Μηχανισμοί νευροεκφύλισης και νευροπροστασίας μετά από τη χορήγηση νευροστεροειδών σε παρκινσονικά μοντέλα

Μούρτζη, Θεοδώρα

29 April 2014

Η Νόσος του Πάρκινσον αποτελεί τη δεύτερη συχνότερη νευροεκφυλιστική ασθένεια μετά τη νόσο του Αλτσχάιμερ, η οποία εμφανίζεται στο 2% των ανθρώπων άνω των 65 ετών. Η μέχρι στιγμής αντιμετώπισή της περιορίζεται σχεδόν αποκλειστικά στη χορήγηση του προδρόμου μορίου της ντοπαμίνης L-DOPA, με σκοπό την αντιμετώπιση των κινητικών προβλημάτων της ασθένειας, η οποία επιφέρει όμως ισχυρές παρενέργειες. Για το λόγο αυτό κρίνεται σκόπιμη η εύρεση νευροπροστατευτικών ουσιών οι οποίες θα καθυστερούν ή θα αναστέλλουν την εξέλιξη της νόσου, με τις ελάχιστες δυνατές παρενέργειες. Ο μυς weaver, φέρει μία αυτοσωμική υπολειπόμενη μετάλλαξη στο γονίδιο Girk2 και αποτελεί το μοναδικό γενετικό μοντέλο της νόσου του Πάρκινσον, το οποίο εμφανίζει προοδευτική απώλεια των ντοπαμινεργικών νευρώνων της μέλαινας ουσίας, η οποία συμβαίνει ενδογενώς. Για το λόγο αυτό θεωρείται ιδανικό για μελέτες νευροπροστασίας. Τόσο in vitro, όσο και in vivo μελέτες στο μοντέλο weaver αλλά και σε άλλα παρκινσονικά μοντέλα (συμπεριλαμβανομένων προηγούμενων αποτελεσμάτων της ομάδας μας, (Διδακτορική Διατριβή Κωνσταντίνου Μποτσάκη, Σεπτέμβριος 2013) αναδεικνύουν ότι το ενδογενές νευροστεροειδές δεϋδροεπιανδροστερόνη (DHEA), καθώς και ο θειικός της εστέρας (DHEA-S) ασκούν ισχυρότατη νευροπροστατευτική δράση στους ντοπαμινεργικούς νευρώνες της μέλαινας ουσίας των παρκινσονικών αυτών ζώων. Επιπλέον, το συνθετικό ανάλογο του DHEA 17β-spiro[5-androstene-17,20-oxiran]-3β-ol (ΒΝΝ-50), το οποίο δεν μεταβολίζεται ενδογενώς σε οιστρογόνα (και θα μπορούσε κατά συνέπεια να είναι κατάλληλο για κλινική χρήση), φαίνεται να ασκεί την ίδια νευροπροστατευτική επίδραση στους ντοπαμινεργικούς νευρώνες της μέλαινας ουσίας των ομοζυγωτικών μυών weaver (Δ.Δ Κωνσταντίνου Μποτσάκη, Σεπτέμβριος 2013), αλλά και σε κυτταροκαλλιέργειες PC12 κυττάρων. Σκοπός της παρούσας εργασίας ήταν η διερεύνηση του μηχανισμού δράσης των νευροπροστατευτικών αυτών ουσιών. Για το λόγο αυτό διερευνήθηκε η πιθανή αντιαποπτωτική δράση των DHEA-S και ΒΝΝ-50, μέσω προσδιορισμού του λόγου των επιπέδων της αντιαποπτωτικής πρωτεΐνης Bcl-2 προς τα επίπεδα της προαποπτωτικής πρωτεΐνης Bax. Ο προσδιορισμός αυτός πραγματοποιήθηκε στο μεσεγκέφαλο φυσιολογικών μυών και μυών weaver ηλικίας Ρ21 ημερών, μετά από χρόνια χορήγηση των νευροστεροειδών (από την Ρ1 έως την Ρ21). Επιπλέον, διερευνήθηκε η πιθανή αντιοξειδωτική δράση του νευροστεροειδούς ΒΝΝ-50, μέσω του προσδιορισμού της ελεύθερης (frMDA) και προσδεδεμένης σε πρωτεΐνες (prMDA) μαλονικής διαλδεΰδης, στο μεσεγκέφαλο φυσιολογικών μυών και μυών weaver ηλικίας Ρ21 ημερών, μετά από χρόνια χορήγηση του αναλόγου (από την Ρ1 έως την Ρ21). Τα αποτελέσματα ανέδειξαν ότι τόσο το DHEA-S, όσο και το BNN-50 ασκούν ισχυρή αντιαποπτωτική δράση στο μεσεγκέφαλο των μυών weaver, αυξάνοντας τον λόγο Bcl-2/Bax (o οποίος