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Molecular Control of the δ-opioid Receptor Signaling and Functional Selectivity by SodiumBlgacim, Nuria 27 June 2018 (has links)
Accumulating evidence suggests a prominent role of the arrestin-dependent signaling pathway in triggering most of the deleterious side effects observed using δ-OR targeting drugs. Numerous small molecules targeting the δ-OR receptors have been developed but their pharmacological properties, including their functional selectivity, have been poorly characterized. The absence of functionally selective opioid drugs, and the lack of knowledge of the pharmacological profile and signaling properties of the δ-OR receptor, limits its therapeutic exploitation. The development of functionally selective modulator toward the canonical G protein pathway could importantly increase the therapeutic potential of this receptor while decreasing its deleterious effects. An approach to fine-tune the functional selectivity of a GPCR is by using allosteric modulators. These allosteric modulators would reduce problems associated with drugs targeting the orthosteric site by not chronically activating the receptor. The overall goal of the proposed research is to study the molecular mechanism by which sodium-channel inhibitors allosterically regulates the delta opioid receptor (δ-OR) signaling and functional selectivity. Additionally, the signaling features of the δ-OR signal transduction triggered by biased receptor activation have been investigated. A combination of approaches, including functional studies, molecular modeling and mutagenesis, were used to study the general mechanism underlying the activation and tuning of the δ-OR signal transduction behavior. Thus, this work suggests the druggability of the allosteric sodium pocket by using sodium channel inhibitors. The current research represent discovery of two different allosteric profiles for the β-arrestin recruitment and one allosteric profile for the G-protein pathway at activated DOR and would serve as scaffold for further refinement of modulators with the desired pharmacological profile.
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The Molecular and Behavioural Effects of Glial Modulators Propentofylline and PJ34 in a Rodent Model of Neuropathic PainGRENIER, PATRICK, 31 August 2010 (has links)
Neuronal-glial interactions play an important role in the development of neuropathic (NP) pain states. Earlier studies in our laboratory suggest a role for activated glia in morphine-induced delta opioid receptor (DOR) trafficking by altering DOR functional competence. Thus, chronic treatment with the glial inhibitor, propentofylline (PF) blocks the anti-allodynic and anti-hyperalgesic effects of the DOR agonist deltorphin II. The present study aimed to determine whether NP pain-induced changes in DOR function and trafficking are dependent on glial activation.
The first global aim of this study was to determine the molecular and behavioural effects of glial activation by two glial inhibitors, PF and PJ34 in a model of neuropathic pain. Glial activation was assessed via changes in specific proteins using fluorescent immunohistochemistry (IHC). Neuropathy-induced c-Fos activation was assessed by IHC and pain hypersensitivity was assessed, including mechanical allodynia and spontaneous pain. The second global aim determined the role of activated glia in changes in neuropathy-induced increases in DOR function and DOR subcellular localization using immunogold IHC and transmission electron microscopy (EM).
Chronic PJ34 attenuated chronic constriction injury (CCI)-induced mircoglial, but not astrocyte activation. Chronic administration of either PF or PJ34 attenuated the CCI-induced increase in c-Fos immunoreactive expression. However, neither drug attenuated CCI-induced mechanical allodynia or spontaneous pain.
Both chronic PF and PJ34 administration in NP animals attenuated the anti-allodynic effects of the DOR-selective agonist deltorphin II, suggesting glial inhibition blocks DOR function. However, chronic PF, but not PJ34, blocked the anti-allodynic effects of another DOR agonist, SNC80. These data suggest that SNC80 might be targeting a different DOR molecular species that is not affected by factors released from microglia. Finally, EM experiments revealed that chronic PF treatment prevented the CCI-induced increase in DOR trafficking providing a positive correlation between behaviour and receptor localization.
