INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

VISCERAL AFFERENTS from the gastrointestinal tract are thought to carry important signals to the brain that are used in the process of food satiation and meal termination. Information from gastric mechanosensors (9, 11, 15, 19), small intestinal chemosensors (12, 13, 22), the hormone cholecystokinin (CCK) (27), and vagal afferents (20, 22, 26) have been most strongly implicated in this pathway. If this information is indeed important for meal termination, then interruption of the signaling cascade at any location should result in delayed satiety and larger meals. For example, blockade of the CCK-A receptor with selective antagonists has been demonstrated to increase meal size (5, 18, 20).

We have recently shown that rats with capsaicin-induced ablation of a portion of both dorsal root and vagal primary afferents overingest, relative to controls, various diets in short-term feeding tests (4, 16). However, this relative overconsumption was not seen during the second and subsequent trials a few days later, and intake of familiar chow was not different for capsaicin- and vehicle-treated rats (4, 16). We hypothesized that although signals mediated by capsaicin-sensitive visceral afferents, such as gastric distension and the arrival of nutrients in the small intestine, play an important role in limiting intake of novel foods, they are relatively unimportant in meal termination with familiar foods. Signals generated by alternative sensors located pre- or postabsorptively and carried to the brain by either capsaicin-resistant afferents (1) or the circulation may be used. They generate associations between the taste/flavor and its metabolic consequences during the first exposure to a novel food, which then guide intake in future trials, known as learned appetite and satiety (2, 24). This interpretation is supported by recent findings of Phillips and Powley (20) that after selective surgical vagal afferent rhizotomy, food intake was significantly increased during the first meals on the first day but not on the second day or thereafter. Furthermore, the results of another recent study, reporting that overconsumption of a relatively low-concentration sucrose solution (10%) was not only observed during initial exposure but was permanently displayed (6), suggest that the low metabolic impact of this calorically dilute food may not have stimulated the postulated alternative or redundant sensors. In contrast to this relatively low-energy sucrose solution, we had used diets with medium (complete liquid diet Ensure) to very high (pure vegetable shortening or corn oil) energy density in our earlier studies (4, 16).

The aim of the present series of studies was to determine the conditions and possible mechanisms that allow either persistent or transient overconsumption of sucrose and other sugar solutions by capsaicin-treated rats. The initial purpose was to determine whether we could replicate, within our deprivation regime, the sustained overconsumption effect with 10% sucrose that Curtis and Stricker reported (6). In our design, rats were 12-h food deprived prior to testing, in contrast to Curtis and Striker (6), who used chronically food-restricted rats and, furthermore, allowed the animals 48-h continuous exposure to the solution prior to testing.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals

Capsaicin Treatment and Tests for Its Effectiveness

Capsaicin-treated rats weighed the same as vehicle-treated rats within 10 days following treatment (265 ± 3 g) and gained weight at a similar rate throughout the study.

Eight days following capsaicin treatment, one drop of 1% NH₄OH was applied to the left eye with a Pasteur pipette, and the number of eye wipes in 30 s and the latency to the first wipe were recorded. All capsaicin-treated rats fulfilled the criterion of less than three wipes and a latency of >5 s to the first wipe. All vehicle control animals wiped vigorously, with a latency of <1 s and >15 wipes/30 s.

At the end of the experimental period, ~23 wk following capsaicin treatment, animals were tested for the known food intake-suppression effects of exogenous CCK. In overnight food-deprived capsaicin- and vehicle-treated rats, CCK (6 µg/kg ip) or saline as a control was administered 5 min before access to chow, and 30-min intake was then measured. Half the animals of each group received CCK first, and the other half received saline first, with tests 3 days apart.

As expected (12), administration of CCK-8 suppressed intake of chow in the overnight food-deprived rats by more than 80% in vehicle-treated control rats [saline, 6.5 ± 0.2 g; CCK, 1.1 ± 0.2 g; t(11) = 6.88, P < 0.001] but failed to induce significant suppression in capsaicin-treated rats [saline, 6.3 ± 0.2 g; CCK, 5.6 ± 0.3 g; t(19) = 1.32, P = 0.12].

