Mechanism of biphasic response of renal nerve activity during acute cardiac tamponade in conscious rabbits

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Mechanism of biphasic response of renal nerve activity during acute cardiac tamponade in conscious rabbits

Masanobu Hagiike¹^,², Hajime Maeta¹, Hiroshi Murakami³, Kenji Okada³, and Hironobu Morita²

Departments of ¹ Surgery and ³ Physiology, Kagawa Medical University School of Medicine, Kagawa 761-0793; and ² Department of Physiology, Gifu University School of Medicine, Gifu 500-8705, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Renal sympathetic nerve activity (RSNA) responses to acute cardiac tamponade were studied in conscious rabbits with all reflexesintact (Int) or after either surgical sinoaortic denervation (SAD)or administration of intrapericardial procaine (ip-Pro) or intravenousprocaine (iv-Pro). In Int rabbits, the mean arterial pressure(MAP) remained relatively constant until the pericardial volumereached 7.7 ml, whereas the RSNA increased to 226% [compensatedcardiac tamponade (CCT)], then, at a pericardial volume of 9.3ml, the MAP fell sharply and RSNA decreased to 34% [decompensatedcardiac tamponade (DCT)]; 1 min after cessation of pericardialinfusion, an intravenous injection of naloxone resulted in increasesin both MAP and RSNA. In SAD rabbits, RSNA did not alter throughoutCCT and DCT, but increased on injection of naloxone. In ip-Prorabbits, RSNA increased during CCT but did not decrease duringDCT, whereas, in iv-Pro rabbits, the RSNA response was similarto that in Int rabbits. These results indicate that RSNA responsesto cardiac tamponade are biphasic, with an increase during CCTand a decrease during DCT. Sinoaortic baroreceptors are involvedin mediating the increase in RSNA, whereas cardiac receptors maybe involved in mediating the decrease in RSNA. An endogenous opioidmay be responsible for the decrease in RSNA seen duringDCT.

sinoaortic denervation; cardiac denervation; naloxone

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

SINCE THE INITIAL REPORT of an experimental model for acute cardiac tamponade (21), many studies have been performed onthe hemodynamics of cardiac tamponade, in both experimental animalsand patients (6, 11, 21). In conscious dogs, during theearly stage of cardiac tamponade, the arterial pressure (AP) ismaintained, but cardiac output falls due to impaired cardiac filling[compensated cardiac tamponade (CCT)], whereas during the latestage, the AP decreases abruptly and the cardiovascular systemfalls into hemodynamic decompensation [decompensated cardiac tamponade(DCT)] (15). These changes in AP during cardiac tamponade aresimilar to those seen during hemorrhage in conscious animals,in which the AP is maintained during the early stage of bloodloss and decreases abruptly in the late stage (3, 13, 24).This abrupt decrease in AP during hemorrhage is believed to becaused by sympathoinhibition (13, 31). Direct measurementof renal sympathetic nerve activity (RSNA) reveals that RSNA increasesduring nonhypotensive hemorrhage and abruptly decreases duringhypotensive hemorrhage (3, 13, 24). The increase in RSNAis mainly mediated by sinoaortic baroreceptors, whereas the decreasein RSNA is mediated by unknown receptors located outside the heartin conscious dogs (24) or by cardiac receptors in consciousrabbits (3). Furthermore, the endogenous opioid system appearsto play a significant role in the decrease in AP and RSNA becausethe opioid receptor antagonist, naloxone, when given in the latestage of hemorrhage, increases AP and RSNA to control levels (24),whereas naloxone pretreatment abolishes the decrease in AP andRSNA (3).

Because the hemodynamic responses during cardiac tamponade and hemorrhage are similar, it is possible that RSNA responsesduring cardiac tamponade and hemorrhage may also be similar. Reportsof the direct measurements of RSNA during cardiac tamponade arestill rather rare in the literature, and those that have appearedrelate to acutely prepared anesthetized animals in which the RSNAresponses during cardiac tamponade are controversial, with onestudy showing a continuous increase and the other a biphasic response(27, 32). Because anesthesia affects sympathetic nervous systemresponses (20, 23), sympathetic nerve activity must be measuredin the conscious animals. Accordingly, one aim of the presentstudy was to examine RSNA responses during cardiac tamponade inconscious rabbits. A second was to examine the afferent mechanismof the RSNA responses, and cardiac tamponade was therefore performedon rabbits after either surgical sinoaortic baroreceptor denervation(SAD) or the administration of intrapericardial procaine (ip-Pro)or intravenous procaine (iv-Pro), as well as on rabbits with allreflexes intact (Int). The effects of naloxone during cardiactamponade in conscious rabbits were alsostudied.

