Fastigial inputs to paraventricular neurosecretory neurones studied by extra- and intracellular recordings in rats

Integrity of Cerebellar Fastigial Nucleus Intrinsic Neurons Is Critical for the Global Ischemic Preconditioning

Excitation of intrinsic neurons of cerebellar fastigial nucleus (FN) renders brain tolerant to local and global ischemia. This effect reaches a maximum 72 h after the stimulation and lasts over 10 days. Comparable neuroprotection is observed following sublethal global brain ischemia, a phenomenon known as preconditioning. We hypothesized that FN may participate in the mechanisms of ischemic preconditioning as a part of the intrinsic neuroprotective mechanism. To explore potential significance of FN neurons in brain ischemic tolerance we lesioned intrinsic FN neurons with excitotoxin ibotenic acid five days before exposure to 20 min four-vessel occlusion (4-VO) global ischemia while analyzing neuronal damage in Cornu Ammoni area 1 (CA1) hippocampal area one week later. In FN-lesioned animals, loss of CA1 cells was higher by 22% compared to control (phosphate buffered saline (PBS)-injected) animals. Moreover, lesion of FN neurons increased morbidity following global ischemia by 50%. Ablation of FN neurons also reversed salvaging effects of five-minute ischemic preconditioning on CA1 neurons and morbidity, while ablation of cerebellar dentate nucleus neurons did not change effect of ischemic preconditioning. We conclude that FN is an important part of intrinsic neuroprotective system, which participates in ischemic preconditioning and may participate in naturally occurring neuroprotection, such as "diving response".

Modulatory effects of theta burst stimulation on cerebellar nonsomatic functions

Clinical and functional imaging studies suggest that the cerebellar vermis is involved in the regulation of a range of nonsomatic functions including cardiovascular control, thirst, feeding behavior, and primal emotions. Cerebello-hypothalamic circuits have been postulated to be a potential neuroanatomical substrate underlying this modulation. We tested this putative relationship between the cerebellar vermis and nonsomatic functions by stimulating the cerebellum noninvasively via neuronavigated transcranial magnetic stimulation. In this randomized, counter-balanced, within-subject study, intermittent theta burst stimulation (TBS) was applied on three different days to the vermis and the right and left cerebellar hemispheres of 12 right-handed normal subjects with the aim of modulating activity in the targeted cerebellar structure. TBS-associated changes were investigated via cardiovascular monitoring, a series of emotionally arousing picture stimuli, subjective analog scales for primal emotions, and the Profile of Mood States test. All 36 sessions of cerebellar stimulation were tolerated well without serious adverse events. Cardiovascular monitoring pointed to a mild but significant decrease in heart rate subsequent to vermal stimulation; no changes were detected in systolic or diastolic blood pressure measurements. Subjective ratings detected a significant increase in Thirst and a trend toward increased Appetite following vermal stimulation. These observations are consistent with existing neurophysiological and neuroimaging data indicating a role for the cerebellum in the regulation of visceral responses. In conjunction with the modulatory function of the cerebellum, our results suggest a role for the vermis in somatovisceral integration likely through cerebello-hypothalamic pathways. Further research is warranted to elucidate the potential mechanisms underlying the cerebellar modulation of nonsomatic functions.

Influences of cerebellar interpositus nucleus and fastigial nucleus on neuronal activity of lateral hypothalamic area

Stimulation of cerebellar interpositus nucleus and fastigial nucleus could influence the neuronal activity of lateral hypothalamic area in the cat, and some of the neurons which respond to the cerebellar stimulations are glucose-sensitive neurons. These results suggest that the cerebellum is involved not only in motor control, but also in the regulation of non-somatic functions through the cerebello-hypothalamic pathways.

Pharmacologic characteristics of bladder micturition function in anesthetized mice

