Increased heat-escape/cold-seeking behavior following hypertonic saline injection in rats

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Increased heat-escape/cold-seeking behavior following hypertonic saline injection in rats

Kei Nagashima, Sadamu Nakai, Masahiro Konishi, Liu Su, and Kazuyuki Kanosue

Department of Physiology, Osaka University Faculty of Medicine School of Allied Health Sciences, Yamadaoka 1 - 7, Suita, Osaka 565 - 0871, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

We examined the effect of hypertonic saline injection on heat-escape/cold-seeking behavior in desalivated rats. Rats wereexposed to 40°C heat after normal (154 mM NaCl, control) or hypertonicsaline (2,500 mM NaCl) injection (1 ml/100 g body wt). The ratsreceived a 0°C air for 30 s when they entered a specific areain an experimental box. Core temperature (T_c) surpassed 40°C inboth conditions when 0°C air was not available. Hypertonic salineinjection produced a lower baseline T_c than control [36.9 ± 0.2and 37.9 ± 0.2°C (means ± SE), P < 0.05] and a greater numberof 0°C air rewards during the 2-h heat with lower T_c at the end(48 ± 1 and 34 ± 2, 37.6 ± 0.1, and 37.3 ± 0.1°C in the controland hypertonic saline injection trial, respectively, P < 0.05,n = 6). However, T_c was similar (37.7 ± 0.2 and 37.6 ± 0.4°C inthe control and hypertonic saline injection trial, n = 5) when0°C air was automatically and intermittently (35 times) givenduring the heat. Rats augment heat-defense mechanisms in responseto osmotic stress by lowering the baseline T_c and increasing heat-escape/cold-seekingbehavior.

hyperosmolality; operant behavior; desalivation

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

IT IS WELL KNOWN THAT DEHYDRATION impairs thermoregulation in heat and can lead to heat stroke in extreme conditions. Twofactors during dehydration, a reduction in blood volume and anincrease in plasma osmolality, are thought to be involved in themechanism (1, 2, 6-9, 14, 15, 19). These factorssuppress autonomic responses necessary for thermoregulation suchas panting (1, 2, 9), sweating (6, 7), salivarysecretion (8), and skin vasodilation (14, 15, 19). Thesuppression of these thermoregulatory responses during dehydrationwould be important to preserve fluid in the body and/or maintaina greater central blood volume. Besides the autonomic responses,all animals use behavioral means to regulate body temperature(3, 16, 20, 21). In general, they first try to escapethermally untenable environments (16). Indeed, when readilyavailable, heat-escape and/or cool-seeking behaviors are the leastcostly responses in terms of energetics and fluid balance. Thus,for dehydrated animals, alterations in core temperature wouldbe most efficiently accomplished with behavioral responses. Brummermannand Rautenberg (3) first analyzed the effect of osmotic stresson behavioral thermoregulation in the heat: pigeons conditionedto get cold-air rewards in the heat by an instrumental responseincreased their responding following hypertonic saline infusion.However, it still remains unknown if heat-escape/cold-seekingbehavior is activated by osmotic stress per se or if the activationis a compensatory response as a result of attenuated autonomicresponses.

In the present study, we investigated heat-escape/cold-seeking behavior in rats following hypertonic saline injection to evaluatethe importance of osmotic changes in this behavior. Rats spreadsaliva on their body surface for the evaporative heat loss. Tominimize the influence of this additional evaporative heat loss,salivary secretion was blocked by surgical ligature of the salivaryducts. In addition, a novel operant system that Chen et al. (4)recently reported was used for quantitative assessment of heat-escape/cold-seekingbehavior in freely moving rats. We hypothesized that heat-escape/cool-seekingbehavior in rats with attenuated salivary secretion would be increasedfollowing hypertonic salineinjection.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Male crj-Wistar rats (Charles River Japan, Osaka, Japan) were used for the present experiments. The experimental protocolfor this study was approved by the Animal Committee of Osaka UniversityMedical School. Rats were housed individually at the room temperatureof 23°C in a 12:12-h light-dark cycle (light on at 7:00 AM) andhad free access to food andwater.

