Afferent signalling through the common hepatic branch of the vagus inhibits voluntary lard intake and modifies plasma metabolite levels in rats

The common hepatic branch of the vagus nerve is a two-way highway of communication between the brain and the liver, duodenum, stomach and pancreas that regulates many aspects of food intake and metabolism. In this study, we utilized the afferent-specific neurotoxin capsaicin to examine if common hepatic vagal sensory afferents regulate lard intake. Rats implanted with a corticosterone pellet were made diabetic using streptozotocin (STZ) and a subset received steady-state exogenous insulin replacement into the superior mesenteric vein. These were compared with non-diabetic counterparts. Each group was then subdivided into those whose common hepatic branch of the vagus was treated with vehicle or capsaicin. Five days after surgery, the rats were offered the choice of chow and lard to consume for a further 5 days. The STZ-diabetic rats ate significantly less lard than the non-diabetic rats. Capsaicin treatment restored lard intake to that of the insulin-replaced, STZ-diabetic rats, but modified neither chow nor total caloric intake. This increased lard intake led to selective fat deposition into the mesenteric white adipose tissue depot, as opposed to an increase in all visceral fat pad depots evident after insulin replacement-induced lard intake. Capsaicin treatment also increased the levels of circulating glucose and triglycerides and negated the actions of insulin on these and free fatty acids and ketone bodies. Collectively, these data suggest that afferent signalling through the common hepatic branch of the vagus inhibits lard, but not chow, intake, directs fat deposition and regulates plasma metabolite levels.     

Dietary fat-induced hyperphagia in rats as a function of fat type and physical form

The influence of dietary fat on food intake and weight gain was assessed by feeding adult female rats diets that differed in the type and form of fat, as well as in the availability of other macro- and micronutrients. Compared to chow-fed controls, the various fat diets increased total food intake by 4% to 27%. Specifically, rats fed chow and a separate source of fat (fat option diet) consumed more fat and total calories, and gained more weight when the fat source was emulsified corn oil rather than pure corn oil or was vegetable shortening rather than corn oil. However, corn oil and shortening had similar effects on caloric intake and weight gain when presented as emulsified gels. Also, pure and emulsified-gel forms of shortening did not differ in their effects on caloric intake and weight gain. Supplementing the vegetable shortening with micronutrients, however, enhanced its hyperphagia-promoting effect. The results of two-choice tests revealed that the rats' preferences for the orosensory properties of the various fat sources did not account for the differential hyperphagias obtained. Rather, it appears that long-term fat selection and caloric intake are influenced primarily by postingestive factors. Fat selection and total intake were determined not only by the fat source itself, but also by the other diet options. That is, rats selected more fat and consumed more calories when chow was the alternative food than when separate sources of carbohydrate and protein were available.     

Fat substitutes promote weight gain in rats consuming high-fat diets

The use of food products designed to mimic the sensory properties of sweet and fat while providing fewer calories has been promoted as a method for reducing food intake and body weight. However, such products may interfere with a learned relationship between the sensory properties of food and the caloric consequences of consuming those foods. In the present experiment, we examined whether use of the fat substitute, olestra, affect energy balance by comparing the effects of consuming high-fat, high-calorie potato chips to the effects of consuming potato chips that sometimes signaled high calories (using high-fat potato chips) and that sometimes signaled lower calories (using nonfat potato chips manufactured with the fat substitute olestra). Food intake, body weight gain and adiposity were greater for rats that consumed both the high-calorie chips and the low-calorie chips with olestra compared to rats that consumed consuming only the high-calorie chips, but only if animals were also consuming a chow diet that was high in fat and calories. However, rats previously exposed to both the high- and low-calorie chips exhibited increased body weight gain, food intake and adiposity when they were subsequently provided with a high fat, high calorie chow diet suggesting that experience with the chips containing olestra affected the ability to predict high calories based on the sensory properties of fat. These results extend the generality of previous findings that interfering with a predictive relationship between sensory properties of foods and calories may contribute to dysregulation of energy balance, overweight and obesity.     

Deafferentation affects short-term but not long-term control of food intake

Deafferentation affects short-term but not long-term control of food intake (PHYSIOL BEHAV XX(X) 000-000, 2005). Rats were treated neonatally with capsaicin (CAP) to investigate the involvement of vagal afferents in food intake control and body weight regulation. In the first set of experiments, rats were offered increasing concentrations of sucrose (10-15-20-40%) in short-term feeding tests of 1 h. At the end, 10% was offered again to see whether CAP rats modified their intake after repeated exposure to different concentrations of sucrose solution. Results demonstrated that CAP animals overconsume persistently compared to vehicle (VEH) controls. This overconsumption is most pronounced and variable at 10% trials. Hypertonic 40% sucrose solution resulted in a small but significant drop in intake in CAP rats. Overall, if the concentration of sucrose solution is more than 10%, sucrose ingestion of CAP and VEH rats does not depend on the concentration of sucrose solution and remains relatively constant during all trials. In another experiment, rats were exposed to a high-fat condensed milk suspension (CMS) for 5 days. CAP rats initially overconsumed from this CMS compared to VEH. This was accompanied by a decreased intake in chow. However, over the 5 day period CAP animals adjusted their CMS and chow intake to control levels. During both experiments there were no differences in body weight gain between CAP and VEH. Together, these results suggest that capsaicin-sensitive vagal C-fibers are involved in the control of volume ingestion and short-term food intake control but are not required for long-term control of energy intake.     

