Neurons of a Limited Subthalamic Area Mediate Elevations in Cortical Cerebral Blood Flow Evoked by Hypoxia and Excitation of Neurons of the Rostral Ventrolateral Medulla

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (11)

Citing Articles via Google Scholar

Google Scholar

Articles by Golanov, E. V.

Articles by Reis, D. J.

Search for Related Content

PubMed

PubMed Citation

Articles by Golanov, E. V.

Articles by Reis, D. J.

Previous Article  |  Next Article

The Journal of Neuroscience, June 1, 2001, 21(11):4032-4041

Neurons of a Limited Subthalamic Area Mediate Elevations in Cortical Cerebral Blood Flow Evoked by Hypoxia and Excitation of Neurons of the Rostral Ventrolateral Medulla
Eugene V. Golanov, John R. C. Christensen, and Donald J. Reis
Division of Neurobiology, Department of Neurology and Neuroscience, Weill Medical College of Cornell University, New York, New York 10021

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Sympathoexcitatory reticulospinal neurons of the rostral ventrolateral medulla (RVLM) are oxygen detectors excited by hypoxiato globally elevate regional cerebral blood flow (rCBF). The projection,which accounts for >50% of hypoxic cerebral vasodilation, relaysthrough the medullary vasodilator area (MCVA). However, thereare no direct cortical projections from the RVLM/MCVA, suggestinga relay that diffusely innervates cortex and possibly originatesin thalamic nuclei. Systematic mapping by electrical microstimulationof the thalamus and subthalamus revealed that elevations in rCBFwere elicited only from a limited area, which encompassed medialpole of zona incerta, Forel's field, and prerubral zone. Stimulation(10 sec train) at an active site increased rCBF by 25 ± 6%. Excitationof local neurons with kainic acid mimicked effects of electricalstimulation by increasing rCBF. Stimulation of the subthalamiccerebrovasodilator area (SVA) with single pulses (0.5 msec; 80µA) triggered cortical EEG burst-CBF wave complexes with latency24 ± 5 msec, which were similar in shape to complexes evoked fromthe MCVA. Selective bilateral lesioning of the SVA neurons (ibotenicacid, 2 µg, 200 nl) blocked the vasodilation elicited from theMCVA and attenuated hypoxic cerebrovasodilation by 52 ± 12% (p< 0.05), whereas hypercarbic vasodilation remained preserved.Lesioning of the vasodilator site in the basal forebrain failedto modify SVA-evoked rCBF increase. We conclude that (1) excitationof intrinsic neurons of functionally restricted region of subthalamuselevates rCBF, (2) these neurons relay signals from the MCVA,which elevate rCBF in response to hypoxia, and (3) the SVA isa functionally important site conveying vasodilator signal fromthe medulla to thetelencephalon.

Key words: cerebral blood flow; neural regulation; electroencephalogram; hypoxia; thalamus; medulla

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cerebral hypoxia or ischemia elicits a rapid, patterned, autonomic response, which originates in the lower brainstem (Dampneyet al., 1979; Guyenet and Brown, 1986) and includes sympatheticexcitation, visceral and muscular vasoconstriction, bradycardia,and expiratory apnea (Dampney et al., 1979; Dampney and Moon,1980; Guyenet and Brown, 1986; Sun and Reis, 1992; Sun et al.,1992). In addition, there is a widespread increase in regionalcerebral blood flow (rCBF) without change in a cerebral metabolism[as evaluated by regional cerebral glucose utilization (rCGU)]and synchronization of the EEG (Underwood et al., 1992, 1994;Golanov and Reis, 1996; Golanov et al., 2000b;). The integratedresponse simulates the oxygen-conserving (diving) reflex of mammals,an integrated pattern of responses considered to protect the brainfrom hypoxia by redirecting blood from the systemic to cerebralcirculation in response to submersion or other stimuli activatingthe network (Butler, 1982; Blix and Folkow, 1983).

Much of the integrated response to cerebral ischemia/hypoxia results from excitation of reticulospinal sympathoexcitatoryneurons of the rostral ventrolateral medullary nucleus (RVLM)(Pluta et al., 1991; Sun and Reis, 1994a,b; Guyenet, 2000). Theseneurons are directly, selectively, rapidly, and reversibly excitedin vitro or in vivo by hypoxia (Sun et al., 1992; Sun and Reis,1993). Although the elevations in sympathetic, cardiovagal, orrespiratory nerve activities are mediated over spinal or intramedullarypathways (Sun and Reis, 1999), hypoxic activation of RVLM neuronselevates rCBF and synchronizes the EEG, and this is not fullyunderstood. Most likely, it is multisynaptic because the RVLMdoes not innervate the cerebral cortex (Ruggiero et al., 1989).

Recently we have functionally identified a region of the medullary reticular formation caudal to the RVLM and adjacent tothe nucleus ambiguus termed medullary cerebrovasodilator area(MCVA), which may contain the first synapse of this neuronal network(Golanov et al., 2000b). However, because the effects on rCBFand EEG elicited by hypoxic or electrical stimulation of RVLMare bilateral and diffuse (Underwood et al., 1992; Golanov andReis, 1994), it is likely that distal neurons in the chain arisefrom nuclei that diffusely project to the cortex. These wouldinclude areas such as the midline thalamic/centromedian complex(for review, see Jones, 1985; Price, 1995) and the basal forebrain(BF) (Saper and Loewy, 1980; Wenk et al., 1980; Eckenstein etal., 1988).

In this study, we sought to functionally identify regions of the diencephalon in which activation by microstimulation would,like hypoxia, elevate rCBF and interruption would block the responseselicited by stimulating the MCVA. We report that when excitedelectrically or with kainate, a small heretofore unrecognizedarea in a subthalamic region coincident with the Forel's fieldand medial pole of zona incerta (ZI) replicates the effects ofexcitation of the RVLM or MCVA. When the function of this areais interrupted, the cerebrovascular and electrocortical responseselicited from the MCVA are blocked. We have named the region thesubthalamic cerebrovasodilator area (SVA) to emphasize functionrather thantopography.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

General procedures. Male Sprague Dawley rats were maintained in a thermally controlled (27°C), light-cycled (lights on at7:00 A.M.; lights off at 7:00 P.M.) environment with ad libitumaccess to water and lab chow. Anesthesia was induced by 5% isofluranein a gas mixture (nitrogen 80%, oxygen 19.5%, carbon dioxide 0.5%)and maintained during surgery by 2.5% isoflurane. For the remainderof the experiment, isoflurane was maintained between 2 and 1.2%.The depth of anesthesia was assured by the absence of a desynchronizedEEG, variation in arterial pressure (AP), corneal reflexes, andhindleg flexing in response to pinch throughout the procedure.The experimental protocol was approved by the Institutional AnimalCare and Use Committee of Weill Medical College of CornellUniversity.

