Vol. 278, Issue 4, R973-R979, April 2000
Carotid and cardiopulmonary chemoreceptor activity increases
hippocampal theta rhythm in conscious rabbits
Ying-Hui
Yu and
W. W.
Blessing
Centre for Neuroscience, Departments of Medicine and Physiology,
Flinders University, Bedford Park 5042 SA, Australia
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ABSTRACT |
We have examined whether activation of carotid artery
chemoreceptors causes alerting in conscious rabbits. Injection of
phenylbiguanide (a 5-hydroxytryptamine3-receptor agonist)
into the common carotid artery of conscious rabbits increased the
proportion of theta rhythm in the hippocampal EEG, commencing in the
first 5-s epoch after the injection. Intravenous injection of
phenylbiguanide also increased the proportion of theta rhythm in the
hippocampal electroencephalogram (EEG), but the onset of the change was
not until the second 5-s epoch following injection. Injection of Ringer solution, either into the common carotid artery or into the marginal ear vein, did not affect the hippocampal EEG. Results suggest that
phenylbiguanide-mediated activation of carotid and cardiopulmonary chemoreceptor afferents alerts the animal, as assessed by induction of
theta rhythm in the hippocampal EEG. This alerting response presumably
reflects the action of neural inputs that enter the brain with the
carotid sinus nerve at the level of the medulla oblongata.
electroencephalogram; arousal/orientation response; carotid body; carotid sinus nerve; sudden infant death syndrome; 5-hydroxytryptamine3 receptors.
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INTRODUCTION |
EFFECTS OF CAROTID CHEMORECEPTOR activation on
cardiovascular and respiratory parameters are now reasonably understood
(22). Less is known regarding the effects of peripheral chemoreceptor activation on arousal responses. An inadequate arousal response to such
activation could underlie sudden infant death syndrome (SIDS) (7, 8,
12, 13, 19, 23). However, identification of brain stem pathways
mediating the various effects initiated by peripheral chemoreceptors is
confounded by direct effects of hypoxia and hypercapnia on the central
nervous system. Because the neuroanatomical substrates of the relevant
neural circuitry are still obscure, it is difficult to carry out
hypothesis-driven postmortem neuropathological studies in SIDS patients
(14). Direct stimulation of peripheral chemoreceptor afferents is more likely to prove useful in the identification of central pathways mediating their effects, because the direct links of these receptors with the medulla oblongata are now reasonably understood (5, 6).
Physiological indices of alerting/arousal responses include activation
of the neocortical electroencephalogram (EEG) and the appearance of a
regular slow activity in the hippocampal EEG (hippocampal theta
rhythm). Effects of carotid chemoreceptor activation on alerting-related EEG parameters, including hippocampal theta rhythm, have not been adequately established in conscious animals. We have
previously documented the occurrence of hippocampal theta rhythm in
conscious rabbits alerted by stimuli in the external environment (29).
In the present study, we first measured breathing indices in
anesthetized rabbits to confirm that intracarotid administration of
phenylbiguanide (PBG), a 5-hydroxytryptamine3
(5HT3)-receptor agonist, activates carotid arterial
chemoreceptors, as has been demonstrated directly in rats (10, 26) and
indirectly in rabbits (27). We have now determined in conscious rabbits
the effects of intracarotid PBG on the hippocampal EEG and compared the
results with the effects of intravenous injections.
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METHODS |
New Zealand White rabbits (2.5-3.5 kg), bred for laboratory use,
were cared for in accordance with Flinders University Animal Welfare
Committee guidelines.
We first established a model of intracarotid PBG injection in
anesthetized rabbits, using respiratory parameters to monitor the
effects of chemoreceptor stimulation. For these experiments, rabbits
were anesthetized with thiopentone sodium (40 mg/kg iv) and intubated;
anesthesia was maintained with 1-2% halothane in O2
via endotracheal tube. We recorded arterial pressure from one femoral
artery and assessed respiratory activity either by recording the
phrenic nerve electrical discharge in the conventional manner or by
measuring respiratory rate from the end-tidal CO2 monitor (Datex, Helsinki, Finland) or with a spirometer (MacLab, ADInstruments Sydney). Signals were digitized (40-Hz sampling rate) with MacLab and
displayed on an Apple Macintosh G3 computer using MacLab Chart Software.