In the present study, we observed the effects of an α(1)-adrenoceptor agonist (phenylephrine), β-adrenoceptor agonist (isoprenaline), muscarinic cholinoceptor agonist (carbachol), and α(1)-adrenoceptor antagonist (doxazosin) on the bladder micturition function in anesthetized mice. Changes in bladder pressure in response to filling and blood pressure were recorded by using a data acquisition system. Phenylephrine (50 to 800 μg/kg) increased vesical micturition pressure in a dose-dependent manner but increased micturition basal pressure only at 800 μg/kg. Carbachol (3 to 7 μg/kg) increased the intercontraction interval and micturition time in a dose-dependent manner but increased micturition basal pressure only at 7 μg/kg. Isoprenaline (10 to 1000 μg/kg) increased micturition time and decreased vesical micturition pressure in a dose-dependent manner. Doxazosin (10 to 1000 μg/kg) did not affect bladder micturition function but dose-dependently inhibited phenylephrine-induced increases in vesical micturition pressure. Carbachol (7 μg/kg) and isoprenaline (1 mg/kg) caused a transient fall in blood pressure, whereas doxazosin (1 mg/kg) had a long-lasting hypotensive effect. The maximal decrease in systolic and mean blood pressure by carbachol did not differ from that by doxazosin and isoprenaline, respectively. Phenylephrine (800 μg/kg) transiently increased the blood pressure of anesthetized mice. These results indicate that activation of muscarinic cholinoceptors decreases voiding frequency and increases bladder capacity in anesthetized mice. Activation of α(1)-adrenoceptors mainly increases vesical micturition pressure, whereas activation of β-adrenoceptors decreases vesical micturition pressure and prolongs micturition time in anesthetized mice.

The cerebellum in feeding control: possible function and mechanism

Accumulating anatomical, functional, and behavioral studies reveal that the cerebellum is involved in the regulation of various visceral functions including feeding control. Cerebellar lesions may induce alterations in feeding behavior and decreases in body weight. Although the exact mechanisms underlying the cerebellar regulation of food intake is still unclear, a series of studies have demonstrated that there are neural pathways directly and/or indirectly connecting the cerebellum with several important centers for feeding control, such as the hypothalamus. Electrophysiological data suggest that via the direct cerebellohypothalamic projections, the cerebellar outputs may reach, converge, and be integrated with some critical feeding signals including gastric vagal afferents, CCK, leptin, and glycemia on single hypothalamic neurons. Furthermore, recent functional imaging studies provide substantial evidences that hunger, satiation, and thirst are accompanied with a cerebellar activation. Here we describe that the cerebellum may be much more than a movement coordinator and actively participate in feeding control, i.e., it may act as an essential node linking somatic and visceral systems and help to generate an integrated and coordinated somatic-visceral response in feeding behavior.

Cerebellar modulation of feeding-related neurons in rat dorsomedial hypothalamic nucleus

Cerebellum has newly been implicated in many more nonsomatic functions other than motor control. Previous studies indicate that the cerebellum is involved in feeding regulation and that the gastric vagal nerves transmit short-term meal-related visceral signals, including cholecystokinin (CCK), into the hypothalamus. Recently, the dorsomedial hypothalamic nucleus (DMN) has been thought to play an important role in feeding control. Here we investigate whether the inputs from cerebellar interpositus nucleus (IN) can reach and converge onto single DMN neurons with some feeding-related visceral signals, including gastric vagal inputs, CCK, and blood glucose, whose concentration is closely linked to food intake. Among the 259 DMN neurons recorded, 120 (46.3%) and 169 (65.3%) responded to the cerebellar IN and gastric vagal stimulations, respectively. Within the 120 DMN neurons responsive to the cerebellar IN stimulation, 98 (81.7%) also responded to the gastric vagal stimulus, and a summation of the responses was observed further (n = 20), suggesting a convergence and interaction of cerebellar and gastric vagal inputs on the cells. Moreover, among the 98 cells receiving convergent inputs from cerebellar IN and gastric vagal nerves, 69 (70.4%) were identified to be glycemia sensitive, and 22 (68.8%) of the 32 tested neurons were also sensitive to systemic CCK. These results demonstrate that the DMN integrates somatic information forwarded by the cerebellar IN and visceral signals related to food intake, including gastric vagal, CCK and glycemia, and electrophysiologically reveal a novel cerebellohypothalamic IN-DMN pathway through which the cerebellum may actively participate in short-term feeding regulation.

The cerebellar-hypothalamic circuits: potential pathways underlying cerebellar involvement in somatic-visceral integration