This study suggests that activated glia contribute to changes in DOR function and trafficking in NP pain states. It also suggests that there is a dissociation between glial inhibition and pain hypersensitivity. / Thesis (Master, Pharmacology & Toxicology) -- Queen's University, 2010-08-31 14:45:47.888
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Atypical Opioid Interactions – Development of Selective Mu-Delta Heterodimer Antagonists, Clinical Opioids at Non-Mu Pain Targets and Endogenous Biased SignalingOlson, Keith Mathew, Olson, Keith Mathew January 2017 (has links)
Most clinical opioids produce analgesia through the Mu Opioid Receptor (MOR) providing the only effective treatment for chronic pain patients. These studies explore three pre-clinical strategies to improve MOR analgesia and minimize side effects: 1) compounds that target G-protein Coupled Receptors (GPCRs) heterodimers, such as heterodimerization between the Delta Opioid Receptor (DOR) and MOR (MDOR); 2) multi-functional compounds that target multiple receptor systems for synergistic effects, such as a MOR agonist and a the serotonin reuptake transporter (SERT) inhibitor; or 3) biased agonists that preferentially activate one signaling pathway associated with analgesia over another associated with side effects at the same receptor.
First, several indirect lines of evidence indicate the MOR-DOR heterodimer (MDOR) can regulate MOR opioid tolerance and withdrawal. However, studying MDOR remains difficult because no selective MDOR antagonists are available. To address this need, we created a novel series of bivalent MDOR antagonists by connecting a low affinity MOR antagonist (H-Tyr-Pro-Phe-D1Nal-NH2) to a moderate affinity DOR (H- Tyr-Tic-OH) antagonist with variable length polyamide spacers (15-41 atoms). In vitro radioligand binding and [35S]-GTPγS coupling assays in MOR, DOR, and MDOR expressing cell lines show bivalent ligands produce a clear length dependence in MDOR but not MOR or DOR cell lines. The lead compound – D24M with a 24-atom spacer – displayed high potency (IC50MDOR = 0.84 nM) with 91-fold selectivity for MDOR:DOR and 1,000-fold MDOR:MOR selectivity.
Second, clinicians have long appreciated subtle but distinct differences in analgesia and side effects of MOR opioids. A variety of non-MOR targets including DOR, Kappa Opioid Receptor (KOR), the Cannabinoid Receptor-1 (CB1), the Sigma-1 Receptor (σ1R), the Dopamine- (DAT), Serotonin- (SERT) and Norepinephrine- Reuptake Transporters (NET) induce analgesia and/or modulate MOR mediated side effects. To determine if different opioid profiles arise from non-MOR interactions, we evaluated the binding and function of nine clinical analgesics at the nine aforementioned targets revealing several clinical opioids contain previously unidentified affinity’s or activity’s. Hydrocodone displayed low affinity at the MOR (KI = 1800 nM) and only ~2 fold less affinity at the σ1R (KI = 4000 nM). Second buprenorphine promoted monoamine influx at DAT, SERT and NET with EC50 > 1,000 nM. These novel interactions suggest the nuanced differences of clinical opioids may arise from previously unappreciated off-target effects. Future studies will assess whether these in vitro results predict hydrocodone and buprenorphine activity in vivo.
Finally, the unique function of the numerous endogenous opioid peptides at a given receptor remains unclear. How endogenous ligands interact with ORs produces obvious drug design consequences. These studies show two endogenous Dynorphin analogues – Dynorphin A and Dynorphin B – differentially regulate two ubiquitous signaling modules – βarrestin2 and Gαi/o– at the DOR. Dynorphin A and Dynorphin B swap potency rank orders for β-arrestin2 recruitment and [35S]-GTPγS signaling, indicating two distinct signaling platforms are formed. Dynorphin A but not Dynorphin B treatment simulated AC super activation, while Dynoprhin B internalized DOR better than Dynorphin A. These in vitro assays suggest endogenous Dynorphin analogues differentially regulate signals at the DOR in vitro. Future work includes further characterizing signaling differences in vitro and testing these changes in vivo.
