Vol. 276, Issue 6, R1766-R1771, June 1999
Identification of barosensitive neurons in the mediobasal
forebrain using juxtacellular labeling
Gilbert J.
Kirouac and
Quentin J.
Pittman
Department of Physiology and Biophysics, Neuroscience Research
Group, University of Calgary, Calgary, Alberta T2N 4N1,
Canada
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ABSTRACT |
Previous
investigations suggest a possible role in cardiovascular regulation for
neurons of the mediobasal forebrain. The present study was designed to
determine the location and morphology of basal forebrain neurons that
respond to acute changes in arterial blood pressure. Extracellular
recordings of single units were done in 
-chloralose- or
urethan-anesthetized rats. The effect of cardiovascular pressor
(phenylephrine, 1-2 µg/kg iv) and depressor (sodium
nitroprusside, 0.5-1 µg/kg iv) events on the discharge rates of
units was determined. Some of the neurons tested were subsequently
filled with biocytin using the juxtacellular method. Brain sections
were processed using the avidin-biotin complex reaction to reveal a
Golgi-like appearance of the neuron. Of 32 neurons located in the
horizontal limb of the diagonal band of Broca (hDB), 13 (41%) were
found to be excited by depressor events. Barosensitive biocytin-labeled
cells were located in all regions of the hDB and had small- to
medium-sized cell bodies with sparse and simple dendritic morphology.
Only 2 of 47 neurons tested in the region of the olfactory tubercle,
islands of Calleja (IC), and ventral pallidum responded to changes in
arterial blood pressure. The results of the present investigation
suggest a role in the regulation of cardiovascular function for neurons
of the hDB. The findings also suggest that most neurons in the
olfactory tubercle, including the IC complex, do not respond to acute
changes in arterial blood pressure.
diagonal band of Broca; baroreceptors; cardiovascular regulation; electrophysiology; biocytin
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INTRODUCTION |
THE MEDIOBASAL FOREBRAIN may be involved in the
regulation of the cardiovascular system. For example, the protein Fos
was expressed in neurons of the horizontal limb of the diagonal band of
Broca (hDB) and of the islands of Calleja (IC) following a decrease in
arterial pressure (AP) (8, 17). Single-unit studies indicated that
neurons recorded in the olfactory tubercle and region of the IC
responded to both depressor and pressor changes in the circulation (2).
Chemical stimulation with the excitatory amino acid
L-glutamate of sites within the
hDB and around the IC caused cardiovascular depressor responses (2,
14). These studies suggest that neurons in mediobasal forebrain receive
information about the level of AP in the circulatory system and may be
involved in cardiovascular control or baroreflexes.
The basal forebrain contains several nuclei that are identified based
on their projection patterns and neurochemical identity (10). However,
the boundaries between the different nuclei are not clearly demarcated,
and cells believed to be functionally or anatomically related may be
intermixed with a variety of other cell types. For example, the
olfactory tubercle contains the granule cell clusters of the IC along
with a combination of pallidal and striatal types of neurons (6, 19).
The ventral pallidum extends ventrally into the polymorph layer of the
olfactory tubercle, whereas clusters of striatal-type cells form the
striatal cell bridges that connect the polymorph layer of the olfactory
tubercle with the nucleus accumbens and caudate nucleus (6, 19). Mixed within these different cellular elements are fibers and neurons of the
hDB (19). Traditional extracellular recording techniques allow an
estimation of the location of the recorded neuron and provide no
anatomic information about the cell type recorded. The present
investigation takes advantage of the recent development of the
electrophysiological juxtacellular labeling technique that labels the
recorded neuron with biocytin (23) to identify the precise location and
morphology of barosensitve neurons in the mediobasal forebrain.
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METHODS |
Animal surgery and preparation.
