Sensory innervation of the brain (primary interoceptor neurons of the brain and their asynaptic dendrites)

Published data and our own studies on the sensory innervation of the brain are summarized. Primary interoceptive sensory neurons were analyzed: brain neurons bearing cilia; supraependymal plexuses and intraependymal neurons in contact with the cerebrospinal fluid; Cajal—Retzius neurons in the boundary layer of the cerebral cortex; Dolgo-Saburov paravasal neurons in the brain and spinal cord; Lugaro cells in the cerebellum; and various synaptically NO-positive neurons in the cerebral cortex, whose asynaptic dendrites innervate the precapillary space. Consideration of the lack of pain sensitivity of the brain and the parenchymatous tissues of the internal organs, which contain local primary sensory neurons similar to intramural metasympathetic sensory neurons of Dogel type II, led to the hypothesis that brain and other intraorgan tissue receptors are involved in short “autonomic” reflex arcs controlling only local metabolism but not pain reactions. __________ Translated from Morfologiya, Vol. 127, No. 2, pp. 7–15, March–April, 2005. The editors advise that many of the views and conclusions expressed by Professor O. S. Sotnikov are not generally accepted and are controversial.     

Calretinin in rat brain: an immunohistochemical study.

Calretinin is a calcium-binding protein related to calbindin-D28k; both are present in different though overlapping sets of neurons in brains of birds and mammals. We describe in detail the pattern of calretinin immunoreactivity in the rat brain. As in chick brain, calretinin immunoreactivity is abundant in various sensory pathways (particularly certain cells and fibres of the cochlear nuclei and olfactory bulb), in the heterogeneous parts of the brainstem and in parts of the hypothalamus. Many primary sensory fibres are strongly positive. Major groups of calretinin-positive neurons also include the thalamic reticular nucleus, triangular septal nucleus, lateral mammillary nucleus and substantia nigra pars compacta. Many other calretinin-positive cells are recognizable as local inhibitory neurons. Calretinin is absent from all but a few cells in the cerebral cortex, and is never found in motor neurons. There are also some distinctive positive structures whose identity is uncertain, notably irregular "shells" of cells and fibres around the thalamus and in the amygdala and an unnamed cell type in the vestibulocerebellum.     

Cellular pattern of type-I insulin-like growth factor receptor gene expression during maturation of the rat brain: comparison with insulin-like growth factors I and II.

Insulin-like growth factors have a number of potent trophic effects on cultured neural tissue and most if not all of these effects appear to be mediated by the type-I insulin-like growth factor receptor. In order to establish the identity of cell types expressing this receptor in the rat central nervous system during development and maturity, we have used in situ hybridization to map sites of type-I insulin-like growth factor receptor mRNA synthesis in the developing and adult rat brain. In order to identify possible local sources of peptide ligands for this receptor, we have also mapped the sites of insulin-like growth factors I and II mRNA synthesis in parallel brain sections. From early development onward, there is a uniform and stable pattern of type-I insulin-like growth factor receptor gene expression in all neuroepithelial cell lineages, in which regional variations reflect primarily differences in cell density. In addition to this generalized pattern, during late postnatal development, high levels of type-I insulin-like growth factor receptor gene expression are found in specific sets of sensory and cerebellar projection neurons in conjunction with abundant insulin-like growth factor-I gene expression in these same neurons. While insulin-like growth factor-I expression is confined to the principal neurons in each system, receptor mRNA is also found in local interneurons. In the cerebral cortex and hippocampal formation, type-I insulin-like growth factor receptor mRNA and insulin-like growth factor-I are concentrated in different cell populations: receptor mRNA is abundant in pyramidal cells in Ammon's horn, in granule cells in the dentate gyrus, and in pyramidal cells in lamina VI of the cerebral cortex. Insulin-like growth factor-I mRNA is found in isolated medium- to large-sized cells which are rather irregularly distributed throughout the hippocampus and isocortex. In the hypothalamus, receptor mRNA is concentrated in the suprachiasmatic nucleus but is in low abundance elsewhere, including the median eminence, while insulin-like growth factor-I mRNA is not detected in this region at all. Type-I insulin-like growth factor receptor and insulin-like growth factor-II mRNAs are both abundant in choroid plexus, meninges and vascular sheaths from early development to maturity, but insulin-like growth factor-II mRNA is not detected in cells of neuroepithelial origin at any stage of development. This study provides evidence for two fundamentally different patterns of gene expression for the brain type-I insulin-like growth factor receptor.(ABSTRACT TRUNCATED AT 400 WORDS)     