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EVALUATION OF NATURALLY OCCURRING OPIOIDS AND SYNTHETIC DERIVATIVES FOR THERAPEUTIC APPLICATION IN ALCOHOL ABUSE AND PAINAnna M Gutridge (11819636) 19 December 2021 (has links)
<div>
<p>Historically, natural products
from plants, fungi, bacteria and animals have played an important role in the
discovery of new drugs. In fact, it has been found that 34% of new FDA-approved
drugs over the last 30 years were derived from natural products or their
derivatives. Because of the chemical and structural diversity of natural
products, they continue to be one of the best options for discovering novel
compounds and scaffolds; this is especially true for compounds targeting the
µ-, δ-, and κ- opioid receptors. However, traditional opioids such as morphine cause
many therapeutically limiting side effects. Therefore, there have been immense
efforts to develop opioids that avoid these side effects, with “signal-biased”
compounds being an intense area of interest. The research presented here investigates
of the biased mechanisms of compounds found in and derived from <i>Mitragyna
speciosa</i>, also known as kratom, and <i>Picralima nitida</i>, also known as
akuamma. Kratom and akuamma compounds are examined for their therapeutic
potential in treating alcohol abuse and pain, respectively, two prevalent
conditions with extreme societal and economic costs.</p>
</div>
<br>
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L'inhibition de la production d'AMPc est modulée différemment à court et long terme par l'internalisation du récepteur opioïde deltaBagheri, Haniyeh 08 1900 (has links)
Les opioïdes sont les analgésiques les plus puissants mais leur utilisation prolongée peut entraîner le développement d’une tolérance analgésique. La tolérance serait en partie associée à l’inhibition prolongée de l’adénosine monophosphate cyclique (AMPc) entraînant des changements compensatoires dans la voie de l’adénylate cyclase. Pour cette étude, nous avons eu recours à un biosenseur basée sur la technologie de Bioluminescence Resonnance Energy Transfer (BRET) et qui fournit des mesures de l’AMPc en fonction du temps réel. Durant les 15 premières minutes de stimulation, la réponse de l’AMPc est bi-phasique. Cette progression de la réponse à l’AMPc n’est pas la même pour tous les ligands. Par exemple, la deltorphine II qui induit l’internalisation du récepteur opioïde delta (DOR) affiche une baisse de l’inhibition de l’AMPc. À l’inverse la morphine qui n’induit pas l’internalisation du DOR affiche une réponse stable à l’inhibition de l’AMPc. Ainsi le profil d’internalisation permet de prédire la progression de l’inhibition de l’AMPc à court terme (15 minutes). Nous avons aussi mesuré la réponse à l’AMPc durant 30, 60 et 120 min, étant donné qu’un traitement chronique aux opioïdes induit une tolérance analgésique. Selon les résultats obtenus, le profil d’internalisation du DOR induits par les ligands ne permet pas d’expliquer l’inhibition persistante de l’AMPc. / Opioids are the most powerful analgesics but their prolonged use can cause the development of analgesic tolerance. The tolerance may be associated with the duration of response to cAMP. For this study, we used a biosensor based on Bioluminescence Resonnance Energy Transfer technology that provides measurements of cAMP levels as a function of real time. The aim of our study was to determine whether there is a correlation between the internalization profile of delta-opioid receptor (DOR) when stimulated by different ligands, with respect to the duration of signaling in the short-term (≤15 min) and long term (120 min). This evolution of the duration of cAMP inhibition is biphasic and is explained in part by the efficiency of ligands to promote Gαi activation and by the profile of internalization for each of the different ligands used in this study. For example, deltorphin II which displayed high efficiency to promote Gαi activation and internalization shows a more pronounced decline in cAMP response, unlike morphine which displayed low efficiency to promote Gαi activation, and a poor sequestration, displaying a minimal response decay of inhibition of cAMP. However, ligand ability to promote internalization of DOR does not explain the kinetic profile of a persistent inhibition of cAMP over a longer period of 120 min.
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Développement d'un biosenseur BRET permettant le criblage de drogues qui causent l'activation de canaux Kir3 via les récepteurs couplés aux protéines GRichard-Lalonde, Mélissa 08 1900 (has links)
Les récepteurs couplés aux protéines G forment des complexes multimériques comprenant protéines G et effecteurs. Nous cherchons à caractériser de tels complexes comprenant les récepteurs opioïdes delta (DOR) et les canaux Kir3, qui nous sont d’intérêt vu leur implication dans l’analgésie des opioïdes.