εμφανίζεται μειωμένος στo μεσεγκέφαλο των wv/wv ζώων, σε σχέση με τα φυσιολογικά ζώα) κατά 74% και 83% αντίστοιχα, σε σχέση με τα weaver μύες που έλαβαν φυσιολογικό ορό. Η δράση αυτή επιτυχάνεται με διαφορετικό τρόπο, ανάμεσα στα δύο νευροστεροειδή. Πιο συγκεκριμένα, το DHEA-S επαναφέρει πλήρως τα μειωμένα επίπεδα της αντιαποπτωτικής πρωτεΐνης Bcl-2 στo μεσεγκέφαλο των wv/wv ζώων χωρίς να επηρεάζει τα επίπεδα της προαποπτωτικής πρωτεΐνης Bax, ενώ το ΒΝΝ-50 επαναφέρει πλήρως τα αυξημένα επίπεδα της προαποπτωτικής πρωτεΐνης Βax στo μεσεγκέφαλο των wv/wv ζώων, χωρίς να επηρεάζει τα επίπεδα της αντιαποπτωτικής πρωτεΐνης Bcl-2. Επιπλέον, κατέστει σαφές ότι το στεροειδές ΒΝΝ-50 κατέχει και αντιοξειδωτική δράση, αφού επάγει τη δραματική μείωση των επιπέδων της ολικής μαλονικής διαλδεΰδης, τελικού προϊόντος της υπεροξείδωσης των λιπιδίων που εμφανίζεται αυξημένη στo μεσεγκέφαλο των wv/wv ζώων, φέρνοντάς τα κοντά στα φυσιολογικά επίπεδα. Η μείωση αυτή οφείλεται αποκλειστικά στη μείωση των επιπέδων της προσδεδεμένης σε πρωτεΐνες και όχι της ελεύθερης ΜDA, πιθανότατα λόγω της πολύ μεγαλύτερης αύξησης της πρώτης σε σχέση με τη δεύτερη, στο μεσεγκέφαλο των ομοζυγωτικών weaver μυών. Τα παραπάνω αποτελέσματα οδηγούν στο συμπέρασμα ότι τα νευροστεροειδή DHEA-S και ΒΝΝ-50 ασκούν τη νευροπροστατευτική τους επίδραση δρώντας πλειοτροπικά, τουλάχιστον μέσω δύο γραμμών δράσης, της αντιαποπτωτικής και αντιοξειδωτικής. Το γεγονός αυτό είναι ιδιαίτερα σημαντικό καθώς για πρώτη φορά, γίνεται μελέτη του μηχανισμού της δράσης του στεροειδούς ΒΝΝ-50 in vivo. Καθώς το BNN-50 δεν μεταβολίζεται ενδογενώς σε φυλετικές ορμόνες, και θα μπορούσε συνεπώς να είναι κατάλληλο για κλινική χρήση, κρίνεται απαραίτητη η περαιτέρω διερεύνηση του μηχανισμού δράσης του, ώστε να διευκρινιστεί η πιθανή ικανότητα χρήσης του για αντιμετώπιση της σοβαρής αυτής νόσου, μελλοντικά. / Parkinson’s Disease is the second most common neurodegenerative disease, affecting about 2% of the population aged over 65 years old. The most common treatment of the disease until now, is the administration of L-DOPA, a dopamine precursor, in order to reduce the locomotive defects caused by the disease, a drug that causes severe side effects. Hence, the discovery of neuroprotective compounds that can prohibit or at least prolong the progression of the disease is highly required. The weaver mouse carries an autosomic recessive mutation at the Girk-2 gene and consists the only non-invasive genetic model of Parkinson’s Disease that exhibits progressive neurodegeneration of the nigrostriatal dopaminergic neurons. Thus, it is ideal for neuroprotection studies. The endogenous neurosteroif dehydroepiandrosterone (DHEA) as well as its sulphated ester (DHEA-S) exhibit a significant neuroprotective effect on the dopaminergic neurons of the weaver mouse (K. Botsakis phD thesis, 2013), as well as in other in vitro and in vivo studies. Additionally, the synthetic