Experimental Protocols

Experiment 1. Tests were begun 2 wk after capsaicin treatment, when body weights were similar between the capsaicin- and vehicle-treated control rats. Two groups were formed, each containing body weight-matched capsaicin-treated (n = 10) and vehicle-treated (n = 6) animals. Each group was initially exposed to five short-term feeding tests, 3 days apart, and each was preceded by 18 h of food deprivation. The first test was conducted with the familiar pelleted chow diet for both groups. Then, for the next four trials, one group was exposed to 10% and the other to 40% sucrose solution as the novel diet. For several days before the first exposure to sucrose, the rats were offered the appropriate concentration, and allowed to lick for 10 s (<0.2 ml). The purpose of this training was to eliminate any neophobia toward the new food and source but without allowing significant ingestion and its metabolic consequences. By the fourth day, all rats immediately approached the spout and started drinking. The test solution was given between 0830 and 1100 in a calibrated burette attached to the cage front. Intake levels were measured manually every 5 min for 1 h by reading the volume on the burette to the nearest 0.1 ml. Chow was returned to the animals 1 h after completion of the test.

Experiment 2. After the last trial in this series, all rats were given a period of ad libitum access to chow, and then the group initially exposed to 10% sucrose was successively exposed to 15%, 20%, and finally 40% sucrose, with three to four trials at each concentration (ascending group). Likewise, the group originally exposed to 40% was now successively exposed to 20%, 15%, and finally 10% sucrose, with three to four trials at each concentration (descending group). As above, each 1-h trial was preceded by 18-h food deprivation, with 2-3 days between trials.

Statistical Analysis

For experiment 2, separate repeated measures three-way ANOVAs were carried out for 60-min intakes in milliliters and kilocalories for the averages of the last two trials for each sucrose concentration (within subject factor) across the ascending and descending series. Post hoc, Bonferroni-adjusted multiple comparisons tests were applied throughout for comparisons of individual means.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Experiment 1

View larger version (16K): [in this window] [in a new window]   Fig. 1.   Cumulative intake during first exposure to 10% (A) and 40% (B) sucrose solution of 2 separate groups of capsaicin-treated (CAP, circles) and vehicle-treated (VEH, triangles) rats maintained on chow diet. Rats were trained to lick from a spout with water deprivation and were food deprived for 15 h prior to the first test. Capsaicin-treated rats significantly overconsumed both concentrations of sucrose. Note that the initial (5 min) rate of consumption is not different, with the major overconsumption effect occurring between 5 and 20 min. Values are means ± SE of 6 VEH and 10 CAP rats in each group. *P < 0.05 and **P < 0.01, VEH vs. CAP, Bonferroni-adjusted multiple comparison tests based on ANOVA.

View larger version (43K): [in this window] [in a new window]   Fig. 2.   One-hour intake of 10% and 40% sucrose solution of 2 separate groups of vehicle-treated (open bars) and capsaicin-treated (hatched bars) rats during trials 1-4 (T1-T4). Note that although CAP rats continue to significantly overconsume 10% sucrose solution throughout all trials, they significantly underconsume 40% sucrose in trial 2 (T2) and thereafter exhibit similar intake to VEH rats. Values are means ± SE of 6 VEH and 10 CAP rats in each group. **P < 0.01, for VEH vs. CAP, Bonferroni-adjusted multiple comparison tests based on ANOVA.

During subsequent trials (Fig. 2), overconsumption of 10% sucrose by capsaicin- vs. vehicle-treated rats persisted, so that in trial 4 they ingested 100% more [t(28) = 8.02, P < 0.001]. On the contrary, capsaicin-treated rats significantly decreased 40% sucrose intake during the second trial [t(28) = 4.23; P < 0.001] and then slowly recovered during the next trials, so that intake was similar for both treatment groups during trial 4. There was a significant three-way concentration × trial × treatment interaction with intake expressed both in milliliters [F(3,28) = 3.54, P < 0.001] or in kilocalories [F(3,28) = 3.92, P < 0.001], confirming that the overconsumption by capsaicin-treated rats persisted and became even larger with each trial with 10%, but was lost with 40% sucrose.

