Forced swimming test and fluoxetine treatment: in vivo evidence that peripheral 5-HT in rat platelet-rich plasma mirrors cerebral extracellular 5-HT levels, whilst 5-HT in isolated platelets mirrors neuronal 5-HT changes.

Low levels of central serotonin (5-HT) have been related to the state of depression, and 5-HT is the major target of the newer antidepressant drugs such as selective serotonin reuptake inhibitors (SSRIs). Neurons and platelets display structural and functional similarities, so that the latter have been proposed as a peripheral model of central functions. In particular, in blood more than 99% of 5-HT is contained in platelets, so that one could consider changes in 5-HT levels in platelets as a mirror of changes in central 5-HT. Here, this hypothesis has been studied via the analysis of the influence of: (1) the forced swimming test (FST, which has been proved to be of utility to predict the clinical efficacy of antidepressants in rodents) and (2) treatment with the SSRI fluoxetine upon 5-HT levels monitored in brain regions and in peripheral platelets by means of electrochemical in vivo and ex vivo measurements. The results obtained confirm that the FST increases immobility; furthermore they show a parallel and significant decrease in cerebral (brain homogenate) and peripheral (in platelet-rich plasma, PRP) voltammetric 5-HT levels following the FST in naive rats. In addition, subchronic treatment with fluoxetine was followed by a significant increase in 5-HT levels in PRP, while the same SSRI treatment performed within the FST resulted in a decrease in the 5-HT levels in PRP. However, this decrease was inferior to that observed without SSRI treatment. These data suggest that there is an inverse relationship between immobility and the levels of 5-HT in PRP and that these peripheral 5-HT levels are sensitive to: (1) the FST, (2) the treatment with fluoxetine and (3) the combination of both treatments, i.e. SSRI + FST. It has been reported that SSRI treatment at first inhibits the 5-HT transporter in brain, resulting in increased extracellular 5-HT, while following sustained SSRI treatments decreased intracellular levels of central 5-HT were observed. Accordingly, the present data show that the initial block of 5-HT reuptake is revealed by the selective increase in 5-HT levels (extracellular content) measured in PRP (not in insulated platelets, IPs) the 1st day of fluoxetine treatment. The initial action of this SSRI upon the 5-HT transporter in brain has also been confirmed by in vivo voltammetric data showing selective increase in the serotonergic signal following local injection of fluoxetine into the brain region studied. Successively, the major effect monitored is a decrease in 5-HT levels, which is more evident in IPs than in PRP. However, it is known that following 2 weeks treatment with an SSRI, 5-HT autoreceptors are desensitized and the serotonin synthesis is restored, together with the intracellular 5-HT levels. The present data showing that the levels of 5-HT in IPs tend to return to control values 12 days after the beginning of chronic fluoxetine treatment suggest that 5-HT levels in IPs (intracellular environment) mirror the influence of SSRI treatment upon the central 5-HT system. On the other hand, at day 12 of the chronic fluoxetine treatment, 5-HT content remains low in PRP. Similarly, low levels of 5-HT have been monitored in brain homogenate of rats chronically treated with fluoxetine. This would support the similarity between PRP preparation and brain homogenate as in both cases cells are disrupted by sample preparation. In conclusion this work supports the literature in proposing platelets as a peripheral model of central functions. In particular, the present data support the idea that peripheral 5-HT platelet levels can reflect the state of the central 5-HT system in conditions of depression. Furthermore, the main outcome of this study is that PRP may mirror central extracellular 5-HT levels, whilst IPs mirror neuronal 5-HT changes.

Electrochemical evidence that lacidipine stimulates release of nitrogen monoxide in rat aorta.

Dihidropyridines (DHPs) such as amlodipine, lercanidipine and lacidipine, are compounds capable of vascular protection via their calcium antagonist activity. In addition, they present vascular dilatation function, which has been related to an anti endothelin efficacy, particularly for lacidipine. Recent works have suggested that DHPs modulate vascular relaxation via increase in the release of nitrogen monoxide (NO). Using voltammetry with selective biosensors the present experiments performed in rat aortic rings demonstrate the capability of DHPs to implement endothelial NO at 'useful' and not toxic nanomolar levels, with a maximum efficacy for lacidipine. This activity joins the already described positive effects of these compounds upon vascular functions.

Voltammetric and functional evidence that N-methyl-D-aspartate and substance P mediate rat vascular relaxation via nitrogen monoxide release.

It is known that substance P acts as a vasodilator via activation of the enzyme nitrogen monoxide synthase (NOS) in endothelial tissue and it is suggested that N-methyl-D-aspartate (NMDA) could stimulate nitrogen monoxide (NO) release within nervous tissue. However, the data reported concern NO metabolites (nitrites, nitrates), while there is no clear evidence to date of the action of the latter compound within the aortic tissue. In this study, amperometry with specifically prepared carbon fiber electrodes has been applied to examine the effect of NMDA or substance P upon NO release. In particular, the data obtained confirm that NMDA can stimulate NO release in vivo, in the striatum of anaesthetized rats, and that substance P can stimulate NO release in rat aortic rings (ex vivo experiments). In addition, they indicate that NMDA also stimulates NO release in rat aortic rings. This original data has been confirmed by the observation of a vasorelaxant action of NMDA within noradrenaline precontracted aortic rings. Thus, these experiments provide the first direct evidence that NMDA can mediate vascular relaxation via NO release.