Antinociceptive action of vaginocervical stimulation in rat spinal cord: 2-DG analysis

Activation and circuitry of uterine-cervix-related neurons in the lumbosacral dorsal root ganglia and spinal cord at parturition

Stimulation of the uterine cervix at parturition activates neural circuits involving primary sensory nerves and supraspinally projecting neurons of the lumbosacral spinal cord, resulting in output of hypothalamic neurohormones. Dorsal root ganglia (DRG) and spinal neurons of these circuits are not well-characterized. The objectives of this study were to detail the activation of DRG and spinal neurons of the L6/S1 levels that are stimulated at late pregnancy, verify hypothalamic projections of activated spinal neurons, and determine whether activated neurons express estrogen receptor-alpha (ERalpha). Expression of phosphorylated cyclic-AMP response element-binding protein (PCREB) and Fos immunohistochemistry were used to "mark" activated DRG and spinal neurons, respectively. Retrograde tracing identified uterine-cervix-related and spinohypothalamic neurons. Baseline PCREB expression in the DRG increased during pregnancy and peaked during the last trimester. Some PCREB-expressing neurons contained retrograde tracer identifying them as cervix-related neurons. Fos-expressing neurons were few in spinal cords of nonpregnant and day 22 pregnant rats but were numerous in parturient animals. Some Fos-expressing neurons located in the dorsal half of the spinal cord contained retrograde tracer identifying them as spinohypothalamic neurons. Some DRG neurons expressing PCREB also expressed ERalpha, and some spinal neurons activated at parturition projected axons to the hypothalamus and expressed ERalpha. These results indicate that DRG and spinal cord neurons are activated at parturition; that those in the spinal cord are present in areas involved in autonomic and sensory processing; that some spinal neurons project axons to the hypothalamus, ostensibly part of a neuroendocrine reflex; and that sensory and spinal neurons can respond to estrogens. Moreover, some activated sensory neurons may be involved in the animal's perception of labor pain.

Neural pathways mediating vaginal function: the vagus nerves and spinal cord oxytocin

The initial observations, made in our laboratory with Knut Larsson, of the ability of vaginocervical stimulation (VCS) to block withdrawal responses to foot pinch in rats has led to findings of multiple behavioral, autonomic, and neuroendocrine effects of this potent stimulus in rats and also in women. It has led to an understanding of: (1) the neuroanatomical and neurochemical basis of a novel and potent pain-blocking mechanism; (2) likely neuroanatomical pathways mediating both the Ferguson reflex and a specific autonomic response - the pupil-dilating effect of VCS; (3) a role for oxytocin as a putative central nervous system neurotransmitter that stimulates autonomic sympathetic preganglionic neurons within the spinal cord; and (4) a novel pathway that can convey sensory activity from the cervix, adequate to induce orgasm, via the vagus nerves. This latter pathway bypasses the spinal cord and projects directly to the medulla oblongata, and thus can convey genital afferent activity despite complete spinal cord injury at any level.

Brain (PET) responses to vaginal-cervical self-stimulation in women with complete spinal cord injury: preliminary findings

Our recent research provides evidence that women with complete spinal cord injury (SCI) at the midthoracic level show perceptual responses to vaginal and/or cervical self-stimulation (for example, pain suppression and sexual response, including orgasm). On the basis of studies in laboratory rats, we hypothesized that the vagus nerves provide a sensory pathway from the vagina, cervix, and uterus directly to the brain in women. To test this hypothesis, we performed a PET-MRI study on two women with complete SCI and 1 woman with no injuries. Whereas control foot stimulation of the women with SCI did not activate the somatosensory thalamus, cervical self-stimulation increased activity in the region of the nucleus of the solitary tract, which is the brainstem nucleus to which the vagus nerves project. These preliminary findings suggest that the vagus nerves can convey genital sensory input directly to the brain in women, completely bypassing SCI at any level.

