A rodent model of human organophosphate exposure producing status epilepticus and neuropathology.

Exposure to organophosphates (OPs) often results in seizures and/or status epilepticus (SE) that produce neural damage within the central nervous system (CNS). Early control of SE is imperative for minimizing seizure-related CNS neuropathology. Although standard therapies exist, more effective agents are needed to reduce OP-induced SE and neuronal loss, particularly therapies with efficacy when administered 10's of minutes after the onset of SE. To evaluate novel antiseizure compounds, animal models should simulate the CNS effects of OP exposure observed in humans. We characterized in rats the effects of the OP, diisopropyl flourophosphate (DFP) as a function of dose and route of administration of supporting agents (pyridostigmine, 2-PAM, atropine); outcome measures were mortality, electrographic seizure activity during SE, and subsequent CNS neuropathology. Doses of DFP between 3 and 7mg/kg consistently caused SE, and the latency to behavioral tremors and to subsequent initiation of SE were dose related. In distinction, all doses of DFP that resulted in electrographic SE (3-7mg/kg) produced seizures of similar intensity and duration, and similar CNS neuropathology (i.e., the effects were all-or-none). Although SE was similar across doses, mortality progressively increased with higher doses of DFP. Mortality was significantly lower when the route of administration of therapeutic agents was intramuscular compared to intraperitoneal. This rodent model of OP poisoning demonstrates pathological characteristics similar to those observed in humans, and thus begins to validate this model for investigating potential new therapeutic approaches.

Central blockade of oxytocin receptors during mid-late gestation reduces amplitude of slow afterhyperpolarization in supraoptic oxytocin neurons.

The neurohypophysial hormone oxytocin (OT), synthesized in magnocellular paraventricular (PVN) and supraoptic (SON) nuclei, is well known for its effects in lactation. Our previous studies showed that central OT receptor (OTR) binding is increased during gestation and that blockade of central OTRs, specifically during mid-late gestation, causes a delay in OT release during suckling and reduces weight gain in pups, suggesting decreased milk delivery. In the present study, we tested whether central OTR blockade during late gestation disrupts the gestation-related plasticity in intrinsic membrane properties. Whole cell current-clamp recordings were performed in OT neurons from pregnant rats (19-22 days in gestation) that were infused with an OTR antagonist (OTA) or artificial cerebrospinal fluid (aCSF) and from virgin rats infused with aCSF into the third ventricle via an osmotic minipump beginning on days 12-14 of gestation. The amplitudes of both Ca(2+)-dependent afterhyperpolarizations (AHPs), an apamin-sensitive medium AHP (mAHP) and an apamin-insensitive slow AHP (sAHP), were significantly increased during late gestation in control pregnant animals. However, the amplitude of the sAHP from pregnant rats treated with the OTA was significantly smaller than that of pregnant control rats and similar to that of virgins. These results indicate that the diminished efficiency in lactation due to OTR blockade may be partly a result of an altered sAHP that would shape OT bursting. These findings suggest that central actions of OT during late gestation are necessary for programming the plasticity of at least some of the intrinsic membrane properties in OT neurons during lactation.

Neurochemical bases of plasticity in the magnocellular oxytocin system during gestation.

The central and systemic release of oxytocin (OT) has been well documented during parturition and lactation. In preparation for the demands of these events, the magnocellular hypothalamic neurons of the central OT system undergo a variety of biochemical, molecular, electrophysiological, and anatomical adaptations during gestation. However, the mechanisms responsible for these changes have not been well established. A number of neurochemical mediators have been implicated in contributing to the plasticity in the OT magnocellular system during gestation, including ovarian hormones, as well as central neurotransmitters, such as glutamate, gamma-amino butyric acid (GABA), and central neurosteroids, e.g., allopregnanolone. In addition, several lines of evidence suggest that central OT release and subsequent OT receptor stimulation may contribute to adaptations of the OT system during gestation, and may be necessary for its subsequent functioning during lactation. Here, we review evidence for involvement of the neurochemical systems implicated in contributing to adaptations that occur in the OT system during the course of gestation.

Central blockade of oxytocin receptors during late gestation disrupts systemic release of oxytocin during suckling in rats.

