Neurophysiological properties of the pineal body

Visual deprivation at the critical period modulates photic evoked responses

Average visual evoked responses (AVER) were recorded from the striate cortex of normal (control) and monocular visually deprived Long-Evans hooded rats. One month of monocular visual deprivation (MD) at the critical period of development resulted in marked reduction of all the three AVER components (i.e., components P2, N2 and P3) as compared to the control recording (P < 0.001). In control animals, the AVER amplitudes of the two hemispheres were identical, while in MD rats, the P2 and N2 components of the AVER obtained from the hemisphere ipsilateral to the MD eye were markedly smaller than those of the AVER obtained from the contralateral hemisphere (P < 0.001). The latencies of the late components (N2 and P3) obtained from the hemisphere ipsilateral to the MD eyes were significantly delayed as compared to those from the contralateral hemisphere (P < 0.05 for N2, P < 0.01 for P3). The AVER following paired photic stimuli with various time intervals between the stimuli were used to study the neuronal recovery function of control animals compared to MD animals. The AVER to the second stimulus obtained from the MD rats exhibited greater attenuation in their amplitude responses than the AVER obtained from the control group, i.e., slower neuronal recovery. The neurophysiological changes observed in this study may relate to the neurocytological alteration occurring in the striate cortex following monocular visual deprivation at the critical period. In conclusion, AVER recorded from monocular visually deprived rats during the critical period is a simple and reliable electrophysiological animal model to study neuroplasticity during postnatal development.

Monocular visual deprivation at the critical period modulates photic evoked responses

Photic evoked responses were recorded from the striate cortex of Long-Evans hooded normal (control) rats and from monocular visual deprivation (MD) rats. The averaged visual evoked responses (AVER) were obtained from both hemispheres and provide comparison between the contralateral and the ipsilateral striate cortex with relation to the monocular deprived eye. The AVER recorded following binocular photic stimulation after 1 month of monocular deprivation demonstrated that the two visual cortexes responded differently. In the contralateral hemisphere of the visual cortex (related to the MD eye), all three components (P2, N2 and P3) of the AVER of the MD rats had significant increases in their peak amplitude as compared to the control recordings. In the ipsilateral cortex, the amplitude of component P2 and N2 was significantly reduced as a result of 1 month of MD. Comparing the AVER amplitudes of the two homotopic sites of the visual cortex obtained from the control group reveals no differences between the two hemispheres but markedly significant differences in P2, N2 and P3 components for the MD group. Based on the literature, the possibility that the monocular visual deprivation at the critical period in early developmental stage modulates the AVER as a result from the neurocytological alteration from altering of GABA and ACh within the striate cortex was discussed. In conclusion, the AVER is a reliable and practical method for studying the effects of monocular deprivation and neuroplasticity in the rat visual cortex.

Interaction of serotonin and norepinephrine in spinal antinociception

The interactions between different doses of serotonin (5-HT) and norepinephrine (NE) in in vivo experiments on rat spinal cord dorsal horn cells was investigated using the integrated electromyography (EMG) measurement of the nociceptive hindlimb flexor reflex (FR). The results indicate that (1) intrathecal (IT) administration of low doses of 5-HT (60 nmol) or NE (1.5 nmol) suppresses the nociceptive FR by 40% for 20 min, respectively; (2) administration of higher doses of 5-HT (240 nmol, IT) multiplies the suppression of the nociceptive FR by 80% for 40 min, and NE (15 nmol, IT) produces similar suppression of the nociceptive FR for 80 min; (3) concomitant administration of low doses of 5-HT (60 nmol, IT) and NE (1.5 nmol, IT) produces a summation of the nociceptive FR suppression both in amplitude and duration; (4) concomitant administration of the higher doses of 5-HT (240 nmol IT) with NE (15 nmol, IT) produces similar effect obtained as 5-HT given separately, and no summation was obtained as observed following the lower dosages; (5) serotonin (240 nmol, IT) given 40 min before NE (15 nmol, IT) attenuates the duration of the suppression induced by NE; (6) pretreatment with a selective 5-HT2 receptor antagonist ketanserin (60 nmol, IT) failed to abolish the 5-HT effects; (7) pretreatment with ketanserin prior to concomitant administration of the higher doses of 5-HT and NE prolongs the time duration of the nociceptive FR suppression.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of the heterogeneity within bovine pineal gland by immunohistochemistry and in situ hybridization

