306 research outputs found
Apoptotic gene expression in neuropathic pain
Pain initiated or caused by a primary lesion or dysfunction in the nervous system is defined as neuropathic pain. It results from direct injury to nerves in the peripheral or central nervous system and is associated with several clinical symptoms. Neuropathic pain treatment is extremely difficult, as it is a very complex disease, involving several molecular pathways. Excitatory or inhibitory pathways controlling neuropathic pain development show altered gene expression, caused by peripheral nerve injury.
This study used several experimental pain models to demonstrate the occurrence of programmed cell death in the centers controlling pain induction and maintenance, such as spinal cord and pre-frontal cortex. We combined behavioural, molecular and morphological approaches to assess the involvement of bcl-2 gene family and caspases in neuropathic pain. Chronic constriction injury (CCI) and spared nerve injury (SNI) of rodent sciatic nerve induced the appearance of pain-like behaviours, such as hyperalgesia and allodynia. An early (2-3 days post-CCI) apoptosis appeared in the spinal cord neurons as the pro-apoptotic bax gene increased (320±19%). The incidence of apoptosis appeared to be limited to the first few days following nerve injury. Subsequently, increased expression of anti-apoptotic bcl-2 family genes may inhibit further neuron loss. SNI triggered apoptotic pathway and caspases activation in pre-frontal cortex 7, 14, and 21 days post-injury. Among the time-points analyzed, RT-PCR analysis showed increased expression of the bax/bcl-2 ratio (40±2%), bid (16±2%), caspase-1 (84±3%), caspase-8 (53±6%), caspase-9 (25±6%), caspase-12 (58±2%), TNF (32±2%) genes in the cortex by 7 days post-injury. Western blot analysis showed increased active Caspase-3 protein levels in the cortex at 3, 7, 14, and 21 post-surgery. This study shows that apoptotic genes could be an useful pharmacological target in neuropathic pain controlling.

Neuronutraceuticals Modulate Lipopolysaccharide- or Amyloid-β 1-42 Peptide-Induced Transglutaminase 2 Overexpression as a Marker of Neuroinflammation in Mouse Microglial Cells
Background: Tissue type 2 Transglutaminase (TG2, E.C. 2.3.2,13) is reported to be involved in phagocytosis of apoptotic cells in mouse microglial BV2 cells and peripheral macrophages. In this study, by using Lipopolysaccharide (LPS)- or Amyloid-beta 1-42 (Abeta 1-42) peptide-stimulated mi-croglial cell line BV2 and mouse primary microglial cells, we examined the effects of different neuronutraceutical compounds, such as Curcumin (Cu) and N-Palmitoylethanolamine (PEA), known for their anti-inflammatory activity, on TG2 and several inflammatory or neuroprotective biomarkers expressions. Methods: Mouse BV2 cells were treated with LPS or Abeta1-42 in presence of Curcumin or PEA, in order to evaluate the expression of TG2 and other inflammatory or neuro-protective markers by RealTime PCR and Western Blot analyses. Results: Curcumin and PEA were capable to reduce TG2 expression in mouse microglial cells during co-treatment with LPS or Abeta 1-42. Conclusions: The results show the role of TG2 as an important marker of neuroinflamma-tion and suggest a possible use of Curcumin and PEA, in order to reduce LPS- or Abeta1-42-induced TG2 overexpression in mouse microglial cells
Role of Neurotrophins in Neuropathic Pain
Neurotrophins (NTs) belong to a family of structurally and functionally related proteins, they are the subsets of neurotrophic factors. Neurotrophins are responsible for diverse actions in the developing peripheral and central nervous systems. They are important regulators of neuronal function, affecting neuronal survival and growth. They are able to regulate cell death and survival in development as well as in pathophysiologic states. NTs and their receptors are expressed in areas of the brain that undergo plasticity, indicating that they are able to modulate synaptic plasticity
Autism Spectrum Disorders: Is Mesenchymal Stem Cell Personalized Therapy the Future?