Surgery. Each rat was anesthetized with an intraperitoneal injection of pentobarbital sodium (5 mg/100 g body wt). The major salivaryducts from the parotid, major sublingual, and submaxillary glandswere doubly ligated, then cut in the middle as previously reported(12). The successful procedure was verified by polydipsia forseveral days following the surgery and postmortem examinationof salivary glands that showed atrophy. A biotelemetry device(15 × 30 × 8 mm; Physiotel, Data Science, St. Paul, MN) for themeasurement of core body temperature was placed in the peritonealcavity. The accuracy of the measurement was within 0.1°C. At least2 wk after the surgery, each rat was anesthetized in the sameway as above, and a silicone catheter (diameter 1.0 mm; Fuji Systems,Tokyo, Japan) was placed in the intrathoracic inferior vena cavathrough the right femoral vein. Its free end was pulled out throughthe skin of the nape. The catheter was filled with heparinized(50 units/ml) saline, and the end was plugged with a stainlessrod. To avoid clogging, the catheter was flushed with the heparinizedsaline everyday.

Experimental operant behavior system. For quantitative assessment of heat-escape/cool-seeking behavior in heat, we used the experimental system previously reported(4). Briefly, a box (50 × 10 × 30 cm) made of Plexiglas wasplaced in an environmental chamber (80 × 65 × 60 cm, Fig. 1A).The box was well ventilated with numerous 1-cm diameter holeson the sides and a metal mesh lid. The chamber had an air inletand an outlet that were connected to two air-supply units (CAU-210,Tabai Espec, Osaka, Japan). One of the units supplied hot airranging from 25 to 40°C, and the other supplied cold air rangingfrom 0 to 30°C. Computer-controlled electromagnetic valves switchedthe unit ventilating the chamber. Rats were able to move freelywithin the box. Movement of the rats was continuously monitoredwith an infrared video camera. In addition, five pairs of photosensorunits located the animals' position to one of five 10 × 10-cmsquare areas.

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Fig. 1. The experimental system is illustrated. A: Plexiglas box was put in a chamber, which was connected to 2 air-supply units. One supplied cold air (0-30°C), and the other supplied warm air (25-40°C). The unit supplying the chamber was switched by computer-controlled valves. B: top view of the box. The position of rats in the box was located with 5 pairs of photosensors, dividing the box into five 10 × 10-cm square areas in a single plane (1).

Protocol 1 (operant behavior in heat). Six rats (200-300 g body wt) with ligated salivary ducts were individually put in the experimental system for 2 h three times.A 2-day interval separated the training sessions. The followingparameters were used. The hot unit was set at 40°C, and the coldunit was set at 0°C. The chamber was normally ventilated by thehot unit. Once rats moved into the reward area (areas 4 and 5in Fig. 1B), ventilation via the cold unit was given by switchingthe valves for 30 s. Rats had to move out of the area and thenmove into the area again to get another 30 s of cold air. Therats easily learned this procedure during the training sessions.At least 3 days after the training sessions, either normal (154mM NaCl) or hypertonic (2,500 mM NaCl) saline was injected (1ml/100 g body wt) into the subcutaneous tissue of the lower backunder local anesthesia (0.5% lidocaine). After 1.5 h, each ratwas put in the experimental box with temperatures of both air-supplyunits set at 26°C. The rat was kept under these conditions for>1 h until the core temperature became stable (within 0.2°C for>10 min). The air-source temperatures were then altered to 40and 0°C for another 2 h. After a 5- or 6-day interval, the sameexperimental protocol was repeated with a saline injection ofthe other concentration, e.g., normal saline injection in caseof hypertonic saline injection in the first trial. The order ofthe trials was randomly chosen. Food and water were not givento the rats during the measurementperiod.

