INTRODUCTION

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OVER THE LAST FEW YEARS there has been increasing evidence that cardiorespiratory responses to hypoxic stimulation may be exaggerated in hypertensive subjects. For example, the blood pressure and ventilatory responses to hypoxia have been shown to be exaggerated in young men with borderline hypertension compared with normotensive controls (12). Exaggerated increases in muscle sympathetic nerve activity during brief exposure to hypoxia have also been reported in mildly hypertensive subjects (11). Additional data supporting a link between increased chemoreflex sensitivity and hypertension comes from an animal model of hypertension, the spontaneously hypertensive (SH) rat (2, 8). Anatomic studies have shown that the carotid body is considerably larger in the SH rat than in the Wistar-Kyoto (WKY) rat (a normotensive control) (2). Furthermore, extracellular recordings from carotid sinus nerve afferents have demonstrated that the sensitivity of arterial chemoreceptors to hypoxia is increased in the adult SH rat compared with two different normotensive controls (WKY and Wistar) (2). On the basis of these observations, it has been suggested that the development of an exaggerated response to arterial chemoreceptor stimulation may contribute to the pathophysiology of essential hypertension.

Although previous studies suggest that the SH rat may represent an excellent animal model for investigating the interconnection between hypertension and altered chemoreflex sensitivity, surprisingly few studies have actually examined the reflex effects of arterial chemoreceptor stimulation in the SH rat. Moreover, the studies that have examined the reflex response have focused almost exclusively on the ventilatory component of the arterial chemoreflex. The lack of focus on the cardiovascular component of the chemoreflex in the SH rat primarily reflects the fact that the sympathetic and vagal components of the reflex are markedly reduced in anesthetized rats (1). No investigations have examined the effect of chemoreceptor stimulation in the conscious SH rat. Therefore, because it remains to be determined whether the cardiovascular component of the chemoreflex is exaggerated in SH rats relative to normotensive controls, the present study was undertaken. The cardiovascular response to stimulation of peripheral chemoreceptors was recorded in conscious adult SH rats and compared with responses evoked in two strains of normotensive rats, WKY and Sprague-Dawley (SD) rats. In addition, ventilatory responses to arterial chemoreceptor stimulation were evaluated in anesthetized and unanesthetized rats. The results of this investigation suggest that there is no significant difference in the cardiovascular or the respiratory components of the arterial chemoreflex between SH and WKY rats. The responses of the SH and WKY rats, however, are markedly different from the response of a third strain of rat, the normotensive SD rat.

	METHODS

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All experiments were performed on age-matched (13- to 14-wk-old) adult male SH, WKY, and SD rats (250-350 g; Harlan Sprague) housed in the university animal care facility and exposed to a normal 12:12-h light (6:00 AM-6:00 PM)-dark (6:00 PM-6:00 AM) cycle. All experimental procedures were approved by the University Animal Care and Use Committee before they were carried out.

Conscious animal preparation. Two days before experimental testing the rats were anesthetized with a mixture of chloral hydrate, magnesium sulfate, and pentobarbital sodium (equithesin, 3.3 ml/kg), and a PE-10 catheter connected to PE-50 tubing was inserted into the abdominal aorta through the femoral artery for direct measurement of arterial pressure. A PE-50 catheter was inserted into the femoral vein for intravenous injection of potassium cyanide (KCN) for brief stimulation of the carotid chemoreceptors (1). Catheters were filled with heparinized saline (50 U/ml) and temporarily plugged with 23-gauge obturators. The femoral catheters were then brought under the skin to be secured between the scapulae and exited at the back of the neck through a small incision. In a small group of animals (3 of each strain) a second incision was made in the skin on the right side of the chest. Thin electromyographic (EMG) Teflon-insulated, tungsten wire electrodes (0.005, California Wire) with bared tips (0.5 cm) were inserted into the diaphragm through the abdominal wall with 27-gauge needles, brought under the skin, and exited at the back of the neck. The small incision on the right side of the chest was then sutured closed. Animals were allowed to recover from anesthesia on a warming blanket and then returned to their home cages.

Anesthetized animal preparation. In a separate group of spontaneously breathing anesthetized animals, the effect of carotid chemoreceptor stimulation on respiration was tested. Animals were anesthetized with urethan (1.3-1.4 g/kg ip), instrumented with femoral arterial and venous catheters, and intubated. After instrumentation, thin-wire EMG electrodes were inserted into the diaphragm through a small incision on the right side of the abdomen. The arterial catheter was connected to a pressure transducer and heart rate (HR) monitor (Stoelting), which was connected to the computer data-sampling system (Cambridge Electronic Designs). EMG_di wires were connected to a preamplifier. The amplified signal was then rectified and integrated (Bak Electronics, 50-ms time constant). Blood gases and body temperature were monitored (Sensor Devices and Harvard Apparatus, respectively). Body temperature was kept at 37 ± 1°C with a heating blanket. Supplemental anesthesia was given when necessary, as evidenced by marked changes in blood pressure, HR, or respiration during surgery or in response to a pinch of the hindpaw. Chemoreflex testing in the anesthetized animals typically took place 2 h after the initial induction of anesthesia.