Des expériences d’immunopurification, de BRET et de liaison GTPgS ont été réalisées à l’intérieur de cellules HEK293 transfectées. Les canaux Kir3 ont été co-immunopurifiés avec les DOR, suggérant une interaction spontanée entre récepteur et effecteur. Des essais BRET ont corroboré que l’interaction était présente dans des cellules vivantes et nous ont permis d’identifier une interaction spontanée et spécifique entre DOR/Gg et Gg/Kir3, indiquant leur coexistence en un même complexe. Puisque l’activation du récepteur implique la présence de changements conformationnels à l’intérieur de celui-ci, nous étions intéressés à vérifier si l’information conformationnelle circule à partir du récepteur lié au ligand jusqu’à l’effecteur en aval. Ainsi, nous avons déterminé l’effet de différents ligands sur le signal BRET généré par les paires suivantes : DOR/Gbg, DOR/Kir3 et Kir3/Gbg. Nous avons constaté une modulation de l’interaction DOR/Gbg et Gbg/Kir3 suivant l’ordre d’efficacité des ligands à stimuler la protéine G, ce que nous n’avons pas observé entre DOR et Kir3.
Donc, nous concluons que l’information conformationnelle circule du récepteur au canal Kir3 via la protéine Gbg. Ces résultats nous ont permis de développer un biosenseur BRET (EYFP-Gg2/Kir3.1-Rluc) qui pourrait être utilisé dans le criblage à haut débit afin de détecter de nouvelles molécules ayant une grande efficacité à activer les canaux Kir3. / G protein-coupled receptors form multimeric complexes comprising G protein and effectors. We want to characterize such complexes comprising delta opioid receptors (DOR) and Kir3 channels, which interest us due to their involvement in opioid analgesia.
Immunopurification, BRET and GTPgS binding experiments were done in transfected HEK293 cells. Kir3 channels were co-immunopurified with DOR, implying a spontaneous interaction between the receptor and effector. BRET assays corroborated the presence of this interaction in living cells and allowed us to identify a spontaneous and specific interaction between DOR/Gg and Gg/Kir3, indicating their co-existence within the same complex. Since the activation of the receptor implies it undergoes conformational changes, we were interested in evaluating if the conformational information flows from the ligand-bound receptor until the downstream effector. Hence, we determined the effect of different ligands on the BRET signal that was generated by the following pairs: DOR/Gbg, DOR/Kir3 and Kir3/Gbg. We noticed a modulation of the DOR/Gbg and Gbg/Kir3 interactions that followed the order of efficacy of the ligands to activate the G protein, which we did not observe between DOR and Kir3.
Therefore, we concluded that the conformational information flows from the receptor to the Kir3 channel via the Gbg protein. These results allowed us to develop a BRET biosensor (EYFP-Gg2/Kir3.1-Rluc), which could be used in high throughput screening to detect new molecules that activate Kir3 channels with high efficacy.
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Étude du trafic du récepteur delta-opiacé suite à sa stimulation par différents agonistesCharfi, Iness 06 1900 (has links)
Les opiacés figurent parmi les analgésiques les plus puissants pour le traitement des douleurs sévères. Les agonistes du DOR (récepteur delta opiacé) induisent moins d'effets secondaires que ceux du mu, ce qui les rend une cible d'intérêt pour le traitement des douleurs chroniques. Cependant, ils induisent la tolérance à l'analgésie. Des hypothèses récentes proposent que le potentiel des drogues à induire la tolérance soit la conséquence de la stabilisation de différentes conformations du récepteur induites par la liaison avec différents ligands, chacune ayant différentes propriétés de trafic. Dans ce contexte, nous avons déterminé si différents ligands du DOR différaient dans leur capacité à induire la signalisation et le trafic du récepteur. Nos résultats indiquent que DPDPE et SNC-80 sont les drogues les plus efficaces à inhiber la production