The cerebellum has been considered only as a classical subcortical center for motor control. However, accumulating experimental and clinical evidences have revealed that the cerebellum also plays an important role in cognition, for instance, in learning and memory, as well as in emotional behavior and in nonsomatic activities, such as visceral and immunological responses. Although it is not yet clear through which pathways such cerebellar nonsomatic functions are mediated, the direct bidirectional connections between the cerebellum and the hypothalamus, a high autonomic center, have recently been demonstrated in a series of neuroanatomical investigations on a variety of mammals and indicated to be potential pathways underlying the cerebellar autonomic modulation. The direct hypothalamocerebellar projections originate from the widespread hypothalamic nuclei/areas and terminate in both the cerebellar cortex as multilayered fibers and the cerebellar nuclei. Immunohistochemistry studies have offered fairly convincing evidence that some of these projecting fibers are histaminergic. It has been suggested that through their excitatory effects on cerebellar cortical and nuclear cells mediated by metabotropic histamine H(2) and/or H(1) receptors, the hypothalamocerebellar histaminergic fibers participate in cerebellar modulation of somatic motor as well as non-motor responses. On the other hand, the direct cerebellohypothalamic projections arise from all cerebellar nuclei (fastigial, anterior and posterior interpositus, and dentate nuclei) and reach almost all hypothalamic nuclei/areas. Neurophysiological and neuroimaging studies have demonstrated that these connections may be involved in feeding, cardiovascular, osmotic, respiratory, micturition, immune, emotion, and other nonsomatic regulation. These observations provide support for the hypothesis that the cerebellum is an essential modulator and coordinator for integrating motor, visceral and behavioral responses, and that such somatic-visceral integration through the cerebellar circuitry may be fulfilled by means of the cerebellar-hypothalamic circuits.

Effect of lesions of cerebellar fastigial nuclei on lymphocyte functions of rats

The cerebellum, probably owing to its traditional concept limited to motor control, is less well studied in immunoregulation. To obtain more comprehension and knowledge on cerebellar functions, we investigated effect of cerebellar fastigial nucleus (FN), an output nucleus of the spinocerebellum, on lymphocyte functions, and explored central and peripheral pathways involved in the effect. Kainic acid (KA) was microinjected into bilateral FN of rats (0.4 microg KA in 0.4 microl saline for each side) to destroy neurons of the nuclei. On days 8, 16 and 32 following the FN lesions, methyl-thiazole-tetrazolium (MTT) assay and flow cytometry were used to measure proliferation of concanavalin A (Con A)-induced lymphocytes and cytotoxicity of natural killer (NK) cells against YAC-1 cells, respectively. Meanwhile, glutamate and monoamine neurotransmitters, including norepinephrine (NE), dopamine (DA) and 5-hydroxytryptamine (5-HT), in the hypothalamus and the spleen were determined by means of high-performance liquid chromatography (HPLC) assay. Adrenocorticotropic hormone (ACTH) and cortisol in the plasma were also detected respectively by radioimmunoassay and chemiluminescent immunoassay after the FN lesions. We found that the Con A-induced lymphocyte proliferation and the NK cell cytotoxicity were both significantly enhanced on days 8, 16 and 32 following the effective lesions of the bilateral FN in comparison with those of matching control rats microinjected with saline in their FN. Contents of glutamate and NE, not DA and 5-HT, in the hypothalamus, and concentration of NE, not DA, in the spleen were all remarkably reduced on the 16th day following the FN lesions, when both the T lymphocyte proliferation and the NK cell cytotoxicity were dramatically increased. However, levels of ACTH and cortisol in the plasma had no notable differences between FN lesion rats and FN saline ones when the enhanced T and NK cell functions occurred. These findings reveal that the cerebellar FN participates in the modulation of lymphocyte functions and that the hypothalamus and sympathetic nerves innervating lymphoid organs are involved in this neuroimmunomodulation. Thus, a possible central and peripheral pathway for the spinocerebellum to regulate lymphocyte functions is suggested, i.e. cerebellum-hypothalamus-sympathetic nerves-lymphocytes, while the functional axis of hypothalamus-pituitary-adrenal gland may not contribute to mediation of the spinocerebellar immunomodulation.

Cerebellar interpositus nuclear inputs impinge on paraventricular neurons of the hypothalamus in rats

Several reports have indicated that the cerebellum is involved in regulation of some non-somatic activities through the cerebellohypothalamic projections. Therefore, the modulatory effects of the cerebellar interpositus nucleus (IN) on neuronal activity of the paraventricular nucleus of the hypothalamus (PVN) was investigated in this study by using in vivo extracellular recording technique in rats. We recorded from 115 PVN neurons, 51 (44.3%) responded to the cerebellar IN stimulation. Of the responsive PVN neurons tested for their sensitivity to hypertensive and/or hyperosmotic stimulations, 66.7% (6/9) and 75.0% (6/8) responded to intravenous metaraminol and hypertonic saline administration, respectively. These results demonstrate that the cerebellar IN afferent inputs impinge on the PVN neurons, including those baroreflex-sensitive and osmoresponsive neurons, suggesting that the cerebellum may actively participate in the cardiovascular regulation and osmoregulation through the cerebellohypothalamic projections.