Both femoral arteries and veins were cannulated with polyethylene catheters (outer diameter = 0.97 mm). One arterial cannulawas used to continuously measure AP, whereas the second was usedto sample blood for measurement of blood gases. One venous catheterwas used for continuous infusion of phenylephrine to maintainAP after spinal cordtransection.

A tracheal cannula was inserted, wounds were closed, and animals were ventilated with a small animal respirator at 50-60 strokesper minute with the isoflurane/gas mixture. The stroke volumewas adjusted to be equal (in milliliters) to the animal's weightin grams/100. The concentrations of O₂, N₂, and CO₂ were adjustedusing calibrated flowmeters. Blood gases were measured severaltimes during the experiment in 0.1 ml samples of arterial bloodby a blood gas analyzer. Blood gases were sampled and adjustedif necessary to keep them in the normal range for rat (pH, 7.46± 0.023; Pa_O₂, 95.3 ± 1.1; Pa_CO₂, 34.2 ± 0.8) (Loeb and Quimby,1989). Body temperature was monitored with a rectal probe connectedto an electric thermometer-controlled heating pad, maintainingtemperature at 37 ± 0.6°C.

After instrumentation, animals were placed in a stereotaxic frame with the bite bar adjusted at $-$ 11 mm below the interauralline. The calvarium was exposed through a midline incision fromthe frontal bone to the atlanto-occipital junction, and the inferiorhalf of the occipital bone was removed to expose the dorsal medulla.The calvarium was carefully thinned by a dental drill irrigatedwith saline at room temperature over two areas 3 × 4 mm and centered3 mm caudal to the frontal suture and 2.5 mm lateral to the sagittalsuture and 5 mm caudal to frontal suture and 2 mm lateral to sagittalsuture. Bone was removed until only the internal layer (laminavitrea) remained. A stainless steel screw was inserted ipsilaterallyextradurally (0.5 mm rostral to the frontal and 1 mm lateral tothe sagittal suture) to record EEG monopolarly. The indifferentlead was an electrode placed on the exposed neckmuscles.

In some experiments the spinal cord was transected at the C1-C2 segment. To avert the acute elevation in AP associated withthe procedure, 0.1 ml of 2% procaine was injected locally justbefore sharp transection. Gelfoam was inserted into the cut, andan infusion of phenylephrine was started immediately (1.3-6.4µg/min) to maintain AP (90-100 mmHg). Completeness of the transectionwas established histologically postmortem. Animals were allowedto stabilize for 30-40 min before the experiment wasinitiated.

Pulsatile AP was recorded using a strain gauge pressure transducer connected to an amplifier. EEG was recorded monopolarlyand amplified and filtered (1-100 Hz). The respective signalswere displayed simultaneously on channels of a chart recorderand also digitized and stored in a computer. rCBF was recordedwith a laser-Doppler flowmeter (LDF) (PeriFlux PF3, Perimed).The probe (0.8 mm in diameter) was mounted on a micromanipulatorand placed, under magnification, just over the exposed laminavitrea, avoiding large pial vessels (Golanov and Reis, 1994) thatcan generate false signals. The opening was filled with paraffinoil, and the probe was left in place for the remainder of theexperiment. Flow values recorded with the time constant of 0.2sec were expressed in arbitrary units (perfusion units). Cerebrovascularreactivity was assessed immediately after positioning of the probeand randomly during the experiment by increasing the concentrationof CO₂ in the inhaled gas mixture to 5-7% for 2 min. The procedure,which increased Pa_CO₂ to 51-75 mmHg, but did not change Pa_O₂ (95-118mmHg), rapidly elevated rCBF by 60-90%. If CO₂ reactivity waslost during the course of an experiment, the experiment was discontinuedand the animal waskilled.

Electrical and chemical stimulation. To stimulate the thalamic area electrically or chemically, electrodes or micropipettes,respectively, were attached to the stereotaxic electrode holder.The coordinates of the bregma were taken as stereotaxic zero.An area of the brain from 3.5 to 6.5 mm caudal to bregma, 0.5-3mm lateral, and from $-$ 4 to $-$ 9 mm ventral to cortical surface wasexplored systematically for evoked changes inrCBF.

The thalamic and medullary areas were stimulated through monopolar electrodes consisting of Teflon-insulated stainless steelwire (150 µm) exposed only at the cut tip. An indifferent electrodewas attached to the neck muscles. Cathodal square-wave pulses(5-150 µA,0.5 msec, 50-100 Hz) were generated by a square-wavestimulator and delivered to the electrodes through a constantcurrent stimulus isolation unit. To determine the threshold ofthe reaction, the current was increased from 5 µA in steps of5 µA until the maximum amplitude of reaction exceeded 2 SD ofbaseline values. Electrolytic lesions were made through the sameelectrodes by a constant anodal current (500 µA, 30sec).

To stimulate the medulla oblongata electrically or chemically, electrodes or micropipettes, respectively, were attached tothe stereotaxic electrode holder and positioned over the calamusscriptorius at a 10° posterior inclination. The coordinates ofthe calamus were taken as stereotaxiczero.

Intracerebral microinjections were made through glass capillary micropipettes with an outer diameter of 0.9 mm. The pipettetip was broken back to 40-60 µm in diameter. Drugs were injectedmanually in 20 nl of solution by pressure during 15-20 sec. L-Gluwas injected in the amount of 5 nmol mixed with rhodamine beadsto mark the site of injection. Kainate was microinjected as afresh solution in saline (pH 7.3 after adjustment with phosphatebuffer) in the amount of 300pmol.

At the end of each experiment, animals were killed by an intravenous bolus of 1.0 ml of saturated KCl. Brains were removed,frozen, and sectioned in 20 µm slices in a cryostat microtomewithout fixation to prevent shrinking. Alternate slices were stainedwith thionine. Fluorescent images of unstained sections were superimposedon the images of corresponding stained sections using a computerizedimaging system. Structures were identified microscopically, andtheir distribution in the brain wasplotted.

Hypoxia and hypercarbia. Normocarbic hypoxic hypoxia was produced by adjusting the O₂ content in the gas mixture to ~10%.The concentration of CO₂ was increased appropriately (to 2-5%)to maintain Pa_CO₂ within normal range (see Table 3). Animalswere ventilated for 2 min at the lowered concentration of O₂ beforemeasurement of rCBF and blood gases. The decrease in AP that isusually observed under hypoxia (Marshall, 1987) was preventedby continuous infusion of phenylephrine (2-10 µg/min). Hypercarbiawas created by ventilating animals with a gas mixture with theCO₂ level increased to ~5% for 2 min before measurements weretaken.

Data analysis. After amplification and filtering (Cyberamp, Axon), AP, EEG, and rCBF signals were digitized (DT 2821 board,Data Translation) by a computer-based data acquisition system(DataWave Technologies) and stored on hard disk for further processing.The principal parameters of the responses (latency, amplitude,and duration) were extracted and averaged. Deviations of any parameterby >2 SDs from the baseline were established as the thresholdof a reaction. rCBF measurements made by LDF were expressed aspercentage changes overbaseline.