There is evidence that the central oxytocin system is activated and undergoes reorganization before parturition. The present study was designed to determine the effects of central oxytocin receptor blockade during late gestation on parturition, pup growth, and oxytocin release during suckling. Female Sprague-Dawley rats were implanted on gestation day 12-14 with Alzet osmotic minipumps containing an oxytocin receptor antagonist (d(CH2)5, Tyr(Me)(2), Orn(8)-vasotocin; OT-X) or artificial cerebrospinal fluid (VEH), which was infused into the third cerebral ventricle. Pumps were removed within 24 h of parturition. Daily maternal body weight and food intake were monitored during gestation and lactation. The length of gestation, duration of parturition, pup number, litter weight and interbirth interval were recorded. Subsequently, pup number and litter weights were recorded daily until lactation day 10 or 11, when maternal and pup behaviour, and plasma oxytocin concentration before and during suckling were measured. Central oxytocin blockade had no effect on the timing of parturition, maternal behaviour, litter size, still births, or litter weights at birth. However, beginning on day 3 of lactation, average weights of litters of OT-X females were significantly lower than litters of VEH-treated females. Furthermore, while basal plasma oxytocin concentrations, oxytocin increases in response to suckling and dam/pup interactions did not differ between groups, a significant delay in suckling-induced systemic oxytocin release was observed in OT-X females. Finally, OT-X dams weighed less than VEH dams during the postpartum observation period, although food intakes were similar. These data suggest that central actions of oxytocin during late gestation are necessary for the normal timing of systemic release of oxytocin during suckling, normal pup weight gain, and maintenance of maternal body weight.

Histaminergic control of oxytocin release in the paraventricular nucleus during lactation in rats.

The central neurotransmitters regulating both systemic and central release of oxytocin (OT) during lactation are not completely defined. Although central histaminergic systems have been implicated in systemic release of OT, the role of this neurotransmitter in suckling-induced intranuclear OT secretion has not been investigated. Therefore, microdialysis of the paraventricular nucleus (PVN) was used to determine if suckling stimulates histamine release within the PVN and if nursing-induced intranuclear OT release is reduced by local blockade of either H1 or H2 histamine receptors. Female Holtzman rats were implanted with microdialysis probes adjacent to the PVN on lactation days 8-12. The next day, the pups and dam were separated for 4 h, reunited, and again separated. Histamine concentrations in dialysates were measured before, during, and following suckling. In separate animals, a similar separation/reunion paradigm was used, but the dialysate OT concentration was measured during PVN perfusion with vehicle or an H1 or H2 receptor antagonist. Suckling increased dialysate concentrations of both histamine and OT in the PVN. Furthermore, local pharmacological blockade of either H1 or H2 receptors prevented the increase in OT release in the PVN during suckling. These data demonstrate that activation of histamine receptors in the PVN is necessary for intranuclear release of OT induced by suckling and extend previous findings demonstrating a similar relationship between central histamine and systemic release of OT.

Anteroventral third ventricle periventricular tissue contributes to cardiac baroreflex responses.

1. The studies reviewed in the present paper demonstrate that the anteroventral third ventricle (AV3V) region contains tissue that can modify cardiac baroreflex sensitivity in response to circulating angiotensin (Ang)II and hyperosmolality. 2. The response to hyperosmolality appears to be mediated by noradrenergic receptors. Although the role of noradrenergic receptors in the AV3V region in modification of baroreflex-induced responses to AngII has not been directly tested, this neurotransmitter is a good candidate for control of heart rate because noradrenaline in the AV3V region is critical for mediating other responses to AngII. 3. Results from studies indicate that the AV3V region is part of a central nervous system circuit involved in modulation of cardiac baroreflex sensitivity by circulating substances, possibly acting at the organum vasculosum lamina terminalis. 4. The findings extend the role of the AV3V periventricular tissue as a central site integrating autonomic nervous system function by demonstrating that this brain area contributes to cardiac function, in addition to its well-characterized role in sympathetic nervous system regulation of blood pressure and mechanisms of fluid and electrolyte regulation.

Central control of cardiac baroreflex responses during peripheral hyperosmolality.

Acute increases in peripheral osmolality evoke a pressor response and baroreflex-mediated bradycardia. These experiments were designed to determine if the fall in heart rate during peripheral sodium loading is 1) equivalent to bradycardia accompanying phenylephrine (PE) infusion, 2) mediated by the parasympathetic (PSNS) or sympathetic (SNS) nervous system, and 3) controlled by the median preoptic nucleus (MnPO). Male rats received an intravenous infusion of isotonic saline, hypertonic saline (2.5 M NaCl), or PE for 30 min. Blood pressure increased equivalently in the hypertonic NaCl and PE groups. However, heart rate fell more in animals infused with PE. Furthermore, pretreatment with methylatropine to block the PSNS had no effect on bradycardia, whereas blocking SNS influences on cardiac function significantly attenuated the fall in heart rate during peripheral hyperosmolality. Finally, kainic acid administration in the MnPO before testing increased bradycardia observed during hypertonic saline loading. Taken together, these data suggest that acute peripheral hyperosmolality acts at the MnPO to reduce cardiac SNS withdrawal during the pressor response that reduces the associated baroreflex bradycardia.