Experiments were conducted on 15 male Sprague-Dawley rats (300-450
g) according to guidelines of the Canadian Council on Animal Care. Rats
were anesthetized with urethan (1.4-1.6 g/kg ip) or with
intravenous administrations of -chloralose (60 mg/kg after induction
of anesthesia with administration of 0.3 ml/100 g ip of equithesin,
supplemented by additional doses of 30 mg/kg of -chloralose
approximately every 1-2 h). Polyethylene catheters were inserted
into the femoral artery and vein for the recording of AP and the
administration of drugs, respectively. Rats anesthetized with urethan
were allowed to breathe normally. The trachea was cannulated in rats
anesthetized with -chloralose, and the animal was paralyzed with
pancuronium bromide (Pavulon, Organon Canada, Toronto, ON; 1 mg/kg iv
initially and additional doses of 0.5 mg/kg when necessary) and
artificially ventilated with 100% oxygen. Rectal temperature was
monitored and maintained at 35-37°C with a heating pad.
Rats were placed in a stereotaxic frame, and a burr hole was made above
the forebrain. Regions of the mediobasal forebrain were systematically
explored for spontaneously active units 0-1.5 mm anterior to
bregma, 0.5-2.5 mm lateral to the midline, and 7.0-9.0 mm
ventral to the surface of the brain. A minimum distance of 0.5 mm was
placed between each pipette tract. Glass micropipettes (tip diameter
1-2.5 µm) containing 0.5 M solution of potassium acetate or
sodium chloride plus 1.7% biocytin (Sigma, St. Louis, MO) were used
for recording and labeling of cells.
Data acquisition and analysis.
Arterial blood pressure was recorded using a Statham P23 XL pressure
transducer and Gould transducer amplifier (model 13-4615-50), and heart rate was measured with a Gould Electrocardiogram/Biotach amplifier (model 13-4615-65), which was triggered by the
pressure pulse. Mean AP was defined as the diastolic pressure plus
one-third of the pressure pulse. Single unit activity was amplified
(×10) through a multipurpose microelectrode amplifier (Axoclamp
2A, Axon Instruments, Foster City, CA), which was further amplified (×100; Neurolog) and filtered (Neurolog NL126; filtered at 500 Hz
to 5 kHz). The signal was displayed on an oscilloscope, and the spikes
were discriminated using a Neurolog NL200 spike trigger discriminator.
The electronic signals for AP, heart rate, and unit activity were
digitized using a Cambridge Electronic 1401 Plus Interface Design (CED;
Cambridge, UK), and the data were captured and analyzed on a computer
(CED Spike2 data capture and analysis software).
The neuronal discharge rate was recorded during acute pressor and
depressor events in the circulation. The neuronal discharge rate during
changes in AP was compared with the baseline discharge rate before the
administration of pressor or depressor agents. A mean of at least 30%
above or below the mean baseline discharge rate for at least five
consecutive bins (1-s bin width) was considered a significant response
(13, 15). In addition, a response was considered to be due to the
direct effect of changes in AP if 1)
the changes in discharge rate and AP coincided,
2) the response was reproducible,
and 3) the response was induced by
depressor responses of <50 mmHg, which are not of sufficient
magnitude to compromise cerebral blood flow (1) but sufficient to cause a reflex tachycardia. The shape and amplitude of the spike were carefully observed to eliminate the possibility that changes in activity were due to movement artifacts. Results are expressed as means ± SE.
Experimental protocol.
Spontaneously active units were tested for their responses to pressor
and depressor events in the circulation produced by the intravenous
administration of phenylephrine (1.0-2.0 µg/kg; Sigma) or sodium
nitroprusside (0.5-1.0 µg/kg; Sigma). Units that responded to
acute changes in AP were filled with biocytin using the single-cell
juxtacellular procedure according to a previously described method (20,
23, 26). Briefly, depolarizing pulses of anodal current (1-10 nA,
200-ms duration, 50% duty cycle) for periods of 1-7 min were
applied under continuous electrophysiological monitoring of cell firing
rate. Current intensity was increased to entrain the firing rate of the
neuron with the current pulse. The intensity of the current was then
adjusted to maintain the entrainment and was terminated when there were
indications that the neuron was being damaged by the electrical current
(spike broadening and increased discharge rate during the off period). Attempts to label neurons were done on both sides of the brain. A
distance of at least 0.5 mm between each attempt was used when there
was more than one attempt unilaterally.
Histology.