Cerebellar interpositus nuclear and gastric vagal afferent inputs reach and converge onto glycemia-sensitive neurons of the ventromedial hypothalamic nucleus in rats

The glycemia-sensitive neurons of the ventromedial hypothalamic nucleus (VMN) have traditionally been implicated in feeding regulation. Some studies reported that the neuronal activity of the VMN could be modulated by inputs from the gastric vagal afferent, and the cerebellum might participate in regulating non-somatic visceral activities via the cerebellohypothalamic projections. The present study was therefore undertaken to investigate whether the inputs from the gastric vagal nerves and the cerebellar interpositus nucleus (IN) could reach and converge onto single VMN neurons, especially those glycemia-sensitive ones. Among recorded 283 VMN neurons, 187 (66.1%) and 139 (49.1%) responded to the gastric vagal and the cerebellar IN stimulations, respectively. Within the VMN neurons that were responsive to either of the gastric vagal or cerebellar IN stimulation, 91 responded to both of the stimuli, suggesting a convergence of gastric vagal and cerebellar inputs on the cells. When the gastric vagal nerves and cerebellar IN were stimulated simultaneously, a summation of the responses could be observed (n = 22). Moreover, of the 91 cells that responded to both of the gastric vagal and cerebellar IN stimuli, 61 (67.0%) were identified to be glycemia-sensitive neurons. These results demonstrate that the visceral signals conveyed by the gastric vagal afferents and the somatic information forwarded by the cerebellar IN could converge onto single VMN neurons, especially the glycemia-sensitive neurons. And the findings suggest that an integration of the somatic-visceral response related to the food intake could take place in the VMN and the cerebellum might actively participate in the short-term feeding regulation through the cerebellohypothalamic projections.

Possible pathways for cerebellar modulation of autonomic responses: micturition

Experimental and clinical studies have shown that the cerebellum participates in the regulation of various visceral responses, including micturition. It is not yet clear through which parts of the central nervous system such cerebellar influences are mediated. However, a series of investigations have shown that the cerebellum is directly or indirectly connected to various centres that appear to be involved in autonomic control. These include parts of the cerebral cortex, the hypothalamus, the periaquaductal grey, nuclei in and around the pontine micturition centre, the dorsal vagal nucleus and nucleus of the solitary tract, and the medullary reticular formation. This article examines some of the circuits that may be involved in cerebellar modulation of visceral reflexes, especially the micturition reflex.

Excitatory effects of histamine on cerebellar interpositus nuclear cells of rats through H(2) receptors in vitro

Neuroanatomical studies have revealed a direct hypothalamocerebellar histaminergic pathway, and our previous studies have demonstrated an excitatory effect of histamine on granule and Purkinje cells of the cerebellar cortex. In this study, we further investigated the effect of histamine on the neuronal firing of cerebellar interpositus nucleus (IN) by using cerebellar slice preparations. Eighty-seven IN cells were recorded from 38 slices. The vast majority of the cells responded to histamine stimulation with an excitatory response (79/87, 90.8%), and the rest of them showed no reaction (8/87, 9.2%). The histamine-induced excitation was not blocked by application of low-Ca(2+)/high-Mg(2+) medium (n=8), supporting a direct postsynaptic action of histamine. The histamine H(2) receptor antagonist ranitidine effectively blocked the excitatory response of IN cells to histamine (n=23), but the histamine H(1) receptor antagonist triprolidine could not significantly block the histamine-induced excitation, or only very slightly decreased the excitatory effect of histamine on the cells (n=21). On the other hand, the highly selective histamine H(2) receptor agonist dimaprit mimicked the excitatory effect of histamine on IN cells and the dimaprit-induced excitation was also blocked by ranitidine (n=14). Successively perfusing slices with the medium containing ranitidine and triprolidine, respectively, we found that ranitidine exhibited the same blocking effect on the dimaprit-induced excitation, but triprolidine had no such effect (n=8). Moreover, the histamine H(1) receptor agonist 2-pyridylethylamine did not show any effect on the IN cells (n=9). These results demonstrate that histamine excites cerebellar IN cells via the histamine H(2) receptor mechanism. Together with our previous results, we suggest that the hypothalamocerebellar histaminergic fibers may modulate neuronal activities of the cerebellar cortex and deep nuclei in parallel. The significance of the excitatory effect of histamine on the cerebellar nuclear cells is discussed.