A catheter was placed in the left common carotid artery with the distal
end directed away from the heart and positioned about 1.5 cm proximal
to the carotid bifurcation (Fig. 1). We
employed either an "open carotid" preparation (ligatures
A and B in Fig. 1 not tied) or a "blind-sac"
preparation formed by ligating the external carotid artery just distal
to the common carotid bifurcation and the internal carotid artery ~5
mm distal to the carotid sinus region (ligatures A and
B in Fig. 1 tied). PBG (0.1-5 mg/ml in 0.2 ml Ringer) was
injected into the common carotid artery in ~2 s. Effects on arterial
pressure, heart rate, and respiration rate were determined. When
rabbits with a blind-sac preparation recovered from anesthesia, some
animals developed a contralateral hemiparesis (presumably from cerebral
emboli arising from thrombosis on the brain side of the internal
carotid ligation), so the animals were killed, and the blind-sac model
was not used for EEG studies in the conscious animal. For these studies
we used an open carotid system with a fine catheter in the superior
thyroid artery (see below) to minimize the occurrence of cerebral
emboli from thrombi forming on the intra-arterial catheter.
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Fig. 1.
Diagram explaining different methods of injecting phenylbiguanide (PBG)
or Ringer vehicle into carotid chemoreceptor region. In anesthetized
rabbits, catheter was introduced into common carotid artery and glued
in position, with artery remaining patent. In open carotid situation,
neither external carotid ligature (ligature A in Fig. 1) nor
internal carotid ligature (ligature B in Fig. 1) was tightened.
In blind-sac preparation, both these ligatures were tightened. In
unanesthetized rabbits, PBG or vehicle was introduced via a catheter in
superior thyroid artery with both external and internal carotid
arteries patent.
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For EEG studies, bipolar stainless steel electrodes were inserted into
the dorsal hippocampal region and stainless steel screws were implanted
on frontal and parietal skull regions (29) with the animal anesthetized
with thiopentone and halothane (as above). After surgery, halothane was
discontinued and the endotracheal tube removed. Animals recovered from
anesthesia and appeared to be in normal health. After 1 wk, again under
general anaesthesia as described above, a fine polyvinyl catheter was
inserted into the left superior thyroid artery and the lumen was
positioned at the junction of this vessel with the common carotid
artery. The proximal end of the catheter was connected to an osmotic
pump (Alzet 2ML1, Alza Palo Alto, CA) positioned in a subcutaneous pouch, with access to the catheter distal to the osmotic pump via a
three-way tubing connector (20 G, Small Parts, FL) also positioned
subcutaneously. The free end of the catheter system was left protruding
through the skin at the back of the neck with the open end sealed. The
intracarotid line was kept patent by continuous infusion of heparinized
Ringer solution (1,000 units/ml) from the osmotic pump. The rabbit
recovered from anesthesia.
On the following day, the rabbit was placed in a wooden box in a quiet
laboratory (room temperature 20-22°C). An intravenous line was
established via a marginal ear vein. The catheter leading to the
carotid artery was connected to an arterial pressure transducer and
also made available (via the 3-way tap) for intra-arterial administration of PBG. The EEG electrodes were connected via a headstage to the MacLab system, as previously described (29). Arterial
pressure and EEG signals were digitized (100 Hz) and recorded with the
MacLab system. The carotid arterial catheter was not available for
arterial pressure recording during the period when it was used for PBG
or Ringer injection. In addition, the fine caliber of the cannula meant
that a pulsatile arterial pressure signal was not available on every
occasion in which Ringer or PBG was injected into the carotid artery.
When the environment was quiet, the animal was still, and the
hippocampal EEG registered an irregular pattern, PBG (0.2 ml, 1 mg/ml
in Ringer solution) or vehicle was gently injected into either the left
common carotid artery or into the marginal ear vein over a period of
2-3 s. Care was taken not to move the catheter during the
injection period. Injections were repeated after intervals of ~3 min.
If an obvious environmental stimulus occurred (e.g., a noise or a
person entering the laboratory) or if the rabbit moved during or just
after the injection period, the injection was aborted and the data were
not included in our analysis. In some animals, PBG was administered
first and then Ringer solution; in other animals we reversed the order.