When comparing intake of 10% and 40% sucrose during the last two trials, differences in volume vs. calorie tracking were revealed (Fig. 3). Control rats drank only moderately less 40% compared with 10% sucrose and as a consequence ingested significantly more calories [t(28) = 15.9-17.5, P < 0.01]. In contrast, the difference between intake of 40% and 10% sucrose was much larger and significant [t(28) = 13.0-14.5, P < 0.01] in capsaicin-treated rats, and as a consequence their calorie intake was not different [t(28) = 0.47-0.73, not significant (NS)].

View larger version (26K): [in this window] [in a new window]   Fig. 3.   Comparison of intake of 10% and 40% sucrose solutions expressed as volume (ml, left) or energy (kcal, right) for trials 3 and 4 of experiment 1. Note that vehicle-treated control rats but not capsaicin-treated rats ingested significantly larger numbers of calories with access to 40% compared with 10% sucrose, because they reduced volume intake much less. **P < 0.01, 10% vs. 40% sucrose, Bonferroni-adjusted multiple comparison tests based on ANOVA.

Experiment 2

In the ascending series (Fig. 4A), capsaicin-treated rats continued to significantly overconsume 15% sucrose in three consecutive trials [average of last 2 trials: t(28) = 7.0, P < 0.001], but when switched to 20%, this response was gradually lost, so that in the 3rd and 4th trial, intakes were no longer significantly different [t(28) = 1.70, P = 0.8]. When finally exposed to 40% sucrose, capsaicin-treated rats did not consume more than vehicle-treated control rats in any of the four trials.

View larger version (69K): [in this window] [in a new window]   Fig. 4.   One-hour intake of various sucrose solutions in 2 separate groups of vehicle-treated (open bars) and capsaicin-treated (hatched bars) rats. In an ascending series (A), group 1 rats were exposed to 3-4 trials each (T1-T4) with 10%, 15%, 20%, and 40% sucrose solutions; and in a descending series (B), group 2 rats were exposed to 3-4 trials each with 40%, 20%, 15%, and 10% sucrose. The last 2 trials with 10% (group 1) and 40% (group 2) sucrose are the same as in Fig. 2, and are shown here for comparison. Note that in the ascending series capsaicin-treated rats "lost" their overconsumption response with 20% sucrose, and in the descending series the overconsumption response was "recovered" with 10% sucrose. Values are means ± SE of 6 VEH and 10 CAP rats in each group. *P < 0.05 and **P < 0.01, CAP vs. VEH, Bonferroni-adjusted multiple comparison tests based on ANOVA.

In the descending series (Fig. 4B), it was not before the last three trials with 10% sucrose that the capsaicin-treated rats started to consume significantly more than the vehicle control rats [average of last 2 trials: t(28) = 3.51, P = 0.012]. There was a significant effect of the order of sucrose concentration on intake of capsaicin-treated [t(28) = 4.19, P < 0.001] but not vehicle-treated rats [t(28) = 1.8, P = 0.16]. This effect was particularly clear with 15% sucrose. At this concentration, there was a highly significant overconsumption by capsaicin-treated rats in the ascending series but no effect in the descending series.

If looking at the last trials only for a given concentration in the ascending series, the vehicle-treated control rats did not change the volume ingested when they went from 10% to 15% sucrose [t(28) = 0.04, NS] and from 15% to 20% [t(28) = 1.26, NS] (Fig. 5, top). This was reflected by significantly different energy intakes of 10% vs. 15% sucrose [6.0 ± 0.7 vs. 9.0 ± 0.6 kcal, t(28) = 3.89, P = 0.007] and 10% vs. 20% sucrose [6.0 ± 0.7 vs. 10.5 ± 1.1 kcal, t(28) = 3.36, P = 0.027] (Fig. 5, bottom). It was only in the last two trials with 40% sucrose that control rats significantly reduced the volume ingested. Although control rats ingested about 50% more calories from 40% compared with 15% sucrose, this difference did not reach significance [t(28) = 2.43, NS].