	METHODS

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All experiments were performed on 35 chronically instrumented conscious male Japanese white rabbits weighing 2.7-3.2 kg. Thestudy was conducted in accordance with the "Guiding Principlesfor Care and Use of Animals in the Field of Physiological Science"of the Physiological Society ofJapan.

Animals were anesthetized with pentobarbital sodium after induction with a cocktail of anesthetics (intramuscular xylazine,chlorpromazine, and ketamine), and an endotracheal tube was insertedfor artificial ventilation. The pericardial sac was exposed througha left thoracotomy via the fourth intercostal space, then a Silasticcatheter, with two distal side holes and connected to polyvinyltubing (5-Fr), was inserted into the pericardial space througha small incision that was then closed using a purse-string suture.The catheter and pericardium were carefully checked for leakageby acute injection of 5 ml of sterile saline. The dead space ofthe pericardial catheter was then filled with heparinized saline,the catheter was exteriorized through the back of the neck, andthe incision was closed. After the operation, antibiotics (15,000U im penicillin G; Banyu, Tokyo, Japan) were given and the animal'scondition was checkeddaily.

Four to five days after pericardial catheter implantation, the second operation, implantation of renal nerve electrodes, wasperformed under pentobarbital sodium anesthesia (30 mg/kg iv).The left or right kidney was exposed through a retroperitonealflank incision, and a renal nerve bundle from the aorticorenalganglion was dissected free from the surrounding tissue. Two stainlesssteel electrodes (no. 7935; A-M Systems) were placed around it,and the nerve and electrodes were fixed together with siliconegel (Semicosil 932 A and B; Wacker-Chemie, Munich, Germany). Theelectrodes were then exteriorized through the back of the neck,and the incision was closed. Catheters were inserted into thethoracic aorta and superior vena cava via the subclavian arteryand external jugular vein to measure the AP and drug injection,respectively.

A minimum of 2 days after electrode implantation, the tamponade experiment was carried out on the conscious rabbit. The APwas measured by connecting the previously implanted catheter toa pressure transducer (model TP-101T; Nihon Kohden, Tokyo, Japan),and the heart rate (HR) was measured using a cardiotachometer(model AT-601G; Nihon Kohden) triggered by pulse pressure. Duringthe progressive cardiac tamponade, the HR was not triggered bythe pulse pressure, because the pulse pressure decreased and wastherefore counted directly from the pressure wave. An electronicR-C filter with a 2-s time constant was used to determine themean AP (MAP). RSNA was recorded after amplifying the originalrenal nerve signal with a differential amplifier, using a bandpass filter of 30 Hz to 1 kHz (model AVB-10; Nihon Kohden), andmonitored using an oscilloscope (model VC-10; Nihon Kohden) andaudio speaker. The output from the amplifier was passed througha gate circuit to remove baseline noise, and the output from thegate circuit was rectified by an absolute value circuit and integratedusing an R-C filter (50 ms). To quantify RSNA, RSNA during the30 s just before the tamponade experiment was defined as 100%.MAP, HR, and RSNA were sampled using an analog-to-digital converter(MacLab/8) at a rate of 100 samples/s. After the stabilizationof all measured variables, a 5-min control period was begun. A10-s averaged value (1,000 points) was used for the data at agiven intrapericardial volume. For MAP, HR, and RSNA, no differencewas seen among three time points during this control period andthe averaged data for these three points were used as the controlvalue. Cardiac tamponade was produced by step infusion of warmedsterile saline into the pericardial space via the previously implantedpericardial catheter. The rate of infusion for the first 6 mlwas 2 ml/30 s; it was then changed to 1 ml/30 s until the MAPfell below 50 mmHg (DCT). To investigate whether an endogenousopioid mechanism was involved in the decrease in RSNA seen duringDCT, after a 1-min observation of DCT, we injected a bolus doseof naloxone (3 mg/kg) intravenously (Int; n = 7). This dose ofnaloxone was chosen because it had no effect on the basal levelof MAP, HR, or RSNA and was sufficient to restore the fall inMAP and RSNA seen during hypotensive hemorrhage to normal values(22, 28). In five other rabbits, the effects of increasedintrapericardial volume on intrapericardial pressure (ipP) andcentral venous pressure (CVP) were examined, but RSNA was notmeasured.