After a survival period ranging from 30 min to 6 h, rats were perfused
transcardially with saline (0.9% NaCl, 200-300 ml) followed by
750 ml of a fixative containing 4% paraformaldehyde and 0.25%
glutaraldehyde in 0.1 M phosphate buffer (pH 7.4). The brain was
removed and postfixed for 1 h in the same fixative. Horizontal sections
(100 µm) of the basal forebrain were cut using a vibrating microtome,
and sections were collected in PBS (0.1 M, pH 7.4) and washed (3 × 10 min) in PBS. The sections were then incubated in
avidin-biotin-peroxidase complex (Vectastain ABC Elite, Vector
Laboratories, Burlingame, CA) PBS solution containing 0.1% Triton
X-100 for 18-24 h. Sections were rinsed in PBS (3 × 10 min) and Tris buffer saline (TBS, 0.05 M, pH 7.6, 1 × 10 min) and reacted in TBS containing diaminobenzidine,
hydrogen peroxide, and nickel ammonium sulfate (substrate kit for
peroxidase, Vector Laboratories) followed by several rinses in PBS (4 × 10 min). Sections were mounted on gelatin-coated slides,
allowed to dry overnight, dehydrated in alcohol, cleared in xylene, and placed under a coverslip without staining.
Sections were examined for biocytin-labeled cells, and the location of
the labeled cells along with the position of the micropipette tract was
mapped on drawings of the rat brain (22). The approximate location of
nonlabeled cells was determined using the detailed record of the
stereotaxic coordinates along with the location of the pipette tract
and biocytin-labeled cells. Biocytin histochemistry with the ABC Elite
kit provided sufficient background staining to delineate basal
forebrain nuclei. Biocytin-labeled neurons were examined at high
magnification to determine the cytoarchitecture and dimensions of the
labeled cells. Some cells were traced using a camera lucida and scanned
in Corel PhotoPaint to produce drawings of biocytin-labeled neurons.
The photomicrographs were acquired by a light microscope (Zeiss,
Germany) equipped with a digital camera (Quantix System, Photometrics,
Tucson, AZ), and viewed on a computer screen by using the program V for
Windows (Quantix System) and printed using an ink-jet printer (Epson
Stylus Color 600).
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RESULTS |
A total of 84 neurons in the basal forebrain were tested for their
responses to pressor and depressor events in the circulation. Rats
anesthetized with urethan had a mean AP of 88 ± 3 mmHg and a heart
rate of 366 ± 15 beats/min (n = 5), whereas rats anesthetized with -chloralose had a mean AP of 112 ± 5 mmHg and a heart rate of 391 ± 6 beats/min
(n = 10). Figure
1 shows the location of neurons in the
basal forebrain that responded to changes in AP. Of the 84 neurons
tested, 32 were located in the hDB of which 13 (41%) responded to
depressor responses with an increase in discharge rate. There was no
statistical difference in the baseline activity of responsive
(discharge rate 5.6 ± 1.6 spikes/s) and nonresponsive (discharge
rate 9.3 ± 2.1 spikes/s) neurons in the hDB. Depressor events
caused an increase from the baseline discharge rate of 5.6 ± 1.5 to
a discharge rate of 11.98 ± 3.2 spikes/s (n = 13) for a similar period of time
prior to and during the depressor event. Two of the neurons that
responded to depressor events also responded to pressor events with an
increase in discharge rate. Of five neurons tested in the vertical limb
of the diagonal band of Broca (vDB), two responded with excitation to
depressor events and one neuron responded to pressor events. From a
total of 30 neurons tested in the region of the olfactory tubercle, only one neuron (discharge rate 3.3 spikes/s) responded with excitation to an acute decrease in AP. Only one of 17 neurons (discharge rate 7.5 ± 2.9 spikes/s) located in the ventral pallidum responded with
excitation to depressor events in the circulation. There was no
significant difference in the baseline discharge rates of neurons
located in the hDB (9.0 ± 1.8 spikes/s), vDB (8.4 ± 3.6),
olfactory tubercle (6.5 ± 1.3), and ventral pallidum (7.3 ± 2.6).
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Fig. 1.
