Both painful and non-painful CS applied at the three heterotopic sites caused significant and site-dependent decreases in the perceived pain intensity of the TS (range 15%-37%; P < 0.05). We conclude that a hypoalgesic DNIC-like effect on muscle pain is not produced exclusively by painful stimuli, and that the valence and magnitude of the modulation depend on the nature of the CS and its location relative to the applied TS.
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Contusive spinal cord injury (SCI) may result in central neuropathic pain marked by allodynia-like features in the dermatomes close to the level of injury. The aim of this study was to compare the laminar distribution of activated neurons (as determined by c-fos immediate early gene expression) in the spinal cord immediately above the level of a SCI in rats with or without allodynia-like features. Non-noxious mechanical stimulation was applied to half the animals in the dermatomes corresponding to the level of injury prior to perfusion. ⋯ Animals that had allodynia also demonstrated a significant increase in the level of c-fos labelling in lamina III, IV and V of the dorsal horn without stimulation. Thus, allodynia following SCI is associated with significant increases in basal and evoked c-fos expression ("neuronal activity") in response to non-noxious mechanical stimulation. The data also suggest that allodynia-like behaviour following SCI cannot be accounted for solely by changes occurring at a spinal level.
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Some of the neurological deficits that emerge after aneurysmal subarachnoid hemorrhage (SAH) in humans are presumably caused by ischemic brain damage consequential to SAH-induced delayed cerebral vasospasm. This vasospasm probably results from an imbalance among vasoactive factors released from both the clot formed by extravasated blood and adjacent tissues, and in particular from a decrease in the endothelium-derived relaxing factor nitric oxide (NO). Brain ischemia is also known to elevate brain production and deposition of beta-amyloid, and to induce a delayed increase in total NO synthase (NOS) activity due to induction of expression of so-called induced NOS isoform, phenomena that may secondarily contribute to SAH-related brain damage. ⋯ Intraperitoneal (i.p.) administration of 0.18 mmol/kg hydroxylamine hydrochloride (12.5 mg/kg) twice daily for 7 days beginning immediately after the first 'hemorrhage' (intracisternal blood injection) reduced basilar arterial wall damage and attenuated post-SAH neurological deficit. It also reduced the SAH-related increases in hippocampal and cortical beta-APP immunoreactivities and hippocampal NOS activity measured 24 h after commencement of the treatment. These results indicate that intracellular NO donors that yield NO through the action of widely distributed enzymes in brain cells (cytochromes, catalase) can attenuate detrimental effects of SAH.