The MacLab Chart records of hippocampal EEG were analyzed offline using
the fast Fourier transform facility in IgorPro Software (WaveMetrics,
Oregon). For each rabbit in each experimental condition, we selected
four episodes of hippocampal EEG, each 25.60 s long. These four
episodes were each divided into five epochs, each epoch being 5.12 s
long. The injection was made toward the end of the first epoch so that
the next four epochs were from the postinjection period. Both ends of
each epoch were smoothed by a cosine function, and the magnitude of the
real component of the Fourier transform of each epoch was obtained.
Relative power spectra for corresponding epochs for each of the four
episodes were averaged. The area of the power spectra for each EEG
epoch occupied by theta rhythm (defined as 4-10 Hz) was expressed
as a percentage of the total area (0-50 Hz) of the epoch. The
parietal and frontal EEG traces were inspected by eye to determine
whether or not the onset of hippocampal theta rhythm was associated
with activation-desynchonization of the trace.
For each experimental condition (intracarotid or intravenous PBG or
Ringer), the averaged hippocampal theta proportions for the five epochs
were examined using analysis of variance with repeated measures.
Statistical significance was set at the 0.05 level, and appropriate
differences between epoch means were examined with Fisher's protected
t-test.
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RESULTS |
In anesthetized rabbits, in both the open carotid and blind-sac
preparations, injection of PBG into the common carotid artery caused a
brisk increase in respiratory rate, commencing a few seconds after the
injection and continuing for 20-30 s (Fig.
2). Arterial pressure and heart rate fell
slightly (Fig. 2). We assessed the response to 0.2 ml of 0.1-5
mg/ml of PBG and found that a concentration of 1 mg/ml gave a
reasonable respiratory effect.
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Fig. 2.
Effect of intracarotid injection of PBG (0.2 ml of 1 mg/ml) on
breathing rate, arterial pressure (AP), and heart rate (HR) in
anesthetized rabbits with both carotids patent (A) or in a
blind-sac preparation (B).
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In conscious rabbits, manipulation of the intravenous or intra-arterial
line occasionally disturbed the animal so that slight movement occurred
and the proportion of hippocampal theta rhythm increased for both PBG
and Ringer administration. These episodes were omitted from analysis.
Injection of PBG (0.2 ml of 1 mg/ml) did not cause observable bodily
movement in its own right.
Injection of PBG into the common carotid artery (n = 6 rabbits)
caused hippocampal EEG to express a theta rhythm dominant pattern,
commencing durng the first postinjection epoch and continuing throughout the following three epochs (Figs.
3 and 4 and
Table 1). Injection of PBG into the
common carotid artery also caused a fall in arterial pressure and a
bradycardia commencing ~3 s after the onset of the injection.
Arterial pressure fell from 63 ± 4 mmHg before intracarotid injection
of PBG to 47 ± 5 mmHg 10 s after injection of PBG (n = 8 injections in 4 rabbits, P < 0.01). As can be seen
in Fig. 4, theta rhythm clearly increased in the hippocampal EEG before
the fall in arterial pressure commenced. Injection of Ringer solution
into the common carotid artery (n = 6 rabbits) did not change
the proportion of hippocampal EEG theta rhythm in any of the
postinjection epochs (Fig. 3, Table 1). Similarly, intracarotid Ringer
injections did not change arterial pressure (63 ± 5 mmHg before
injection and 63 ± 5 mmHg 10 s after injection, n = 8 measurements in 4 rabbits).
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Fig. 3.
A: hippocampal electroencephalogram (EEG) traces before and
after injection of either Ringer or PBG (0.2 ml of 1 mg/ml) into common
carotid artery in conscious rabbit. B: power spectra derived
from Fourier analysis of hippocampal EEG recordings. Intracarotid
injection of Ringer or PBG occurred at beginning of epoch 2.
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Fig. 4.
EEG traces from bilateral parietal extradural electrodes and from
bilateral intrahippocampal electrodes before and after injection of PBG
(0.2 ml of 1 mg/ml) into common carotid artery. Phasic arterial
pressure is illustrated in bottom trace.