analogue of DHEA 17β-spiro[5-androstene-17,20-oxiran]-3β-ol (BNN-50), that is not metabolized to estrogens in vivo, exhibits the same neuroprotective effect on the dopaminergic neurons of the weaver mouse as DHEA-S (K. Botsakis phD thesis, 2013) as well as in PC12 cell cultures. The aim of this study was the investigation of the mechanism of action of DHEA-S and BNN-50 in vivo. To that extend, we investigated the possible antiapoptotic action of DHEA-S and BNN -50 by determining the ratio of the levels of the antiapoptotic protein Bcl-2 to the levels of pro-apoptotic protein Bax. The assay was performed in the midbrain of control mice and omozygous weaver mice at P21, after chronic administration of neurosteroids ( from P1 to P21 ) . Furthermore , we investigated the potential antioxidant properties of the neurosteroid BNN -50 , through the determination of free (frMDA) and protein-bound (prMDA) malonic dialdeyde in the midbrain of control mice and omozygous weaver mice at P21 after chronic administration of analogue ( from P1 to P21 ) . The results revealed that DHEA-S as well as the BNN-50 exert a very important antiapoptotic action in the weaver mouse midbrain, increasing the ratio of Bcl-2/Bax (that is reduced in the midbrain of the wv / wv animals, compared to control) by 74 % and 83 % respectively, compared with the weaver mice that received saline. This antiapoptotic action is achieved in different ways for the two neurosteroids . More specifically, DHEA-S fully restore the reduced levels of the antiapoptotic protein Bcl-2 in the wv/wv midbrain, without affecting the levels of the proapoptotic protein Bax, while the BNN -50 fully restored the elevated levels of proapoptotic protein Bax in the wv/wv midbrain, without affecting the levels of the antiapoptotic protein Bcl-2. Moreover , it became clear that the steroid BNN -50 possesses significant antioxidant activity, inducing a dramatic reduction in the levels of total MDA , the end product of lipid peroxidation that is displayed increased in the wv/wv midbrain, bringing the MDA level almost to control. The decrease is due to the reduction of the levels of protein-bound and not free MDA , probably due to the much higher increase of the first than the second , in the midbrain of homozygous weaver mice . The aforementioned results suggest that thee neurosteroids DHEA-S and BNN -50 exert their neuroprotective effects by acting pleiotropically , at least through two lines of action, one antiapoptotic and one antioxidant . This is particularly important because for the first time , there is a study of the mechanism of action of steroid BNN -50 in vivo. As BNN-50 is not metabolized endogenously in sex hormones , it could therefore be suitable for clinical use. Hence, it is necessary to further investigate the mechanism of action of the steroid, in order to clarify its possible usability for treating this serious disease in the future .