In the present study, we demonstrate a cortical and medullary arrangement of parenchymal cells in the bovine pineal gland by using antibodies for neuron-specific enolase, synaptophysin, and hydroxyindole O-methyltransferase (HIOMT) as markers of pinealocytes, and glial fibrillary acidic protein (GFAP) as a marker of interstitial (glial) cells. Furthermore, by means of probes specific for HIOMT mRNA, we have examined possible differences in melatonin synthesis between the cortex and the medulla. Immunoreactive pinealocytes for each antigen investigated are more densely distributed in the cortex than in the medulla. In the cortex, GFAP-positive interstitial cells have large intenselystained somata endowed with several long, thin cytoplasmic processes, whereas in the medulla, they display smaller, less intensely labeled perikarya from which numerous fine short processes emerge. Golgi staining has confirmed these morphological differences between the interstitial cells in the cortex and those in the medulla. An analysis using confocal laser microscopy together with in situ hybridization for HIOMT mRNA has shown that the expression of mRNA transcripts in the cortex is more intense than that in the medulla. The expression of the HIOMT gene in a cluster of cells in the medial habenular nucleus is lower than that in pinealocytes of the pineal organ proper.

The influence of the pineal gland on migraine and cluster headaches and effects of treatment with picoTesla magnetic fields

For over half a century the generally accepted views on the pathogenesis of migraine were based on the theories of Harold Wolff implicating changes in cerebral vascular tone in the development of migraine. Recent studies, which are based on Leao's concept of spreading depression, favor primary neuronal injury with secondary involvement of the cerebral circulation. In contrast to migraine, the pathogenesis of cluster headache (CH) remains entirely elusive. Both migraine and CH are cyclical disorders which are characterised by spontaneous exacerbations and remissions, seasonal variability of symptoms, and a relationship to a variety of environmental trigger factors. CH in particular has a strong circadian and seasonal regularity. It is now well established that the pineal gland is an adaptive organ which maintains and regulates cerebral homeostasis by "fine tuning" biological rhythms through the mediation of melatonin. Since migraine and CH reflect abnormal adaptive responses to environmental influences resulting in heightened neurovascular reactivity, I propose that the pineal gland is a critical mediator in their pathogenesis. This novel hypothesis provides a framework for future research and development of new therapeutic modalities for these chronic headache syndromes. The successful treatment of a patient with an acute migraine attack with external magnetic fields, which acutely inhibit melatonin secretion in animals and humans, attests to the importance of the pineal gland in the pathogenesis of migraine headache.

Pineal and habenula calcification in schizophrenia

Animal data indicate that melatonin secretion is stimulated by the paraventricular nucleus (PVN) of the hypothalamus and that lesions of the PVN mimic the endocrine effects of pinealectomy. Since the PVN lies adjacent to the third ventricle, I propose that periventricular damage, which is found in schizophrenia and may account for the third ventricular dilatation seen on computed tomographic (CT), may disrupt PVN-pineal interactions and ultimately enhance the process of pineal calcification (PC). To investigate this hypothesis, I conducted CT study on the relationship of PC size to third ventricular width (TVW) in 12 chronic schizophrenic patients (mean age: 33.7 years; SD = 7.3). For comparison, I also studied the relationship of PC size to the ventricular brain ratio and prefrontal cortical atrophy. As predicted, there was a significant correlation between PC size and TVW (r pbi = .61, p < .05), whereas PC was unrelated to the control neuroradiological measures. The findings support the hypothesis that periventricular damage may be involved in the process of PC in schizophrenia and may indirectly implicate damage to the PVN in the mechanisms underlying dysfunction of the pineal gland in schizophrenia. In a second study, I investigated the prevalence of habenular calcification (HAC) on CT in a cohort of 23 chronic schizophrenic-patients (mean age: 31.2 years; SD = 5.95). In this sample HAC was present in 20 patients (87%). Since the prevalence of HAC in a control population of similar age is only 15% these data reveal an almost 6-fold higher prevalence of HAC (X2 = 84.01, p < .0001) in chronic schizophrenia as compared to normal controls. The implications of HAC for the pathophysiology of schizophrenia are discussed in light of the central role of the habenula in the regulation of limbic functions.