Protocol 2 (periodical passive cooling in heat). Five rats (200-300 g) with ligated salivary ducts were used for this experiment. Each rat was placed in the box for one 2-hsession to familiarize them with the apparatus. The system wasprogrammed to switch intermittently the ventilating air from 40°Cto 0°C regardless of the rats' movements in the box. The switchfor the cold unit was maintained for 30 s. The number of cold-airventilations (35 times during the session) was determined basedon the mean number of cold-air rewards in the normal saline trialof protocol 1. Two days after the session, normal or hypertonicsaline was injected in the same way as in protocol 1. Each ratwas first placed in the box for 1 h with the air temperature setat 26°C. For another 2 h, the air temperature was set at 40°Cwith intermittent 0°C air ventilation as in the training session.The same experimental protocol was repeated after the saline injectionwith the other concentration following a 5- or 6-dayinterval.

Protocol 3 (passive heating). Three rats (250-300 g) with ligated salivary ducts were used. In the initial session, each rat was put in the box with 26°Cventilating air for 2 h. Two days after this session, either normalor hypertonic saline was injected in the same way as in protocols1 and 2. The rat was placed in the box for 1 h with 26°C ventilatingair followed by 40°C for 2 h. No cold air was given in this protocol.We stopped the experiment when the body core temperature exceeded40°C. The same heat exposure was repeated in the second salineinjection following a 5- or 6-dayinterval.

Measurements. Measurements of body weight and blood sampling (0.5 ml) were done before and 1.5 h after the saline injection and at the endof the experiment for protocols 1 and 2. Hematocrit (Hct, microcentrifuge),total plasma protein concentration (TP, refractometry; Atago,Tokyo, Japan), and plasma osmolality (freezing-point depression;One-Ten osmometer, Fiske, MA) were determined. Percent changesin blood volume ( $Delta$ %BV) were estimated by changes in Hct and TP,assuming plasma content of total protein was constant throughoutthe measurement period. The following formula was used (13):

&Dgr;%BV = <FENCE><FR><NU>(1 − Hct0/100)</NU><DE>(1 − Hctt/100)</DE></FR> · <FR><NU>TP0</NU><DE>TPt</DE></FR> − 1</FENCE> · 100

where Hct₀ and Hct_t represent Hct at baseline and measurement point, respectively; TP_o and TP_t represent TP at baseline andmeasurement point,respectively.

Statistics. Differences between variables were determined by analysis of variance for repeated measurements (18). Significant differencesat specific time points were identified by Newman-Keuls post hoctest. Confidence level for statistical significance was set atP < 0.05. All variables are expressed as means ±SE.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Protocol 1. Figure 2 illustrates data for one rat in the normal-saline trial. The rat first moved restlessly in the box (Fig. 2A). However,the rat moved periodically in and out of the reward area (areas4 and 5 in Fig. 1) during the heat exposure. The core body temperaturewas basically stable during the heat exposure (Fig. 2B). The ambienttemperature measured in the box reached ~10°C within 30 s afterthe rat moved in the reward area, then returned immediately to40°C (Fig. 2C).

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Fig. 2. Position (A) and core temperature (T_core; B) of 1 rat as well as the ambient temperature (T_a; C) in the box in the normal-saline trial of protocol 1 are illustrated. Air at 0°C was given for 30 s when the rat entered the reward area (areas 4 and 5) in the box.

The averaged core temperature during the last 30 min of baseline period at the ambient temperature of 26°C and the 2-h heatperiod in the normal- and hypertonic-saline trials are shown inFig. 3A. The baseline core temperature in the hypertonic-salinetrial was lower (P < 0.05) than that in the normal-saline trial(36.9 ± 0.2 and 37.9 ± 0.2°C, respectively). Although the coretemperature at 30-90 min during the heat exposure was similarbetween the two trials, that in the hypertonic saline trial decreasedto a lower level (P < 0.05) than in the normal-saline trial at90-120 min (37.2 ± 0.1 and 37.6 ± 0.1°C, respectively). Therewas no significant difference in core temperature from the baselineduring the heat in the two trials. The counts of cold-air rewardsduring the heat exposure for the hypertonic-saline trial weregreater (P < 0.05) than for the normal- saline trial (Fig. 3B)except at 30-60 min. The mean ambient temperature for the hypertonic-salinetrial was lower (P < 0.05) than for the normal- saline trial (33.6± 0.1 and 35.2 ± 0.3°C, respectively).