Protocol. In all animals, arterial chemoreflex responses were evoked by intravenous bolus injections of several doses of KCN. Doses were calculated by weight (30-125 µg/kg). The appropriate volume (50-125 µl) was taken from a stock solution of KCN (0.3 mg/ml) and flushed through the catheter with an additional 0.3 ml of saline. A 5-min interval separated each KCN dose, and the order in which the doses of KCN was given was randomized. An equal volume of saline was given to control for the effects of volume injection (0.3 ml). The efficacy of KCN to selectively stimulate the peripheral chemoreceptors was tested in seven conscious animals in which the cardiovascular responses to KCN injection were recorded in the conscious state before and 10-24 h after recovery from bilateral sectioning of the carotid sinus nerves and ligation of the carotid body arteries.

Data analysis. In conscious and anesthetized animals, reflex changes in respiration and blood pressure or HR typically began 1-2 s after intravenous KCN administration. In the conscious animals the peak reflex change in HR typically occurred as arterial pressure was increasing (Fig. 1). Thus the peak change in HR was calculated from the difference between the average resting HR before chemoreceptor stimulation (calculated from the average number of systolic beats during a 3-s interval immediately before chemoreceptor stimulation) and the peak HR response (calculated from the average number of systolic beats during the time arterial pressure was increasing from baseline to the 1st maximum systolic peak; see Fig. 1, right, for an example of the time period over which HR changes were calculated). In conscious animals the mean arterial pressure (MAP) response typically peaked 3-4 s after intravenous injection of KCN. Peak changes in MAP during chemoreceptor stimulation were calculated from the difference between the peak MAP response (averaged over a 500-ms interval) during chemoreceptor stimulation and the baseline MAP (averaged over a 3-s window immediately before chemoreceptor stimulation).

View larger version (26K): [in this window] [in a new window]   Fig. 1.   Cardiovascular responses to increasing doses of potassium cyanide (KCN) given intravenously to a spontaneously hypertensive rat (SH), a Wistar-Kyoto rat (WKY), and a Sprague-Dawley rat (SD). In all strains, reflex changes in arterial pressure (AP) and bradycardia [heart rate (HR), in beats/min (bpm)] increased with increasing doses of KCN. * Approximate time of KCN bolus. Horizontal bars at right, approximate times over which changes in HR were calculated.

	RESULTS

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Conscious animals. Eighteen animals of each strain were tested for their cardiovascular responses to increasing doses of KCN. The average weight of the SH and WKY rats was similar but significantly lower than that of the SD rats (Table 1). The conscious resting MAP of the SH rats was significantly higher than the resting MAP of the WKY and SD rats. The resting HR of WKY rats was significantly lower than that of the SH and SD rats (Table 1).

View larger version (15K): [in this window] [in a new window]   Fig. 2.   Cardiovascular responses to increasing intravenous doses of KCN in conscious normotensive and hypertensive unrestrained rats. Mean arterial pressure (MAP) and HR responses evoked by increasing doses of KCN in SH rats (, n = 18), normotensive WKY rats (, n = 18), and normotensive SD rats (, n = 18) are shown. Values are means ± SE. * Significant difference in dose-response relationship from 2 other strains of rats.

View larger version (16K): [in this window] [in a new window]   Fig. 3.   Respiratory response to increasing intravenous doses of KCN in conscious normotensive and hypertensive unrestrained rats. Average peak respiratory rate, diaphragm EMG (EMGdi) burst duration, and EMGdi interburst interval evoked by increasing doses of KCN in SH rats (n = 3), normotensive WKY rats (n = 3), and normotensive SD rats (n = 3) are shown. See Fig. 2 legend for explanation of symbols. Zero KCN represents baseline value. Values are means ± SE.

View larger version (10K): [in this window] [in a new window]   Fig. 4.   Respiratory response elicited during intravenous saline injection in conscious vs. anesthetized normotensive and hypertensive rats. Average increase in respiratory rate (breaths/min) in response to intravenous bolus injection of saline (0.3 ml) in conscious (left, n = 3 each strain) and urethan-anesthetized (right, n = 5 each strain) SH, WKY, and SD rats is shown. Values are means ± SE. * Significantly different from WKY and SD rats.