To estimate changes in cerebrovascular resistance (CVR), we compared the ratio between AP and rCBF before and after each experimentalprocedure, calculated as a percentage of baselinevalues.

Fast Fourier transform analysis of EEG was performed over a 10 sec epoch before and immediately after stimulation or microinjectionof drugs. Resulting data were averaged across experimental animals.Statistical analysis of differences in the means before and afterintervention was performed by using Student's paired t test, ort test for independent samples was used for different groups ofanimals. ANOVA was used for multiple comparisons. Results wereassessed as significant at p < 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subthalamic cerebrovasodilator area

To localize sites in the thalamic area elevating rCBF, we systematically mapped the diencephalic area in 14 rats while recordingrCBF, EEG, and AP (Fig. 1). The brain was stimulated every 200µm with a 10 sec train of pulses at 50 Hz and with a stimuluscurrent of 30 µA. The thalamic area that was explored stretchedfrom anterodorsal and anteroventral to parafascicular thalamicnuclei in the rostrocaudal direction, from midline to reticularnucleus in the lateral direction, and from the area immediatelyventral to the lateral ventricle to the level of supramammillarynuclei in the dorsoventral direction. Electrode tracks and stimulationsites (n = 738) were reconstructed (see Materials and Methodsfor details). Bilateral elevations in rCBF were elicited onlyfrom a limited area in the caudal subthalamic area and includedthe medial pole of ZI, Forel's field, part of the prerubral zone,and rostral pole of deep mesencephalic nucleus. We designatedthis area the SVA.

View larger version (33K):
[in this window]
[in a new window]
Figure 1. Cerebrovasodilator area (circled in bold) (A) and distribution at three different levels of the rat brain (B) (expressed as distances in millimeters caudal from bregma) of sites from which electrical stimulation increased cerebral blood flow (closed circles). Stimulation consisted of a 10 sec train (50 Hz at 50 µA). BF, Basal forebrain; BST, bed nucleus of stria terminalis; CM, centrum medianum; Cpu, caudate putamen; DLG, dorsal lateral geniculate nucleus; DMH, dorsomedial hypothalamic nucleus; GP, globus pallidus; LP, lateral posterior nucleus; LH, lateral hypothalamus; M, medial vestibular nucleus; MCVA, medullary cerebrovasodilator area; MD, mediodorsal nucleus, MG, medial geniculate nucleus; MM, medial mammillary nucleus; ML, lateral mammillary nucleus; MP, medial preoptic nucleus; NTS, nucleus tractus solitarius; PAG, pariaqueductal gray; PH, posterior hypothalamic area; PF, parafascicular nucleus; Po, posterior nucleus; PR, prerubral nucleus; PT, paratenial nucleus; PVP, paraventricular nucleus; RI, rostral interstitial nucleus; RN, red nucleus; RO, nucleus raphe obscurus; SG, superior colliculus; SNR, substantia nigra; VLG, ventrolateral geniculate nucleus; VMH, ventromedial hypothalamic nucleus; VPL, ventral posterolateral nucleus; VPM, ventral posteromedial nucleus; ZID, dorsal zona incerta; ZIV, ventral zona incerta.

Stimulation of the SVA in non-spinalized (intact) rats

Stimulation at an active site in spinal-intact rats (10 sec train) at a frequency of 50 Hz and a current of 30 µA (averagethreshold for 10% increase in rCBF was 15 ± 7 µA; n = 24) increasedrCBF within 1-2 sec after onset of stimulation, which peaked at25 ± 6% (n = 32; p < 0.01) in 20 ± 4 sec to recover ~5-7 min later(Fig. 2A, Table 1). An increase in rCBF was paralleled by a sharpdrop in CVR of 20 ± 3% (p < 0.05) in 20 sec and returned to baselinelevel simultaneously with rCBF. In response to stimulation, APchanged biphasically: after an initial increase by 10 ± 2% at7 sec, it decreased by 6 ± 1% at 14 sec and returned to baselinein 20 sec. Along with the changes of rCBF, the power of the 2-6Hz EEG components immediately after stimulation increased by 66± 23% (p < 0.05), whereas EEG amplitude remained unchanged (768± 134 µV before and 698 ± 168 µV after; p > 0.05) (Fig. 3).

View larger version (25K):
[in this window]
[in a new window]
Figure 2. Averaged responses in cortical rCBF (top trace), CVR (middle trace), and AP (bottom trace) in response to electrical stimulation (Stim; 10 sec train, 50 Hz, 5× threshold current) of the SVA in spinal-intact rats (A) and rats with transected spinal cord (B) and dependency of the SVA-evoked rCBF responses on the frequency (C) and intensity (D) of stimulation.


View this table:
[in this window]
[in a new window]
Table 1. Effects of electrical and chemical stimulation of the SVA on cerebral blood flow and EEG

View larger version (20K):
[in this window]
[in a new window]
Figure 3. Sample of EEG response (A) and changes in power of components of cortical EEG (B) evoked by electrical stimulation of the SVA.

To evaluate the distribution of the SVA-evoked (10 sec train, 45 µA, 3× threshold, 100 Hz) cerebrovasodilation over the cortex,we recorded rCBF over the contralateral occipital cortex and ipsilateraland contralateral to the stimulated site parietal cortex in thesame animal. Maximum increase of rCBF was comparable at all threesites (occipital cortex, 44 ± 5%; parietal cortex contralateral43 ± 6% and ipsilateral 43 ± 3%; p > 0.05 (ANOVA); n =3).

Effects of electrical stimulation of the SVA were frequency and current dependent (Fig. 2C). The optimal stimulus frequency,established while stimulating with a constant stimulus current(50 µA), was ~100 Hz. At 100 Hz, the threshold for elevating rCBFwas 12 ± 7 µA (n = 6), and the response was graded with increasingstimulus currents. In all subsequent studies, the SVA was stimulatedfor 10 sec at 100 Hz, with stimulus currents 5× the thresholdcurrent. The optimum parameters of the stimulation are probablydetermined by the electrical properties of the SVAelements.

To establish the role of SVA neurons, we stimulated them selectively by microinjections of kainic acid (300 pmol, 20 nl; n= 3). Microinjection of kainate into the SVA reversibly increasedrCBF by 46 ± 8% (p < 0.05) over ~75 sec and, in parallel, reducedCVR by $-$ 26 ± 6% (p < 0.01) (Fig. 4). AP did not change. Similarto electrical stimulation, chemical stimulation synchronized theEEG, increasing the power of the 2-6 Hz components by 80 ± 19%(p < 0.05), without changing the EEG amplitude (659 ± 152 µV beforeand 781 ± 127 µV after; p > 0.1).

View larger version (12K):
[in this window]
[in a new window]
Figure 4. Averaged responses (three animals) of rCBF (top trace), CVR (middle trace), and AP (bottom trace) to microinjection of kainate (300 pmol, 20 nl) in the SVA.