Relevance of the habenular complex to neuropsychiatry: a review and hypothesis

Since the initial observation by Brown (1914) that electrical stimulation applied to the habenular efferent bundle in the chimpanzee evoked a pattern of respiration which closely resembled the act of laughter, the habenular complex has remained a mysterious structure. The anatomy of the habenular complex is well delineated (Jones, 1985) forming a major component of the dorsal diencephalic conduction system. Data derived mainly from animal experimentation over the past decade point to the fact that the habenular complex functions as an important link between the limbic forebrain and the midbrain-extrapyramidal motor system. The elucidation of the functions of the habenular complex may thus significantly increase the current insight into the understanding of the interaction between behavioral and motor functions. Clearly, such information would be of great relevance for further understanding of neuropsychiatric disorders such as schizophrenia, Parkinson's disease, Tardive dyskinesia, and Tourette's syndrome in which behavioral and motor impairments are interfaced. This review summarizes anatomical, functional, and pharmacological aspects of the habenular complex and discusses its potential contribution to the pathophysiology of selected neuropsychiatric and movement disorders.

Pineal microdialysis in freely moving rats

We describe a surgical technique to implant the guide cannula for in vivo microdialysis in the rat pineal gland. This technique has the following features and advantages: (a) does not require ligation of the superior or transverse sinus, (b) minimizes bleeding from the dural veins, (c) does not disturb the sympathetic innervation originating from superior cervical ganglia, which is essential for pineal function. This new technique makes it possible to carry out chronic pineal microdialysis of freely moving rats.

Effects of central and peripheral inputs on single pineal cell activity in the rat

The influences exerted by central and peripheral afferents to the pineal gland have been studied in rats anesthetized with urethane (1.2 g/kg, i.p.). Spontaneous action potentials arising from the pinealocytes were recorded by means of glass micropipettes filled with 3 M NaCl containing a dye. The electrical stimulation of suprachiasmatic nucleus, superior cervical ganglia, sciatic nerve and retina evoked discharge changes in a significant number of pineal cells. However, a relatively higher proportion of pinealocytes failed to respond to these afferents. Three types of responses could be observed. Inhibitions were the predominant response patterns to suprachiasmatic nucleus, superior cervical ganglia and sciatic nerve, while excitations were mainly elicited following photic stimulation, whereas the remaining evoked activity was biphasic responses, which were observed in a small number of cells after stimulation of suprachiasmatic nucleus, superior cervical ganglia and retina. These data confirm some previous neural inputs to the pineal and demonstrate the existence of a modulatory effect of the suprachiasmatic nucleus on pinealocyte discharges as well as somatosensory afferents to the gland by way of the sciatic nerve.

Two types of cells with central innervation in pineal gland of guinea pigs

Cells within pineal glands isolated from young, male guinea pigs were impaled with intracellular microelectrodes and their responses to stimulate the nerve supply to the gland were studied. Two types of cells were identified. The response of cells of type I was a depolarization on which spikes were superimposed. Blockers of alpha-adrenoceptors abolished the spikes while beta-adrenoceptor blockers reduced the depolarization to 27%, leaving a small tetrodotoxin-sensitive depolarization. After bilateral removal of the superior cervical ganglia (SCG) the beta-mediated depolarization was not observed while the spikes and the smaller depolarization persisted. The response of cells of type II was an initial large, transient depolarization followed by a smaller depolarization. Both components were reversibly blocked by tetrodotoxin. The only agents found to have any effect on these cells were oxytocin, vasopressin, and vasotocin. These peptides caused depolarization similar in amplitude to the larger response to nerve stimulation, although more prolonged. The large depolarization was not observed following ganglionectomy, but the smaller one persisted. It is concluded that cells of type I and II both receive inputs from nerves whose cell bodies lie in the SCG. Cells of both types are also innervated through another pathway.