Systemic angiotensin II and volume expansion release norepinephrine in the preoptic recess.

The periventricular tissue surrounding the anteroventral portion of the third cerebral ventricle (AV3V) of the preoptic recess is critical for several responses evoked by central and peripheral angiotensin II (ang II), and the natriuresis produced by extracellular fluid volume expansion. In addition, several other studies have suggested that the pressor and natriuretic responses evoked by these stimuli are regulated by activation of noradrenergic systems in AV3V tissue. The purpose of the present experiments was to directly determine if i.v. infusion of ang II and volume expansion increase norepinephrine release in the AV3V area using in vivo microdialysis. Male, Sprague-Dawley rats were implanted with microdialysis probes in the AV3V and were tested conscious and unrestrained. Dialysate was collected before, during, and following i.v. administration of ang II or phenylephrine which raised blood pressure 40-50 mmHg, or volume expansion with isotonic saline. Dialysate norepinephrine concentrations from these rats were compared to dialysate norepinephrine content from animals which received no treatment. Both i.v. infusion of ang II and isotonic volume expansion significantly increased dialysate norepinephrine concentration, while infusion of phenylephrine did not alter norepinephrine release in AV3V tissue. These data demonstrate that peripheral ang II and volume expansion selectively increase norepinephrine release in the AV3V region, and are consistent with the conclusion that activation of noradrenergic systems in the AV3V region contribute to cardiovascular and drinking responses evoked by peripheral ang II and to natriuresis following volume expansion.

Stimulation of central and systemic oxytocin release by histamine in the paraventricular hypothalamic nucleus: evidence for an interaction with norepinephrine.

Central histaminergic neurons have been implicated in the control of oxytocin (OT) secretion in various physiological conditions, including parturition and lactation. The present studies investigated whether histamine also influences the central intranuclear release of OT, which is known to be important in the activation of OT neurons, and the possible interaction of histamine with norepinephrine in systemic and central OT release. Microdialysis probes were placed immediately adjacent to the hypothalamic paraventricular nucleus (PVN) and used for administration of artificial cerebrospinal fluid (ACSF) vehicle, ACSF containing histamine, ACSF containing histamine in combination with a specific H1 or H2 histamine receptor antagonist, or ACSF containing histamine and the alpha-adrenergic antagonist phentolamine. Dialysates and plasma were collected, and OT concentrations were determined using RIA. Dialysis of the PVN with ACSF containing histamine significantly increased the release of OT systemically and centrally within the PVN. Furthermore, the increases in OT concentration in dialysates and plasma were prevented by simultaneous administration of chlorpheniramine (an H1 receptor antagonist) or ranitidine (an H2 receptor antagonist) as well as by the adrenergic antagonist phentolamine. These data demonstrate that histamine acts within the PVN to increase both systemic and intranuclear release of OT. Furthermore, the increased OT release induced by histamine is dependent upon stimulation of both H1 and H2 histaminergic receptors and subsequent activation of alpha-noradrenergic receptors. These findings suggest that histamine induces systemic and intranuclear OT release by stimulating the release of norepinephrine.

Preoptic recess noradrenergic receptors control modification of baroreflex sensitivity by hypertonicity.

These studies examined the effects of alpha1- and alpha2-adrenoreceptor blockade in the anteroventral portion of the third cerebral ventricle (AV3V) on modification of baroreflex-induced changes in heart rate and renal sympathetic nerve activity (RSNA) induced by hyperosmolality. Local administration of hypertonic artificial cerebrospinal fluid (aCSF) in the AV3V significantly increased baroreflex-induced bradycardia during intravenous phenylephrine but did not alter changes in RSNA during the pressor response or alter tachycardia and neural responses evoked by decreased blood pressure. The enhanced cardiac response was not observed during simultaneous administration of phentolamine (alpha1- and alpha2-antagonist) or yohimbine (selective alpha2-antagonist) in the AV3V region. However, treatment with prazosin (alpha1-antagonist) did not alter the exaggerated cardiac response evoked by hypertonic aCSF to increased blood pressure. These data demonstrate that acute, local hypertonic stimulation in the AV3V region selectively enhances baroreflex-induced bradycardia by stimulation of alpha2-adrenergic receptors during acute pressor responses.