View larger version (14K): [in this window] [in a new window]   Fig. 5.   Effect of bilateral carotid sinus nerve denervation on cardiovascular response of conscious, unrestrained SD rats to peripheral chemoreceptor stimulation. Average increases in MAP and HR elicited by increasing intravenous doses of KCN before () and 10-24 h after bilateral carotid sinus denervation (, n = 5) are shown. Values are means ± SE. * Significant difference in dose-response relationship after denervation.

Urethan-anesthetized animals. The cardiorespiratory responses to KCN were examined in five anesthetized SH, WKY, and SD rats. Similar to the conscious animals, the mean body weight of the SH and WKY rats was significantly lower than that of the age-matched SD rats (Table 1). The average resting MAP was also significantly higher in the SH rats than in the WKY and SD rats (P < 0.02). There was no significant difference in baseline HR across rat strains, although similar to the conscious animals there was a trend for the baseline HR of the WKY rats to be the lowest.

View larger version (15K): [in this window] [in a new window]   Fig. 6.   Effect of chemoreceptor stimulation on respiration in urethan-anesthetized normotensive and hypertensive rats. Average peak respiratory rate, EMGdi burst duration, and EMGdi interburst interval evoked by increasing doses of KCN in SH rats (n = 5), normotensive WKY rats (n = 5), and normotensive SD rats (n = 5) are shown. See Fig. 2 legend for explanation of symbols. Values are means ± SE. Zero KCN represents baseline values. * Significant difference in dose-response relationship between SD rats and other 2 strains.

	DISCUSSION

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An exaggerated chemoreflex in the SH rat was first suggested in the late 1970s, when the blood gases of young SH and normotensive Wistar rats were compared and it was found that young SH rats had increased arterial PO₂ and pH and decreased arterial PCO₂ (8). It was hypothesized that these blood gas changes in the SH rat reflected hyperventilation, possibly resulting from a hyperactivity of the chemoreflex. In agreement with this hypothesis, recordings from the carotid sinus nerve in the adult rat have demonstrated that the sensitivity of arterial chemoreceptors to hypoxia is increased in the adult SH rat compared with normotensive controls (WKY and Wistar rats) (2). In addition, several studies have confirmed that the resting minute ventilation of the adult, anesthetized SH rat is significantly higher than the resting ventilation rate of the normotensive Wistar rat (7, 9). The changes in chemoreceptor sensitivity in the SH rat have been attributed to a decrease in the lumen of the carotid body arteries, perhaps resulting from arteriosclerosis of the carotid artery (5). It was suggested that these morphological changes may reduce blood flow to the carotid body in these animals, making the region of the carotid body ischemic and resulting in a tonic increase in chemoreceptor drive.

More recent studies, however, have questioned whether the chemoreflex response of the adult SH rat is actually enhanced. For example, in 1995, Grisk and colleagues (4) found no differences in ventilatory responses to hypoxia in unanesthetized neonatal SH and WKY rats. These investigators also found no differences in respiratory responses to hypoxia between anesthetized adult SH rats and WKY and Wistar rats. Their results demonstrated that the resting respiratory rate was higher in the WKY rats than in the SH and Wistar rats and that the increase in the respiratory rate during hypoxia was smaller in the WKY rats than in the other two strains (4). However, the reflex increase in minute ventilation during 1 min of hypoxia in SH rats was not significantly different from the response of the Wistar rat. These results suggest that the respiratory component of the arterial chemoreflex may be different between rat strains, with no relation to the presence of hypertension.

Observations concerning chemoreflex function in the SH rat have potentially important implications for our understanding of cardiovascular regulation. Because the arterial chemoreflex has cardiovascular and respiratory components and changes in respiration can strongly influence cardiovascular reflex responses, it is conceivable that an enhanced chemoreceptor responsiveness might be causally related to hypertension in the SH rat. Our data in the adult SH rat provide no support for that hypothesis. On the contrary, in our small sample of conscious animals, normotensive WKY rats had a slightly higher baseline respiratory rate and a greater response to KCN than the SH rats, although these trends did not reach statistical significance. In our anesthetized rats the baseline respiratory rate for the WKY rats also tended to be highest, and the change in respiratory rate during chemoreceptor stimulation was not different between the SH and WKY rats. Whether conscious or anesthetized, the SD rats had smaller respiratory responses to KCN, consistent with data published by others (1). In summary, in the conscious and anesthetized adult rats we found no evidence for a link between hypertension and the respiratory responses to chemoreceptor activation.