To investigate afferent mechanisms, i.e., the role of sinoaortic baroreceptors and cardiac receptors in response to cardiactamponade, the same experiment was performed on SAD (n = 7), ip-Pro(n = 8), or iv-Pro (n = 6)rabbits.

SAD was performed 2 wk before the cardiac tamponade experiment by bilateral cervical section of the aortic nerves and strippingof the carotid sinuses while rabbits were under pentobarbitalsodium anesthesia; 7 and 12 days later, the pericardial catheterand renal nerve electrodes, respectively, were implanted. Completenessof SAD was confirmed before the experiment by testing the baroreceptor-HRreflex; phenylephrine (10 µg/kg iv) increased the MAP by 34 ±11 mmHg without any effect on HR ( $-$ 3 ± 3 beats/min), and nitroprussidesodium (20 µg/kg iv) decreased MAP by 53 ± 18 mmHg without anyeffect on HR (+6 ± 4 beats/min). Because it was easier to decreasethe MAP in SAD rabbits compared with Int rabbits, a differentrate of pericardial infusion of 2 ml/30 s was used for the first2 ml, followed by 1 ml/30 s until DCT. After a 1-min observationof DCT, a bolus dose of naloxone (3 mg/kg iv) wasinjected.

In eight rabbits, cardiac afferent blockade was performed by intrapericardial infusion of 2% procaine (1 ml) (2, 8,9). Before starting the tamponade experiment, we confirmedthe completeness of cardiac afferent blockade by using the Bezold-Jarischreflex (20 µg/kg veratridine intrapericardially); before procaineinjection, the MAP and HR decreased by 24 ± 4 mmHg and 32 ± 5beats/min, respectively, and these responses were abolished afterprocaine injection (+2 ± 1 mmHg, +3 ± 2 beats/min). The cardiactamponade experiment was performed in the same way as in Int rabbits.In two other rabbits, the effects of procaine were studied for20 min. During this period, the CVP and RSNA were not altered(CVP, +0.5 mmHg; RSNA, +2.2%); the MAP increased by 13 mmHg; theHR showed a biphasic response, decreasing by 25 beats/min at 2min after injection then gradually increasing by 37 beats/minat 20 min; the Bezold-Jarisch reflex was completely abolishedfrom 2 to 20 min after procaine injection; no respiratory incoordinationwas seen; and arterial blood oxygen saturation, measured usinga pH-blood gas analyzer (model Stat PO 5; Nova Biomedical, Newton,MA), was maintained at >97%. To exclude effects of leakage ofprocaine into peripheral vasculature in ip-Pro rabbits, the sameexperiment was performed after iv-Pro administration (1 ml 2%procaine).

At the end of the experiment, the rabbits were killed by anesthetic overdose, and a necropsy was performed to confirm thepositioning of the pericardial catheter and the absence ofleakage.

Statistical analysis. All values are presented as means ± SE. In Table 1, the pericardial volume was analyzed by one-way ANOVA, with the groupsof animals as a factor (Int, SAD, ip-Pro, and iv-Pro). MAP, HR,and RSNA were analyzed by two-way ANOVA, with conditions of cardiactamponade and groups of animals as two factors, followed by posthoc comparison of Fisher's protected least significant difference.The effects of ip-Pro and iv-Pro to MAP, HR, and RSNA were comparedwith the preinjection level using Student's paired t-test. Inall tests, a P value <0.05 was considered statistically significant.

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Table 1. Changes in variables during cardiac tamponade

	RESULTS

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The effects of the increased pericardial volume on ipP, CVP, MAP, and HR in the five ipP-CVP rabbits were summarized in Fig.1. During cardiac tamponade, both the ipP and CVP increased inproportion to the pericardial volume (y = 0.24x, r = 0.986 andy = 0.46x + 2.7, r = 0.934, respectively). In contrast, the changesin MAP and HR were not a linear response.

