Topography of short portal vessels in the rat pituitary gland: a scanning electron-microscopic and morphometric study of corrosion cast replicas.

We applied scanning electron microscopy combined with imaging and morphometric techniques to analyze the dorsal topography and morphology of short portal vessels linking the capillary beds of the pituitary neural and anterior lobes in adult male albino rats. The pituitary microvasculature was replicated by intracarotid injection of Batson's No. 17 compound producing plastic casts that were advantageous for comprehensive morphometric analyses using an imaging device. The analysis revealed the existence of two types of portal vessels having quantitatively different morphological properties. The bilateral venular plexus of 3-4 vessels located at the base of the infundibular stalk (each venule measuring 300 microns in length and 32 microns in diameter) appears to be the major part of the short portal system in the dorsum of the rat pituitary gland. Narrower capillary-like shunt vessels (6.8 microns in diameter), of about the same length as the venules, were situated throughout other subregions of the intermediate lobe cleft. The short portal vessels of both types made direct anastomoses with the capillary networks in the neural and anterior lobes. The neural lobe capillaries were twice as numerous (1324 per mm2), and only half as wide (6.2 microns), as the sinusoidal capillaries in the anterior lobe (density of 637 per mm2; diameter of 13.7 microns). The topographical position of the portal venular system suggests that the caudolateral subregions of the pituitary neural and anterior lobes have a functional relationship dependent on rapid interlobe transfer of neurohumoral factors such as hormones via the portal blood. This process appears to be supplemented throughout the rest of the cleft between the two lobes by a small number of capillary shunts that supply the epithelial cell lobules of the intermediate lobe in situ. The findings collectively indicate that this portal system provides a constant stream of neurohumoral information that is shared moment-by-moment between the pituitary neural and anterior lobes.

Calcium-mediated metabolic stimulation of neuroendocrine structures by intraventricular endothelin-1 in conscious rats.

We examined the hypothesis that the vascular- and brain-derived peptide, endothelin-1 (ET), would affect cerebral neuroendocrine structures when administered via the peripheral circulation or via a lateral cerebral ventricle (i.c.v.). ET was infused intravenously (14 nmol/min) or injected i.c.v. (9 pmol) in conscious rats in which local cerebral glucose metabolism was assessed by the quantitative autoradiographic [14C]deoxyglucose technique. Whereas intravenously infused ET was previously demonstrated to selectively stimulate metabolic activity in the pituitary intermediate and anterior lobes of conscious rats, it was without effect in 20 individual structures or subnuclei involved in neuroendocrine functions, including several circumventricular organs. Intraventricular ET, however, caused hypermetabolic responses in 9 neuroendocrine structures, including the pineal gland, subfornical organ, median eminence, the hypothalamic paraventricular and supraoptic nuclei, and other hypothalamic and preoptic structures. The metabolic stimulation resulting from central ET was abolished or attenuated regionally by i.c.v. pretreatment with the calcium L-channel inhibitor, nimodipine. The findings indicate that i.c.v. ET elicits a calcium-mediated hypermetabolic effect on several neuroendocrine structures in the forebrain involved in the regulation of fluid homeostasis, the cardiovascular system, and body temperature.

Potent metabolic stimulation of septal gray and cerebral white matter in vivo by intraventricular endothelin and nitric oxide.

Endothelin-1 (ET) and sodium nitroprusside (SNP, which liberates nitric oxide, NO) were given alone or together into a lateral cerebral ventricle (icv) of anesthetized rats to assess their potential interaction on cerebral rates of glucose metabolism (autoradiographic [14C]deoxyglucose technique). ET (9 pmol) produced hypermetabolic effects ipsilaterally in the septal nuclei and periventricular white matter. NO lesioned the septum, which displayed neuronal damage and diminished metabolic activity, and evoked potent increases in glucose metabolism bilaterally in commissural and projection white matter tracts. Together, ET and NO had synergistic hypermetabolic effects in the hippocampal fimbria, but were antagonistic on the metabolic rate of the lateral septal nucleus and choroid plexus. The results reveal an extraordinary sensitivity in the metabolic rate of septal gray matter to ET and of white matter fibers to NO in vivo. Icv administration offers a useful approach for examination of the metabolic and toxicological properties of the novel neurotransmitter substances ET and NO on septal neurons, myelinated fibers, and choroidal epithelia.

Metabolic and neuroanatomical correlates of barrel-rolling and oculoclonic convulsions induced by intraventricular endothelin-1: a novel peptidergic signaling mechanism in visuovestibular and oculomotor regulation?