Effects of stimulation of the SVA on rCBF, EEG, and AP in spinalized rats

To exclude the possible effects of activation of autonomic nerves on rCBF, we repeated stimulation of the SVA in spinalizedrats (n = 4) in which AP was maintained by continuos infusionof phenylephrine. Electrical stimulation (100 Hz, 52 µA, 10 sec)of the SVA in spinalized rats increased rCBF by 17 ± 2% (p < 0.05,n = 10) in 37 sec, which was accompanied by a decrease in CVRof 14 ± 1% (p < 0.01) in 13 sec. rCBF and CVR gradually returnedto baseline level after 5-7 min. AP changed biphasically: afteran initial decrease of 4 ± 1% (p < 0.05) at 9 sec, it increasedby 6 ± 1% (p < 0.05) at 36 sec after onset of stimulation (Fig.3B). EEG changed similarly to non-spinalized animals: the powerof 2-6 Hz components increased by 52%, whereas EEG amplitude remainedstable.

Effects of single pulse stimulation of the SVA on rCBF and EEG

We also stimulated the SVA with single pulses (0.5 msec, 100 µA) while recording rCBF and EEG. Single pulse stimulation in52% of the cases triggered short-lasting bursts (5-8 sec) of synchronizedEEG activity accompanied by an increase in rCBF. Responses appearedbilaterally and synchronously with a latency between stimulusand burst onset of 24 ± 2 msec. Individual responses to SVA stimulationconsisted of an initial triphasic wave varying in configurationfrom burst to burst followed by high-amplitude low-frequency oscillationsof varying duration (on average 5 ± 3 sec). When averaged, evokedresponses from the SVA consisted of an initial triphasic potentialcomplex, accompanied by a wave of increase in rCBF of 5 ± 1% in4 sec that returned to baseline level in 9-10 sec (Fig. 5).

View larger version (26K):
[in this window]
[in a new window]
Figure 5. Cortical EEG burst-cerebrovascular wave complexes evoked by single pulse stimulation of the SVA (A) and MCVA (B). Single electrical pulses delivered to the SVA or MCVA triggered a burst of EEG activity (second trace) followed by an increase in rCBF (top trace). Averaging of burst-wave complexes (bottom traces) demonstrated a stable initial potential of EEG followed by highly reproducible cerebrovasodilation.

These burst-wave complexes were identical to those observed in response to single pulse stimulation of the MCVA or FN as wedemonstrated earlier. Single pulse stimulation of the MCVA triggeredshort bursts of synchronized EEG after a 24 ± 2 msec latency.The bursts lasted 6-7 sec and were accompanied by an increasein rCBF of up to 8%, which lasted ~10 sec. The individual responsesevoked by single pulse stimulation of the SVA or MCVA were similarto burst-wave complexes occurring spontaneously (Fig. 5).

Effects of electrolytic lesion of the SVA on the effects of electrical stimulation of the MCVA

To establish the possible role of the SVA in mediation of the cerebrovasodilatory effects of MCVA stimulation, we comparedresponses with train stimulation (10 sec, 0.5 msec rectangularpulses, 50 Hz, 50 µA) of the MCVA before and after electrolyticlesion of the SVA. In five spinalized rats, a stimulating electrodewas placed unilaterally into a functionally active site of theMCVA and into functionally defined regions of the SVA. After measuringthe effects of MCVA stimulation on rCBF, CVR, and EEG, small bilateralelectrolytic lesions were made in the SVA. After a recovery periodof 20-30 min the MCVA wasrestimulated.

Before lesions, in agreement with our previous observations in response to stimulation of the MCVA in spinalized rats, rCBFbegan to rise within 3 sec of the stimulus onset and reached amaximum of 28 ± 9% (n = 21; p < 0.01) at 35 ± 5 sec. It graduallyreturned to baseline within 3-5 min. The CVR fell by $-$ 21 ± 9%(p < 0.01) in 9sec.

With stimulation, AP initially fell by 13 ± 4% (p < 0.05) at 10 sec and then reversed to rise to 29 ± 9%. It recovered 3-4min later. The pressor component of the AP response results fromthe release of AVP sufficient to elevate AP in rats (Del Bo etal., 1983; Golanov and Reis, 1994; Golanov et al., 2000b).

Stimulation of the MCVA also synchronized the EEG by increasing the 4-6 Hz component power by 59% without a change in amplitude.EEG activity recovered in parallel withrCBF.

Acute bilateral electrolytic lesions of the SVA (Fig. 6) did not affect resting rCBF or EEG. However, the lesions significantlyattenuated the elevation of rCBF (to 14 ± 5%, decrease of 56%),the reductions in CVR (to $-$ 11 ± 6%, decrease of 48%) (p < 0.05for both), and the synchronization of the EEG (decrease by 78%p < 0.05), without changing EEG amplitude. As depicted in Figure6, the common area of destruction in all five animals was confinedto the prerubral zone, Forel's field, and medial pole of zonaincerta.

View larger version (32K):
[in this window]
[in a new window]
Figure 6. Effect of electrolytic lesion of the SVA on the increase in rCBF (C), evoked by electrical stimulation of the MCVA in spinalized rats. Contours of lesions in different animals (A) are superimposed, and the area common for all lesions is blackened. The site of the MCVA stimulation in B is circled and filled with gray. C, Changes in rCBF [top trace and middle trace indicate changes in CVR; bottom trace indicates AP before (solid line) and after (dotted line) the lesion]. Abbreviations are as in Figure 1.

Control lesions (n = 3), which involved areas located dorsal to the SVA, did not affect responses to MCVA stimulation (Table2).


View this table:
[in this window]
[in a new window]
Table 2. Effect of electrolytic lesion of the SVA on rCBF and EEG effects of MCVA stimulation

Effects of excitotoxic lesions of the SVA on hypoxic, hypercarbic, and MCVA-evoked elevations of rCBF

The observation that limited electrolytic lesion of the SVA significantly attenuated cerebrovascular effects of MCVA stimulationsuggested that neurons of the SVA may be an important relay elementof vasodilator signals generated by the MCVA and by oxygen sensorsof RVLM. To test this hypothesis, we lesioned neurons of the SVAby microinjecting the excitotoxin ibotenic acid (Table 3). Ratswere anesthetized and intubated, and micropipettes were insertedinto the area corresponding to the SVA. After testing responsesto hypoxia, hypercarbia, and MCVA stimulation, ibotenate was microinjected(3 nmol in 20 nl) into the SVA bilaterally, and animals were allowedto recover. They were reanesthetized 45 d later, and responsesto stimulation of the MCVA, hypoxia, and hypercarbia were retested.