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Fig. 1. Effects of increasing pericardial volume on intrapericardial pressure (ipP), central venous pressure (CVP), mean arterial pressure (MAP), and heart rate (HR) during cardiac tamponade. bpm, Beats/min.

Figures 2-4 show the original recording illustrating typical AP, RSNA, and integrated RSNA responses to cardiac tamponadein one Int, SAD, and ip-Pro rabbit, respectively.

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Fig. 2. Original recording of arterial pressure (AP), renal sympathetic nerve activity (RSNA), and integrated RSNA responses to cardiac tamponade in an intact (Int) rabbit. The total pericardial volume is shown at bottom of recording (2, 4, 6, 7, 8, and 9 ml). Intravenous naloxone (3 mg/kg) was administrated at point indicated by arrow.

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Fig. 3. Original recording of AP, RSNA, and integrated RSNA responses to cardiac tamponade in a sinoaortic baroreceptor-denervated (SAD) rabbit. The total pericardial volume is shown at bottom of recording (2, 3, 4, and 5 ml). Intravenous naloxone (3 mg/kg) was administrated at point indicated by arrow.

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Fig. 4. Original recording of AP, RSNA, and integrated RSNA responses to cardiac tamponade in an intrapericardial procaine (ip-Pro) rabbit. Total pericardial volume is shown at bottom of recording (2, 4, 6, 7, 8, and 9 ml). Intravenous naloxone (3 mg/kg) was administrated at point indicated by arrow.

For the Int rabbits, the averaged data (Fig. 5) show that the MAP was maintained relatively constant at about 80 mmHg untilthe pericardial volume increased to 7.7 ± 0.5 ml, then fell abruptlyto 44 ± 2 mmHg at a pericardial volume of 9.3 ± 0.4 ml. As theintrapericardial volume increased to 7.7 ± 0.5 ml, the HR increasedfrom 221 ± 7 to 311 ± 17 beats/min, but a further increase inintrapericardial volume resulted in an abrupt fall in HR to thecontrol level. RSNA increased with increasing intrapericardialvolume up to 226 ± 24% at a volume of 7.7 ± 0.5 ml, then decreasedto below the control level as the intrapericardial volume continuedto increase. Responses of iv-Pro rabbits were similar to thosein Int rabbits (Fig. 5).

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Fig. 5. Averaged data for MAP, HR, and RSNA during cardiac tamponade. $open circle$ , Int rabbits (n = 7);

, SAD rabbits (n = 7); $down-triangle$ , ip-Pro rabbits (n = 8); $black-down-triangle$ , intravenous procaine-treated rabbits (iv-Pro, n = 6). Six data points for Int and iv-Pro rabbits indicate averaged data for control values and those at an intrapericardial volume of 2, 4, or 6 ml and during compensated cardiac tamponade (CCT) and decompensated cardiac tamponade (DCT). Five points for SAD rabbits indicate averaged data for control values and those at an intrapericardial volume of 2 or 3 ml and during CCT and DCT. Five points for ip-Pro rabbits indicate averaged data for control values and those at an intrapericardial volume of 3 or 5 ml and during CCT and DCT.

In contrast, the averaged data for the SAD rabbits (Fig. 5) show that the MAP gradually decreased as the intrapericardialvolume increased, whereas the HR and RSNA did not alter significantlythroughout the tamponadeperiod.

In ip-Pro rabbits, the MAP stayed relatively constant around the control level until the pericardial volume increased to 7.6± 0.6 ml, then fell abruptly to 45 ± 1 mmHg at an intrapericardialvolume of 9.6 ± 0.8 ml, whereas the HR did not alter throughoutthe tamponade period. In contrast to Int rabbits, RSNA in ip-Prorabbits increased continuously, reaching 333 ± 84% at 9.6 ± 0.8ml, although the MAP had decreased to 45 ± 1 mmHg at this point.In four animals in this group, tamponade experiments were repeatedon the next day without the use of ip-Pro and the biphasic RSNAresponse was again found to bepresent.