Neurotransmitter interaction in release of intranuclear oxytocin in magnocellular nuclei of the hypothalamus.

Oxytocin (OT) is released within the paraventricular (PVN) and supraoptic (SON) nuclei of the hypothalamus in response to several stimuli. However, the neurotransmitters that control this intranuclear OT release are unknown. In vivo microdialysis was used to examine the roles of norepinephrine and histamine in intranuclear OT release in conscious, lactating female rats. Administration of alpha- or beta-noradrenergic agonists, or histamine, increased OT release in the PVN. In addition, the increase in PVN OT evoked by exogenous histamine was prevented by simultaneous blockade of either H1 or H2 receptors. Furthermore, histamine-induced release of intranuclear OT was also prevented by blockade of alpha-adrenergic receptors. Finally, the increase in magnocellular OT release induced by suckling was abolished by administration of alpha-adrenergic antagonists. These data demonstrate that norepinephrine and histamine are important neurotransmitters for release of intranuclear OT, and histamine releases intranuclear OT by stimulating norepinephrine release.

Cytoarchitectonic analysis of Fos-immunoreactivity in brainstem neurones following visceral stimuli in conscious rats.

Visceral inputs to the brain make their initial synapses within the nucleus of the solitary tract (NTS), where information is relayed to other brain regions. These inputs relate to markedly different physiological functions and provide a tool for investigating the topography of visceral processing in brainstem nuclei. Therefore, Fos immunoreactivity was used to determine whether a gastric stimulus affects neurones within different or similar parts of the NTS, ventrolateral medulla (VLM) and parabrachial nucleus (PBN), compared to a baroreceptive stimulus. The contribution of catecholaminergic neurones in these areas was studied by combining Fos and tyrosine hydroxylase (TH) immunoreactivity. Conscious male rats received either cholecystokinin (CCK) intraperitoneally to activate gastrointestinal afferents, or were made hypertensive by intravenous infusion of phenylephrine (PE) to activate baroreceptors. Tissue sections were processed immunocytochemically for Fos and/or TH. Phenylephrine infusion and CCK injection elicited Fos expression in distinct and in overlapping regions of the NTS and the VLM. Cholecystokinin injections increased the number of Fos-immunoreactive neurones in the area postrema (AP) and throughout the rostral-caudal extent of the NTS, including commissural neurones and the medial subnuclei. Some reactive neurones in NTS were also positive for TH, but most were not, and most of the TH-positive NTS neurones were not Fos-positive. In contrast, PE infusion produced a more restricted distribution of Fos-positive neurones in the NTS, with most neurones confined to a dorsolateral strip containing few TH-positive neurones. The medial NTS at the level of the AP and the AP itself were largely unresponsive, but rostral to the AP the medial NTS was labelled, including some TH-positive neurones. Both treatments produced labelling in the caudal and mid-VLM, but PE infusion had a stronger effect in the rostral VLM. In the PBN, CCK elevated Fos expression in several subregions, whereas PE infusion failed to specifically alter any subdivision. The results suggest that stimulation of baroreceptor and gastric afferents evoke both overlapping and cytoarchitectonically distinct pathways in the brainstem.

Noradrenergic control of central oxytocin release during lactation in rats.

Noradrenergic systems regulate the systemic release of oxytocin (OT) in lactating rats. However, a role for norepinephrine (NE) in release of OT within the magnocellular nuclei during suckling has not been established. These studies were designed to determine 1) if suckling induces NE release in the supraoptic (SON) and paraventricular (PVN) nuclei of conscious rats and 2) the role of NE in the central, intranuclear release of OT within these nuclei. Female Holtzman rats were implanted with microdialysis probes adjacent to the PVN or SON on lactation days 8-12. The following day, the pups were isolated from the dams for 4 h. Microdialysis probes were perfused with artificial cerebrospinal fluid (ACSF) or with ACSF containing an alpha- or a beta-adrenergic receptor antagonist. Dialysate was collected before, during, and after suckling and analyzed for NE or OT. In an additional experiment, an alpha- or beta-adrenergic agonist was administered via the microdialysis probes into the PVN in nonsuckled, lactating rats. Extracellular NE increased in the PVN during suckling but was not detectable in the SON. OT concentrations in dialysates from the PVN and SON significantly increased during suckling. Blockade of either alpha-(in both PVN and SON) or beta- (PVN) adrenergic receptors prevented the suckling-induced increase in central OT release. OT release was increased in nonsuckled, lactating rats by central application of either an alpha- or beta-adrenergic agonist. These data demonstrate that intranuclear NE release is increased in the PVN by suckling and that subsequent stimulation of both alpha- and beta-noradrenergic receptors mediates intranuclear OT release.

