Paraventricular oxytocinergic hypothalamic prevention or interruption of long-term potentiation in dorsal horn nociceptive neurons: electrophysiological and behavioral evidence.

Spinal long-term potentiation (LTP) elicited by noxious stimulation enhances the responsiveness of dorsal horn nociceptive neurons to their normal input, and may represent a key mechanism of central sensitization by which acute pain could turn into a chronic pain state. This study investigated the electrophysiological and behavioral consequences of the interactions between LTP and descending oxytocinergic antinociceptive mechanisms mediated by the hypothalamic paraventricular nucleus (PVN). PVN stimulation or intrathecal oxytocin (OT) reduced or prevented the ability of spinal LTP to facilitate selectively nociceptive-evoked responses of spinal wide dynamic range (WDR) neurons recorded in anesthetized rats. In a behavioral model developed to study the effects of spinal LTP on mechanical withdrawal thresholds in freely moving rats, the long-lasting LTP-mediated mechanical hyperalgesia was transiently interrupted or prevented by either PVN stimulation or intrathecal OT. LTP mediates long-lasting pain hypersensitivity that is strongly modulated by endogenous hypothalamic oxytocinergic descending controls.

The lateral ventromedial thalamic nucleus spreads nociceptive signals from the whole body surface to layer I of the frontal cortex.

Neurons within the lateral ventromedial thalamic nucleus (VMl) convey selectively nociceptive information from all parts of the body. The present experiments were performed in rats and were designed to determine the organization of cortical projections from VMl neurons. In a first series of experiments, these cells were characterized electrophysiologically and individually labelled in a Golgi-like manner following juxtacellular electrophoresis of biotin-dextran. In a second experimental series, topical applications of the tracers fluorogold and tetramethylrhodamine-labelled dextran were placed into both the rostral-most and caudal areas of layer I of the dorsolateral frontal cortex, respectively. All VMl nociceptive neurons were fusiform and their full dendritic arborizations were bipolar, extending in the lateromedial axis. VMl cells are thus particularly well located to receive widespread nociceptive inputs via a brainstem link, viz. the medullary subnucleus reticularis dorsalis. VMl neurons driven by 'whole body' nociceptive receptive fields project to the rostral part of the layer I of the dorsolateral frontal cortex. These projections are widespread because double-labelling data showed a great number of VMl neurons labelled from both rostral and caudal dorsolateral cortices. The VMl comprises a homogeneous, organized subset of thalamic neurons that allow any signals of pain to modify cortical activity in a widespread manner, by interacting with the entire layer I of the dorsolateral neocortex.

[Neurobiology of trigeminal pain]. / Neurobiologie de la douleur trigéminale.

The brainstem trigeminal complex integrates somatosensory inputs from orofacial areas and meninges. Recent studies have shown the existence of a double representation of pain within the brainstem, at the level of both caudalis and oralis subnuclei. Noxious messages are mainly conveyed by C-fibers that activate the subnucleus caudalis neurons. These neurons in turn activate the subnucleus oralis whose neurons share similar features with the deep spinal dorsal horn neurons. In contrast with the nearness of the laminar organization of the dorsal horn, the vertical organization of the trigeminal complex offers an easier access for the study of segmental mechanisms of nociceptive processing. This model allowed us to show the existence of subtle NMDA-related mechanisms of segmental nocious processing. The trigeminal complex conveys nociceptive messages to several brainstem and thalamic relays that activate a number of cortical areas responsible for pain sensations and reactions. Cortical processing is sustained by reciprocal interactions with thalamic areas and also by a direct modulation of their pre-thalamic relays. The dysfunction of these multiple modulatory mechanisms probably plays a key role in the pathophysiology of chronic trigeminal pain.

Convergence of cutaneous, muscular and visceral noxious inputs onto ventromedial thalamic neurons in the rat.

We have recently described a population of neurons in the lateral part of the ventromedial thalamus (VMl), that respond exclusively to noxious cutaneous stimuli, regardless of which part of the body is stimulated. The purpose of the present study was to investigate the convergence of cutaneous, muscular and visceral noxious inputs onto single, VMl neurons in anesthetized rats. VMl neurons were characterized by their responses to Adelta- and C-fiber activation as well as noxious heat applied to the hindpaw. We investigated whether they responded also to colorectal distensions. In an additional series of experiments, we tested the effects of colorectal, intraperitoneal, intramuscular and subcutaneous applications of the chemical irritant mustard oil (MO). The present study shows that a population of neurons located within the thalamic VMl nucleus, carries nociceptive somatosensory signals from the entire body. All these neurons responded to noxious cutaneous and intramuscular stimuli but not to levels of distension that could be considered innocuous or noxious, of the intact and inflammed colon and rectum. Although colorectal distension did not elicit VMl responses, convergence of visceral as well as muscle and cutaneous nociceptors was demonstrated by the increases in ongoing (background) discharges following intracolonic MO. A distinct effect is seen after MO injection into the lumen of the colon: an increase in ongoing activity for 15min but still a lack of effect of colorectal distension. Moreover, following inflammation induced by subcutaneous injections of MO VMl neurons developed responses to both thermal and mechanical innocuous skin stimulation, reminiscent of allodynia phenomena. It is suggested that the VMl contributes to attentional aspects of nociceptive processing and/or to the integration of widespread noxious events in terms of the appropriate potential motor responses.