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Fig. 3. A: changes in body T_core averaged for each 30 min at the T_a of 26°C (baseline) and during operant behavior at 40°C for the normal- and hypertonic-saline trials of protocol 1. The rats received the saline injections 1.5 h before being placed in the box. B: counts of cold-air rewards in the normal- and hypertonic-saline trials of protocol 1. Values are means ± SE (n = 6). *Significantly different between normal- and hypertonic-saline trials (P < 0.05). $dagger$ Significantly different from the baseline in each trial (P < 0.05).

Figure 4 shows percent changes in body weight (A) and blood volume estimated by Hct and TP (B) and plasma osmolality (C) beforeand 1.5 h after the saline injection (before entrance into theexperimental box) and at the end of the experiment in the normal-and hypertonic-saline trials of protocol 1. Although body weightbefore the saline injection was similar between the two trials(263 ± 12 and 256 ± 11 in the normal- and hypertonic-saline trials,respectively), %reduction in body weight following the injectionwas greater (P < 0.05) in the hypertonic- than the normal-salinetrial. Blood volume in both trials was increased (P < 0.05) followingthe saline injection, and there was no significant differencebetween the two trials. Plasma osmolality increased (P < 0.05)only after the hypertonic saline injection and remained at theincreased level during the heat exposure.

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Fig. 4. %Changes in body wt (A) and blood volume (B) and plasma osmolality (C) before and 1.5 h following saline injections (pre-heat exposure) and at the end of the experiment (post-heat exposure) in the normal- and hypertonic-saline trials of protocol 1. Values are means ± SE (n = 6). *Significantly different between normal- and hypertonic-saline trials (P < 0.05). $dagger$ Significantly different from the baseline in each trial (P < 0.05). $Delta$ , Change.

Protocol 2. Figure 5A illustrates averaged core temperature. Thirty-second ventilation of 0°C air was automatically and intermittentlygiven during the heat exposure regardless of the rats' movement.The core temperature in the normal-saline trial remained stablethroughout the experiment. Despite a lower (P < 0.05) baselinecore temperature, core temperature in the hypertonic-saline trialincreased (P < 0.05) during the heat such that there was no significantdifference from the normal-saline trial. The increase in coretemperature from the baseline value in the hypertonic-saline trialwas 1.3 ± 0.2°C at 90-120 min, which was greater (P < 0.05) thanthat of the normal-saline trial (0.3 ± 0.3°C). Although the coldair was automatically given regardless of the rats' position inprotocol 2, we counted movements of the rats into the area correspondingto the "reward area" in protocol 1 to evaluate nonspecific movementsof rats in the heat (Fig. 5B). The counts of movements duringthe heat were greater (P < 0.05) than the baseline at 0-120 minin the normal-saline trial and at 0-60 min in the hypertonic-salinetrial. However, the counts of nonspecific movements were significantly(P < 0.05) lower than the counts of cold-air rewards in protocol1 at 30-120 min in both trials. The percent changes in body weightand blood volume and plasma osmolality were similar to the valuesin protocol 1.

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Fig. 5. A: changes in body T_core at an ambient temperature of 26°C (baseline) and during heat exposure of 40°C in the rats for the normal- and hypertonic-saline trials of protocol 2. Cold air of 0°C intermittently and automatically ventilated the chamber during the heat exposure. B: movements into areas 4 or 5 of the experimental box. The counts estimate nonspecific movements. Values are means ± SE (n = 5). *Significantly different between normal- and hypertonic-saline trials (P < 0.05). $dagger$ Significantly different from baseline in each trial (P < 0.05).

Protocol 3. The rats were exposed to 40°C without either operant or automatic cold-air ventilation. The baseline core temperature beforethe heat exposure was 37.6 ± 0.2 and 36.8 ± 0.2°C in the normal-and hypertonic-saline trial, respectively, with a significantdifference (P < 0.05). We had to cease the protocol for all therats within 30 min after the onset of heat exposure because thecore temperature exceeded 40°C. The mean duration of heat exposurewas 20 ± 2 and 24 ± 3 min in the normal- and hypertonic-salinetrial,respectively.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In the present study, we evaluated the effect of hypertonic saline injection on heat-escape/cool-seeking behavior in the ratswith ligated salivary ducts. The results strongly suggest thathypertonic saline injection increases heat-escape/cool-seekingbehavior.