View this table:
[in this window]
[in a new window]
Table 3. Effects of excitotoxic (ibotenic acid) lesion of the SVA on the effects of electrical stimulation of MCVA, hypoxemic hypoxia, and hypercarbia

Excitotoxic lesions of the SVA practically abolished the increase in rCBF in response to MCVA stimulation, decreasing it by>85% (p < 0.01) (Table 2). The hypoxic increase in rCBF was decreasedby 51% (p < 0.05). The increase in rCBF evoked by hypercarbiawas reduced by 30%; however, this decrease did not reach the levelof significance (p > 0.05) and was similar in SVA- and non-SVA-lesionedanimals. Overall, the results were comparable to those observedafter electrolytic lesion of the SVA (Fig. 7).

View larger version (48K):
[in this window]
[in a new window]
Figure 7. Effect of excitotoxic lesion of the SVA on the increase in rCBF, evoked by hypoxia, hypercarbia, and electrical stimulation of the MCVA. Representative area with gliosis is circled on the photo of brain slice.

Subsequent histological examination of the area of excitotoxic lesion revealed extensive gliosis and disappearance of neuronalcell bodies in the area consisting of Forel's fields, the medialpole of the zona incerta, the rostral portion of the prerubralarea, and the caudal pole of the lateral hypothalamicarea.

Control lesions placed in the area dorsal to the SVA did not affect rCBF responses to MCVA stimulation and nonsignificantly(p > 0.05) reduced hypoxic and hypercarbic cerebralvasodilation.

Effects of electrolytic lesion of basal forebrain on SVA-evoked elevations of rCBF

Pathways ascending from the parvicellular reticular formation innervate the SVA and project further to the BF (Jones, 1995),chemical or electrical stimulation of which increases rCBF ipsilaterallyto stimulation (Biesold et al., 1989; Lacombe et al., 1989; Vaucheret al., 1995). The rCBF increase evoked from BF is independentof metabolism (Kimura et al., 1990) and mediated by cholinergicmechanisms (Dauphin et al., 1991; Scremin et al., 1991; Sato andSato, 1992; Zhang et al., 1995). We hypothesized that the BF mightmediate the vasodilation evoked by the stimulation of theSVA.

To test this hypothesis, we electrolytically lesioned the vasoactive area of the BF on one side (Fig. 8) while we monitoredipsilateral hemisphere rCBF responses to the electrical stimulationof the SVA on the same side. Electrical stimulation of BF (10sec train, 100-150 µA, 0.5 msec rectangular pulses, 50 Hz; n =3) triggered an increase in ipsilateral rCBF within 1-2 sec afterthe onset of stimulation. rCBF reached a maximum of 35 ± 7% (p< 0.05) in 10 sec and gradually returned to the baseline in 2-3min. Simultaneously with the increase in rCBF, CVR significantlydropped by 28 ± 9% (p < 0.05) and recovered in parallel (Fig.8). Electrolytic lesion of the BF site, stimulation of which increasedrCBF, did not affect basal rCBF or amplitude of the rCBF responsesto SVA stimulation. Maximum SVA-evoked rCBF increase was 19 ±5% before BF lesion, and after lesion it reached 23 ± 6% (p >0.01).

View larger version (28K):
[in this window]
[in a new window]
Figure 8. Localization of the lesion sites in the BF (A) and effect of stimulation of these sites (B) before the lesions on rCBF (top trace), CVR (middle trace), and AP (bottom trace). Contours of all lesions are superimposed, and the area common for all lesions is blackened. Abbreviations are as in Figure 1.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The MCVA is a functional area located dorsocaudally to the RVLM-C1 area in the periambigual zone of the lateral reticularparvicellular area (Golanov et al., 2000b). Lesion of the MCVAreverses cerebrovasodilation evoked by RVLM excitation or by hypoxia(Underwood et al., 1992; Golanov and Reis, 1994). Electrical orchemical stimulation of the MCVA increases rCBF independentlyof metabolism in parallel with the decrease of CVR (Underwoodet al., 1992; Golanov and Reis, 1994) and the increase in powerof a 4-6 Hz component of cortical EEG (Golanov et al., 2000b).

To explore the ascending pathway relaying the vasodilator signal from the MCVA to the telencephalon, we systematically surveyedthe thalamic region with electrical stimulation, searching forsites that are capable of increasing rCBF globally. We discoveredthat electrical or chemical simulation of the limited zone inthe subthalamic area, which includes Forel's field, the medialpole of ZI and the rostral part of the prerubral area, increasesrCBF. We have termed the region the subthalamic vasodilator area(SVA) to stress a function, rather than topography, because itdoes not exactly correspond to a known nucleargroup.

Data indicate that SVA might relay the cerebrovasodilator signal generated in the medulla. The elevation in rCBF elicitedfrom the SVA with a 10 sec stimulus train is comparable to thecerebral vasodilation evoked from RVLM (Underwood et al., 1992;Golanov and Reis, 1994) or the MCVA (Golanov and Reis, 1996; Golanovet al., 2000b). Similar to RVLM and the MCVA, the electrical stimulationof SVA elevated rCBF and decreased CVR. This response (1) appearedwithin seconds of the stimulus onset, (2) was graded with respectto stimulus intensity and shared a comparable frequency optima,~50-100 Hz, (3) was bilateral and diffuse, (4) was associatedwith the appearance of 4-6 Hz rhythm in the cortical EEG, and(5) was not affected by spinal cord transection. Unlike the RVLMor the MCVA, however, stimulation of the SVA in spinal-intactrats had a negligible effect onAP.

The effects of electrical stimulation of the SVA were fully mimicked by the chemical stimulation, indicating that excitationof SVA neurons is sufficient to produce cortical cerebrovasodilationand modify theEEG.

Electrical stimulation of the SVA with single pulses triggered cortical EEG bursts followed ~1.2 sec later by a monophasicelevation of the rCB-forming cerebrovascular wave (EEG burst-CW)complex appearing simultaneously and diffusely over both hemispheres.Similar burst-CW complexes appear spontaneously in deeply anesthetizedanimals (Golanov et al., 1994) and humans (Lam et al., 1995) andcan be evoked by single pulse stimulation delivered to vasodilatorsites of the MCVA or FN (Golanov and Reis, 1995). That the latencyof burst-CW complexes evoked by single pulse stimulation of SVA(~24 msec) was shorter than those evoked by stimulation of theMCVA (~33 msec) (Golanov and Reis, 1995) supports the contentionthat the SVA is a relay between the MCVA and more rostral sites.The difference of ~9 msec between latencies of burst-CW complexesevoked from the SVA and MCVA implies that a major delay of thesignal occurs in the SVA projections to cortical neurons, whichprobably involve some diffusesystem.

Selective lesioning of SVA neurons with bilateral excitotoxic lesions, which preserve fibers of passage, abolished the elevationof rCBF and EEG synchronization elicited by electrical stimulationof the MCVA. The effect is comparable to that of the electrolyticlesion of the SVA, indicating that local neurons rather than passingfibers convey vasodilator signals from the medulla. The blockof the cerebrovasodilator effect of FN stimulation mediated bythe MCVA (Glickstein et al., 1999; Golanov et al., 2000a) afterexcitotoxic lesion of the SVA (Glickstein et al., 1999) also supportsthe role of the SVA as the relay for the MCVA-generated vasodilatorsignals.