Autism and autism spectrum disorders (ASDs) are heterogeneous neurodevelopmental disorders. They are enigmatic conditions that have their origins in the interaction of genes and environmental factors. ASDs are characterized by dysfunctions in social interaction and communication skills, in addition to repetitive and stereotypic verbal and nonverbal behaviours. Immune dysfunction has been confirmed with autistic children. There are no defined mechanisms of pathogenesis or curative therapy presently available. Indeed, ASDs are still untreatable. Available treatments for autism can be divided into behavioural, nutritional, and medical approaches, although no defined standard approach exists. Nowadays, stem cell therapy represents the great promise for the future of molecular medicine. Among the stem cell population, mesenchymal stem cells (MSCs) show probably best potential good results in medical research. Due to the particular immune and neural dysregulation observed in ASDs, mesenchymal stem cell transplantation could offer a unique tool to provide better resolution for this disease
Moving towards supraspinal TRPV1 receptors for chronic pain relief
Transient receptor potential vanilloid type 1 (TRPV1) receptor is a non selective ligand-gated cation channel activated by capsaicin, heat, protons and endogenous lipids termed endovanilloids. As well as peripheral primary afferent neurons and dorsal root ganglia, TRPV1 receptor is also expressed in spinal and supraspinal structures such as those belonging to the endogenous antinociceptive descending pathway which is a circuitry of the supraspinal central nervous system whose task is to counteract pain. It includes periaqueductal grey (PAG) and rostral ventromedial medulla (RVM) whose activation leads to analgesia. Such an effect is associated with a glutamate increase and the activation of OFF and inhibition of ON cell population in the rostral ventromedial medulla (RVM). Activation of the antinociceptive descending pathway via TPRV1 receptor stimulation in the PAG may be a novel strategy for producing analgesia in chronic pain. This review will summarize the more recent insights into the role of TRPV1 receptor within the antinociceptive descending pathway and its possible exploitation as a target for new pain-killer agents in chronic pain conditions, with particular emphasis on the most untreatable pain state: neuropathic pain
Long-Lasting Effects of Human Mesenchymal Stem Cell Systemic Administration on Pain-Like Behaviors, Cellular, and Biomolecular Modifications in Neuropathic Mice
Background: Neuropathic pain (NP) is an incurable disease caused by a primary lesion in the nervous system. NP is a progressive nervous system disease that results from poorly defined neurophysiological and neurochemical changes. Its treatment is very difficult. Current available therapeutic drugs have a generalized nature, sometime acting only on the temporal pain properties rather than targeting the several mechanisms underlying the generation and propagation of pain. Methods: Using biomolecular and immunohistochemical methods, we investigated the effect of the systemic injection of human mesenchymal stem cells (hMSCs) on NP relief. We used the spared nerve injury (SNI) model of NP in the mouse. hMSCs were injected into the tail vein of the mouse. Stem cell injection was performed 4 days after sciatic nerve surgery. Neuropathic mice were monitored every 10 days starting from day 11 until 90 days after surgery. Results: hMSCs were able to reduce pain-like behaviors, such as mechanical allodynia and thermal hyperalgesia, once injected into the tail vein. An anti-nociceptive effect was detectable from day 11 post surgery (7 days post cell injection). hMSCs were mainly able to home in the spinal cord and pre-frontal cortex of neuropathic mice. Injected hMSCs reduced the protein levels of the mouse pro-inflammatory interleukin IL-1β and IL-17 and increased protein levels of the mouse anti-inflammatory interleukin IL-10, and the marker of alternatively activated macrophages CD106 in the spinal cord of SNI mice. Conclusion: As a potential mechanism of action of hMSCs in reducing pain, we suggest that they could exert their beneficial action through a restorative mechanism involving: (i) a cell-to-cell contact activation mechanism, through which spinal cord homed hMSCs are responsible for switching pro-inflammatory macrophages to anti-inflammatory macrophages; (ii) secretion of a broad spectrum of molecules to communicate with other cell types. This study could provide novel findings in MSC pre-clinical biology and their therapeutic potential in regenerative medicine
5'-C-ethyl-tetrazolyl-N 6-substituted adenosine and 2-chloro-adenosine derivatives as highly potent dual acting A1 adenosine receptor agonists and A3 adenosine receptor antagonists
A series of N(6)-substituted-5'-C-(2-ethyl-2H-tetrazol-5-yl)-adenosine and 2-chloro-adenosine derivatives was synthesized as novel, highly potent dual acting hA1AR agonists and hA3AR antagonists, potentially useful in the treatment of glaucoma and other diseases. The best affinity and selectivity profiles were achieved by N(6)-substitution with a 2-fluoro-4-chloro-phenyl- or a methyl- group. Through an in silico receptor-driven approach, the molecular bases of the hA1- and hA3AR recognition and activation of this series of 5'-C-ethyl-tetrazolyl derivatives were explained
Palmitoylethanolamide reduces granuloma-induced hyperalgesia by modulation of mast cell activation in rats
The aim of this study was to obtain evidences of a possible analgesic role for palmitoylethanolamide (PEA) in chronic granulomatous inflammation sustained by mast cell (MC) activation in rats at 96 hours. PEA (200-400-800 μg/mL), locally administered at time 0, reduced in a concentration-dependent manner the expression and release of NGF in comparison with saline-treated controls. PEA prevented nerve formation and sprouting, as shown by histological analysis, reduced mechanical allodynia, evaluated by Von Frey filaments, and inhibited dorsal root ganglia activation. These results were supported by the evidence that MCs in granuloma were mainly degranulated and closely localized near nerve fibres and PEA significantly reduced MC degranulation and nerves fibre formation. These findings are the first evidence that PEA, by the modulation of MC activation, controls pain perception in an animal model of chronic inflammation, suggesting its potential use for the treatment of all those painful conditions in which MC activation is an initial key step
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