Drawings of transverse sections of mediobasal forebrain
(A) modified from stereotaxic atlas
(22), extending 8.5-9.5 rostral to intra-aural line showing
location of single units that were tested for their response to
depressor and pressor events in circulation
(B).  , responsive cells to either
pressor or depressor events;  , nonresponsive cells. AC, anterior
commissure; Cpu, caudate-putamen; IC, islands of Calleja; hDB,
horizontal limb of diagonal band of Broca; MFB, medial forebrain
bundle; MS, medial septal nucleus; NA, nucleus accumbens; OT, olfactory
tubercle; PO, preoptic area; vDB, vertical limb of diagonal band of
Broca; VP, ventral pallidum.
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An attempt to label 20 neurons in the diagonal band of Broca with the
juxtacellular application of biocytin resulted in the successful
labeling of 12 neurons (60% success rate), 9 of which were
barosensitive neurons. Figure 2 shows an
example of a barosensitive neuron in the hDB labeled with biocytin.
Attempts at labeling neurons in the ventral pallidum and olfactory
tubercle resulted in the labeling of 10 of 19 neurons (53% success
rate). Figure 3 shows examples of
nonresponsive neurons in the ventral pallidum and olfactory tubercle
that were successfully labeled with biocytin. Of the labeled neurons,
only one nonresponsive neuron was found in a granule cell cluster of
the IC. Labeled neurons were scattered within different regions of the
ventral pallidum (4 of 5 attempts) and olfactory tubercle (6 of 14 attempts).
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Fig. 2.
Representative example of biocytin-labeled neuron in hDB that was
activated by acute decreases in arterial pressure (AP).
A: photomicrograph of biocytin-labeled
neuron (arrow) with single dendrite (not in plane of focus) and axon
containing en passant varicosities directed toward ventral surface of
brain. Electrode tract is seen immediately above filled soma.
B: AP tracing and running ratemeter
record showing that unit responded with excitation to depressor events
(intravenous sodium nitroprusside) but not to pressor events
(intravenous phenylephrine).
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Fig. 3.
Examples of biocytin-labeled neurons in the ventral pallidum
(A) and olfactory tubercle
(B) that did not respond to changes
in AP.
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Labeled neurons in the hDB that responded to depressor responses had
cell body dimensions that ranged from small (45.5 µm2) to large (300 µm2) diameter. The majority of
these neurons were medium sized (50-100 µm2, discharge rate 7.1 ± 2.7 µm2,
n = 6), two were large (>100
µm2, discharge rate 4.8 ± 3.7 spikes/s, n = 2), and one was
small (<50 µm2, 3.6 spikes/s).
All the barosensitive cells in the hDB had regular discharge rates.
Most of the labeled neurons had elongated cell bodies with short aspiny
primary dendrites (2-4 primary dendrites, dendritic field
extending 52.5 ± 10.3 µm, n = 9)
and few secondary aspiny dendrites (Fig.
4). In a few cases
(n = 3) an axon containing varicose
terminals could be followed for a short distance as it projected toward
the ventral surface of the hDB (Fig. 2). Labeled neurons in the ventral
pallidum were large cells (100-200
µm2,
n = 4) with aspiny dendrites. Labeled
neurons in the olfactory tubercle were composed of a mixed population
of small granule-like cells (<50
µm2,
n = 3), large cells (100-200
µm2,
n = 2) with aspiny dendrites, and one
large striatal-type cell (187.5 µm2) with spiny and aspiny
dendrites (Fig. 3).
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Fig. 4.
Camera lucida drawings of biocytin-labeled neurons in hDB that
responded to depressor events in circulation. Arrows indicate location
of axonal processes.
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DISCUSSION |
The present investigation demonstrates that 41% of spontaneously
active neurons tested in the hDB respond to acute decreases in AP with
an increase in discharge rate. Two of the 13 neurons were activated by
both depressor and pressor responses in the circulation. A few
spontaneously active neurons in the vDB were also found to respond to
depressor events with excitation. Only a few (2 of 47) of the neurons
located in the ventral pallidum, olfactory tubercle, and the IC
responded to depressor events in the circulation. The use of the
juxtacellular labeling technique to label the recorded neuron yielded a
success rate of 56%, which resulted in a Golgi-like labeling of
responsive neurons in the hDB as well as nonresponsive neurons
throughout the mediobasal forebrain. The majority of barosensitive
neurons in the hDB had small- to medium-sized cell bodies with simple
and sparse dendritic fields.