The neuroactive peptide endothelin-1 has receptors distributed abundantly among subdivisions and nuclei of the visuovestibular and oculomotor systems. In previous work, we and others described the convulsive manifestations resulting from central injection of this neuropeptide, including nystagmus, oculoclonus, exophthalmos, tonic hindlimb extension, and a generalized repetitive motor disturbance called barrel-rolling. We applied the quantitative, autoradiographic [14C]deoxyglucose method to examine the hypothesis that visuovestibular and oculomotor structures would become metabolically stimulated when endothelin was introduced into the brain via the ventricular system in conscious rats. Since previous work had demonstrated that hypermetabolic responses to endothelin in other neural systems were inhibited by an antagonist of neuronal calcium L-type channels, nimodipine, we further tested whether the increased function of vestibulooculomotor nuclei whose metabolic activity was sensitive to endothelin could be altered following nimodipine pretreatment via the ventricle. A single unilateral injection of endothelin (9 pmol in 3 microliters saline) into a lateral ventricle provoked significantly increased rates of glucose metabolism in 22 of 39 individual anatomical structures of the visuovestibular and oculomotor systems. Among those affected were the superficial stratum of the caudal superior colliculus (+25%), the optic tract bilaterally (+35 to 43%), the oculomotor cranial nerve nuclei (III, IV, VI; range of +21 to 47%), and the medial terminal nucleus of the accessory optic tract which harbors dense fields of endothelin binding sites (bilateral increase of +70 to 96%). Several other nuclei involved in the proprioceptive and visuovestibular disturbance caused by endothelin displayed increased metabolic activity, including the cuneate, gracile, sensory trigeminal, and prepositus hypoglossal nuclei, the vestibular subnuclear system, and the cerebellar flocculus. Identification of hypermetabolic responsivity to endothelin in these structures provides further information on the anatomical substrates mediating the behavioral phenomenology of endothelin-induced motor convulsions which involve the paroxysmal participation of the extraocular muscles and motor control systems producing barrel-rolling convulsions. Nimodipine pretreatment inhibited both the convulsive activity and the cerebral hypermetabolic responses to intraventricular endothelin. The results indicate that the neural systems sensitive to intraventricular endothelin become functionally active via a calcium-mediated process that may involve the neuropeptide as an intrinsic signaling molecule.

Intraventricular endothelin-1 uncouples the blood flow: metabolism relationship in periventricular structures of the rat brain: involvement of L-type calcium channels.

Endothelin-1 (ET) produces contraction of cerebral resistance vessels in vitro and in situ, but also is neuroactive causing increases in tissue energy metabolism as measured by [14C]deoxyglucose autoradiography in the intact rat brain. ET may, therefore, disengage the normally tight linkage between cerebral blood flow and tissue metabolism. Using anatomically rigorous autoradiographic and imaging techniques to measure focal blood flow in anesthetized, ventilated rats, we found that intraventricular injection of 9 pmol of ET reduced rates of perfusion by an average of 29% (compared to a saline-injected condition) in 6 individual periventricular structures bordering the injected lateral ventricle. A significant vasoconstrictor effect (41% decrease in blood flow) also occurred in the ipsilateral choroid plexus after ET injection, despite its increased rate of glucose metabolism. We employed a hydrogen clearance method to monitor rates of blood flow serially within the periventricular margin of the caudate nucleus after intraventricular injection of the dihydropyridine calcium-channel antagonist, nimodipine (72 nmol), or 9 pmol ET, alone and in sequence. Nimodipine increased caudate blood flow (by 47%) and prevented the vasoconstriction produced by ET. The results indicate that ET causes vasoconstriction in penventricular brain structures and choroid plexus even in the presence of substantial increases in glucose metabolism. The simultaneous stimulation by intraventricular ET of tissue hypermetabolic and vascular constrictor mechanisms, leading to a net reduction of periventricular blood flow, is mediated, at least in part, by dihydropyridine-sensitive calcium L-channels.

Regional quantitative permeability of blood-brain barrier lesions in rats with chronic renal hypertension.

Blood-brain transfer constants for a small, neutral amino acid tracer, [14C]alpha-aminoisobutyric acid (AIB), were measured by quantitative autoradiography and image analysis in 15 individual brain structures of 2-kidney, 1-clip renal hypertensive rats (RHR) and age-matched normotensive controls (NR). Mean arterial pressures (MAP) for 4 month-old RHR and NR were 182 +/- 19 and 121 +/- 3 mmHg, respectively. Most brain structures in RHR had very low [14C]AIB transfer constants similar to those in NR (1-3 microliters.g-1.min-1), indicative of normal blood-brain barrier (BBB) function. Focal lesions, however, having transfer constants 2-7x normal and measuring less than 1.7 mm2 in area, appeared in RHR primarily in the cerebellar vermian and cerebral cortices. Chronic unilateral cervical sympathectomy did not influence the incidence or magnitude of BBB lesions in the denervated hemisphere of RHR. Acute arterial hypertension produced by systemic infusion of phenylephrine (elevation of MAP in RHR by 43%) increased the incidence and magnitude of lesions by 48% and 2-12x, respectively, although many brain regions in acutely hypertensive RHR retained normal permeability to [14C]AIB. The results demonstrate normal BBB permeability for much of the brain in chronic renal hypertension, with focal lesions having 7x or less the normal rate of blood-brain transfer for a small physiological probe.