Sexual dimorphism in regional blood flow responses to vasopressin in conscious rats.

The greater pressor response to vasopressin in male than in nonestrous female rats results from a greater increase in total peripheral resistance in males. The present study was performed to identify the vascular beds that contribute to this difference. Mean arterial blood pressure (MABP) and changes in blood flow in the mesenteric and renal arteries and terminal aorta were measured in conscious male and nonestrous female rats 3 h after surgery. Graded intravenous infusions of vasopressin induced greater increases in MABP and mesenteric vascular resistance and a greater decrease in mesenteric blood flow in males. Vasopressin also increased renal vascular resistance to a greater extent in males. Because renal blood flow remained unchanged, this difference may be due to autoregulation. The vasopressin-induced reduction in blood flow and increased resistance in the hindquarters were moderate and did not differ between sexes. Thus the greater vasoconstrictor response to vasopressin in the mesenteric vascular bed of male than nonestrous females contributed importantly to the sexually dimorphic pressor response to vasopressin in these experiments.

Preoptic recess alpha-adrenoceptors control cardiovascular responses to hyperosmolality.

The roles of alpha-adrenoceptors in the anteroventral third ventricle (AV3V) and diagonal band of Broca (DBB) in cardiovascular responses to peripheral hypertonicity were investigated in conscious rats. Normal artificial cerebrospinal fluid (aCSF) or aCSF containing phentolamine (alpha1- and alpha2-antagonist), yohimbine (alpha2-antagonist), or prazosin (alpha1-antagonist) was perfused through microdialysis probes in the DBB, AV3V, or lateral ventricle during a 30-min infusion of isotonic (0.17 M; 0.1 or 1.7 ml x kg(-1) x min(-1) i.v.) or hypertonic (2.5 M; 0.1 ml x kg(-1) x min(-1) i.v.) NaCl. Hypertonic infusion increased blood pressure [mean arterial blood pressure (MAP); 17 +/- 2 mmHg] and decreased heart rate (HR; 36 +/- 6 beats/min). Both responses were abolished by AV3V administration of phentolamine or yohimbine, whereas prazosin selectively prevented the bradycardia. Phentolamine in the DBB or lateral ventricle did not alter either response. Stimulation of AV3V alpha1-adrenoceptors (phenylephrine) decreased HR and MAP, whereas alpha2-adrenoceptor stimulation (clonidine) produced bradycardia but increased MAP. Data suggest that alpha-adrenoceptors in the AV3V, but not the DBB, regulate cardiovascular responses to hyperosmolality.

Acute hypertension increases norepinephrine release in the diagonal band of Broca.

In vivo microdialysis was used to measure extracellular concentrations of norepinephrine in the diagonal band of Broca (DBB) during changes in blood pressure in conscious rats. Dialysate norepinephrine concentration was significantly increased during acute hypertension (280 +/- 40% of control), but was not changed by hypotensive hemorrhage. These results are consistent with the proposal that noradrenergic innervation of the DBB is selectively activated by increased blood pressure.

The effects of hexamethonium on cerebral blood flow and cerebral function during relative cerebral ischaemia in rats.

Cerebral blood flow in either the cortex, thalamic region or the brain stem, as well as somatosensory evoked potentials were measured in a model of moderate cerebral ischaemia in three groups of anaesthetized spontaneously hypertensive rats. The rats were bled to reduce evoked potential amplitudes to approximately 50-60% of pre-haemorrhage control. The consequent blood pressure fall reduced blood flow to approximately 65, 80 and 85% of pre-haemorrhage control in the cortical, thalamic and brain stem regions, respectively, as measured with a laser Doppler flowmeter. Hexamethonium (10 mg kg-1 i.v.), an autonomic ganglion blocker, caused vasodilation and a slight (7-13 units of prebleeding control) increase in blood flow in all the three regions, and the somatosensory evoked potentials normalized. In addition, the latency of the first evoked potential component decreased toward prebleeding values. Heart rate decreased and a transient decrease was also observed in mean arterial pressure despite an attempt to keep it constant with a pressure regulating reservoir. It is possible that the slightly increased regional cerebral blood flow after hexamethonium injection can explain the improved cerebral function as indicated by the enhanced somatosensory evoked potentials. However, the results might also indicate an autonomic regulation of afferent sensory pathways.