The MCVA generates hypoxic cerebrovasodilator signal (Golanov et al., 2000b). In agreement with the suggested role of SVAas a relay of MCVA-generated signals, lesion of SVA reduced hypoxemicelevations of rCBF by ~50%, an impairment comparable to that elicitedby lesions of the RVLM or MCVA (Underwood et al., 1994; Golanovand Reis, 1996; Golanov et al., 2000b).

Reversal of rCBF increase and EEG synchronization by electrolytic or excitotoxic lesions of the SVA was specific and did notresult from the nonspecific brain damage, because lesions of comparablesize placed dorsally to the SVA did not affect responses to stimulationof the MCVA, and hypercarbia-induced elevation of rCBF was notaffected by SVAlesion.

Projections from the lateral reticular parvicellular nucleus, where the MCVA is located, reach the SVA within intermediategroup of fibers ascending from the brain stem (Jones and Yang,1985) independently of the medial forebrain bundle. These pathwaysproject bilaterally diffusely to multiple thalamic nuclei, givecollaterals to ZI (Jones and Yang, 1985; Vertes et al., 1986),issue projections to the lateral hypothalamus, basal ganglia,and BF (Ricardo, 1981), and are able to influence the entire forebrain.ZI-SVA projects further to the BF (Ricardo, 1981; Jones 1995)and makes it a good candidate to mediate cerebrovasodilator effectsof SVA excitation. Electrical or chemical stimulation of the BFproduces global and independent of metabolism increase in rCBF(Biesold et al., 1989; Lacombe et al., 1989; Kimura et al., 1990;Sato and Sato, 1992). However, failure of electrolytic lesionof BF to reverse the vasodilator effect of SVA stimulation refuteda possible relay role of the BF. It is still possible, however,that lesions were not large enough to completely destroy the wholeBF area in ourexperiments.

Stimulation of the thalamic centrum medianum-parafascicular nucleus (CM-Pf) in rats elevates rCBF globally and independentlyof metabolism (Mraovitch et al., 1986; Mraovitch and Seylaz, 1987;Mraovitch et al., 1992; Goadsby et al., 1993). We did not observesignificant changes in rCBF during exploratory stimulation ofthe CM-Pf area, probably because we used different exploratorystimulation parameters (~50 vs 200 Hz and ~50 vs ~150 µA) andisoflurane anesthesia [vs chloralose (Mraovitch et al., 1986;Mraovitch and Seylaz, 1987)], although it is known that neurogenic(primary) cerebrovasodilation is sensitive to the depth and natureof anesthesia (Iadecola and Reis, 1990; Iadecola et al., 1990).

Vasoactive sites in the CM-Pf of Mraovitch et al. (1986, 1987) are located just dorsally to the SVA. Although ventral siteswere not explored in this work, stimulation of the CM-Pf producedthe most significant functional correlated increase in rCBF andrCGU in the SVA (ZI-Forel's fields) (Mraovitch and Seylaz, 1987;Mraovitch et al., 1992), indicating functional activation of theSVA. It is reasonable to speculate that the CM-Pf and SVA mayrelatefunctionally.

Stimulation of the SVA, as well as the MCVA, simultaneously with rCBF increased the delta rhythm component of cortical EEG(Dossi et al., 1992; Amzica and Steriade, 1998). This may be relatedto the observed correlative increase of delta rhythm and corticalrCBF in humans (Hofle et al., 1997). Delta rhythm is thought tobe generated by thalamocortical cells, when their hyperpolarizationreaches a certain level (Steriade et al., 1997). It is thereforepossible that the SVA may affect the activity of thalamocorticalcells. It is also feasible that the appearance of delta rhythmin response to stimulation of the SVA, RVLM, FN, or MCVA is theso-called "paradoxical arousal," the phenomenon observed underisoflurane anesthesia in humans in response to strong stimulinormally triggering EEG desynchronization (Schwartz and Scott,1978; Kochs et al., 1994; Litscher and Schwarz, 1999).

Hypoxemic hypoxia that is independent of the arterial chemoreceptors (Heistad et al., 1976; Miyabe et al., 1989) potentlyelevates rCBF independently of metabolism (Heistad and Kontos,1983; Siesjö, 1987; Edvinsson et al., 1993). We have proposedthat at least 50% of hypoxic cerebrovascular vasodilation is neurogenic(Underwood et al., 1994; Golanov and Reis, 1996). The neurogeniccomponent is triggered by RVLM-C1 oxygen-sensing neurons in responseto hypoxia (Sun and Reis, 1994b; Miyawaki et al., 1996), cerebralischemia (Guyenet and Brown, 1986), or NaCN (Sun et al., 1992;Underwood et al., 1992; Golanov and Reis, 1994, 1996; Kawai etal., 1999). Bilateral lesions of the RVLM selectively (comparedwith hypercarbia) reduce the hypoxic vasodilation by ~50% (Underwoodet al., 1994; Golanov and Reis, 1996). Because the RVLM does notinnervate the cerebral cortex (Ruggiero et al., 1989), the intracerebralpathway mediating cortical vasodilation is indirect, and the firstsynapse resides in the MCVA, which is innervated directly fromRVLM (Golanov et al., 2000b). Excitation of the MCVA elicits changesin AP, rCBF, and EEG qualitatively identical to those elicitedfrom RVLM. Bilateral lesions of the MCVA block the cerebrovascularand electrocortical responses to stimulation of RVLM as well ashypoxia-induced cerebrovasodilation. The vasodilator effects ofMCVA excitation is relayed by the SVA to other brainareas.

In conclusion, we demonstrated that excitation of neurons of the limited area in the posterior subthalamus increases rCBFand the delta component of EEG, whereas their lesioning attenuatesthe increase in rCBF evoked by stimulation of the MCVA or by hypoxia.These findings allow us to hypothesize that the SVA is a key elementof the endogenous brain system, which relays a cerebrovasodilatorsignal of different origin (hypoxic, activation, visceral) totheforebrain.

  FOOTNOTES

Received Jan. 12, 2001; revised March 9, 2001; accepted March 14, 2001.

Deceased, Nov. 1,2000.
Correspondence should be addressed to Dr. Eugene Golanov, Division of Neurobiology, Department of Neurology and Neuroscience,Weill Medical College of Cornell University, 411 East 69th Street,New York, NY 10021. E-mail: egolano{at}mail.med.cornell.edu.