阿魏酸及其酯化产物与体外培养大鼠大脑皮质神经元的存活

背景：大量体外筛选中得到的中药脑神经保护活性成分,多因脂溶性低难以透过血脑屏障而限制了其临床应用。 目的：比较阿魏酸及其酯化产物阿魏酸甲酯、乙酯对原代培养的大鼠大脑皮质神经元体外存活的保护作用。 方法：出生1 d内的乳鼠采用酶消化法分离培养大脑皮质神经元。培养6 d后,分别进行阿魏酸、阿魏酸甲酯及乙酯干预,继续培养1 d。 结果与结论：形态学观察结果显示细胞生长良好,NSE染色检查表明培养6 d的存活细胞大部分均为神经元。MTT比色法测量结果显示,与空白对照组比较,阿魏酸仅在质量浓度为200 mg/L时有明显促进大脑皮质神经元存活的作用,而阿魏酸甲酯、乙酯在质量浓度为0.16~20 mg/L时均能明显促进神经元体外存活,且作用趋势、作用强度相近。表明阿魏酸的酯化产物阿魏酸甲酯和阿魏酸乙酯均能促进原代培养的大脑皮质神经元体外存活,显示出较好的脑神经元保护作用,且活性比阿魏酸更强。     

Cholinergic neurons containing GABA-like and/or glutamic acid decarboxylase-like immunoreactivities in various brain regions of the rat

Summary The coexistence of immunoreactivities for choline acetyltransferase (ChAT) and glutamic acid decarboxylase (GAD) and/or gamma-aminobutyric acid (GABA) was revealed in some brain regions of the rat, using the peroxidase-antiperoxidase method. Consecutive 40 m thick vibratome sections were incubated in different antisera and those cells which were bisected by the plane of sectioning so as to be included at the paired surfaces of two adjacent sections were identified. The coexistence of the immunoreactivities for ChAT and GAD or GABA in the same cell could thus be determined by observing the immunoreactivity of the two halves of the cell incubated in two different antisera. In the retina, cerebral cortex, basal forebrain and spinal cord, colocalization of ChAT-like and GAD-like or GABA-like immunoreactivities was observed in some cell types, whereas no such colocalization was observed in cells in the striatum or brainstem. In the retina, the majority of ChAT-like immunoreactive (ChAT-LI) amacrine cells contained GABA-like or GAD-like immunoreactivity. About half of the ChAT-LI neurons in the cerebral cortex showed GABA-like immunoreactivity. In the basal forebrain only a small proportion of ChAT-LI neurons (0.6%) contained GAD-like immunoreactivity. In the spinal cord, about one-third of ChAT-LI central canal cluster cells and about half of ChAT-LI dorsal horn cells showed GAD-like and/or GABA-like immunoreactivities. These observations indicate the possible coexistence of two classical transmitters, GABA and acetylcholine, in various brain regions and spinal cord of the rat.This paper is dedicated to Prof. Hama on the occasion of his 66th birthday     

Cholinergic nucleus basalis neurons display the capacity for rhythmic bursting activity mediated by low-threshold calcium spikes.

Acetylcholine has long been known to play an important role in the cortical activation that accompanies the states of wakefulness and paradoxical sleep (for review, see Refs 17, 21) when this neurotransmitter is released from the cerebral cortex at the highest rates. The major supply of acetylcholine to the cerebral cortex arises from the cholinergic neurons of Meynert's Basal-ganglion or nucleus basalis of the forebrain. Lying in the substantia innominata within the major ascending pathway from the brain stem reticular formation, magnocellular basalis neurons project upon the cerebral cortex as the important ventral, extrathalamic relay of the ascending reticular activating system. Although the cholinergic basalis nucleus neurons have been shown to be important for cortical activation, the precise manner in which they influence cortical activity has not as yet been elucidated, in part because the cholinergic cells of this nucleus have not been identified in electrophysiological studies. Using intracellular recording in guinea-pig brain slices, we were able to record and fill with biocytin nucleus basalis neurons which were subsequently revealed by immunohistochemical staining to be choline acetyltransferase-positive and thus cholinergic. The cholinergic cells displayed rhythmic bursting activity mediated by a low-threshold calcium spike in vitro, which would endow them with a capacity for phasic (in addition to tonic) firing in vivo. By virtue of these different modes, cholinergic basalis neurons may accordingly deter or facilitate the cortical response to sensory input and may furthermore modulate the major frequencies of cortical activity across the different states of the sleep-waking cycle.     