View larger version (69K): [in this window] [in a new window]   Fig. 5.   Comparison of volume (top) and energy (bottom) intake across the four sucrose concentrations 10%, 15%, 20%, and 40%, for the last trial with each concentration in vehicle- and capsaicin-treated rats. Note that at least for the range of 10-20% sucrose, control rats tended to ingest the same volume but different amounts of calories, whereas the capsaicin-treated rats tended to ingest the same number of calories but different volumes. For each group, bars that do not share the same letter are significantly different (P < 0.05, Bonferroni-adjusted multiple comparison tests based on ANOVA).

In contrast, capsaicin-treated rats demonstrated a concentration-dependent decrease in volume intake [F(3,28) = 53.4, P < 0.001; Fig. 5, top] and as a consequence showed less change in calorie intake, although the difference between 10% and 15% was significant [F(3,28) = 9.6, P < 0.01; Fig. 5, bottom].

Looking only at the last trials for each concentration in the descending series, the difference in volume vs. calorie tracking between control and capsaicin-treated rats was less evident, but the general trend was also present (Fig. 5). Control rats did not significantly change volume ingested from 20% to 10% [t(28) = 1.58, NS] and from 15% to 10% sucrose [t(28) = 2.0, NS] and as a consequence ingested significantly more calories from 20% than from 10% sucrose [t(28) = 3.56, P = 0.002]. However, control rats did significantly increase the volume of 20% compared with 40% sucrose [t(28) = 4.24, P < 0.003] and as a result ingested a similar number of calories [t(28) = 0.84, NS].

In contrast and similar to the ascending series, capsaicin-treated rats concentration-dependently reduced volume intake [F(3,28) = 51.6, P < 0.001]. The exception was the similar volume of 15% and 20% sucrose ingested (Fig. 5, top). As a consequence, none of the calorie intakes from the different sucrose concentrations was significantly different [F(3,28) = 3.68, NS; Fig. 5, bottom].

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

This study was designed to identify and specify changes in ingestive behavior in rats treated systemically with high doses of capsaicin, a toxin that has been shown to chronically ablate a class of visceral afferents. The results show that changes in ingestive behavior by capsaicin-treated rats depend on the familiarity and energy density of a particular test food. The following conclusions can be drawn from the present study. 1) Capsaicin-treated rats ingest significantly more of various concentrations of sucrose solutions if presented for the first time: they overconsume. This overconsumption is the result of increased meal size, with the initial rate of ingestion similar to controls (delayed satiety). Also, overconsumption of low concentration was more pronounced than that of high-concentration sucrose solutions. 2) The ingestive experience from a single 1-h trial was sufficient to abolish or mask overconsumption of high- but not low-concentration sucrose solutions in subsequent trials. Prior experience with high-concentration sucrose is more potent than experience with low sucrose to abolish overconsumption in subsequent trials. 3) Although vehicle-treated control rats, within a certain range of sucrose concentrations, drank relatively constant volumes, capsaicin-treated rats drank a relatively constant number of calories, by adjusting the volume of the different sucrose concentrations.

Overconsumption During First Exposure to Novel Food

However, ingestion rate and total amount ingested (meal size) are not only governed by negative feedback signals from the gut but also by the acceptance of the novel diet. Acceptance depends on palatability (hedonic value) and the individual level of caution characteristic for any neophobic behavior. We have tried to keep this neophobic caution to a minimum by allowing animals to taste and get accustomed to small amounts of the novel food before the first test exposure. If this training did not completely eliminate a neophobic hypophagia, then any overconsumption seen in capsaicin-treated rats could theoretically be ascribed to interference with the mechanism underlying the neural control of neophobic behavior.