This work was supported by National Institutes of Health Grants NS36154 (E.V.G.) and HL18974 (D.J.R.). We express our deepestsympathy at the loss of our esteemed co-author and colleague,Donald J.Reis.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Amzica F, Steriade M (1998) Electrophysiological correlates of sleep delta waves. Electroencephalogr Clin Neurophysiol 107:69-83[ISI][Medline].
Biesold D, Inanami O, Sato A, Sato Y (1989) Stimulation of the nucleus basalis of Meynert increases cerebral cortical blood flow in rats. Neurosci Lett 98:39-44[Medline].
Blix AS, Folkow B (1983) Cardiovascular adjustments to diving in mammals and birds. In: The cardiovascular system, Section 2 (Renkin EM, Michel CC, eds), pp 917-945. Bethesda, MD: American Physiological Society.
Butler PJ (1982) Respiratory and cardiovascular control during diving in birds and mammals. J Exp Biol 100:195-221[Abstract/Free Full Text].
Dampney RA, Moon EA (1980) Role of ventrolateral medulla in vasomotor response to cerebral ischemia. Am J Physiol 239:H349-358[Abstract/Free Full Text].
Dampney RA, Kumada M, Reis DJ (1979) Central neural mechanisms of the cerebral ischemic response. Characterization, effect of brainstem and cranial nerve transections, and simulation by electrical stimulation of restricted regions of medulla oblongata in rabbit. Circ Res 45:48-62[Free Full Text].
Dauphin F, Lacombe PM, Sercombe R, Hamel E, Seylaz J (1991) Hypercapnia and stimulation of the substantia innominata increase rat frontal cortical blood flow by different cholinergic mechanisms. Brain Res 553:75-83[ISI][Medline].
Del Bo A, Sved AF, Reis DJ (1983) Pressor effects of vasopressin released by fastigial nucleus stimulation in rat. J Hypertension 1[Suppl 2]:237-239.
Dossi RC, Nunez A, Steriade M (1992) Electrophysiology of a slow (0.5-4 Hz) intrinsic oscillation of cat thalamocortical neurones in vivo. J Physiol (Lond) 447:215-234[Abstract/Free Full Text].
Eckenstein FP, Baughman RW, Quinn J (1988) An anatomical study of cholinergic innervation in rat cerebral cortex. Neuroscience 25:457-474[ISI][Medline].
Edvinsson L, MacKenzie ET, McCulloch J (1993) In: Cerebral blood flow and metabolism. New York: Raven.
Glickstein SB, Golanov EV, Ilch CP, Reis DJ (1999) Stimulation of the subthalamic cerebrovasodilator area (SCA), a functionally restricted cerebral vasodilator region, protects against focal ischemic infarction. Soc Neurosci Abstr 25:2052.
Goadsby PJ, Seylaz J, Mraovitch S (1993) Noncholinergic, nonadrenergic cortical vasodilatation elicited by thalamic centromedian-parafascicular complex. Am J Physiol 264:R1150-R1156[Abstract/Free Full Text].
Golanov EV, Reis DJ (1994) Nitric oxide and prostanoids participate in cerebral vasodilation elicited by electrical stimulation of the rostral ventrolateral medulla. J Cereb Blood Flow Metab 14:492-502[Medline].
Golanov EV, Reis DJ (1995) Vasodilation evoked from medulla and cerebellum is coupled to bursts of cortical EEG activity in rats. Am J Physiol 268:R454-R467[Abstract/Free Full Text].
Golanov EV, Reis DJ (1996) Contribution of oxygen-sensitive neurons of the rostral ventrolateral medulla to hypoxic cerebral vasodilatation in the rat. J Physiol (Lond) 495:201-216[ISI][Medline].
Golanov EV, Yamamoto S, Reis DJ (1994) Spontaneous waves of cerebral blood flow associated with a pattern of electrocortical activity. Am J Physiol 266:R204-R214[Abstract/Free Full Text].
Golanov EV, Christensen JR, Reis DJ (2000a) The medullary cerebrovascular vasodilator area mediates cerebrovascular vasodilation and electroencephalogram synchronization elicited from cerebellar fastigial nucleus in Sprague-Dawley rats. Neurosci Lett 288:183-186[Medline].
Golanov EV, Ruggiero DA, Reis DJA (2000b) Brainstem area mediating cerebrovascular and EEG responses to hypoxic excitation of rostral ventrolateral medulla in rat. J Physiol (Lond) 529:413-429[Abstract/Free Full Text].
Guyenet PG (2000) Neural structures that mediate sympathoexcitation during hypoxia. Respir Physiol 121:147-162[ISI][Medline].
Guyenet PG, Brown DL (1986) Unit activity in nucleus paragigantocellularis lateralis during cerebral ischemia in the rat. Brain Res 364:301-314[ISI][Medline].
Heistad DD, Kontos HA (1983) Cerebral circulation. In: Handbook of physiology, circulation, Vol III. Peripheral circulation and organ blood flow (Shepherd JT, Abboud FM, eds), pp 137-182. Bethesda, MD: American Physiological Society.
Heistad DD, Marcus ML, Ehrhardt JC, Abboud FM (1976) Effect of stimulation of carotid chemoreceptors on total and regional cerebral blood flow. Circ Res 38:20-25[Abstract/Free Full Text].
Hofle N, Paus T, Reutens D, Fiset P, Gotman J, Evans AC, Jones BE (1997) Regional cerebral blood flow changes as a function of delta and spindle activity during slow wave sleep in humans. J Neurosci 17:4800-4808[Abstract/Free Full Text].
Iadecola C, Reis DJ (1990) Continuous monitoring of cerebrocortical blood flow during stimulation of the cerebellar fastigial nucleus: a study by laser-Doppler flowmetry. J Cereb Blood Flow Metab 10:608-617[ISI][Medline].
Iadecola C, Springston ME, Reis DJ (1990) Dissociation by chloralose of the cardiovascular and cerebrovascular responses evoked from the cerebellar fastigial nucleus. J Cereb Blood Flow Metab 10:375-382[Medline].
Jones BE (1995) Reticular formation: cytoarchitecture, transmitters, and projections. In: The rat nervous system (Paxinos G, ed), pp 155-171. New York: Academic.
Jones BE, Yang TZ (1985) The efferent projections from the reticular formation and the locus coeruleus studied by anterograde and retrograde axonal transport in the rat. J Comp Neurol 242:56-92[ISI][Medline].
Jones EG (1985) In: The thalamus. New York: Plenum.
Kawai Y, Qi JG, Comer AM, Gibbons H, Win J, Lipski J (1999) Effects of cyanide and hypoxia on membrane currents in neurones acutely dissociated from the rostral ventrolateral medulla of the rat. Brain Res 830:246-257[ISI][Medline].
Kimura A, Sato A, Takano Y (1990) Stimulation of the nucleus basalis of Meynert does not influence glucose utilization of the cerebral cortex in anesthetized rats. Neurosci Lett 119:101-104[Medline].