Immunocytochemical localization of glycogen phosphorylase kinase in rat brain sections and in glial and neuronal primary cultures

Summary. The physiological function of brain glycogen and the role of phosphorylase kinase as a regulatory enzyme in the cascade of reactions associated with glycogenolysis in the brain have not been fully elucidated. As a first step toward elucidating such a function, we studied the localization of phosphorylase kinase in glial and neuronal primary cell cultures, and in adult rat brain slices, using a rabbit polyclonal antibody against skeletal muscle glycogen phosphorylase kinase. Immunocytochemical examination of rat astroglia-rich primary cultures revealed that a large number of cells were positive for glycogen phosphorylase kinase immunoreactivity. These cells were also positive for vimentin, a marker for immature glia, while they were negative for glial fibrillary acidic protein, a marker for mature astroglia, and for galactocerebroside, an oligodendroglial marker. Neurons in rat neuron-rich primary cultures did not show any kinase-positive staining. In paraformaldehyde-fixed adult rat brain sections, phosphorylase kinase immunoreactivity was detected in glial-like cells throughout the brain, with relatively high staining found in the cerebral cortex, the cerebellum, and the medulla oblongata. Phosphorylase kinase immunoreactivity could not be detected in neurons, with the exception of a group of large neurons in the brain stem, most likely belonging to the mesencephalic trigeminal nucleus. Phosphorylase kinase was also localized in the choroid plexus and to a lesser degree in the ependymal cells lining the ventricles. Phosphorylase kinase thus appears to have the same cellular distribution in nervous tissue as its substrates, i.e. glycogen phosphorylase and glycogen, which suggests that the physiological role of brain phosphorylase kinase is the mobilization of glycogen stores to fuel the increased metabolic demands of neurons and astrocytes.     

Convergence of sensory systems in the orbitofrontal cortex in primates and brain design for emotion

In primates, stimuli to sensory systems influence motivational and emotional behavior via neural relays to the orbitofrontal cortex. This article reviews studies on the effects of stimuli from multiple sensory modalities on the brain of humans and some other higher primates. The primate orbitofrontal cortex contains the secondary taste cortex, in which the reward value of taste is represented. It also contains the secondary and tertiary olfactory cortical areas, in which information about the identity and also about the reward value of odors is represented. A somatosensory input is revealed by neurons that respond to the viscosity of food in the mouth, to the texture (mouth feel) of fat in the mouth, and to the temperature of liquids placed into the mouth. The orbitofrontal cortex also receives information about the sight of objects from the temporal lobe cortical visual areas. Information about each of these modalities is represented separately by different neurons, but in addition, other neurons show convergence between different types of sensory input. This convergence occurs by associative learning between the visual or olfactory input and the taste. In that emotions can be defined as states elicited by reinforcers, the neurons that respond to primary reinforcers (such as taste and touch), as well as learn associations to visual and olfactory stimuli that become secondary reinforcers, provide a basis for understanding the functions of the orbitofrontal cortex in emotion. In complementary neuroimaging studies in humans, it is being found that areas of the orbitofrontal cortex are activated by pleasant touch, by painful touch, by taste, by smell, and by more abstract reinforcers such as winning or losing money. Damage to the orbitofrontal cortex in humans can impair the learning and reversal of stimulus-reinforcement associations and thus the correction of behavioral responses when these are no longer appropriate because previous reinforcement contingencies change. It is striking that humans and other catarrhines, being visual specialists like other anthropoids, interface the visual system to other sensory systems (e.g., taste and smell) in the orbitofrontal cortex.     