In addition, capsaicin treatment could affect hedonic acceptability and palatability of the food. The initial (first 5 min) rate of ingestion, which is often used as an indicator of acceptability, was not significantly different in capsaicin-treated rats for both sucrose concentrations. In addition, we did not find significant differences in the number of licks during the first 10 s of exposure to 0.005 M (0.17%) to 0.1 M (3.4%) sucrose (unpublished observations). A near maximal lick rate of 6 licks/s was already observed with 0.1 M sucrose in both vehicle- and capsaicin-treated rats. Furthermore, Silver and coworkers (25) have reported that capsaicin-treated rats emitted the same number of licks to salty (NaCl), sour (HCl), and low concentrations of bitter (1-5 × 10⁴ M quinine) stimuli. Only the response to the highest concentration of quinine (10³ M) was slightly impaired. Acceptance of sweet stimuli was not tested by these authors (25). On the basis of these observations, it is thus unlikely that overconsumption was the result of capsaicin-induced damage to gustatory pathways.

The overconsumption observed with 10% sucrose was considerably larger than with 40% sucrose solution. Earlier we showed that solid (vegetable shortening) and liquid (corn oil) fat foods caused large overconsumption, whereas a complete liquid diet (Ensure) and fat-free carbohydrate cookies produced only small or no overconsumption. Our original interpretation was that high fat content was necessary for overconsumption to occur (16), but in the light of the present findings it is no longer tenable. It is more likely that the magnitude of the overconsumption response depends on how rapidly a novel food can generate satiety signals at postgastric and/or postabsorptive sites not damaged by capsaicin treatment. These signals would tend to make up for the lacking satiety signals from gastric distension sensors before the first meal has ended. With a 40% sucrose solution, glucose absorption and portal glucose levels are higher than with 10% sucrose, and in general, glucose absorption is much faster than fat absorption. This would explain why overconsumption of low-concentration sugar solutions and high-fat foods is more pronounced than high-concentration sugar solutions.

Another consideration is the osmolality of the novel food. Osmotic concentration seems to be an important satiety signal (14, 30). Abdominal vagotomy abolished the inhibiting effect of mannitol, a nonmetabolizeable sugar, on ingestion (8). It is therefore possible that capsaicin-resistant osmosensors may provide the "missing" negative feedback during the first exposure to 40% sucrose in capsaicin-treated rats. The low osmotic value of fat foods would explain why there is no such intake-inhibiting effect during the first exposure to high-fat foods.

Intake During Subsequent Trials

The major new finding of the present study is that in contrast to 10% sucrose, higher sucrose concentrations abolish the overconsumption exhibited by capsaicin-treated rats. Apparently, this higher concentration was able to produce sufficient postgastric signal to counteract and neutralize the intake-enhancing effect of the missing gastric distension signal by a learning process as outlined above. It is not clear whether the effect was due to a caloric or osmotic effect. Because osmotic concentration may play an important role in satiation (14, 30), additional experiments with metabolically inactive sugars such as mannitol or 2-deoxyglucose will be necessary to distinguish between caloric and osmotic stimuli.

Volume-Sensitive vs. Concentration-Sensitive Regulation

In contrast to control rats, capsaicin-treated rats in both the ascending and descending series showed a more or less concentration-dependent adjustment in volume consumed, resulting in only small differences in calories consumed. It may indicate the recruitment of a normally inactive or masked energy- or osmolar-based sensory mechanism that is not damaged by capsaicin. Because most of the sucrose concentrations in our experiment were hypertonic, this redundant mechanism that decreased volume intake at higher concentrations may be similar to the labile negative feedback signal demonstrated to operate at higher sucrose concentrations by Davis et al. (10).

That the newly recruited sensor is not of vagal origin is supported by the observation that capsaicin treatment almost completely eradicated traceable vagal afferent fibers and terminals in the small intestinal myenteric plexus (1). This is further supported by the observation that the rate of ingestion and meal size of milk or sucrose decreased following abdominal vagotomy and the conclusion that vagotomy enhanced the strength of an extravagally mediated negative feedback signal likely resulting from increased gastric emptying (7). Because capsaicin also eliminates most of the dorsal root afferents, it is tempting to speculate that an as yet unidentified capsaicin-resistant pathway such as the one mediating the reinforcing actions of nutrients delivered into the duodenum (17) may be recruited for caloric metering purposes in this unusual situation.

Perspectives