Kochs E, Bischoff P, Pichlmeier U, Schulte EJ (1994) Surgical stimulation induces changes in brain electrical activity during isoflurane/nitrous oxide anesthesia. A topographic electroencephalographic analysis. Anesthesiology 80:1026-1034[ISI][Medline].
Lacombe PM, Sercombe R, Verrecchia C, Philipson V, MacKenzie ET, Seylaz J (1989) Cortical blood flow increase induced by stimulation of the substantia innominata in unanaesthetized rat. Brain Res 491:1-14[Medline].
Lam AM, Matta BF, Mayberg TS, Strebel S (1995) Change in cerebral blood flow velocity with onset of eeg silence during inhalation anesthesia in humans: evidence of flow-metabolism coupling? J Cereb Blood Flow Metab 15:714-717[ISI][Medline].
Litscher G, Schwarz G (1999) Is there paradoxical arousal reaction in the EEG subdelta range in patients during anesthesia? J Neurosurg Anesthesiol 11:49-52[ISI][Medline].
Loeb WF, Quimby FW (1989) In: The clinical chemistry of laboratory animals. New York: Pergamon.
Marshall JM (1987) Analysis of cardiovascular responses evoked following changes in peripheral chemoreceptor activity in the rat. J Physiol (Lond) 394:393-414[Abstract/Free Full Text].
Miyabe M, Jones Jr MD, Koehler RC, Traystman RJ (1989) Chemodenervation does not alter cerebrovascular response to hypoxic hypoxia. Am J Physiol 257:H1413-H1418[Abstract/Free Full Text].
Miyawaki T, Minson J, Arnolda L, Llewellynsmith I, Chalmers J, Pilowsky P (1996) AMPA/kainate receptors mediate sympathetic chemoreceptor reflex in the rostral ventrolateral medulla. Brain Res 726:64-68[ISI][Medline].
Mraovitch S, Seylaz J (1987) Metablolism-independent cerebral vasodilation elicited by electrical stimulation of the centromedian-parafascicular complex rat. Neurosci Lett 83:269-274[Medline].
Mraovitch S, Lasbennes F, Calando Y, Seylaz J (1986) Cerebrovascular changes elicited by electrical stimulation of the centromedian-parafascicular complex in rat. Brain Res 380:42-53[Medline].
Mraovitch S, Calando Y, Pinard E, Pearce WJ, Seylaz J (1992) Differential cerebrovascular and metabolic responses in specific neural systems elicited from the centromedian-parafascicular complex. Neuroscience 49:451-466[Medline].
Pluta R, Lossinsky AS, Mossakowski MJ, Faso L, Wisniewski HM (1991) Reassessment of a new model of complete cerebral ischemia in rats. Method of induction of clinical death, pathophysiology and cerebrovascular pathology. Acta Neuropathol (Berl) 83:1-11[Medline].
Price JL (1995) Thalamus. In: The rat nervous system (Paxinos G, ed), pp 629-648. San Diego: Academic.
Ricardo JA (1981) Efferent connections of the subthalamic region in the rat. II. The zona incerta. Brain Res 214:43-60[ISI][Medline].
Ruggiero DA, Cravo SL, Arango V (1989) Central control of the circulation by the rostral ventrolateral reticular nucleus: anatomical substrates. Prog Brain Res 81:49-79[ISI][Medline].
Saper CB, Loewy AD (1980) Efferent connections of the parabrachial nucleus in the rat. Brain Res 197:291-317[ISI][Medline].
Sato A, Sato Y (1992) Regulation of regional cerebral blood flow by cholinergic fibers originating in the basal forebrain. Neurosci Res 14:242-274[ISI][Medline].
Schwartz MS, Scott DF (1978) Pathological stimulus-related slow wave arousal responses in the EEG. Acta Neurol Scand 57:300-304[ISI][Medline].
Scremin OU, Torres C, Scremin AM, O'Neal M, Heuser D, Blisard KS (1991) Role of nucleus basalis in cholinergic control of cortical blood flow. J Neurosci Res 28:382-390[Medline].
Siesjö BK (1987) Critical degrees of hypoxia and ischemia when cerebral function and metabolism are perturbed. In: Oxygen transport and utilization (Bryan-Brown C, Ayres SM, eds), pp 293-310. Fullerton, CA: Society of Critical Care Medicine.
Steriade M, Jones EG, McCormick DA (1997) Electrophysiologtical properties of thalamic neurons. In: Thalamus, pp 339-391 New York: Elsevier.
Sun M-K, Reis DJ (1992) Evidence nitric oxide mediates the vasodepressor response to hypoxia in sino-denervated rats. Life Sci 50:555-565[ISI][Medline].
Sun M-K, Reis DJ (1993) Hypoxic excitation of medullary vasomotor neurons in rats are not mediated by glutamate or nitric oxide. Neurosci Lett 157:219-222[ISI][Medline].
Sun M-K, Reis DJ (1994a) Central neural mechanisms mediating excitation of sympathetic neurons by hypoxia. Prog Neurobiol 44:197-219[ISI][Medline].
Sun M-K, Reis DJ (1994b) Hypoxia selectively excites vasomotor neurons of rostral ventrolateral medulla in rats. Am J Physiol 266:R245-R256[Abstract/Free Full Text].
Sun M-K, Reis DJ (1999) Excitatory amino acid-mediated chemoreflex excitation of respiratory neurones in rostral ventrolateral medulla in rats. J Physiol (Lond) 492:559-571[ISI][Medline].
Sun M-K, Jeske IT, Reis DJ (1992) Cyanide excites medullary sympathoexcitatory neurons in rats. Am J Physiol 262:R182-R189[Abstract/Free Full Text].
Underwood MD, Iadecola C, Sved AF, Reis DJ (1992) Stimulation of C1 area neurons globally increases regional cerebral blood flow but not metabolism. J Cereb Blood Flow Metab 12:844-855[Medline].
Underwood MD, Iadecola C, Reis DJ (1994) Lesions of the rostral ventrolateral medulla reduce the cerebrovascular response to hypoxia. Brain Res 635:217-223[ISI][Medline].
Vaucher E, Borredon J, Seylaz J, Lacombe P (1995) Autoradiographic distribution of cerebral blood flow increases elicited by stimulation of the nucleus basalis magnocellularis in the unanesthetized rat. Brain Res 691:57-68[Medline].
Vertes RP, Martin GF, Waltzer R (1986) An autoradiographic analysis of ascending projections from the medullary reticular formation in the rat. Neuroscience 19:873-898[ISI][Medline].
Wenk H, Bigl V, Meyer U (1980) Cholinergic projections from magnocellular nuclei of the basal forebrain to cortical areas in rats. Brain Res 2:295-316[ISI][Medline].
Zhang F, Xu S, Iadecola C (1995) Role of nitric oxide and acetylcholine in neocortical hyperemia elicited by basal forebrain stimulation: evidence for an involvement of endothelia l nitric oxide. Neuroscience 69:1195-1204[ISI][Medline].

Copyright © 2001 Society for Neuroscience 0270-6474/01/21114032-10$05.00/0

This article has been cited by other articles:

K. Xu and J. C. LaManna
Chronic hypoxia and the cerebral circulation
J Appl Physiol, February 1, 2006; 100(2): 725 - 730.
[Abstract] [Full Text] [PDF]

J. C. LaManna, J. C. Chavez, and P. Pichiule
<