Preoptic recess lesions reduce right atrial pressure responses to volume expansion.

Ablation of the periventricular tissue surrounding the anteroventral portion of the third cerebral ventricle (AV3V-X) abolishes natriuresis and diuresis during volume expansion. Although deficits in several efferent mechanisms have been identified, effects of AV3V-X on afferent input to the volume reflex have not been investigated. Therefore, these experiments measured right atrial pressure (RAP) in conscious AV3V-X and control-operated (CONT) rats before, during, and following acute (60 s) or continuous (60 min) infusion of isotonic saline, or vascular volume expansion with whole blood (15 min). Changes in RAP were significantly smaller in AV3V-X rats than CONT animals during acute isotonic saline infusion and during whole-blood expansion. Treatment with hexamethonium abolished the difference in RAP during acute volume infusion. However, there was no significant difference in RAP between groups during continuous isotonic saline expansion. These data suggest that AV3V-X reduces afferent input from cardiopulmonary stretch receptors during acute volume expansion, which may contribute to diminished natriuresis and diuresis observed in these animals.

Central depressor action of nitric oxide is deficient in genetic hypertension.

Inhibition of NO synthase (NOS) in the central nervous system (CNS) causes a pressor response. This observation indicates that NO is normally produced at CNS site(s) where it has a tonic blood pressure lowering effect. The current study tests the hypothesis that a deficient NOS activity in the CNS may contribute to the pressure elevation in genetically hypertensive rats. NO administered intracerebroventricularly (ICV) caused a greater fall in mean arterial pressure (MAP; femoral artery) in hypertensive (SHRSP) than in normotensive (WKY) rats, -66.1 +/- 3.4 mm Hg v -23.7 +/- 3.9 mm Hg, respectively. Yet when endogenous NO was increased by stimulating NOS with ICV calcium, the depressor response was less in SHRSP than in WKY, 13.7 +/- 1.1 mm Hg v 26.7 +/- 1.9 mm Hg. Likewise, when NOS was blocked with N omega- nitro-L-arginine methyl ester (L-NAME), the resultant pressor response was less in SHRSP than in WKY, 13.8 +/- 1.1 mm Hg v 22.2 +/- 1.1 mm Hg. Blockade of the action of cGMP, a mediator of the action of NO, caused a pressor response of 6.0 +/- 2.8 mm Hg and 22.6 +/- 8.7 mm Hg (P < .01) in the hypertensive and normotensive rats, respectively. Electrolytic ablation of the anteroventral third cerebral ventricle (AV3V) did not alter blood pressure responses to NO or to agents that alter NOS activity. We conclude that a deficit in NOS activity in some other central cardiovascular regulatory area may contribute to the elevated arterial pressure of these genetically hypertensive rats.

Differential responses in adrenal and renal nerves to CNS osmotic stimulation.

Hypertonic solutions act in the central nervous system (CNS) to increase mean arterial blood pressure (MAP) by activation of the sympathoadrenal axis. However, adrenal nerve activity (pre- and postganglionic nerve fibers) has not been determined during central osmotic stimulation. Therefore, these experiments evaluated adrenal (AdSNA) and renal (RSNA) sympathetic nerve activity, MAP, and heart rate (HR) following CNS administration of isotonic, hypertonic, and hypotonic sodium chloride solutions in chloralose-anesthetized rats. Injection of isotonic saline (5 microliters) did not alter MAP, HR, RSNA, or AdSNA. However, injection of hypertonic saline (5 microliters of 0.5 M) into the anteroventral portion of the third cerebral ventricle increased MAP (12 +/- 2 mmHg) and decreased HR (16 +/- 6 bpm). In addition, hypertonic saline significantly decreased RSNA (58 +/- 5% control), whereas AdSNA increased (158 +/- 10% control). Injection of hypotonic (5 microliters of 0.05 M) NaCl produced the opposite responses in RSNA (119 +/- 7% control) and AdSNA (86 +/- 5% control) and had no significant effect on MAP or HR. Furthermore, pre- and postganglionic adrenal nerve fibers responded similarly to changes in CNS osmolality. These results demonstrate that osmotic stimulation produces differential responses in RSNA and AdSNA, but not in pre- and postganglionic adrenal nerve fibers.