In that context, it is notable that we also found no evidence for an exaggerated cardiovascular component of the chemoreflex in conscious adult SH rats. Although the peak MAP achieved by the SH rats during chemoreceptor stimulation was significantly higher than that achieved by the WKY rats (primarily because of a significant difference in resting MAP), the change in MAP during chemoreceptor stimulation was not significantly different between the SH and WKY rats. Likewise, the peak change in HR during chemoreceptor stimulation was not significantly different. We also examined the cardiovascular response to chemoreceptor stimulation of another normotensive strain of rat commonly used in cardiovascular research, the SD rat. Our results demonstrated that the peak increase in MAP elicited during peripheral chemoreceptor stimulation was significantly lower in SD rats than in SH and WKY rats, although the HR response was similar to both groups. All cardiovascular responses to KCN administration were abolished by bilateral carotid sinus nerve section. Together these data demonstrate that the magnitude of the cardiovascular response to peripheral chemoreceptor stimulation in the adult rat may differ depending on the rat strain and that hypertension in the SH rat does not result from an exaggerated chemoreflex response. These studies also suggest that use of two normotensive controls may be important when trying to identify differences in the SH rat that are associated with hypertension rather than with strain differences.

Our study differs from all previous studies comparing cardiovascular responses to chemoreflex activation in SH and normotensive control rats, in that we used adult animals. The cardiovascular response to chemoreceptor stimulation is significantly blunted and even reversed in the anesthetized animal [i.e., a depressor vs. a pressor response is recorded in anesthetized rats (1)]. In addition, the cardiovascular response produced during chemoreceptor stimulation in the anesthetized rat has been shown to be unchanged by carotid sinus denervation (7), suggesting that the depressor response in the anesthetized state is not mediated through activation of reflex pathways but may reflect an effect of hypoxia on central receptors or on vasculature. With respect to the cardiovascular responses, data from conscious animals clearly provide a more realistic assessment of chemoreceptor responsiveness. However, as our study demonstrates, the potential influence of environmental stimuli, e.g., respiratory response to intravenous injection, must be recognized.

In our anesthetized animals, respiratory responses to KCN were altered but still present. The baseline respiratory rate in the WKY rats tended to be higher, but the increase in respiratory rate was similar for the SH and WKY rats, whereas the SD rats had a significantly less robust response. These results are slightly different from those reported by Grisk and colleagues (4). In their study a significant difference in the change in breathing rate during activation of the chemoreflex was observed between the SH and WKY rats, but not between the SH and Wistar rat. Some of the differences in results may reflect differences in methodology (the use of hypoxia vs. KCN to stimulate arterial chemoreceptors), differences in rat strains, in anesthesia (i.e., in their study animals were anesthetized with chloralose-urethan). Our finding that the baseline respiratory parameters were more profoundly influenced by anesthesia in the SH and WKY rats than in the SD rats suggests that the differences observed under anesthesia between SH and WKY rats may be related to the effects of anesthesia.

As expected, the cardiovascular responses to chemoreceptor stimulation were substantially altered by anesthesia. The increase in blood pressure was abolished in all three groups, and the HR responses were blunted. Under these conditions, there were no discernible differences in the cardiovascular responses to KCN, but the data must be considered in light of altered chemoreflex sensitivity.

In summary, the present study evaluated for the first time the cardiorespiratory response of conscious unrestrained hypertensive and normotensive rats to brief periods of chemoreceptor stimulation. Our results did not show a significant difference in the peak MAP or HR response between SH rats and the normotensive WKY rat. We did, however, observe an attenuation of the peak MAP response of the SD rats compared with the SH and WKY rats. A similar trend was observed for the respiratory component of the chemoreflex when examined in the conscious and anesthetized state. The respiratory responses of SH and WKY rats were not significantly different, but both appeared to be significantly larger than the response of the SD rats. Thus the results of the present study suggest that a difference in chemoreflex sensitivity may be associated with the common genetic background of the WKY and SH rats but does not appear to be linked specifically to the expression of hypertension in the SH rat. It has, however, been reported that baseline chemoreceptor afferent input is increased in SH rats (2) compared with WKY rats. Thus the role of tonic increases in chemoreceptor afferent input in the SH rat in the development of hypertension remains to be determined. In addition, if the afferent input from chemoreceptors is indeed increased in the adult SH rat, as suggested by Fukuda and colleagues (2), but the reflex output in the SH rat is not significantly different from that of the WKY rat, there may be a central resetting of the chemoreflex response in the SH rat similar to resetting of the arterial baroreflex, which has already been described in adult SH rats (3, 6). In that case, differences in cardiovascular and respiratory components of the chemoreflex might be masked. This hypothesis remains to be tested.