Νευροεκφύλιση

Νευροπροστασία

Νευροστεροειδή

Νόσος Πάρκινσον

572.579

Neurodegeneration

Neuroprotection

Neurosteroids

Parkinson's

DHEA-S

DHEA

Weaver

Mitochondria, neurosteroids and biological rhythms : implications in health and disease states / Mitochondries, neurostéroïdes et rythmes biologiques : implications physiopathologiques

Grimm, Amandine

14 January 2015

Les mitochondries jouent un rôle primordial dans la survie et la mort cellulaire car elles gouvernent à la fois le métabolisme énergétique et les voies apoptotiques. Un dysfonctionnement mitochondrial dans les neurones peut donc conduire à la neurodégénérescence ou à une neuropathologie. Notre objectif a été d'étudier la régulation de la fonction mitochondriale, en particulier la bioénergétique, pour contribuer à l'amélioration des connaissances actuelles sur les mitochondries. Nos résultats montrent que: i) les neurostéroïdes améliorent la bioénergétique mitochondriale en stimulant la respiration cellulaire en condition normale; ii) les neurostéroïdes réduisent les déficits bioénergétiques observés dans la maladie d'Alzheimer; iii) l'horloge circadienne développe une régulation réciproque avec la bioénergétique et la dynamique mitochondriales. Les résultats de cette thèse ouvrent des perspectives intéressantes pour l'élaboration de stratégies régulatrices de l'homéostasie métabolique chez le sujet sain et chez le patient atteint d'une pathologie due à un dysfonctionnement mitochondrial et/ou une altération des rythmes biologiques. / Mitochondria play a paramount role in cell survival and death because they are orchestrating both energy metabolism and apoptotic pathways, while impaired mitochondrial function leads inevitably to disease, especially neurodegeneration. The purpose of the present thesis was therefore to deepen our understanding of the regulation of mitochondrial function, with a focus on mitochondrial bioenergetics and dynamics. Our key findings were that: i) neurosteroids represent promising molecules which are able to increase mitochondrial bioenergetics via enhancement of mitochondrial respiration in healthy condition; ii) neurosteroids are able to alleviate Alzheimer’s disease-related bioenergetic deficits; iii) the circadian clock is able to regulate mitochondrial bioenergetics and dynamics, and vice versa. Collectively, our results contribute to a better understanding of how mitochondria function, and could have multiple implications with regard to the regulation of metabolic homeostasis in health and disease states associated with mitochondrial impairments and/or circadian disruption.

Mitochondrie

Neurostéroïdes

Bioénergétique

Maladie d’Alzheimer

Rythmes circadiens

Mitochondria

Neurosteroids

Bioenergetics

Alzheimer’s disease

Circadian rhythms

572.8

616.83

Studium působení pregnanolon sulfátu a jeho derivátů na NMDA receptorech. / Characterization of the effect of pregnanolone sulfate and its derivatives on NMDA receptors.

Švehla, Pavel

January 2015

N-methyl-D-aspartate (NMDA) receptors are a subtype of receptors for major excitatory neurotransmitter glutamate in the central nervous system. Their activity is regulated by variety of allosteric modulators, including endogenous neurosteroids and their synthetic analogues. NMDAreceptor dysfunction is implicated in various forms of neurodegeneration and inhibitory neurosteroids have unique therapeutic potential to act as neuroprotective agens. The aim of this work is to investigate relationship between structure and function of neurosteroids with modifications in the D-ring region, using whole-cell patch clamp recording at recombinant GluN1/GluN2B receptors. In this work, we characterised inhibition effect of 19 neurosteroid analogues on NMDA receptor activity and found several of them to be potent NMDA receptor inhibitors. According to our results, there is a linear relationship of IC50 and lipophilicity of a neurosteroid compound, suggesting the plasma membrane plays an important role in neurosteroid access to NMDA receptor. Indeed, using capacitance recording configuration in combination with amphipathic molecule gamma-cyclodextrin, we were able to separate the kinetic of neurosteroid membrane binding from receptor binding. Moreover, these experiments showed that neurosteroid accumulation in the...