For the among-groups comparison, the cardiac tamponade was divided into two stages: CCT, defined as the maximal pericardialvolume at which the MAP was maintained at a value $>=$ 80% of thecontrol value; and DCT, defined as the minimum pericardial volumeat which the MAP fell below 50 mmHg. The statistical results,summarized in Table 1, show a significant difference in pericardialvolume as a factor of the group of animals (P < 0.0001), withthe pericardial volumes for CCT and DCT in SAD rabbits being significantlylower than those in Int rabbits, whereas the intrapericardialvolumes for CCT and DCT in ip-Pro and iv-Pro rabbits (including1 ml of procaine in ip-Pro rabbits) were similar to those in Intrabbits. In ip-Pro and iv-Pro rabbits, the values for the MAPand HR were significantly different as a factor of the conditionof tamponade (P < 0.0001 and P < 0.001, respectively). In Intand iv-Pro rabbits, the HR increased significantly during CCTthen decreased to the control level during DCT; the increase inHR during CCT was completely abolished by SAD or ip-Pro. In termsof RSNA, there was a significant difference for two factors (tamponadecondition, P < 0.0001; groups of animals, P < 0.001). In Int andiv-Pro rabbits, the RSNA responses to cardiac tamponade were biphasic;i.e., they increased significantly during CCT then decreased belowthe control level during DCT. In contrast, in ip-Pro rabbits,RSNA increased during CCT, but the decrease during DCT was completelyabolished, and, in SAD rabbits, both the increase during CCT andthe decrease during DCT wereabolished.

After an observation period of at least 1 min of DCT, naloxone was injected (Fig. 6 and Table 1). In Int, iv-Pro, and SADrabbits, the MAP increased to the control level and the RSNA increasedto a value well above the control level, whereas the HR did notalter in Int and iv-Pro rabbits but significantly decreased inSAD rabbits. When naloxone was injected into two ip-Pro rabbitsduring DCT, no reproducible improvement in hemodynamics and RSNAwas seen. In one, the MAP remained at 35 mmHg and RSNA alteredfrom 285% during DCT to 325%, whereas, in the other, the MAP andRSNA altered from 48 to 52 mmHg and from 860 to 756%, respectively.Both rabbits struggled violently after naloxone injection anddied, so no other ip-Pro rabbits were given naloxone.

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Fig. 6. Averaged data for MAP, HR, and RSNA after naloxone (3 mg/kg) administration. $open circle$ , Int rabbits (n = 7);

, SAD rabbits (n = 7); $black-down-triangle$ , iv-Pro rabbits (n = 6).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The major findings of the present study are that 1) in Int conscious rabbits, the RSNA response to acute cardiac tamponadeis biphasic, showing an increase during CCT and a decrease duringDCT; 2) sinoaortic baroreceptors are involved in an afferent mechanismmediating the increase in RSNA, whereas cardiac receptors maybe involved in an afferent mechanism mediating the decrease inRSNA; and 3) endogenous opioid may be one of the mechanisms involvedin the decrease in RSNA duringDCT.

Since the 1980s, the ip-Pro technique has been used by many investigators to block the cardiac nerve (2, 8, 9). Inthe present study, cardiac afferent blockade was confirmed bythe absence of the Bezold-Jarisch reflex. Although efferent blockadewas not directly confirmed, this might reasonably be assumed tobe the case, because higher concentrations of procaine are requiredto produce cardiac afferent blockade compared with efferent blockade(2, 29). In fact, the HR in ip-Pro rabbits did not alterduring CCT and DCT, due mainly to cardiac efferent blockade. Althoughit is well known that cardiac afferents directly influence RSNAvia the reflex pathway (35), it is also possible that cardiacefferents indirectly influence the RSNA response to cardiac tamponade.Öberg and Thorén (25, 26) demonstrated that vigorous cardiaccontraction induced by an increase in sympathetic efferent activity,which resulted in an activation of the left ventricular mechanoreceptorfollowed by the reflex bradycardia and renal vasodilation. Theseresults suggest that the cardiac efferents are also required toinduce sympathoinhibition triggered by the cardiac mechanoreceptor.In addition, in the ip-Pro rabbits, the HR did not alter duringthe experiment and cardiac contractility might not be increasedbecause epicardial procaine abolished responses of cardiac contractilityinduced by electrical stimulation of sympathetic and parasympatheticefferents (1). These hemodynamic changes due to cardiac efferentblockade may therefore indirectly influence the RSNA responseto cardiactamponade.