The possibility exists that the neurons were activated by movement
artifacts or hypoxia caused by decreases in cerebral blood flow to the
basal forebrain. However, the cerebral vasculature possesses an
extensive autoregulatory capability within a perfusion range of
70-160 mmHg (21). The pressor and depressor responses in the
present study (between 25 and 50 mmHg) were within this range and
should not have compromised blood flow to the brain. It is also
possible that significant hypoxia and hypercapnia resulting from the
depressor events could influence the activity of peripheral and central
chemoreceptors sensitive to pH and blood gases. Although neurons in the
hDB may have responded to activation of peripheral and central
chemoreceptors, this is unlikely in the present study because arterial
chemoreceptors are only stimulated with changes in AP greater than 50 mmHg (1).
A previous study showed that neurons in the diagonal band of Broca
antidromically activated by stimulation of the supraoptic nucleus
responded with excitation to the activation of baroreceptors by acute
pressor events in the circulation (11). These results seem to be
somewhat at odds with the present investigation in which neurons in the
hDB were primarily excited by depressor events. However, the present
investigation tested spontaneously active units in the hDB, whereas the
previous study tested mostly silent units in the vDB that were
antidromically activated by stimulation of the supraoptic nucleus (11).
Therefore, neurons in the vDB that project to the supraoptic nucleus
may respond differently than the spontaneously active units recorded in
the hDB.
The results of the present investigation are somewhat contradictory to
those of a recent investigation showing that electrical stimulation of
the aortic depressor nerve resulted in the expression of Fos protein in
the hDB (17), which would indicate that neurons in the hDB are excited
by pressor events. However, the expression of Fos in that study may
have been due to the chronic hypotensive effects produced by activation
of baroreflex pathways in the brain during the stimulation of the
aortic depressor nerve (13). Another possibility is that stimulation of
the aortic depressor nerve may have excited a different population of
neurons within the hDB than the population of spontaneously active
cells recorded in this study. In fact, a few neurons were found in this
study to respond to pressor events in the circulation.
In two cases, a neuron was found to respond with excitation to both
depressor and pressor events in the circulation. There is no
information in the literature that we are aware of concerning barosensitive neurons responding with excitation to both depressor and
pressor events. McKitrick et al. (17) reported a similar observation
for some of their single-unit recordings in the olfactory tubercle. One
could speculate that these neurons receive information about changes in
AP irrespective of the direction and that these neurons may be involved
in mechanisms that do not relate to the baroreflexes. For example,
these neurons may be integrating baroreceptor information with other
physiological functions such as arousal.
Only a few barosensitive cells were found in the region of the
olfactory tubercle and the IC. Our investigation did not confirm the
results of previous studies that demonstrated intense staining for the
Fos protein in the IC of rats following long-term hypotension (1 h) due
to stimulation of the aortic depressor nerve or to the administration
of a vasodilating agent (8, 17). Such a prolonged stimulus could have
activated neurons in the IC that were not activated during an acute
depressor response (<1 min) as used in the present study. The present
investigation is also at odds with a previous single-unit study (2)
showing that 68% of the units in the olfactory tubercle in the region
of the IC responded to pressor and depressor events. However, the doses
of phenylephrine and sodium nitroprusside used in the study of Calaresu
et al. (2) to test whether neurons in the IC received baroreceptor input were several magnitudes greater than in the present
investigation. This may have resulted in the identification of false
positives in the IC because of artifacts such as movement of the
electrode, hypoxia, or hypercapnia. Support for this comes from a
report showing expression of Fos in neurons located in the region of the olfactory tubercle and IC in rats made to breathe high
concentrations of CO2
(9). Indeed, it was recently proposed that the IC are involved in the regulation of blood flow to the ventral striatopallidal region. This is based on the observation that the IC surround and
follow the arterioles that supply the ventral striatopallidal complex
(18). In addition granule cells of the IC contain nitric oxide (18),
which could be released in the vicinity of the arterioles where it
could act as a vasodilator substance. Therefore, the IC may be involved
in regulating blood flow to parts of the ventral striatopallidal region
after prolonged hypotension as opposed to being involved in a long-loop
baroreflex as suggested by Calaresu et al. (2).