Interakce glutamátových receptorů kainátového typu se steroidními látkami / The interaction of kainate subtypes of glutamate receptors with steroid compounds.

Fraňková, Denisa

January 2017

Kainate receptors belong to the family of glutamate receptors, which include NMDA, AMPA and δ receptors. Glutamate receptors are widely found in the brain and therefore they are very dynamically investigated, especially from view of pharmacology, because there is great potential for finding new and more specific modulators which could be used in the treatment of neurodegenerative diseases. The aim of this work was to extend the knowledge about the influence of neurosteroids on homomeric kainate receptors (GluK1, GluK2, GluK3) in which is the study of modulation by neurosteroids still at the beginning. We have investigated interactions of homomeric kainate receptors with selected neurosteroids (pregnenolone sulfate, pregnanolone sulfate, dehydroepiandrosterone, dehydroepiandrosterone sulfate) by using patch clamp method in the configuration of whole-cell recording and also by using microfluorometry. We have found out that the biggest modulating effect on homomeric kainate receptors is caused by pregnenolone sulfate, which inhibits glutamate responses of these receptors. Keywords kainate receptor, glutamate, neurosteroids, steroids, patch-clamp technique

Vlivy neurosteroidů na intracelulární vápník a excitotoxicitu / Neurosteroid effects on intracellular calcium and excitotoxicity

Naimová, Žaneta

January 2019

NMDA receptors belong to the family of ionotropic glutamate receptors, and are involved in synaptic plasticity, learning and memory. However, overactivation by the agonist glutamate can lead to neuronal death - excitotoxicity. Exitotoxicity is a result of excessive calcium influx into the cell through NMDA receptors, and is associated with many cental nervous system (CNS) diseases. Neurosteroids are endogenous compounds capable of NMDA receptor modulation, thus they may have pharmacological potential in the treatment of CNS disorders. The aim of this work was to investigate how pregnanolone sulfate (PA-S) and pregnanolone hemipimelate (PA-hPim) influence somatic calcium and excitotoxicity. We used fluorescence microscopy for recording changes in somatic calcium concentration. We observed that PA-S had no influence on relative somatic calcium concentration. Synthetic analog PA-hPim increased somatic calcium levels slightly. Next, we used oxygen-glucose deprivation (OGD) in vitro to study the influence of neurosteroids on excitotoxicity. Both PA-S and PA-hPim were neuroprotective in the model of acute OGD in vitro. Moreover, PA-S or PA-hPim pretreatment induced ischemic tolerance to a subsequent OGD episode. Our results suggest that neurosteroids PA-S and PA-hPim are potential candidates for the development...

Neurosteroids as regulators of neuroinflammation

Yilmaz, Canelif, Karali, Kanelina, Fodelianaki, Georgia, Gravanis, Achille, Chavakis, Triantafyllos, Charalampopoulos, Ioannis, Alexaki, Vasileia Ismini

19 August 2022

Neuroinflammation is a physiological protective response in the context of infection and injury. However, neuroinflammation, especially if chronic, may also drive neurodegeneration. Neurodegenerative diseases, such as multiple sclerosis (MS), Alzheimer's disease (AD), Parkinson's disease (PD) and traumatic brain injury (TBI), display inflammatory activation of microglia and astrocytes. Intriguingly, the central nervous system (CNS) is a highly steroidogenic environment synthesizing steroids de novo, as well as metabolizing steroids deriving from the circulation. Neurosteroid synthesis can be substantially affected by neuroinflammation, while, in turn, several steroids, such as 17β-estradiol, dehydroepiandrosterone (DHEA) and allopregnanolone, can regulate neuroinflammatory responses. Here, we review the role of neurosteroids in neuroinflammation in the context of MS, AD, PD and TBI and describe underlying molecular mechanisms. Moreover, we introduce the concept that synthetic neurosteroid analogues could be potentially utilized for the treatment of neurodegenerative diseases in the future.