Innervation of the pineal gland in the rat: an HRP study

Injections of horseradish peroxidase were made stereotaxically and directly (surgically exposed) into the pineal gland of Sprague-Dawley and Long-Evans rats weighing 30 to 500 g (20 to 130 days of age). Retrogradely labeled cells were seen in the superior cervical ganglia. Anterogradely labeled fibers were observed within the pineal stalk, lamina intercalaris, and the medial habenular nuclei. Terminal fields were identified in lamina intercalaris and medial habenular nuclei. Labeled cells were not seen within the central nervous system. These results suggest that in the rat the pineal gland is not centrally innervated but in fact is innervated solely by the sympathetic postganglionic fibers.

Pineal indoles: significance and measurement

Despite intensive investigation, particularly over the past fifteen years, many aspects of pineal function with respect to mammalian physiology remain obscure. Much of this work is reviewed and particular attention focussed on indole metabolism within the pineal gland. Emphasis is placed on the development of new analytical techniques with special reference to high performance liquid chromatography coupled with electrochemical detection. The growth in knowledge regarding pineal indole synthesis which can be attributed to the use of this technique is discussed. The possibility that pineal indoles other than melatonin may function as hormones or neuromodulators is considered. A functional role for 5-hydroxytryptophol as a neuromodulator, possibly associated with diffuse neuroendocrine function (amine precursor, uptake and decarboxylation, APUD) is suggested.

Rat pineal exhibits two electrophysiological patterns of response to microiontophoretic norepinephrine application

The spontaneous activity of 117 pineal units was recorded in urethane-anesthetized rats. The pineal units exhibited a wide range of firing rates of which 50% were on average slower than 14 spikes per second. Superior cervical ganglion (SCG) stimulation was studied in 76 pineal units; this stimulation caused excitation in 55% of the units. Microiontophoretic application of norepinephrine (NE) induced changes of firing rates in 61% of the pineal units tested. Two patterns of activity following NE microiontophoresis was observed: increase in firing rate (64%) and decrease in firing rate (36%). NE-induced excitation was observed only in those units excited by SCG stimulation. When NE and SCG stimulation were applied together, partial summation of the excitation induced by each one alone was observed. None of the units in which NE depressed the firing rate responded to SCG stimulation. Local application of propranolol blocked the excitation initiated by SCG stimulation as well as the excitation and the depression induced by NE microiontophoresis.

Interaction of norepinephrine and superior cervical ganglion input in the rat pineal body

The effects of superior cervical ganglion stimulation and the local application of norepinephrine or its antagonist propranolol were studied in 18 pineal cells. In 61% of the pineal cells, stimulation elicited excitation; the same cells also responded by excitation to norepinephrine ejection. When stimulation and norepinephrine ejection were applied together, summation (of the excitation) was observed in these cells. Several cells that failed to respond to stimulation did respond to norepinephrine ejection, but with the opposite pattern, i.e., decrease of firing rates. Propranolol prevented the norepinephrine-induced excitation and inhibition, as well as the excitation produced by stimulation. We suggest that norepinephrine regulates pineal activity by two routes: activation of the sympathetic neuronal input and inhibition by way of the circulation.

Visual input to rat pineal

Electrophysiological recordings from freely behaving rats, previously implanted stereotaxically with permanent electrodes in the pineal, ventromedial hypothalamus, caudate nucleus, lateral geniculate body and medial geniculate body were obtained. The pineal photic responses revealed 5 sequential components. Injection of a neuronal blocker at the level of the superior cervical ganglion did not alter the earlier photic responses, but did eliminate the late components (N2-P3) for 60-90 min after the injection. All of the other responses were unchanged during the experiment. The present experiments demonstrated that photic input travels to the pineal through two pathways.

Photic input to rat pineal gland conveyed by both sympathetic and central afferents

Average photic evoked responses were recorded from the pineal in light and dark adaptation. Permanent semimicroelectrodes were implanted several days before the experiments were begun. Local anesthesia (xylocaine) at the superior cervical ganglion (scg) level was used as a tool to determine whether or not photic responses are transmitted via the scg and/or through another CNS route. The experiments demonstrated that in dark adaptation, photic evoked responses recorded from the pineal exhibited higher amplitude. Moreover, the photic evoked responses are transmitted via two separate routes: one, a faster pathway with a "shorter" latency, via the CNS, i.e. the habenular posterior commissure complex, and the other a "slower" (or longer) pathway via the reticular formation scg to the pineal.