Immunocytochemical evidence for the involvement of glycine in sensory centers of the rat brain.

Glycine-like immunoreactivity was localized to a number of sites in the rat brain which are involved in processing sensory information. In the auditory and vestibular systems, glycine immunoreactivity was seen in dorsal and ventral cochlear nuclei, superior olive, trapezoid body, medial and lateral vestibular nuclei, and inferior colliculus. Staining in the visual system was seen in retina, dorsal lateral geniculate nucleus, and superior colliculus. The olfactory system exhibited staining in the olfactory bulb and accessory olfactory formation. Somatosensory centers with glycine immunoreactivity included the dorsal column nuclei, spinal trigeminal nucleus, principal sensory nucleus of V, reticular formation, and periaqueductal gray. Glycine-immunoreactive neurons were also seen in cerebellar cortex, deep cerebellar nuclei, hippocampus, cerebral cortex, and striatum. The distribution of staining indicates that glycine plays a major role in sensory centers with actions at both strychnine-sensitive and strychnine-insensitive receptors.     

Rapamycin保护大鼠缺血性脑损伤和特定脑区神经新生有关

目的:探讨缺血前给予自噬诱导剂对脑缺血损伤的保护效应及可能机制。方法:双侧颈总动脉结扎建立全脑缺血模型,再灌注后24 h,评价动物神经行为功能,连续脑切片,采用Nissl染色定量检测皮层及海马CA1区细胞密度;通过免疫荧光技术检测Caspase-3阳性神经元,计数皮层及海马CA1凋亡细胞数量;激光共聚焦显微镜观察并计数海马齿状回颗粒下层内呈Ki67阳性、GFAP(胶质纤维酸性蛋白)阴性(Ki67+/GFAP-)细胞的数量。结果:Rapamycin术前预处理可以改善缺血导致的神经功能缺陷(P<0.05)。Nissl染色结果表明Ra-pamincy术前1 h给药可以减轻缺血导致的皮层(P<0.01)及海马CA1区(P<0.01)细胞丢失。同时,Rapamycin术前给药也显著减少了缺血导致的皮层及海马CA1区内Caspase-3阳性细胞的数量,组间比较有显著性差异(P<0.05)。Rapamycin术前1 h给药增加了海马齿状回内Ki67+/GFAP-细胞的数量,和缺血组比较差异有显著性(P<0.05)。结论:在全脑缺血模型上,通过自噬活化途径的缺血预处理可以保护缺血性脑损伤,这一作用和Rapamycin减少凋亡、增加新生神经细胞的数量有关。     

Cortical areas abundant in extracellular matrix chondroitin sulphate proteoglycans are less affected by cytoskeletal changes in Alzheimer's disease.

In the human brain, the distribution of perineuronal nets occurring as lattice-like neuronal coatings of extracellular matrix proteoglycans ensheathing several types of non-pyramidal neurons and subpopulations of pyramidal cells in the cerebral cortex is largely unknown. Since proteoglycans are presumably involved in the pathogenesis of Alzheimer's disease, we analysed the distribution pattern of extracellular chondroitin sulphate proteoglycans in cortical areas, including primary motor, primary auditory and several prefrontal and temporal association areas, in normal human brains and in those showing neuropathological criteria of Alzheimer's disease. In both groups, neurons with perineuronal nets were most numerous in the primary motor cortex (approximately 10% in Brodmann's area 4) and in the primary auditory cortex as a representative of the primary sensory areas. Their number was lower in secondary and higher order association areas. Net-associated pyramidal cells occurred predominantly in layers III and V in motor areas, as well as throughout lower parts of layer III in the primary auditory cortex and neocortical association areas. In the entorhinal cortex, net-associated pyramidal cells were extremely rare. In brains showing hallmarks of Alzheimer's disease, the characteristic patterns of hyperphosphorylated tau protein, stained with the AT8 antibody, largely excluded the zones abundant in perineuronal nets and neuropil-associated chondroitin sulphate proteoglycans. As shown in double-stained sections, pyramidal and non-pyramidal neurons ensheathed by perineuronal nets were virtually unaffected by the formation of neurofibrillary tangles even in severely damaged regions. The distribution patterns of amyloid B deposits overlapped but showed no congruence with that of the extracellular chondroitin sulphate proteoglycans. It can be concluded that low susceptibility of neurons and cortical areas to neurofibrillary changes corresponds with high proportions of aggregating chondroitin sulphate proteoglycans in the neuronal microenvironment.     