Neurosteroids, neuroinflammation

Neurosteroide, Neuroinflammation

info:eu-repo/classification/ddc/610

ddc:610

Hypothalamic-pituitary-adrenal axis dysfunction in critically ill foals

Dembek, Katarzyna Agnieszka

January 2016

No description available.

Veterinary Services

Animal Sciences

Animal Diseases

Animals

Neurosteroids Induce Allosteric Effects on the NMDA Receptor : Nanomolar Concentrations of Neurosteroids Exert Non-Genomic Effects on the NMDA Receptor Complex

Johansson, Tobias

January 2008

<p>The neurosteroids constitute a group of powerful hormones synthesized and acting in the central nervous system. They participate in a number of important central processes, such as memory and learning, mood and neuroprotection. Their effects emerge from rapid interactions with membrane bound receptors, such as the N-methyl-D-aspartate (NMDA) receptor, the gamma-amino-butyric acid receptor and the sigma 1 receptor. The mechanisms of action are separate from classical genomic interactions. </p><p>The aims of this thesis were to identify and characterize the molecular mechanisms underlying the effects of nanomolar concentrations of neurosteroids at the NMDA receptor. </p><p>The results show that the neurosteroids pregnenolone sulfate (PS) and pregnanolone sulfate 3α5βS) differently modulate the NMDA receptor, changing the kinetics for the NMDA receptor antagonist ifenprodil, through unique and separate targets at the NR2B subunit. The effects that appear to be temperature independent were further confirmed in a calcium imagining functional assay. A second functional study demonstrated that PS and 3α5βS affect glutamate-stimulated neurite outgrowth in NG108-15 cells. </p><p>Misuse of anabolic androgenic steroids (AAS) has powerful effects on emotional states. Since neurosteroids regulate processes involved in mood it can be hypothesised that AAS can interact with the action of neurosteroids in the brain. However, chronic administration of the AAS nandrolone decanoate did not alter the allosteric effects of PS or 3α5βS at the NMDA receptor, but changed the affinity for PS, 3α5βS and dehydroepiandrosterone sulfate to the sigma 1 receptor. The results also showed that the neurosteroids displace ³H-ifenprodil from the sigma 1 and 2 receptors without directly sharing the binding site for ³H-ifenprodil at the sigma 1 receptor. The decreased affinity for the neurosteroids at the sigma 1 receptor may be involved in the depressive symptoms associated with AAS misuse.</p><p>The NMDA receptor system is deeply involved in neurodegeneration and the NMDA receptor antagonist ifenprodil exert neuroprotective actions. The findings that neurosteroids interact with ifenprodil at the NMDA receptor may be an opportunity to obtain synergistic effects in neuroprotective treatment.</p>

Pharmaceutical pharmacology

Pharmacology

neurosteroids

NMDA receptor

NR2B subunit

ifenprodil

sigma receptor

anabolic androgenic steroids

allosteric modulation

non-genomic

Farmaceutisk farmakologi

Neurosteroids Induce Allosteric Effects on the NMDA Receptor : Nanomolar Concentrations of Neurosteroids Exert Non-Genomic Effects on the NMDA Receptor Complex