Cerebral hypermetabolism produced by intraventricular endothelin-1 in rats: inhibition by nimodipine.

Injection of endothelin-1 (9 pmol) into the lateral cerebral ventricle of rats produced barrel-rotations, convulsions, tonic hindlimb extensions, facial clonus, and kinetic ataxia for up to 45 min. Quantitative metabolic autoradiographs produced from the [14C]deoxyglucose method and analyzed over 60 individual brain structures or subregions revealed intense hypermetabolism in periventricular tissues close to the injection site and in many of their efferent projection sites. Histological examination of these areas proved that this dose of endothelin was without toxic or ischemic effects on neurons or glial cells. Structures metabolically affected ipsilateral to injection were caudate nucleus (+164%), lateral septal nucleus (+270%), and two white matter tracts--corpus callosum (+236%) and hippocampal fimbria (+318%). Distant stimulated structures included cerebellar cortical layers, but not cerebellar nuclei or white matter. Increased rates of glucose metabolism among many other nuclei, particularly distinct subunits of the hippocampal formation and structures in contact with the ventricular system, signify that endothelin induced widespread metabolic stimulation over much of the neuraxis. Furthermore, although the 9 pmol concentration of endothelin produced convulsive movements and diverse metabolic stimulation, it did not evoke detectable electroencephalographic seizure activity assessed by intra- or extracerebral electroencephalography. Both the convulsions and hypermetabolic activation were inhibited by intraventricular pretreatment with the dihydropyridine calcium-channel antagonist, nimodipine. The results identify endothelin-1 as a calcium-mediated 'convulsive' peptide with selective stimulatory effects on cerebral glucose metabolism.

Morphology and function of capillary networks in subregions of the rat tuber cinereum.

The differentiated cytology, cytochemistry, and functions within subdivisions of the tuber cinereum prompted this morphometric and physiological investigation of capillaries in the medium eminence and arcuate nucleus of albino rats. Morphometric studies established that the external zone of the median eminence had 3-5 times the number and surface area of true and sinusoidal capillaries than the internal or subependymal median eminence zones, or either of two subdivisions examined in the arcuate nucleus. Type-I true capillaries, around which Virchow-Robin spaces comprise 1% of arcuate tissue area, were situated proximally to the median eminence border. This finding is consistent with a premise that confluent pericapillary spaces enable infiltration of arcuate neurons by factors from capillary blood from the median eminence or Virchow-Robin spaces. Physiologically, the rate of penetration across the median eminence capillaries by blood-borne [14C]alpha-amino-isobutyric acid (a neutral amino acid used as a capillary permeability tracer) was 142 times greater than for capillaries in the distal arcuate nucleus within 12 s of tracer administration. A new finding was that the proximal arcuate nucleus had a permeability x surface area product of 69 microliters g-1 min-1, 34 times greater than that in more distal aspects of the tuber where blood-brain barrier properties exist. We also found that the microcirculatory transit time of a plasma space marker, [14C]sucrose, was considerably longer (1.2 s) in the median eminence and proximal arcuate nucleus than in the distal arcuate or ventromedial nucleus (0.4 s). By virtue of its high capillary permeability and extensive blood-tissue surface area, including the wide Virchow-Robin spaces, the median eminence external zone could be a gateway for flooding other tuberal compartments with blood-borne factors. This effect may be compounded by capillary bed specializations in the proximal arcuate nucleus where Type-I true capillaries, Type-III sinusoids, and pericapillary spaces are confluent with those in the median eminence. The results indicate that the proximal arcuate parenchyma could be exposed to circulating neuroactive substances on a moment-to-moment basis.

Differentiated metabolic stimulation of rat pituitary lobes by peripheral and central endothelin-1.

Intravenous infusion (14 nmol/min) and lateral cerebral ventricular injection (9 pmol) of endothelin-1 increased rates of glucose utilization (quantitative autoradiographic [14C]deoxyglucose method) by 75-219% in pars intermedia and distalis of the rat pituitary gland. In rats given intraventricular endothelin, glucose metabolism was also increased significantly in pars nervosa (+92%). Metabolic activation by central endothelin in pars intermedia and distalis was inhibited by intraventricular pretreatment with the dihydropyridine, nimodipine, indicating that endothelin stimulates energy metabolism and probably hormone secretion in melanotrophs and pars distalis cells via L-type calcium channels.

Subregional topography of capillaries in the dorsal vagal complex of rats: II. Physiological properties.