d’AMPc, suivis par UFP-512, morphine et TIPP. DPDPE et SNC-80 induisent à eux seuls l’internalisation du DOR dans les cellules HEK-293 de façon dépendante de la β-arrestine mais pas de la GRK2 ni PKC. Ces deux drogues induisent également l’internalisation du DOR dans les neurones corticaux et c’est seulement le DPDPE qui permet au DOR de regagner la membrane des cellules HEK-293 et des neurones après récupération. Cette capacité de recyclage était suggérée comme un mécanisme protégeant contre la survenue de la tolérance. Ces observations indiquent que le DOR peut subir différentes régulations en fonction du ligand lui étant associé. Cette propriété de sélectivité fonctionnelle des ligands pourrait être utile pour le développement de nouveaux opiacés ayant une activité analgésique plus durable. / Opiates are among the most powerful painkillers to treat severe pain. Delta opioid receptor (DOR) agonists induce fewer side effects than mu opioid receptor agonists, which makes them a target of interest for the treatment of chronic pain. However, they induce tolerance to analgesia. Recent hypotheses suggest that drugs tolerance is the result of stabilization of ligand-specific conformations of the receptor, with distinct traffic properties such as internalization and/or recycling. In this context, we determined whether different DOR ligands differed with respect to their ability to induce signaling and receptor trafficking. Our results indicate that DPDPE and SNC-80 are the most effective drugs to inhibit the production of cAMP, followed by UFP-512, morphine and TIPP. Only DPDPE and SNC-80 manage to induce DOR internalization in HEK-293 cells. This effect is dependent on β-arrestin but not on GRK2 or PKC. Of these two internalizing agonists, only DPDPE allows the DOR to recycle back to the membrane of HEK-293 cells after recovery. DPDPE and SNC-80 also trigger similar DOR internalization in cortical neurons, and as observed in HEK293 cells only DPDPE allowed the receptor to recycle back to the membrane. This recycling capacity was suggested as a mechanism to protect against the onset of tolerance. These observations indicate that the DOR can undergo different regulations depending on the ligand bound to it. This property of functional selectivity of DOR ligands could be useful for the development of new opiates with longer lasting analgesic properties.
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Úloha membránového cholesterolu v signalizaci delta-opioidního receptoru Korelace se strukturou plazmatické membrány / The role of membrane cholesterol in delta-opioid receptor signaling Correlation with plasma membrane structureBrejchová, Jana January 2014 (has links)
Study of HEK293 cells stably expressing fusion protein between delta opioid receptor (δ-OR) and pertussis toxin-insensitive mutant of Gi1α protein, δ-OR-Gi1α (Cys351 -Ile351 ), provided the following results. Decrease of plasma membrane cholesterol content (cholesterol depletion) induced by cyclic oligosaccharide β-cyclodextrin did not affect binding of specific δ-OR agonist, [3 H]DADLE. Neither the maximum number of binding sites nor the affinity of [3 H]DADLE binding was changed by cholesterol depletion. However, the ability of δ-OR to activate cognate trimeric G proteins was impaired. EC50 value of agonist-stimulated [35 S]GTPγS binding was an order of magnitude higher. This effect was observed in case of both control and pertussis toxin-treated cells. It means that cholesterol depletion markedly reduced the efficiency of functional coupling of δ-OR to endogenously expressed pertussis toxin-sensitive G proteins of Gi/Go family as well as covalently bound Gi1α (Cys351 -Ile351 ) protein. Unchanged plasma membrane cholesterol content is therefore important requirement for proper δ-OR function. Detection of the effect of cholesterol depletion on the functional activity of δ-OR was supported by the analysis of changes in biophysical state of plasma membrane using fluorescent membrane probes,...