Histamine excites rat cerebellar Purkinje cells via H2 receptors in vitro

Recent neuroanatomical studies have revealed a direct hypothalamocerebellar histaminergic pathway. However, the functional significance of the histaminergic fibers in the cerebellum is not yet clear. In this study, the effects of histamine on the firing of cerebellar Purkinje cells (PCs) were investigated in vitro. Histamine predominantly produced excitatory (106/111, 95.5%) and in a few cases inhibitory (5/111, 4.5%) responses in PCs. The histamine-induced excitation was not blocked by perfusing the slice with low Ca2+ high/Mg2+ medium (n = 8), supporting a direct postsynaptic action of histamine. The histamine H2 receptor antagonist ranitidine effectively blocked the excitatory response of PCs to histamine (n = 20), but triprolidine, an H1 receptor antagonist, could not significantly block the histamine-induced excitation, or only very slightly decreased the excitatory effect of histamine on the cells (n = 13). On the other hand, the highly selective H2 receptor agonist dimaprit mimicked the excitatory effect of histamine on PCs and this dimaprit-induced excitation was also blocked by ranitidine (n = 20), but not triprolidine (n = 8). However, the H1 receptor agonists betahistine and 2-thiazolylethylamine did not show any effect on the PCs (n = 9 and 14). These results reveal that histamine excites cerebellar PCs via H2 receptors and suggest that the hypothalamocerebellar histaminergic fibers may play an important role in functional activities of the cerebellum.

Histamine excites rat cerebellar granule cells in vitro through H1 and H2 receptors

The effects of histamine on the firing of cerebellar granule cells were investigated in vitro. Histamine predominantly produced excitatory (117/123, 95.1%) and in a few cases inhibitory (6/123, 4.9%) responses in granule cells. The histamine-induced excitation was not blocked by perfusing the slice with low Ca2+/high Mg2+ medium, supporting a direct postsynaptic action of histamine. The H1 receptor antagonists triprolidine and chlorpheniramine significantly diminished the histamine-induced excitation, but the H2 receptor antagonist ranitidine did not significantly reduce the excitation. On the other hand, the H2 receptor agonist dimaprit could elicit a weak excitation of granule cells. This dimaprit-induced excitation was blocked by ranitidine but not triprolidine. These results reveal that the excitatory effect of histamine on cerebellar granule cells is mediated by both H1 and H2 receptors with a predominant contribution of H1 receptors. The relevance of these findings to the possible function of the hypothalamocerebellar histaminergic fibers in cerebellum is discussed.

An investigation of a possible direct projection from the medial nucleus of the cerebellum to the paraventricular nucleus of the hypothalamus in the rat: a study using retrograde WGA-HRP and Fluoro-Gold tracing techniques

Retrograde transport of lectin-conjugated horseradish peroxidase and Fluoro-Gold was used in an attempt to obtain data to confirm the existence, predicted from physiological studies, of a direct, monosynaptic projection from the medial nucleus of the cerebellum (MN) to the paraventricular nucleus of the hypothalamus (PVH) in the rat. Injections of these two tracers that included the PVH and surrounding diencephalic structures, or that in the case of Fluoro-Gold were localized to the PVH, resulted in retrograde neuronal labeling in widely separated nuclei known to project to the areas included in the injection sites. Thus, effective uptake and transport of both tracers occurred under the experimental conditions employed in this study. However, injections confined to the PVH and regions of the hypothalamus adjacent to it, or to the PVH alone, produced no retrograde neuronal labeling in the medial nucleus, indicating that the MN does not project directly to the PVH. Alternative explanations for the findings from physiological experiments were sought. The possibility that electrical stimulation of fibers of passage through the region of the MN might produce a monosynaptic response in the contralateral PVH was discarded, because retrogradely labeled neurons in nuclei such as the locus ceruleus and lateral parabrachial nucleus were distributed mainly ipsilateral to hypothalamic injection sites. However, tracer injections into the MN produced retrograde labeling of neurons in the same region of the lateral paragigantocellular nucleus (LPGi) in which labeled cells were found following tracers injections into the PVH. Axon collaterals of individual neurons in the LPGi might, therefore, project both to the MN and to the PVH. The possibility that such a circuit could, in the absence of a direct MN to PVH projection, provide the basis to explain the physiological findings is discussed.