The differentiated cytoarchitecture, neurochemistry, and capillary organization of the rat dorsal vagal complex prompted this comprehensive investigation of microvascular physiology in 11 subdivisions of area postrema, 5 subnuclei of nucleus tractus solitarii (NTS), the dorsal motor nucleus of the vagus nerve, and 4 other gray matter structures in the dorsal medulla oblongata. Microvascular exchangeable volume (residual plasma volume), capillary blood and plasma flow, and unidirectional transfer constants for a tracer amino acid, [14C]alpha-aminoisobutyric acid (AIB), varied considerably among the structures analyzed. Exchangeable volume, largest in area postrema medial zones (about 29 microliters.g-1) and smallest in medullary gray matter (7-11 microliters.g-1), correlated directly with subregional densities of capillaries and rates of tissue glucose metabolism. Capillary blood flow (range of 1,430-2,147 microliters.g-1.min-1), plasma flow, and tissue glucose metabolism (range of 0.48-0.71 mumol.g-1.min-1) were linearly related in the dorsal vagal complex. The most striking quantitative difference among structures in this brain region were the rates of transcapillary influx and derived permeability X surface area (PS) products of [14C]AIB, which has physicochemical properties resembling those of hormones. PS products for AIB were negligible in most medullary gray matter regions (less than 1 microliter.g-1.min-1, indicative of blood-brain barrier properties), but were 20-59X and 99-402X higher in NTS subnuclei and area postrema, respectively. An extraordinary feature of the microcirculation in area postrema was the long-duration transit of tracer sucrose and blood, a characteristic that would amplify the sensing ability of area postrema as it monitors the composition of the circulation.

Microvascular specializations promoting rapid interstitial solute dispersion in nucleus tractus solitarius.

Nucleus tractus solitarius (NTS), an aggregate of several individual nuclear groups in the dorsal medulla oblongata, is involved in virtually all autonomic functions as the first synaptic site in the brain for many peripheral viscerosomatic inputs. We found morphological evidence that dorsocaudal subregions of rat NTS (approximately 800 microns caudal from obex) had fenestrated capillaries and enlarged Virchow-Robin (perivascular) spaces that were similar to those in area postrema but unlike capillaries elsewhere in the medulla oblongata. Complexes of microvessels, consisting of up to 10 small vessels with smooth muscle layers (luminal diameters of 10-45 microns) and several capillaries (average luminal diameter of 4.5 microns), were located in the dorsal midline of NTS within large Virchow-Robin spaces measuring some 2,000 microns 2 in area. In physiological studies, we determined that most of NTS had a definable blood-brain barrier [permeability-surface area (PS) products for a neutral amino acid near 0], but medial and lateral aspects of the commissural subnucleus of NTS had PS products of 16-63 microliters.g-1.min-1 for alpha-[14C]aminoisobutyric acid 12 s after intravenous injection. Microvascular differentiations permitting such brisk tracer influx from blood resemble those of area postrema and appear to afford the rich neuropil of commissural NTS with a constant stream of blood-borne information for expediting its regulation of viscerosensory and autonomic functions.

Uncoupling of cerebral blood flow and glucose metabolism in conscious rats with chronic renal hypertension.

In an analysis of 46 individual brain structures and regions, we found that 12-14 weeks of renal hypertension in rats were associated with a 42% increase in cerebrovascular resistance, an average 28% reduction in cerebral blood flow, and no general change in cerebral glucose metabolism. A specific increase in metabolic activity, however, was identified in locus coeruleus. Generalized cerebral vasoconstriction resulting from central noradrenergic innervation originating in locus coeruleus is a possible explanation for the uncoupling of cerebral blood flow and metabolism in rats with chronic renal hypertension.

Metabolic activation of efferent pathways from the rat area postrema.

We used the quantitative [14C]deoxyglucose method and autoradiography to evaluate metabolic activity in 47 individual cerebral structures or subregions that are part of neural pathways emanating from the brain stem circumventricular organ, area postrema. Electrical stimulation of the dorsocentral area postrema in halothane-ventilated rats produced hypotension and increased glucose metabolism by several structures within the ascending trajectories of efferent neural projections from the nucleus. Structures in the caudal medulla oblongata, including three subnuclei of the nucleus of the solitary tract, dorsal motor nucleus of the vagus nerve, and nucleus ambiguus-A1 noradrenergic region, had increases of metabolism during stimulation of 32-62%. Pontine activation occurred specifically in the locus coeruleus and lateral parabrachial nuclei (increases of 24-36%). Magnocellular and parvocellular subdivisions of the hypothalamic paraventricular nucleus, supraoptic and suprachiasmatic nuclei, and median eminence showed increases in metabolism of 22-34%. An 89% elevation of glucose metabolism by the pituitary neural lobe resulted. The findings are evidence for functional activation of specific structures within ascending neural pathways from area postrema to forebrain mechanisms regulating blood pressure and fluid balance.