Les mécanismes endogènes de modulation de la douleur et leur dysfonction dans le syndrome de l'intestin irritable

La douleur est une expérience subjective multidimensionnelle accompagnée de réponses physiologiques. Ces dernières sont régulées par des processus cérébraux qui jouent un rôle important dans la modulation spinale et cérébrale de la douleur. Cependant, les mécanismes de cette régulation sont encore mal définis et il est essentiel de bien les comprendre pour mieux traiter la douleur. Les quatre études de cette thèse avaient donc comme objectif de préciser les mécanismes endogènes de modulation de la douleur par la contreirritation (inhibition de la douleur par une autre douleur) et d’investiguer la dysfonction de ces mécanismes chez des femmes souffrant du syndrome de l’intestin irritable (Sii). Dans un premier temps, un modèle expérimental a été développé pour mesurer l’activité cérébrale en imagerie par résonance magnétique fonctionnelle concurremment à l’enregistrement du réflexe nociceptif de flexion (RIII : index de nociception spinale) et des réponses de conductance électrodermale (SCR : index d’activation sympathique) évoqués par des stimulations électriques douloureuses. La première étude indique que les différences individuelles d’activité cérébrale évoquée par les stimulations électriques dans les cortex orbitofrontal (OFC) et cingulaire sont associées aux différences individuelles de sensibilité à la douleur, de réactivité motrice (RIII) et de réactivité autonomique (SCR) chez des sujets sains. La deuxième étude montre que l’analgésie par contreirritation produite chez des sujets sains est accompagnée de l’inhibition de l’amygdale par OFC et d’une modulation du réflexe RIII par la substance grise périaqueducale (PAG) et le cortex somesthésique primaire (SI). Dans les troisième et quatrième études, il est montré que la contreirritation ne produit pas d’inhibition significative de la douleur et du réflexe RIII chez les patientes Sii en comparaison aux contrôles. De plus, les résultats indiquent que la sévérité des symptômes psychologiques est associée au déficit de modulation de la douleur et à une hypersensibilité diffuse chez les patientes Sii. Dans l’ensemble, cette thèse précise le rôle de certaines structures cérébrales dans les multiples composantes de la douleur et dans l’analgésie par contreirritation et montre que les patientes Sii présentent une dysfonction des mécanismes spinaux et cérébraux impliqués dans la perception et la modulation de la douleur.Pain is a subjective experience comprising multiple dimensions and is accompanied by physiological responses. These responses are regulated by neural processes that play a crucial role in cerebral and spinal modulation of pain. However, the mechanisms of this regulation are still not clear and a better understanding of these processes is essential in order to treat pain effectively. The four studies of this thesis were intended to define the central mechanisms of endogenous pain modulation by counterirritation (application of two competing noxious stimuli) and to investigate the dysfunction of these mechanisms in female patients with irritable bowel syndrome (IBS). First, an experimental model was developed in which functional magnetic resonance imaging was used to measure brain activity concurrently to the recording of the nociceptive flexion reflex (RIII: an index of spinal nociceptive processes) and skin conductance responses (SCR: an index of sympathetic activation). The first study indicates that individual differences in shock-evoked brain activity in the orbitofrontal (OFC) and cingulate cortices are associated with individual differences in pain sensitivity, motor reactivity (RIII), and autonomic reactivity (SCR) in healthy volunteers. In the second study, it is shown that counterirritation analgesia produced in healthy volunteers is accompanied by the inhibition of the amygdala by the OFC, and the inhibition of the RIII reflex by the periacqueductal gray matter (PAG) and the primary somatosensory cortex (SI). In the third and fourth studies, pain and RIII reflex were not significantly modulated by counterirritation in patients with IBS in comparison to healthy controls. Furthermore, the severity of psychological symptoms was associated with pain modulation deficits and diffuse hypersensitivity in IBS patients. Together, the results of these studies clarify the functions of pain-related activity in specific brain structures and the mechanisms underlying counterirritation analgesia. Moreover, it is concluded that patients with IBS show a dysfunction of cerebral and spinal processes involved in both the perception and modulation of pain

Cortical integration of bilateral nociceptive signals: when more is less

Integration of nociceptive information is essential to produce adapted responses, to promote body integrity and survival. However, how the brain integrates nociceptive inputs from different body areas remains unknown. The aim of this study was to examine the cortical integration of bilateral nociceptive inputs evoked by laser heat stimuli. Sixteen healthy volunteers (8 F, 8 M; age: 25.5 ± 4.3) were recruited to participate in one session during which painful laser stimuli were applied to their hands with 2 Nd:YAP laser systems. Electroencephalographic activity was recorded to measure laser-evoked potentials and event-related spectral perturbations. Twenty nociceptive stimuli were applied in each of the 4 counterbalanced conditions: (1) right hand, (2) left hand, and both hands with (3) attention to the right or (4) attention to the left. Compared with unilateral conditions, N2 and P2 peak amplitude as well as gamma oscillation power were decreased in bilateral conditions (P 0.1). By contrast, pain was not significantly different in any condition (P > 0.05). These findings show that although more nociceptive inputs reach the brain with multiple nociceptive stimuli, their sensory representation is decreased while pain perception remains unchanged. These interactions between cerebral processing of nociceptive information from different body regions could support coordinated behavioral responses when pain origins from multiple sources. © 2018 International Association for the Study of Pain

Isoflurane anesthesia does not affect spinal cord neurovascular coupling: evidence from decerebrated rats