Reflections on the interaction of the mind and brain

Problems associated with the topic of the mind-brain interaction are reviewed and analyzed. If there is an interaction, then the "mind" and "brain" are independent variables; the mind represents subjective experience and is therefore a non-physical phenomenon. This fact led to the need for a field theory, termed here the "cerebral mental field" (CMF). By definition, the CMF is a system property produced by the appropriate activities of billions of neurons. An experimental test of this theory is possible and a test design is presented. The most direct experimental evidence has been obtained by use of intracranial stimulating and recording electrodes. Important information has also been developed, however, with extracranial imaging techniques. These can be very fast (in ms), but the cerebral neuronal events that produce changes in physiological properties require a time delay for their processing. A number of surprising time factors affecting the appearance of a subjective somatosensory experience are described, and their wider implications are discussed. Among these is a delay (up to 0.5 s) in the generation of a sensory awareness. Thus, unconscious cerebral processes precede a subjective sensory experience. If this can be generalized to all kinds of subjective experiences, it would mean that all mental events begin unconsciously and not just those that never become conscious. In spite of the delay for a sensory experience, subjectively there appears to be no delay. Evidence was developed to demonstrate that this phenomenon depends on an antedating of the delayed experience. There is a subjective referral backward in time to coincide with the time of the primary cortical response to the earliest arriving sensory signal. The subjective referral in time is analogous to the well-known subjective referral in space. In conclusion, features of the CMF can be correlated with brain events, even though the CMF is non-physical, by study of subjective reports from the human subject.     

Reorganization in processing of spectral and temporal input in the rat posterior auditory field induced by environmental enrichment

Environmental enrichment induces powerful changes in the adult cerebral cortex. Studies in primary sensory cortex have observed that environmental enrichment modulates neuronal response strength, selectivity, speed of response, and synchronization to rapid sensory input. Other reports suggest that nonprimary sensory fields are more plastic than primary sensory cortex. The consequences of environmental enrichment on information processing in nonprimary sensory cortex have yet to be studied. Here we examine physiological effects of enrichment in the posterior auditory field (PAF), a field distinguished from primary auditory cortex (A1) by wider receptive fields, slower response times, and a greater preference for slowly modulated sounds. Environmental enrichment induced a significant increase in spectral and temporal selectivity in PAF. PAF neurons exhibited narrower receptive fields and responded significantly faster and for a briefer period to sounds after enrichment. Enrichment increased time-locking to rapidly successive sensory input in PAF neurons. Compared with previous enrichment studies in A1, we observe a greater magnitude of reorganization in PAF after environmental enrichment. Along with other reports observing greater reorganization in nonprimary sensory cortex, our results in PAF suggest that nonprimary fields might have a greater capacity for reorganization compared with primary fields.     

N-methyl-D-aspartate channel and consciousness: from signal coincidence detection to quantum computing

Research on Blindsight, Neglect/Extinction and Phantom limb syndromes, as well as electrical measurements of mammalian brain activity, have suggested the dependence of vivid perception on both incoming sensory information at primary sensory cortex and reentrant information from associative cortex. Coherence between incoming and reentrant signals seems to be a necessary condition for (conscious) perception. General reticular activating system and local electrical synchronization are some of the tools used by the brain to establish coarse coherence at the sensory cortex, upon which biochemical processes are coordinated. Besides electrical synchrony and chemical modulation at the synapse, a central mechanism supporting such a coherence is the N-methyl-D-aspartate channel, working as a 'coincidence detector' for an incoming signal causing the depolarization necessary to remove Mg(2+), and reentrant information releasing the glutamate that finally prompts Ca(2+) entry. We propose that a signal transduction pathway activated by Ca(2+) entry into cortical neurons is in charge of triggering a quantum computational process that accelerates inter-neuronal communication, thus solving systemic conflict and supporting the unity of consciousness.     

