Methods for implatation of cranial windows for the direct observations of the pial microcirculation in experimental animals are described in detail. These techniques are suitable for both acute experiments in anesthetized animals and chronic implantation permitting several months of observation in awake animals. Experience over several years shows that these techniques have an acceptably low rate of failure, are low in cost and can easily be mastered in most laboratories. They make possible observation of the microcirculation and accurate measurement of the diameter of pial vessels, and permit study of the effects on the microcirculation of a variety of maneuvers and vasoactive agents which can be studied by direct application as well as by intravascular administration. Because they preserve the intergrity of the skull, the techniques permit study of the cerebral microcirculation under conditions closely approximating the normal environment of these vessels.
Background-The mechanism of delayed preconditioning induced by activation of adenosine A 1 receptors (A 1 ARs) is not fully understood. We determined the role of inducible nitric oxide synthase (iNOS) in mediating adenosine-induced late cardioprotection using pharmacological inhibitors and iNOS gene-knockout mice. Methods and Results-Adult male mice were treated with saline or an A 1 AR agonist, 2-chloro-N 6 -cyclopentyladenosine (CCPA). Twenty-four hours later, the hearts were perfused in Langendorff mode and subjected to 30 minutes of global ischemia followed by 30 minutes of reperfusion. 8-Cyclopentyl-1,3-dipropylxanthine (DPCPX; 0.1 mg/kg IP) and S-methylisothiourea (SMT; 3 mg/kg IP) were used to block A 1 ARs and iNOS, respectively. Infarct size (IS) was measured by triphenyltetrazolium chloride staining, and iNOS expression was measured by Western blots. Myocardial IS was reduced from 24.0Ϯ3.2% in the saline group to 12.2Ϯ2.5% in CCPA-treated mice (PϽ0.05). The infarct-reducing effect of CCPA was abrogated by DPCPX (29.3Ϯ3.4%) and SMT (32.3Ϯ2.6%) and was absent in mice with targeted ablation of iNOS (23.9Ϯ1.6%). CCPA produced improvement in postischemic end-diastolic pressure, developed pressure, and rate-pressure product, which was also blocked by DPCPX and SMT. Increased iNOS protein expression observed in CCPA-treated hearts was diminished by DPCPX.
Conclusions-Selective
Traumatic brain injury (TBI) triggers a complex pathophysiological cascade, leading to cell death. A major factor in the pathogenesis of TBI is neuronal overloading with calcium, causing the opening of mitochondrial permeability transition pores (MPTP), which consequently inhibit normal mitochondrial function. The immunosuppressant Cyclosporin A (CsA) has been shown to block MPTPs, and to be neuroprotective in ischemia and TBI. However, the translation of these effects on mitochondrial function, into behavioral endpoints has not been investigated thoroughly. Therefore, we tested the effect of a low, clinically evaluated, CsA dose of 0.125 mg/kg (infused for 3 h) and a higher "known" neuroprotective dose of 18.75 mg/kg on brain tissue O(2) consumption, and on motor and cognitive performance following lateral fluid percussion injury (FPI) in rats. CsA at both concentrations abolished the 25% decrease in O(2) consumption (VO(2)), seen in saline-treated animals at 5 h post-FPI. Furthermore, the lower dose of CsA also ameliorated acute motor deficits (days 1-5 post-FPI) and learning and memory impairments in a Morris water maze test on days 11-15 post-FPI. Although, the higher dose of CsA improved cognitive performance, it worsened acute motor functional recovery. These results suggest, that the CsA-induced preservation of mitochondrial function, as assessed by tissue O(2) consumption, directly translated into improvements in motor and cognitive behavior.
Analysis of data in the current study demonstrates that HBO significantly increases brain tissue PO2 after injury. Nonetheless, treatment with HBO was insufficient to overcome injury-induced reductions in mitochondrial redox potential at 1 hour postinjury but was able to restore redox potential by 4 hours postinjury. Furthermore, HBO induced an increase in VO2 in both injured and sham-injured animals. Taken together, these data demonstrate that mitochondrial function is depressed by injury and that the recovery of aerobic metabolic function may be enhanced by treatment with HBO.
This study indicates that the intravenous infusion of 100 mM L-lactate provided the optimal concentration of the substrate to ameliorate cognitive impairment, probably via the regeneration of ATP following TBI in rats.
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