During constant exposure to environmental temperature of 40°C without a cold-air reward in protocol 3, the rats with ligatedsalivary ducts could not regulate body core temperature followingeither normal or hypertonic saline injections. In addition, thelatency to reach the body temperature of 40°C was not differentbetween the normal- and the hypertonic-saline trials. Thus theresults would indicate that the contribution of skin vasodilationto heat dissipation was similar in the two trials. However, coretemperature was maintained within the normal range if 0°C airwas available following an operant behavior (Fig. 3) or when administeredautomatically (Fig. 5). Therefore, getting cold air would be theonly viable mechanism for rats with blocked salivary secretionto regulate core temperature in theheat.

The rats using the operant behavior (moving to 1 part of the box for cold-air rewards in protocol 1) increased the countsof cold-air rewards during the heat exposure both in the normal-and hypertonic-saline trials (Fig. 3). In addition, the countsin the hypertonic-saline trial were greater than those of thenormal-saline trial in the first one-half hour and the last hourof heat exposure. In this operant system, rats learned the operantbehavior (Fig. 2) much more rapidly than when it involves a leverpress (12). We judged that the rats had learned the operantbehavior when they showed the periodical movements into the rewardarea as shown in Fig. 2A. However, we have no precise criteriato separate the operant behavior from nonspecific movements, becausenonspecific movements increased during heat exposure (Fig. 5).Nonspecific movements of the rats in the heat were assessed inprotocol 2 by counting movements into areas 4 or 5 (Fig. 1), whichcorresponded to the reward area in protocol 1 (Fig. 5). The countsin protocol 1 were significantly greater than those in protocol2 at 30-120 min of 40°C. Therefore, the cold-air rewards in protocol1 were, partly at least, due to an operant behavior elicited bythermoregulatorydemand.

The baseline core temperature in the hypertonic-saline trial was lower than the normal-saline trial in all protocols. Seven-percentreduction in body weight at the end of the hypertonic-saline trial(Fig. 4A) indicates a loss of body water largely due to osmoticdiuresis because the reduction in normal-saline trial was muchsmaller. Hypohydration induces a decrease in metabolic rate inrats and camels by the effects of either hypovolemia or hyperosmolality(10, 17). In contrast, hypohydration would attenuate the netheat loss because the threshold of core temperature for the tailvasodilation, which is the important heat-loss mechanism, especiallyin thermoneutral condition, would be elevated by the effect ofhyperosmolality (8, 15). Moreover, evaporative heat losswould be minimum in both trials due to the ligation of major salivaryducts, and the core temperatures below 38°C seen in this partof the study are far below the threshold for saliva spreading(20). Thus the lower baseline core temperature in the hypertonic-salinetrial may have been a result of attenuated heat production ratherthan facilitated heatloss.

The greater loss of body weight in the hypertonic-saline trial might have lowered body temperature due to circulatory shock.However, the rats' operant behavior was pursued more vigorouslythan in the normal-saline trial. In addition, blood volume waspreserved even in this condition (Fig. 4B). These findings suggestthat circulatory shock would be the least likely mechanism forthe lowered bodytemperature.

Despite lower baseline core temperatures in the hypertonic-saline trials of protocols 1 and 2, the core temperatures increasedto the levels of the normal-saline trials within 60 min afterthe heat exposure (Figs. 3 and 5). As long as the cold air wasautomatically given, the core temperatures in the normal- andhypertonic-saline trials remained at similar levels (Fig. 5).Therefore, the number of cold-air rewards was sufficient to maintaina balance between heat production and heat loss. In contrast,the rats decreased their core temperature following the hypertonicsaline infusion when they could use the operant behavior (Fig.3), the major mechanism for thermoregulation in the heat. Theseresults strongly suggest that the rats increased the operant behaviorin the hypertonic-saline trial to maintain a lower body temperaturethan in the normal-salinetrial.