Cerebellar interpositus nucleus modulates neuronal activity of lateral hypothalamic area

Effects of stimulating the cerebellar interpositus nucleus (IN) on the neuronal activity of lateral hypothalamic area (LHA) were first observed in the cat. The results showed that (1) IN stimulation could elicit inhibitory, excitatory, inhibitory-excitatory and excitatory-inhibitory responses from LHA neurones, with a majority of inhibitory responses (46.9%); (2) the responsive latencies of LHA neurones to IN stimulation ranged from 5 to 45 ms, while most (83.6%) showed a short latency of < 15 ms; (3) of 67 LHA neurones which responded to the IN stimulation, 42 (62.7%) cells were identified to be glucose-sensitive neurones. These results suggest that IN may be involved in the role of LHA modulating food intake behaviour, as well as other non-somatic functions.

In vivo Intracellular Recording of Neurons in the Supraoptic Nucleus of the Rat Hypothalamus

Abstract Intracellular recordings were made from cells in the hypothalamic supraoptic nucleus in the urethane-anaesthetized male rat using the ventral surgical approach. Impalements lasted from 5 min to 1 h and recorded cells had an input resistance of 55 to 170 megohms. Spikes of over 50 mV were recorded from 14 cells which could be antidromically activated by stimulation of the neural stalk. The spikes showed a hyperpolarizing afterpotential and the broadening characteristic of rapidly firing magnocellular neurons, which recovered rapidly (<200 ms). When depolarized, the cells showed evidence of a transient potassium current. Recurrent synaptic coupling between the recorded cell and adjacent cells would be expected to alter the hyperpolarizing afterpotential of an antidromic spike as compared with a spontaneous spike; no perceptible difference in the waveforms of the different types of spike could be detected in 11 spontaneously active cells. Application of just subthreshold stimuli to the neural stalk did not evoke depolarizing or hyperpolarizing potentials. Suprathreshold shocks to the neural stalk, when the antidromic spike was prevented by collision, also had no discernible effect on membrane potential. Thus intracellular recordings from magnocellular neurons in vivo revealed electrophysiological properties similar to those seen in vitro. No evidence for synaptic interconnection between magnocellular neurons was found in male rats.

Neuronal connections between the cerebellar nuclei and hypothalamus in Macaca fascicularis: cerebello-visceral circuits

The purpose of this study was to identify the basic pattern of interconnections between the cerebellar nuclei and hypothalamus in Macaca fascicularis. The distribution of retrogradely labeled cells and anterogradely filled cerebellofugal axons in the hypothalamus of M. fascicularis was investigated after pressure injections of a horseradish peroxidase mixture (HRP + WGA-HRP) in the cerebellar nuclei. Following injections in the lateral, anterior, and posterior interposed cerebellar nuclei retrogradely labeled cells were present in the following areas (greatest to least concentration): lateral and dorsal hypothalamic areas, dorsomedial nucleus, griseum periventriculare hypothalami, supramammillary and tuberomammillary nuclei, posterior hypothalamic area, ventromedial nucleus and periventricular hypothalamus, around the medial mammillary nucleus, lateral mammillary nucleus, and infundibular nucleus. Cell labeling was bilateral with an ipsilateral preponderance. In these same experiments anterogradely labeled cerebellar efferent fibers terminated in the contralateral posterior, dorsal and lateral hypothalamic areas, and the dorsomedial nucleus. In these regions retrogradely labeled hypothalamic cells were occasionally found in areas that also contained anterogradely filled cerebellar axons. This suggests a partial reciprocity in this system. In addition, sparse numbers of labeled cerebellar fibers recross in the hypothalamus to distribute to homologous areas ipsilateral to the injection site. Subsequent to an injection in the medial cerebellar nucleus (NM), cell labeling was present in more rostral hypothalamic levels including the lateral and dorsal hypothalamic areas, the dorsomedial nucleus, around or in fascicles of the column of the fornix, and in the periventricular hypothalamic area. Although no fastigiohypothalamic fibers were seen in this study, on the basis of information available from the literature it is likely that such a connection exists in primates. In summary, hypothalamic projections to NM originated mainly from rostral to midhypothalamic levels, whereas those projections to the lateral three cerebellar nuclei came from mid and more caudal levels. The existence of direct hypothalamic projections to cerebellar nuclei in M. fascicularis and of cerebellofugal projection to some hypothalamic centers indicates that circuitry is present through which the cerebellum may influence visceral functions. Furthermore, the fact that projections to NM versus the other cerebellar nuclei originate from somewhat different regions of the hypothalamus would suggest that the visceral functions modulated by each pathway is not the same.