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Table 1.
The proportion (%) of theta rhythm (4-10 Hz) area compared with
total area in the Fourier power spectrum of the hippocampal EEG
for different experimental conditions
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Injection of PBG into the marginal ear vein (n = 4 rabbits)
caused hippocampal EEG to express a theta rhythm dominant pattern commencing at the second postinjection epoch and continuing throughout the remaining two epochs (Fig. 5, Table 1).
In all cases, PBG-induced hippocampal theta activity was bilaterally
symmetrical, as shown in Fig. 4. Injection of Ringer solution into the
marginal ear vein (n = 4) did not significantly change the
hippocampal EEG theta rhythm expression (Fig. 5, Table 1).
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Fig. 5.
A: hippocampal EEG traces before and after injection of either
Ringer or PBG (0.2 ml of 1 mg/ml) into marginal ear vein in conscious
rabbit. B: power spectra derived from Fourier analysis of
hippocampal EEG recordings. Intracarotid injection of Ringer or PBG
occurred at beginning of epoch 2.
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When injection of PBG caused the appearance of theta rhythm in the
hippocampal EEG, the frontal and parietal EEG signal displayed lower
voltage faster rhythms, indicative of activation-desynchonization (Fig. 5).
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DISCUSSION |
Our study demonstrates that PBG, administered into the common carotid
artery or into the marginal ear vein in the conscious rabbit, causes
hippocampal EEG to change to a predominant theta pattern accompanied by
activation-desynchonization of the neocortical EEG without any obvious
change in the behavior of the animal. Our previous study (29), also in
the conscious rabbit, demonstrated that similar hippocampal EEG changes
occur when the rabbit is alerted by a significant stimulus in the
external environment. We therefore consider that the appearance of
hippocampal theta rhythm in response to administration of PBG implies
that the animal has been alerted by events in the internal
physiological environment.
We found a clear difference in the latency of onset of the theta
activity depending on the route of administration of the PBG. When the
drug was administered into the common carotid artery, onset of theta
rhythm occurred 1-3 s after the injection, ~5 s earlier than
occurred after intravenous injection. This earlier onset of theta
suggests that intracarotid PBG acts on chemoreceptors in the arterial
territory. The respiratory effects noted in our open carotid and
blind-sac experiments in anesthetized rabbits confirm that the dose of
PBG used activates carotid chemoreceptors in rabbits, as has been
previously demonstrated (27). If PBG crossed the blood brain barrier
(this is unlikely) in the open carotid situation, injection of the drug
into the common carotid might result in a direct action on the
ipsilateral forebrain. However, in our conscious rabbit studies, it was
clear that induction of hippocampal theta rhythm occurred bilaterally
and symmetrically. Thus we consider it likely that the occurrence of
hippocampal theta rhythm after intracarotid PBG reflects activation of
carotid chemoreceptors by this agent. In rats, there is direct evidence that PBG and 5HT stimulate arterial chemoreceptor endings, but not
baroreceptor endings (10, 26).
Although intracarotid PBG clearly induced an alerting type hippocampal
EEG rhythm in the doses used, we did not observe any dramatic "sham
rage" response such as the one reported after injection of lobeline
into a carotid blind sac in decerebrate cats (4). Similarly, Daly and
Taton (11) evidently did not observe marked behavioral effects with
injections of cyanide into the carotid body region in rabbits. Rats do
show behavioral arousal in this situation (15) so that there appears to
be species differences in the behavioral manifestations of alerting
reactions. Similarly, in our previous study using intravenous
administration of PBG (17), rats exhibited transient behavioral
activation (the animals started to climb the wall of the cage), but
rabbits remained immobile and apparently calm, although, as
demonstrated in the present study, intravenous PBG also activates EEG
indices of arousal. In humans, chemoreceptor activation by intravenous
lobeline is associated with an unpleasant feeling in the upper chest
and throat (16, 24).
Data from our previous study (17) confirm that in rabbits intravenous
PBG causes a marked reduction in arterial pressure and heart rate
(Bezold-Jarisch reflex). It is possible that the EEG changes observed
after intravenous injections of PBG could at least partially reflect
the fall in arterial pressure, possibly via effects on the
baroreceptors (1) or (less likely) by altering cerebral blood flow.
