Neutrophil extracellular traps formed after major trauma and subsequent surgery contain mtDNA and represent a novel marker of heightened innate immune activation. They could be considered when timing surgery after trauma to prevent systemic NET-induced inflammatory complications.
Orexinergic signalling is critical to drug relapse-like behaviour; however, the CNS sites(s) of action remain unknown. Two candidate brain regions are the paraventricular thalamus (PVT) and ventral tegmental area (VTA). We assessed the effect of intra-PVT or -VTA administration of the orexin-1 receptor (OrxR1) antagonist SB-334867 on discriminative cue-induced cocaine-seeking. Animals received either PVT- or VTA-directed SB-334867 (0, 3 or 6 μg; 0, 1 or 3 μg, respectively) prior to reinstatement testing elicited by presenting cocaine-paired stimuli (S+). The effect of VTA-directed injections of SB-334867 (0 or 3 μg) on locomotor activity was also assessed. Intra-VTA, but not -PVT, SB-334867 dose-dependently attenuated S+-induced reinstatement (3 μg dose, p<0.01). Intra-VTA SB-334867 had no effect on locomotor activity. We conclude that OrxR1 signalling within the VTA, but not the PVT, mediates cue-induced cocaine-seeking behaviour. We hypothesize that blockade of VTA OrxR1 signalling may reduce nucleus accumbens dopamine in response to drug cue presentation.
BackgroundCocaine- and amphetamine-regulated transcript (CART) has been demonstrated to play a role in regulating the rewarding and reinforcing effects of various drugs of abuse. A recent study demonstrated that i.c.v. administration of CART negatively modulates reinstatement of alcohol seeking, however, the site(s) of action remains unclear. We investigated the paraventricular thalamus (PVT) as a potential site of relapse-relevant CART signaling, as this region is known to receive dense innervation from CART-containing hypothalamic cells and to project to a number of regions known to be involved in mediating reinstatement, including the nucleus accumbens (NAC), medial prefrontal cortex (mPFC) and basolateral amygdala (BLA).Methodology/Principal FindingsMale rats were trained to self-administer cocaine before being extinguished to a set criterion. One day following extinction, animals received intra-PVT infusions of saline, tetrodotoxin (TTX; 2.5 ng), CART (0.625 µg or 2.5 µg) or no injection, followed by a cocaine prime (10 mg/kg, i.p.). Animals were then tested under extinction conditions for one hour. Treatment with either TTX or CART resulted in a significant attenuation of drug-seeking behaviour following cocaine-prime, with the 2.5 µg dose of CART having the greatest effect. This effect was specific to the PVT region, as misplaced injections of both TTX and CART resulted in responding that was identical to controls.Conclusions/SignificanceWe show for the first time that CART signaling within the PVT acts to inhibit drug-primed reinstatement of cocaine seeking behaviour, presumably by negatively modulating PVT efferents that are important for drug seeking, including the NAC, mPFC and BLA. In this way, we identify a possible target for future pharmacological interventions designed to suppress drug seeking.
There are currently a number of imaging techniques available for evaluating the morphology of liposomes and other nanoparticles, with each having its own advantages and disadvantages that should be considered when interpreting data. Controlling and validating the morphology of nanoparticles is of key importance for the effective clinical translation of liposomal formulations. There are a number of physical characteristics of liposomes that determine their in vivo behavior, including size, surface characteristics, lamellarity, and homogeneity. Despite the great importance of the morphology of nanoparticles, it is generally not well-characterized and is difficult to control. Appropriate imaging techniques provide important details regarding the morphological characteristics of nanoparticles, and should be used in conjunction with other methods to assess physicochemical parameters. In this review, we will discuss the advantages and limitations of available imaging techniques used to evaluate liposomal formulations.
Systemic hypoxia stimulates the release of vasopressin (VP) and adrenocorticotropin hormone (ACTH). To examine the involvement of catecholamine cell groups of the ventrolateral medulla (VLM) in the neuroendocrine responses, we have used the c-fos activity mapping technique to compare the effects of hypoxia on VLM catecholamine cells to those on neurosecretory VP and putative corticotropin releasing factor (CRF) containing cells. A limited degree of catecholamine cell activation was evident at predominantly mid-VLM levels at 12% oxygen in the inspired air. Further reduction in inpsirate oxygen levels enhanced recruitment of caudally located VLM catecholamine cells considered to form part of the A1 noradrenergic cell group. Threshold for activation of VP and putative CRF cells occurred at the 10% oxygen level. Unexpectedly, this stimulus also activated neurosecretory oxytocin (OT) cells. With increasing hypoxic severity the number of activated supraoptic VP and OT cells was not significantly different to that observed at the 10% level. However, paraventricular neuroendocrine responses continued to increase with putative CRF containing cells of the medial parvocellular zone having nearly double the level of activity (as measured by the number of cells within this region displaying Fos-like immunoreactivity; FLI) at 6% compared to that apparent to the 10% level of hypoxia. Paraventricular VP cells displaying FLI were also increased at the most severe levels of hypoxia but this effect was much less marked than the medial parvocellular response. Consistent with a role for VLM catecholamine cells in generation of neuroendocrine cell responses to hypoxia, unilateral VLM lesions, restricted to the caudal two thirds of the catecholamine cell column, resulted in significant reductions in the responses of all three cell types. These results, in addition to establishing a role for VLM catecholamine cells in neuroendocrine cell responses to systemic hypoxia, have important general implications for catecholamine cell group involvement in neuroendocrine regulation.
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