A biphasic RSNA response has been reported in conscious dogs and rabbits during hemorrhage (3, 24), with RSNA increasingduring nonhypotensive hemorrhage and decreasing during hypotensivehemorrhage. The increase in RSNA is mediated by both sinoaorticbaroreceptors and cardiac receptors because, in conscious dogs,neither SAD nor cardiac denervation alone is sufficient to blockthe increase, whereas SAD plus vagotomy completely abolishes theincrease (24). In conscious rabbits, the increase in RSNA ismediated mainly by sinoaortic baroreceptors (19, 31). However,the afferent pathway of the RSNA decrease is controversial (31).Morita and Vatner (24) reported that in conscious dogs the RSNAdecrease is not affected by surgical cardiac denervation or SADplus vagotomy. In contrast, Burke and Dorward (3) reportedthat in conscious rabbits the RSNA decrease is completely abolishedby ip-Pro. The discrepancy might be due to species differences(31) and/or differences in cardiac denervation methodology.In both studies, the RSNA decrease was reversed by naloxone, indicatingthat endogenous opioid is one mechanism involved in the RSNA decreaseoccurring during hypotensive hemorrhage (3, 28). This isalso the case in the present study, because the decreases in MAPand RSNA during DCT were reversed by naloxone. Thus endogenousopioid may be responsible for the decrease in RSNA duringDCT.

In anesthetized dogs, conflicting results have been reported for the RSNA response during cardiac tamponade, with Osborn andLawton (27) reporting that RSNA increases continuously duringcardiac tamponade and Shibamoto et al. (32) reporting a biphasicRSNA response during cardiac tamponade. This discrepancy mightbe due to the MAP reached during cardiac tamponade because, inthe former study, the MAP decreased from 125 to 82 mmHg and RSNAincreased to 240%, whereas, in the latter study, the MAP and RSNAdecreased to 50 mmHg and 77%, respectively. In the present study,the MAP also decreased to 50 mmHg, but the magnitude of the RSNAresponse was greater, with a decrease to 34%, almost the sameas the noise level (in 3 of 7 rabbits, RSNA was completely inhibited).This difference is probably due to the effect of anesthesia andacute surgical stress. It is known that pentobarbital sodium anesthesiaproduces a decrease in RSNA in SAD animals; however, if the baroreflexsystem is intact, RSNA recovers to the control level or slightlyincreases (20, 23). Thus pentobarbital sodium anesthesia modifiesthe baroreflex system and the baseline RSNA level. The other possibilityis that the autonomic nervous system is already modified by endogenousopioid released by anesthesia and surgical stress. Smith et al.(33) demonstrated that acute surgical stress causes a more thanfivefold increase in plasma $beta$ -endorphin levels. In addition, inanesthetized cats, naloxone increases the MAP and sympatheticnerve activity (16), whereas, in conscious rabbits, it has nosignificant effect on MAP or RSNA if there has been no previousblood loss (28). Thus it is possible that the sympathetic nervoussystem in anesthetized acutely prepared animals is already modifiedby endogenousopioid.

The most important difference between cardiac tamponade and hemorrhage is whether the total blood volume changes. Hemorrhageresults in a decrease in total blood volume, venous return, atrialpressure, ventricular filling, cardiac output, and MAP. Both sinoaorticbaroreceptors and cardiac receptors are unloaded, and the increasein RSNA is mediated by these receptors (5, 24). In contrast,cardiac tamponade does not decrease the total blood volume, whereasthe increased ipP impairs cardiac filling and decreases cardiacoutput and MAP. Atrial pressure is reported to increase duringcardiac tamponade (15); however, cardiac receptors may not bestimulated for the following reasons. First, the calculated atrialtransmural pressure is not increased, but actually decreases,despite an increased atrial pressure (15). Second, echocardiographyshows that the atrium is not distended during cardiac tamponade(12). Third, plasma atrial natriuretic peptide levels are decreasedby cardiac tamponade (14). Accordingly, cardiac receptors maynot be stimulated, but remain unaffected or unloaded during cardiactamponade. Thus the input from sinoaortic baroreceptors and cardiacreceptors during cardiac tamponade is similar to that during hemorrhageand/or vena caval occlusion (18).