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Conditional gene knockout approach to investigate Delta opioid receptor functions in the forebrain / Étude des fonctions du récepteur opioïde delta exprimé dans le cerveau antérieur grâce à une approche de knockout conditionnelChu Sin Chung, Paul 04 October 2013 (has links)
Les récepteurs opioïde delta (DORs) sont des récepteurs couplés aux protéines G et sont fortement exprimés au niveau du bulbe olfactif, du cortex, du striatum, du noyau basolateral de l'amygdala et des noyaux du pons (Mansour et al., 1995; Le Merrer et al., 2009). Les souris mutantes de première génération (souris knockout, délétion totale du gène) ont déjà permis de démontrer que DOR joue un rôle critique dans le contrôle de la douleur chronique (Gavériaux-Ruff et al., 2011), la régulation de l’activité motrice et des réponses émotionnelles (Filliol et al ., 2000) et l’association drogue-contexte (Le Merrer et al., 2011). Le but de notre étude est d’identifier les circuits neuronaux dans lesquels les DORs contrôlent les processus émotionnels et cognitifs. Nous avons développé une lignée de souris de deuxième génération, dans laquelle les récepteurs sont supprimés spécifiquement dans les neurones GABAergiques du cerveau antérieur. Nous avons ensuite étudié le rôle des DORs exprimés par ces neurones dans les réponses émotionnelles, locomotrices et la sensibilité aux crises épileptiques. / Delta opioid receptors (DORs) are G-protein coupled receptors belonging to the opioid system, which play a central role in chronic pain and emotional responses. DORs are strongly expressed in olfactory bulb, cortex, striatum, basolateral nucleus of the amygdala and pons nuclei. Using constitutive gene knockout, we have previously demonstrated the role of DORs in reducingchronic pain (Gaveriaux-Ruff, Nozaki et al. 2011), anxiety-related behaviors and impulsivity(Olmstead,Ouagazzal et al. 2009), regulating locomotor activity (Filliol, Ghozland et al. 2000) and facilitating context learning (Le Merrer, Faget et al. 2012; Le Merrer, Rezai et al. 2013), Although these functions are well-established, neuronal networks and mechanisms underlying DOR-regulated behaviors remain poorly understood. The aim of this thesis work was to identify neuronal populations and brain circuits that support DOR functions. Recent evidence showed that DOR is highly expressed in GABAergic neurons (Scherrer et al.. 2006;Erbs et al., 2012; Rezai et al.. 2012). We therefore developed a conditional knockout mouse line (Dlx-DOR)by breeding floxed DOR gene (Oprd1) with a transgenic Dlx-5/6-Cre mouse line (Monorv et al., 2006) in order to produce a specific deletion of DOR in GABAergic neurons of the forebrain. We first determined brain distribution of delta receptors in Dlx-DOR at mRNA and protein levels. Then, behavioral analysis were performed to assess whether DORs expressed in forebrain GABAergic neurons contribute to the regulation of emotional contrai, locomotor activity as well as epileptogenic effect of SNC80, the prototypal DOR agonist. Finally, we initiated a project focused on DORs detected at the level of BLA.
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Delta opioid receptor expression in various models of chronic clinical conditions / Expression du récepteur aux opioïdes delta dans différents modèles de pathologies chroniquesCeredig, Rhian Alice 23 June 2016 (has links)
Les travaux présentés ici visent à déterminer l’implication du récepteur aux opioïdes delta dans des modèles de pathologies chroniques telles que la douleur chronique et l’administration d’opiacés. Nous avons mis en oeuvre des approches génétiques, d’imagerie et comportementales afin de décrire précisément les changements de distribution neuronale du récepteur aux opioïdes delta dans un modèle de douleur neuropathique et dans l’administration chronique de morphine, dans les tissus du système nerveux central et périphérique. Nous avons étudié l’implication des récepteurs aux opioïdes delta périphériques dans l’effet thérapeutique de traitements antiallodyniques dans un modèle de douleur neuropathique, et examiné le rôle des récepteurs aux opioïdes delta dans la sensibilité viscérale et dans les effets thérapeutiques de la Prégabaline. Nos travaux ont permis de décrire précisément les changements et l’implication du récepteur aux opioïdes delta dans plusieurs modèles de pathologies chroniques, dans le but de dégager des pistes thérapeutiques futures. / In this work, we used genetic, imaging and behavioral approaches to describe the changes which the distribution of the delta opioid receptor underwent in models of clinical conditions such as neuropathic pain and chronic opioid exposure, at the peripheral and supraspinal levels. We investigated the role of peripheral delta opioid receptor populations in the antiallodynic effect of chronic treatment by antidepressant and β2 agonist molecules in a model of neuropathic pain. We also described the implication of delta opioid receptors in visceral sensitivity, and their involvement in the pain-relieving effects of Pregabalin in a model of neuropathic pain. Thus, we have brought insight as to the role of delta opioid receptors in these various clinical conditions, and thoroughly described the distribution changes; which may lead the way to therapeutic strategies to treat chronic pain or drug addiction.
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