The pineal gland and stress: effect of pineal stalk section on the plasma corticosteroid response to cold in rabbits

To investigate the role of the pineal gland on plasma corticosteroid elevation during stress, a pineal stalk section was performed in rabbits implanted with a carotid cannula, while a comparable sham operation was carried out in a control group ( n = 8) similarly implanted. Six days after the surgery, the rabbits were exposed to a cold environment for 2 hr. Blood was withdrawn periodically throughout the 2 hr. of cold stress and for an additional 2 hr. after the rabbits were returned to their cages. Results show that plasma corticosteroids (cortisol + corticosterone) concentration in both groups rose during the cold exposure and gradually declined towards resting values after removal from the cold. The lesioned rabbits, however, exhibited an earlier and higher elevation in plasma corticosteroid levels in reaction to the cold. These observations suggest that the pineal stalk in normal animals influences the corticosteroid response to a stress in such a way as to increase the latency of its onset and decrease its amplitude. This effect is interpreted in the context of the general adaptation syndrome.

Neuroendocrine function in long-term pinealectomized male rats, following visual and audiogenic stress

Intact, sham-pinealectomized and pinealectomized adult male rats were maintained for 10 weeks on a light : dark (L : D) cycle of 12 : 12,with lights on at 6 a.m. Subsequently they were acutely exposed to (1) visual or (2) audiogenic stress for periods of 2 or 30 min, immediately following which they were decapitated and serum ACTH, corticosterone, FHS, LH, PRL and TSH concentrations were determined. Serum ACTH and corticosterone levels were similar in control and operated groups following both types of stresses. Serum FSH and LH concentrations were elevated in pinealectomized animals as compared to controls, following 30 min of exposure to visual stimulation; no difference in these parameters was observed between the groups following audiogenic stress. Serum PRL levels tended to be lower in pinealectomized animals following both stresses. Serum TSH concentrations following visual stimulation were similar in all groups, but audiogenic stimulation resulted in elevated TSH levels as compared to controls. These data demonstrate that the pineal gland plays an integral role in the responses of the parvicellular neuroendocrine axes to acute neurogenic stress. Possible molecular bases for this involvement are discussed.

On GABA function and physiology in the pineal gland

Pineal gamma-aminobutyric acid (GABA) content and glutamic acid decarboxylase (GAD) activity were found not to be influenced by environmental light, catecholamines, sympathetic innervation, or input via the pineal stalk. The observation that GAD activity did not disappear after pineal stalk section, ganglionectomy, or 48 h of organ culture leads us to suggest that GAD activity is not located in nerve processes entering the pineal gland. Treatment in organ culture with an inhibitor of protein synthesis did not greatly influence the slow rate of decrease of GAD activity. This finding is consistent with the conclusion that GAD turnover is slow. Treatment of denervated glands or glands containing functional sympathetic nerve structures with GABA, amino-oxyacetic acid (AOAA) or bicuculline in organ culture did not alter unstimulated levels, or significantly block the adrenergic stimulation of the activity of pineal serotonin N-acetyl transferase (NAT). It is clear from our studies that GABA does not influence or modulate the adrenergic regulation of.pineal NAT activity, and that GABA content and synthesis are not regulated by an adrenergic mechanism. The role of GABA in the pineal gland remains to be discovered.

Effects of melatonin on the photosensitive epilepsy of the baboon, Papio papio

The acute pharmacological effects of melatonin (5-methoxy-N-acetyl-tryptamine) were evaluated on behaviour and electrographic signs in the photosensitive baboon (Papio papio), including visually evoked potentials VEPs). Doses of 5 and 10 mg/kg i.v. had little effect, contrasting with the enhancement of spontaneous paroxysmal activity and latency of clinical signs elicited by intermittent light stimulation (ILS) produced by the 20 and 50 mg/kg doses. Moreover, a modification of the electrographic pattern of discharge during ILS-induced myoclonic responses was observed. These observations indicate a slight decrease of light sensitivity after melatonin. Only frontal VEPs were modified, with increase in amplitude of their late components for all doses tested. These effects lasted for 2-4 h. The participation of serotoninergic mechanisms involved in melatonin effect and in this model of experimental epilepsy are discussed.