Johansson, Tobias

January 2008

The neurosteroids constitute a group of powerful hormones synthesized and acting in the central nervous system. They participate in a number of important central processes, such as memory and learning, mood and neuroprotection. Their effects emerge from rapid interactions with membrane bound receptors, such as the N-methyl-D-aspartate (NMDA) receptor, the gamma-amino-butyric acid receptor and the sigma 1 receptor. The mechanisms of action are separate from classical genomic interactions. The aims of this thesis were to identify and characterize the molecular mechanisms underlying the effects of nanomolar concentrations of neurosteroids at the NMDA receptor. The results show that the neurosteroids pregnenolone sulfate (PS) and pregnanolone sulfate 3α5βS) differently modulate the NMDA receptor, changing the kinetics for the NMDA receptor antagonist ifenprodil, through unique and separate targets at the NR2B subunit. The effects that appear to be temperature independent were further confirmed in a calcium imagining functional assay. A second functional study demonstrated that PS and 3α5βS affect glutamate-stimulated neurite outgrowth in NG108-15 cells. Misuse of anabolic androgenic steroids (AAS) has powerful effects on emotional states. Since neurosteroids regulate processes involved in mood it can be hypothesised that AAS can interact with the action of neurosteroids in the brain. However, chronic administration of the AAS nandrolone decanoate did not alter the allosteric effects of PS or 3α5βS at the NMDA receptor, but changed the affinity for PS, 3α5βS and dehydroepiandrosterone sulfate to the sigma 1 receptor. The results also showed that the neurosteroids displace 3H-ifenprodil from the sigma 1 and 2 receptors without directly sharing the binding site for 3H-ifenprodil at the sigma 1 receptor. The decreased affinity for the neurosteroids at the sigma 1 receptor may be involved in the depressive symptoms associated with AAS misuse. The NMDA receptor system is deeply involved in neurodegeneration and the NMDA receptor antagonist ifenprodil exert neuroprotective actions. The findings that neurosteroids interact with ifenprodil at the NMDA receptor may be an opportunity to obtain synergistic effects in neuroprotective treatment.

Pharmaceutical pharmacology

Pharmacology

neurosteroids

NMDA receptor

NR2B subunit

ifenprodil

sigma receptor

anabolic androgenic steroids

allosteric modulation

non-genomic

Farmaceutisk farmakologi

Implication du sexe, des hormones gonadiques et de leurs métabolites dans la réponse nociceptive et la perception de la douleur / Implication of sex, gonadal hormones and their metabolites in nociceptive response and pain perception

Coulombe, Marie-andree

26 June 2013

Plusieurs variables biologiques, psychologiques, ainsi que des différences culturelles, ont été mises en cause afin d'expliquer la différence de perception de la douleur existante entre les hommes et les femmes. Il est connu que les hormones gonadiques influencent la réponse nociceptive chez l’animal et chez l’humain. Le cerveau a aussi la capacité de synthétiser ses propres "hormones sexuelles", les neurostéroïdes. L'objectif de cette thèse était: 1) évaluer les facteurs physiologiques et psychologiques influençant de perception de la douleur chez les hommes et les femmes, 2) évaluer l'implication des androgènes et du cortisol sur les symptômes cliniques et la perception de la douleur chez des sujets atteints de fibromyalgie et sains, et 3) évaluer l'implication des hormones gonadiques et de leurs métabolites 3α5α-réduits dans la transmission et la modulation de la douleur chez animaux les mâles et les femelles par l'utilisation de modèles de douleur comportementaux. / Several biological, psychological, and cultural differences can explain the difference in pain perception between men and women. It is known that gonadal hormones influence the nociceptive response in animals and humans. The brain also has the ability to synthesize its own "sex hormones", also named neurosteroids. The aims of this thesis were: 1) to assess the physiological and psychological factors influencing the difference in pain perception between men and women, 2) to relate the levels of androgens and cortisol with clinical symptoms and pain perception in healthy volunteers and patients with fibromyalgia, and 3) to evaluate the involvement of gonadal hormones and of their 3α5α-reduced metabolites in the transmission of pain and the effectiveness of descending pain modulation systems (DPMS) in males and females using behavioral pain model in rats and mice.

Douleur

Nociception

Sexe

Genre

Stéroïdes

Neurostéroïdes

Récepteur GABA A

Pain

Nociception

Sex

Gender

Steroids

Neurosteroids

GABA A receptors

571.7

612.88