Isolated catecholaminergic projections from substantia nigra and locus coeruleus to caudate,hippocampus and cerebral cortex formed by intraocular sequential double brain grafts

Summary Sequential intraocular grafting of defined areas from fetal rat brain to adult host rats was used to explore the possibility that such double grafts would become interconnected. Norepinephrine- containing neurons of the locus coeruleus were grafted together with either parietal cerebral cortex, hippocampus, or the caudate nucleus. Dopamine-containing neurons of the substantia nigra were transplanted together with either parietal cerebral cortex or the caudate nucleus. The brainstem grafts showed good survival and development in oculo, using both histochemical and electrophysiological criteria. Locus coeruleus neurons were found to innervate cerebral cortex, hippocampus, and the caudate nucleus. Substantia nigra neurons invaded cerebral cortex abundantly, with a terminal distribution typical of cortical DA terminals in situ. The innervation of the caudate nucleus from substantia nigra transplants was variable, but areas of dense confluent terminals were observed.We conclude that sequential brain grafting in oculo permits generation of isolated yet defined catecholaminergic projections, which are suitable for electrophysiological, pharmacological, and histochemical studies.     

Postnatal development of parvalbumin and calbindin D28K immunoreactivities in the cerebral cortex of the rat

Parvalbumin and calbindin D28k immunoreactivities were examined in the neocortex of the rat during postnatal development. Parvalbumin-immunoreactive nonpyramidal neurons first appear in layer V and later in layers VI and IV, and then in II and III. Immunoreactive terminals forming baskets surrounding unlabelled somata appear about 2 days later. The first parvalbumin-immunoreactive neurons appear in the retrosplenial and cingulate cortices, and the rostral region of the primary somatosensory cortex at postnatal days 8 or 9 (P8–P9). These regions are followed by the primary visual, primary auditory and motor cortices at P11. Parvalbumin immunoreactivity appears last in the secondary areas of the sensory regions and association cortices. Adult patterns are reached at the end of the 3rd week. Calbindin D28K-immunoreactive nonpyramidal neurons are found at birth in all cortical layers excepting the molecular layer. The intensity of the immunoreaction increases during the first 8 or 11 days of postnatal life, first in the inner and later in the upper cortical layers, following, therefore, an inside-out gradient. Heavily-labelled calbindin D28K-immunoreactive nonpyramidal cells dramatically decrease in number from P11 to P15 due mainly to a decrease of the multipolar subtypes. This suggests that two populations of calbindin D28k-immunoreactive nonpyramidal neurons are produced in the neocortex during postnatal development: one population of neurons transitorily expresses calbindin D28k immunoreactivity; the other population is composed of neurons that are permanently calbindin D28k immunoreactive. In addition to heavily labelled nonpyramidal cells, a band of weakly labelled pyramid-like neurons progressively appears in layers II and III throughout the cerebral cortex, beginning in layer IV in the somatosensory cortex by the end of the 2st week. Adult patterns are reached at the end of the 3rd week. These results indicate that parvalbumin and calbindin D28k immunoreactivities in the cerebral neocortx follow different characteristic patterns during postnatal development. The appearance of parvalbumin immunoreactivity correlates with the appearance of the related functional activity in the different cortical regions, and, probably, with the appearance of inhibitory activity in the neocortex. On the other hand, the early appearance of calbindin D28k immunoreactivity in the neocortex may be related to the early appearance of calbindin immunoreactivity in many other brain regions, and suggests another, as yet unknown, role for this calcium-binding protein during development of the cerebral cortex.     