Increases or decreases in arterial pressure can arouse lambs from sleep
by baroreceptor-mediated mechanisms, a process that is accompanied by
desynchronization of the neocortical EEG (18). In contrast, after
intracarotid PBG, the EEG change occurred within a couple of seconds,
an effect that clearly preceded any fall in arterial pressure.
Carotid chemoreceptor afferents enter the brain via the carotid sinus
and glossopharyngeal nerves. In rabbits, as in other species, the major
termination site of the carotid sinus nerve is the nucleus tractus
solitarius, but there is also a direct termination in the spinal
nucleus of the trigeminal nerve as well as a direct projection to the
ventrolateral medulla oblongata caudal to the level of the area
postrema (6). Studies in anesthetized animals have reported
experimental manipulations in the nucleus tractus solitarius that
synchronize the neocortical EEG, changes opposite to those usually seen
in arousal (9, 20, 21, 25). So far, no studies have related hippocampal
theta activity to the function of the nucleus tractus solitarius.
However, neuronal activity in a number of brain stem regions (including
the locus coeruleus and the dorsal raphe nucleus) can induce theta
activity in the hippocampal EEG (2, 3, 28). Our demonstration that activation of carotid chemoreceptors causes hippocampal theta activity
suggests that there may be a functional "alerting" connection between relevant neurons in the nucleus tractus solitarius and the hippocampus.
Our present study adds to the body of evidence supporting the view that
arterial chemoreceptor activation normally alerts the individual. As
noted in the introduction, the underlying cause of at least some cases
of SIDS may well be some defect in the brain stem circuitry mediating
this response. This fundamental defect would render the infant more
vulnerable to situations that compromise the airway (e.g., sleeping in
the prone position). Our limited understanding of the actual brain stem
circuitry involved in chemoreceptor-induced arousal makes it difficult
to interpret the pathological finding from SIDS victims (14).
Hypothesis-driven postmortem studies, directed at specific brain stem
regions, are more likely to demonstrate a neuropathological
abnormality. We have previously used the fos procedure to study
central pathways activated by intravenous PBG in the conscious rabbit
(17). Further investigation of the brain stem circuitry activated by
intracarotid administration of this agent may provide specific
hypotheses for the location of neuropathological changes in SIDS victims.
Perspectives
Over the years, different investigators have considered the behavioral
arousal responses elicited by stimulation of peripheral chemoreceptors.
Such responses make physiological sense, because changing the position
of the nose and/or mouth is clearly vital when the patency of the upper
airways is compromised by a particular position of the head. Moving
from one environment to another may well improve the quality of the
inspired air. In rabbits, appearance of theta rhythm in the hippocampal
EEG is a sign that the animal has detected a significant environmental
event (29), although there may be little or no overt behavioral
response. The selective cutaneous vasoconstriction that accompanies the
alerted EEG state no longer occurs in rabbits with inactivated neuronal
function in the region of the amygdala (30) so that this region of the brain acts to integrate the response to possibly dangerous events in
the external environment. Our present study demonstrates that the
hippocampal EEG also displays theta activity when activation of
peripheral chemoreceptors signals the occurrence of potentially dangerous events in the internal environment. The chemoreceptor-derived neural signals travel to the brain in the carotid sinus nerve. We have
recently mapped the central termination sites of this nerve in the
rabbit (6), and it may be possible to elucidate the ascending brain
stem pathway mediating the alerting response to peripheral
chemoreceptor stimulation. This knowledge may well prove relevant to
our understanding of some cases of SIDS.
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ACKNOWLEDGEMENTS |
Supported by the Sudden Infant Death Research Foundation of
Australia, the National Heart Foundation of Australia, the
Neurosurgical Research Foundation of South Australia, and the National
Health and Medical Research Council.
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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: W. W. Blessing,
Dept. of Medicine, Flinders Medical Centre, Bedford Park SA 5042, Australia (Email: w.w.blessing{at}flinders.edu.au).
Received 6 July 1999; accepted in final form 12 October 1999.
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Am J Physiol Regul Integr Comp Physiol 278(4):R973-R979
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ABSTRACT
INTRODUCTION