Influence of estrous cycle on vaginocervical sensitivity: a fos-immunohistochemical study of lumbosacral spinal cord

Expression of c-fos in L(5)-S(1) spinal segments in response to mechanical vaginocervical stimulation was investigated in both cycling and ovariectomized females. The aim of this paper was to verify the influence of estrous cycle on females genital tract sensitivity using immunodetection of a neural activity endogenous marker. The results indicate that lumbosacral spinal Fos-labeling was highly increased in vaginocervical stimulated rats relative to control, and labeled neurons were present more intensively in the dorsal horn in comparison to other spinal areas. Significant differences in Fos-labeling were observed according to the estrous cycle stage at which the stimulation was applied. In estrous females, the response was greater than that obtained at diestrous and much greater than the response of proestrous females. The spinal Fos-labeling of ovariectomized females is equivalent to that of diestrous females. These results give evidence that the vaginocervical induced expression of c-fos is modulated by cyclic changes in circulating sex hormones, whereas results observed in ovariectomized females indicate the likely involvement of other mechanisms independent of ovarian hormones.

Changes in pain threshold and lumbar spinal cord immediate-early gene expression induced by paced and nonpaced mating in female rats

Vaginocervical stimulation (VCS) received during mating is known to induce analgesia and to suppress FOS-immunoreactivity (FOS-IR) in lumbar spinal cord. However, it is not known whether this suppression of FOS-IR reflects inhibition of afferent nociceptive input. The present studies examined whether two immediate-early gene (IEG) products, FOS and Egr-1, covary with nociception by comparing both responses in estrous females that received mating stimulation known to induce varying amounts of FOS-IR in brain. Ovariectomized steroid-treated rats were mated under conditions in which they paced or did not pace sexual contacts with males until receiving 5 or 15 intromissions. Control groups received mounts-without-intromission only from males or remained in their homecages. In experiment I, paced mating resulted in a significant overall suppression of FOS-IR in the lumbar 6 (L6) spinal segment compared to nonpaced and mounts only stimulation. This reduction occurred specifically among paced females receiving five intromissions. In contrast, significant elevations above homecage levels were seen in paced females given 15 intromissions, all nonpaced females, and mounts only animals. The numbers of Egr-1-immunoreactive (Egr-1-IR) cells increased equally above homecage levels in all male-exposed females. In experiment II, females that received five intromissions (paced or nonpaced) showed significant increases in tail-flick latency (TFL) within 5 s (time 0) after mating, while females receiving 15 intromissions showed hyperalgesia (15 nonpaced) or no change (15 paced) in TFL throughout 90 s postmating. Additional females tested immediately after receiving two ejaculations showed analgesia. Paced mating, though more effective than nonpaced mating in suppressing FOS-IR, did not influence the appearance of VCS-induced analgesia. We conclude that the suppression of FOS-IR by paced mating is not related to mating-induced analgesia.

Combined c-fos and 14C-2-deoxyglucose method to differentiate site-specific excitation from disinhibition: analysis of maternal behavior in the rat

On the basis of evidence that 14C-2-deoxyglucose (2-DG) autoradiography indicates activity at axonal terminals, whereas c-fos immunocytochemistry indicates activity of neuronal cell bodies, we combined these techniques in adjacent histological brain sections to assess excitatory and disinhibitory synaptic relations in selected sites in female rats in which maternal behavior was elicited by natural parturition, sensitization (7- to 10-day cohabitation with foster pups), or hysterectomy. All individuals in these three groups expressed maternal behavior immediately before 2-DG injection. Controls were non-maternal virgins. Parturient and Hysterectomized groups: elevation (compared with controls) in both 2-DG and c-fos activity in medial preoptic area (MPOA) indicated an increase in its input and output activity, i.e., an excitatory interaction; the MPOA was previously shown to be critical for maternal behavior. Sensitized group: a decrease in 2-DG activity of vomeronasal nuclei (bed nucleus of the accessory olfactory tract, BAOT, and medial amygdala, ME, replicating our previous study) and an elevation in c-fos activity, jointly indicate disinhibition of these nuclei, that were previously shown to modulate pup-chemostimulation-induced sensitization. All other sites showed evidence of excitatory input-output relationships (i.e., joint increase in both 2-DG and c-fos activity), e.g., bed nucleus of the stria terminalis (BNST), lateral habenula (LHAB), central gray (CG), thalamus (THAL), septum (SEPT), and ventral tegmental area (VTA). The present study demonstrates the feasibility of measuring 2-DG and c-fos activity jointly in adjacent sections of the same brain, thereby providing evidence to distinguish between localized excitation and disinhibition.