Catecholaminergic neurons containing GABA-like and/or glutamic acid decarboxylase-like immunoreactivities in various brain regions of the rat

Summary The coexistence of immunoreactivities for tyrosine hydroxylase (TH) and glutamic acid decarboxylase (GAD) and/or gamma-aminobutyric acid (GABA) was revealed in various brain regions in colchicine-injected and untreated rats, using the peroxidase-antiperoxidase method. Consecutive 40 m thick Vibratome sections were incubated in different antisera and those cells which were bisected by the plane of sectioning so as to be included at the paired surfaces of two adjacent sections were identified. The coexistence of the immunoreactivities for TH and GAD or GABA in the same cell could thus be determined by observing the immunoreactivity of the two halves of the cell incubated in two different antisera. In the olfactory bulb, retina, diencephalon, mesencephalic central grey and cerebral cortex, many TH-like immunoreactive neurons also showed GAD-like or GABA-like immunoreactivity, whereas in the substantia nigra, ventral tegmental area and locus ceruleus none of TH-like immunoreactive neurons showed either GAD-like or GABA-like immunoreactivity. In the olfactory bulb, retina and cerebral cortex, the majority of the TH-like immunoreactive neurons were also GAD-like or GABA-like immunoreactive. In the diencephalon of colchicine-injected rats, at least one-third of the TH-like immunoreactive neurons were GAD-like immunoreactive. Using serial 0.5 m thick plasticembedded sections, it was shown that immunoreactivities for three antigens, GAD, GABA and TH could occur in the same neurons in the olfactory bulb. These observations indicate the possible coexistence of two classical transmitters, GABA and catecholamine, in various brain regions of the rat.     

Corticofugal direct projections to primary afferent neurons in the trigeminal mesencephalic nucleus of rats

Little is known about projections from the cerebral cortex to the trigeminal mesencephalic nucleus (Vmes) which contains the cell bodies of primary sensory afferents innervating masticatory muscle spindles and periodontal ligaments of the teeth. To address this issue, we employed retrograde (Fluorogold, FG) and anterograde (biotinylated dextranamine, BDA) tracing techniques in the rat. After injections of FG into the Vmes, a large number of neurons were retrogradely labeled in the prefrontal cortex including the medial agranular cortex, anterior cingulate cortex, prelimbic cortex, infralimbic cortex, deep peduncular cortex and insular cortex; the labeling was bilateral, but with an ipsilateral predominance to the injection site. Almost no FG-labeled neurons were found in the somatic sensorimotor cortex. After BDA injections into the prefrontal cortex, anterogradely labeled axon fibers and boutons were distributed bilaterally in a topographic pattern within the Vmes, but with an ipsilateral predominance to the injection site. The rostral Vmes received more preferential projections from the medial agranular cortex, while the deep peduncular cortex and insular cortex projected more preferentially to the caudal Vmes. Several BDA-labeled axonal boutons made close associations (possible synaptic contacts) with the cell bodies of Vmes neurons. The present results have revealed the direct projections from the prefrontal cortex to the primary sensory neurons in the Vmes and their unique features, suggesting that deep sensory inputs conveyed by the Vmes neurons from masticatory muscle spindles and periodontal ligaments are regulated with specific biological significance in terms of the descending control by the cerebral cortex.     

Temperature topography of the brain cortex: Thermoencephaloscopy

Summary Thermoencephaloscopy (TES) - a new method of functional imaging of the cerebral cortex by its infrared radiation was advanced and developed since 1984. Improved thermovision and image processing techniques allow 2D, contact-free, dynamic and non-invasive recording of background and evoked cortical activity through an unopened skull. Activated (heated) and deactivated (cooled) zones of the cerebral cortex are revealed. The temporal resolution of TES is 40 msec (25 maps/sec), the spatial resolution is up to 70 × 70 microns/pixel. The diameter of the smallest recordable active region of the cortex is 200–300 microns. The minimal time needed for a session used for averaging of 4–9 responses varied from 40 sec up to 18 min. TES allows to detect the position, size and sequence of operation of precisely located specific cortical zones, and to measure their dynamics before, during and after sensory and direct cortical stimulation, motor acts and conditioning (associative learning). TES-effects were recorded in rats, rabbits, cats, monkeys and humans. Waves were found spreading over the cortex with a speed of up to 30 mm/sec along trajectories specific for the sensory modality and the site of stimulation. Some pathological processes in the brain are detectable by TES: experimental tumours and epileptic foci. There are many sources for local heating: neural activity, local metabolism of units, local cerebral blood flow and thermoconductivity in the activated zones of the cortex. Thermoencephaloscopy is a dynamic, non-invasive, contact-free method with a relatively high temporal and spatial resolution and sensitivity. It can be a useful tool in basic neuroscience and medicine.