The RSNA increase during CCT was completely abolished by SAD, indicating that it is mediated by sinoaortic baroreceptors butnot by cardiac receptors. In contrast, the decrease in RSNA duringDCT was completely abolished by ip-Pro. According to this resultand those reported from other studies on hemorrhage and vena cavalocclusion (3, 10, 19), the decrease in RSNA seen duringDCT might be mainly mediated by the cardiac nerves. The decreasesin MAP and RSNA seen during DCT in Int rabbits were reversed byintravenous naloxone injection. In the two ip-Pro rabbits tested,the MAP was not increased by naloxone. These results indicatethat the cardiac nerve-mediated endogenous opioid secretion occurredduring DCT, in good agreement with results on hemorrhagic hypotensionshowing that cardiac receptors have an opiate synapse on theirreflex pathways to the renal nerve (3) and that an endogenousopioid mechanism is located within the central nervous system(10, 36). In our own unpublished work, methyl-naloxone, whichdoes not pass the blood-brain barrier, had no effect on RSNA duringDCT, suggesting that a central opioid mechanism is also involvedin the decrease in RSNA duringDCT.

In SAD rabbits, RSNA was not altered by cardiac tamponade during either CCT or DCT. This suggests that sinoaortic baroreceptorsmay be involved not only in the increase, but also the decrease,in RSNA. Ludbrook and Ventura (19) examined hemodynamic responsesto inferior vena caval occlusion and showed that the abrupt increasein systemic vascular conductance; i.e., "sympathoinhibition,"occurs by caval occlusion in the Int rabbit but it does not occurin the absence of cardiac receptor input or sinoaortic baroreceptorinput. Their results support the above-mentioned possibility.However, naloxone increased the MAP and RSNA during DCT in SADrabbits, indicating that endogenous opioid should be secretedduring DCT. Thus it is also possible that, in SAD rabbits, anincrease in endogenous opioid levels attempted to decrease RSNAbut failed to do so or that the decrease was not observed; inthis context, it is interesting to note that detection of thesympathoinhibitory phase is difficult if there is no previoussympathoexcitatory phase (31). In the present study, in SADrabbits, RSNA during DCT tended to decrease, although this effectdid not reach statistical significance. Further investigationsare required to clarify thesepossibilities.

Perspectives

The term sympathoinhibition is based on the decrease in RSNA and the limiting of the plasma norepinephrine concentration duringhypotensive hemorrhage and DCT (3, 24, 30, 31). The physiologicaland/or pathophysiological significance of sympathoinhibition causedby endogenous opioid is still unclear, and it is not known whetherit has beneficial or deleterious effects on the animal. One benefitis considered to be that, when faced with reduced ventricularfilling, sympathoinhibition prevents cardiac overload by its effectson the ventricular muscle and peripheral arterioles, i.e., reducedcardiac contractility and afterload (4, 31). The questioncan be raised whether cardiac sympathetic nerve activity decreasesduring the sympathoinhibitory phase. Unfortunately, no data areavailable from conscious animals; however, in anesthetized animals,cardiac sympathetic nerve activity remains elevated during hypotensivehemorrhage and DCT (17, 32). Regional differences in sympatheticnerve activity are well documented (17, 34). It is possiblethat cardiac sympathetic nerve activity would not decrease inthe sympathoinhibitory phase. If this were the case, we wouldhave to consider the significance for the kidney of the RSNA decrease.The renal sympathetic nerve controls sodium and water reabsorptionby effects on renin secretion, by direct effects on tubular reabsorptionof sodium, and by altering renal hemodynamics (7). During CCT,the increased RSNA acts on sodium and water reabsorption to maintainthe blood volume and AP. However, during DCT, if RSNA remainselevated, it is difficult to maintain a minimal urine volume inthe face of decreased AP. Thus the decrease in RSNA during DCTmay have a beneficial effect in maintaining a minimal urine volumeand preserving renalfunction.

	ACKNOWLEDGEMENTS

This study was supported in part by a research grant from the Ministry of Education, Science and Culture of Japan (nos. 09470008and10671262).

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: M. Hagiike, Dept. of Surgery, Kagawa Medical Univ. School of Medicine, Kagawa 761-0793, Japan.

Received 17 February 1998; accepted in final form 12 January 1999.

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