Neurological examination remains the primary clinical investigation in patients with spinal cord injury. However, neuroimaging methods such as functional magnetic resonance imaging (fMRI) are promising tools for following functional changes in the course of injury, disease and rehabilitation. However, the relationship between neuronal activity and blood flow in the spinal cord on which fMRI relies has been largely overlooked. The objective of this study was to examine neurovascular coupling in the spinal cord of decerebrated rats during electrical stimulation of the sciatic nerve with and without isoflurane anesthesia (1.2%). Local field potentials (LFP) and spinal cord blood flow (SCBF) were recorded simultaneously in the lumbosacral enlargement. Isoflurane did not significantly alter LFP (p = 0.53) and SCBF (p = 0.57) amplitude. Accordingly, neurovascular coupling remained comparable with or without isoflurane anesthesia (p = 0.39). These results support the use of isoflurane in rodents to investigate nociceptive functions of the spinal cord using fMRI. © 2018, The Physiological Society of Japan and Springer Japan KK, part of Springer Nature

Improving working memory and pain inhibition in older persons using transcranial direct current stimulation

The aim of the present study was to examine whether transcranial Direct Current Stimulation (tDCS) could enhance working memory and pain inhibition in older persons. Fifteen volunteers (7 women, 8 men; mean ± SD: 64 ± 4.4 y.o.) participated in two tDCS sessions during which an n-back task was performed with two levels of working memory load, while painful stimulation was delivered at the ankle. The experiment included five within-subject counterbalanced conditions (pain alone and 0-back or 2-back with or without pain) performed twice during each session. Compared with the pre-tDCS baseline, anodal tDCS decreased response times and improved pain inhibition by working memory in the 2-back condition (p 0.3). These results indicate that working memory and pain inhibition can be improved by tDCS in older persons. © 2019 Elsevier B.V. and Japan Neuroscience Societ

Electrophysiological investigation of the contribution of attention to altered pain inhibition processes in patients with irritable bowel syndrome

Irritable bowel syndrome (IBS) is a functional gastrointestinal disorder associated with chronic abdominal pain and altered pain processing. The aim of this study was to examine whether attentional processes contribute to altered pain inhibition processes in patients with IBS. Nine female patients with IBS and nine age-/sex-matched controls were included in a pain inhibition paradigm using counter-stimulation and distraction with electroencephalography. Patients with IBS showed no inhibition of pain-related brain activity by heterotopic noxious counter-stimulation (HNCS) or selective attention. In the control group, HNCS and selective attention decreased the N100, P260 and high-gamma oscillation power. In addition, pain-related high-gamma power in sensorimotor, anterior cingulate and left dorsolateral prefrontal cortex was decreased by HNCS and selective attention in the control group, but not in patients with IBS. These results indicate that the central pain inhibition deficit in IBS reflects interactions between several brain processes related to pain and attention. © 2020 The Author(s)

Integration of bilateral nociceptive inputs tunes spinal and cerebral responses

Together with the nociceptive system, pain protects the body from tissue damage. For instance, when the RIII-reflex is evoked by sural nerve stimulation, nociceptive inputs activate flexor muscles and inhibit extensor muscles of the affected lower limb while producing the opposite effects on the contralateral muscles. But how do the spinal cord and brain integrate concurrent sensorimotor information originating from both limbs? This is critical for evoking coordinated responses to nociceptive stimuli, but has been overlooked. Here we show that the spinal cord integrates spinal inhibitory and descending facilitatory inputs during concurrent bilateral foot stimulation, resulting in facilitation of the RIII-reflex and bilateral flexion. In these conditions, high-gamma oscillation power was also increased in the dorsolateral prefrontal, anterior cingulate and sensorimotor cortex, in accordance with the involvement of these regions in cognitive, motor and pain regulation. We propose that the brain and spinal cord can fine-tune nociceptive and pain responses when nociceptive inputs arise from both lower limbs concurrently, in order to allow adaptable behavioural responses. © 2019, The Author(s)

Regulation of cortical blood flow responses by the nucleus basalis of Meynert during nociceptive processing

Cerebral blood flow (CBF) is essential for neuronal metabolic functions. CBF is partly regulated by cholinergic projections from the nucleus basalis of Meynert (NBM) during cortical processing of sensory information. During pain-related processing, however, this mechanism may be altered by large fluctuations in systemic mean arterial pressure (MAP). The objective of this study was to investigate the contribution of NBM to CBF responses evoked by nociceptive electrical stimuli and how it may be affected by systemic MAP. CBF was recorded in isoflurane-anesthetized rats (n = 8) using laser speckle contrast imaging, in two conditions (intact vs left NBM lesion). Electrical stimulation was applied to the sciatic nerve. Sciatic stimulation produced intensity dependent increases in MAP (p < 0.001) that were almost identical between conditions (intact vs left NBM lesion; p = 0.96). In both conditions, sciatic stimulation produced intensity dependent CBF increases (p < 0.001). After NBM lesion, CBF responses were decreased in the left somatosensory cortex ipsilateral to NBM lesion (p = 0.02) but not in the right somatosensory cortex (p = 0.46). These results indicate that NBM contributes to CBF responses to nociceptive stimulation in the ipsilateral, but not contralateral somatosensory cortex and that CBF response attenuation by NBM lesion is not compensated passively by systemic MAP changes. This highlights the importance of NBM's integrity for pain-related hemodynamic responses in the somatosensory cortex. © 2019 Elsevier B.V. and Japan Neuroscience Societ