As discussed previously, a study in rats under urethan anesthesia by
Caleresu et al. (2) suggested that neurons in the IC were responsive to
changes in AP levels. The experiments in the present investigation were
conducted in rats under either -chloralose or urethan to exclude the
possibility that the response of neurons was dependent on the type of
anesthesia. However, a role in cardiovascular regulation for neurons of
the olfactory tubercle and IC cannot be entirely excluded because their
responses to inputs from chemoreceptors or cardiopulmonary receptors
were not examined in the present investigation.
The present investigation, which used the juxtacellular labeling
technique to label the neuron under study, showed that neurons in the
hDB were responsive to depressor events. It has been proposed that the
labeled neuron is the same neuron that was recorded during the
experiment (20, 23, 26). Several observations support this hypothesis.
First, ejection of the same amount of current at a site where no neuron
is active never resulted in the labeling of a neuron. Second, no
labeling occurred in cases that neurons could not be entrained or were
entrained for only a few seconds. Finally, labeled neurons were located
at proper stereotaxic coordinates and in some instances the labeled
neuron was found at the end of a pipette tract. There was only one
occasion where two neurons were labeled during the same attempt. The
identification of the actual cell recorded in this case could easily be
inferred by the location of the cell relative to the pipette tract.
Pinault (23) described some labeled neurons that had been filled by the
retrograde transport of biocytin by damaged axons in the region of
another labeled neuron.
The juxtacellular labeling technique is useful in demonstrating the
precise location of a neuron as well as showing the cytoarchitecture of
the cell. The present study shows that the majority of barosensitive neurons in the hDB had small- to medium-sized somata with short simple
dendrites. The size and morphology of nonbarosensitive neurons in the
mediobasal forebrain were variable with many neurons exhibiting
characteristics of pallidal and striatal types of cells as described by
other investigators using Golgi stain methods (6, 19). The significance
of the observation that barosensitive neurons in the hDB are small
neurons with sparse dendritic morphology is not known. However, it may
be important in terms of how these neurons receive and integrate
afferent inputs. Future investigation may be useful in defining the
functional characteristics of these relatively small barosensitive
neurons in the hDB.
Perspectives
The present investigation provides evidence that neurons in the hDB are
excited by acute depressor events. However, the role of the hDB in
cardiovascular regulation is poorly understood. It has been proposed
that the hDB relays baroreceptor information to the lateral
hypothalamus to modulate the activity of vasopressin-secreting neurons
in the supraoptic nucleus (24). Tracing studies show that the hDB
receives projections from the lateral hypothalamus, parabrachial
nucleus, and the catecholaminergic neurons of the A1, A2, and A6 cell
groups (12, 16, 25, 29, 30). The parabrachial nucleus and the
catecholaminergic brain stem neurons relay baroreceptor information to
various regions of forebrain (4, 27). The hDB in turn projects to a
variety of regions involved in the regulation of the cardiovascular
system, including the prelimbic cortex, bed nucleus of the stria
terminalis, central nucleus of the amygdala, and most of the
hypothalamus (3, 5, 7, 28). Stimulation of the hDB with the excitatory
amino acid L-glutamate causes
cardiovascular depressor responses (14). Based on this observation, we
speculate that decreases in AP may activate neurons in the hDB that may
regulate the level of sympathetic activity to the cardiovascular system.
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ACKNOWLEDGEMENTS |
This work was supported by the Heart and Stroke Foundation of
Alberta. G. J. Kirouac is a recipient of a Fellowship from the Medical
Research Council of Canada and the Alberta Heritage Foundation for
Medical Research. Q. J. Pittman is a Senior Scientist of the Medical
Research Council of Canada and the Alberta Heritage Foundation for
Medical Research.
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FOOTNOTES |
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: G. J. Kirouac,
Dept. of Physiology and Biophysics, 3330 Hospital Drive NW, Univ. of
Calgary, Calgary, Alberta, Canada T2N 4N1 (E-mail:
kirouac{at}ucalgary.ca).
Received 30 November 1998; accepted in final form 15 February
1999.
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