The operant heat-escape/cold-seeking behavior might have been secondary to a rise in body temperature as a result of attenuatedautonomic responses. However, body core temperature is actuallylower in the hypertonic-saline trials than in the normal-salinetrials (Fig. 3A) as noted above. Furthermore, thermal inputs fromthe body surface, which would be important both for autonomicand behavioral thermoregulatory responses (16), were lower inthe hypertonic-saline trial than in the normal-saline trial becausethe mean ambient temperature in the hypertonic-saline trial waslower. Therefore, the increase in the operant behavior is nota secondary response to a rise in body temperature but is a directresponse to hypertonic salineinjections.

The stimulus to increase the operant behavior would be the increase in plasma osmolality and/or the reduction in the intracellularfluid volume (cell dehydration) that occurred subsequently. Thehypertonic saline injection induced an increase in plasma osmolalityand a reduction in body weight, although the normal saline injectiondid not change those values except for a slight decrease in bodyweight at the end of the trial (Fig. 4A). However, blood volumewas rather increased in both trials. We surmised that the normalsaline injection resulted in an increase in the extracellularvolume, including blood volume. In contrast, the hypertonic salineinjection led to osmotic forces that likely caused a redistributionof body fluid from the intracellular to the extracellular compartmentby osmosis despite a reduction in total bodyfluid.

Thermally induced dehydration causes not only a reduction in body water, which, when extreme, is accompanied by a decreasein blood volume (11). In this condition, autonomic responsesfor heat loss are suppressed. The ensuing decrease in evaporativeheat loss (1, 2, 6-9) would help maintain body water. Thesuppression of dry heat loss, i.e., skin vasodilation (14, 15,19), would augment the central blood volume needed for cerebralcirculation. Suppressed autonomic responses for heat loss aregenerally accompanied by a rise in core temperature, such as duringfever. However, the dehydration induced by hypertonic saline injectionled to a decreased core temperature under thermoneutral conditions(Figs. 3 and 5). This may function to delay the activation ofautonomic heat-loss responses when animals face heat. Facilitationof heat-escape/cold-seeking behavior would prevent or lessen theneed to use the autonomic responses, which would result in thepreservation of body water. Thus during dehydration, autonomicand behavioral responses for thermoregulation are simultaneouslymodulated and function to maintain body waterhomeosatasis.

In summary, we showed that plasma hyperosmolality and/or cell dehydration induced by hypertonic saline injections are stimulifor the direct activation of operant heat-escape/cold-seekingbehavior in rats with ligated salivary ducts. The increased operantbehavior results in lower body temperature compared with normal-salinecontrols. Moreover, the hypertonic saline injection also led toa decreased body temperature under thermoneutral conditions, probablyby suppressing heat production. These findings indicate that acoordinated set of autonomic and behavioral thermoregulatory adjustmentsoccurs in response todehydration.

Perspectives

Numerous studies have clarified that several autonomic responses for thermoregulation are suppressed by dehydration: factorsof both hyperosmolality and hypovolemia. It seems that most investigatorssimply understand this mechanism as an upward shift of set-pointbody temperature. However, this study showed that both the behavioraland metabolic responses to dehydration reduced body temperature.Thus each thermoeffector is likely to react to dehydration ina different manner, which would deny the concept of elevated set-pointbody temperature during dehydration. We speculate that body temperatureis just a sum of outputs from various independently controlledthermoeffectors rather than the determined output from an integratedsystem.

	ACKNOWLEDGEMENTS

We gratefully thank to Dr. Larry I. Crawshow for valuablecomments.

	FOOTNOTES

The present study was supported in part by grants-in-aid for scientific research from the Ministry of Education, Science andCulture of Japan (No. 11557003 and12307001)

Address for reprint requests and other correspondence: K. Nagashima, Osaka Univ. Faculty of Medicine School of Allied HealthSciences, Yamadaoka 1-7, Suita, Osaka 565-0871 Japan (E-mail:kei{at}sahs.med.osaka-u.ac.jp).

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.Section 1734 solely to indicate thisfact.

Received 13 July 2000; accepted in final form 28 November 2000.

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