The effect of liver denervation on the consumption of various diets by rats

Liver afferents have been proposed to influence food intake control, however, previous studies have shown that chow (pellet) intake is apparently not altered in total liver denervated rats. The present study explored whether total liver denervation could alter the rats' intake of various diets other than chow pellets. Total liver denervations were verified using staining histological and monoamine histofluorescence techniques. The denervated and sham operated rats were given short-term (4-6 days) exposure to four diets: (diet 1, chow plus a 32% w/v sucrose-water solution; diet 2, 1:1 mixture of powdered chow and granular glucose; diet 3, 33% w/w Crisco and powdered chow mixture and diet 4, a 5% w/v glucose-water solution plus chow. Body weight gains were not affected-by either surgery or diet exposure. Daily consumptions of the diets were similar in both groups, nevertheless, there was a trend for the denervated rats to consume slightly more of a high fat diet, which lends support for one hypothesized liver satiety mechanism. Also, the denervated rats consumed less (an average 5 kcal/day) of the 5% glucose solution (one hypothesis tested would predict an increase consumption of glucose by the denervated rats). Thus the liver may play a role, albeit small, through several ill defined mechanism(s) in the regulation of feeding.     

Dietary self-selection vs. complete diet: body weight gain and meal pattern in rats.

Food intake and body weight gain of male adult Wistar rats were examined in two groups of animals. One group (n = 14) was allowed to select its diet from separate sources of protein (casein, 3.1 kcal/g), fat (lard and sunflower oil, 7.9 kcal/g) and carbohydrate (CHO, starch and sucrose, 3.3 kcal/g). Another group (n = 10) received a nutritionally complete diet (3.3 kcal/g). After 2 weeks of adaptation to the diets, body weights and meal patterns were recorded for at least 4 days. The total caloric intake was nearly identical for the two groups of rats. Rats given dietary choice gained less weight over 4 days than rats fed chow and showed reduced feed efficiency. During the 24-h period, self-selecting rats consumed 20.8% of calories as proteins, 21% as fats and 58.2% as CHO. Self-selecting rats ate significantly less calories during the day than did rats given chow. The chow diet consisting of 17.3% calories as protein, 7.6% as fat and 75.1% as CHO. When comparing the self-selecting group nutrient intakes to those of chow-fed group it was observed that 24-h protein calorie intakes were identical in both groups. Fat intake was significantly higher and CHO reduced as compared to chow-fed rats. During the day, CHO intake was higher in self-selecting rats, and fat intake was not significantly reduced. During the night, protein and fat intakes were significantly higher in self-selecting rats, while CHO intake was significantly decreased, particularly in the last periods of the night.(ABSTRACT TRUNCATED AT 250 WORDS)     

Individual effects of estradiol and progesterone on food intake and body weight in ovariectomized binge rats

The individual roles of estradiol (E) and progesterone (P) in the control of food intake and body weight in ovariectomized (OVX) rats were investigated. Six groups of OVX Sprague-Dawley rats (n = 9/group) were assigned to one of three 4-day cyclic hormone treatments: two groups were treated with E benzoate; two groups were treated with P; two groups were treated with both (EP). All rats had continuous access to chow and water throughout this 4-week study. One group of rats within each hormone treatment condition was fed chow ad libitum, and the second was subjected to a binge schedule: chow ad libitum plus 1-h access to an optional fat source on Monday, Wednesday, and Friday. A seventh OVX group (n = 8) received the oil vehicle and chow. This group was included to monitor body weight and to verify hormone efficacy. The main findings were: (1) relative to rats receiving only P, E alone or EP attenuated 24-h chow intake tonically and cyclically, i.e. intake on Day 4, which models estrus, was lower in E and EP than in P, and also was lower than intake on Day 2, which models diestrus. In contrast, (2) neither E nor EP detectably affected optional fat intake during the 1-h fat access period relative to rats receiving only P when data were collapsed across the entire study. However, (3) E and EP had large effects on fat intake relative to P during the 1-h fat access period at the start of the study, but not at the end, when bingeing was fully established. (4) E and EP led to lower and apparently normal levels of body weight compared to rats receiving only the oil vehicle or only P. These results indicate that (1) administration of E alone has similar effects as co-administration of E and P on feeding and body weight in rats bingeing on fat, (2) with or without P, the inhibitory effects of E on meal size are compromised when bingeing on fat, and (3) the effects of E on binge size change dynamically as bingeing develops.     

Preference for high carbohydrate over various high fat diets by diabetic rats

Streptozotocin-diabetic male rats were hyperphagic relative to nondiabetic controls when offered only high carbohydrate (CHO) laboratory chow. Diabetics and controls ate about the same amount of high fat diets made from 67% w/w chow and 33% either coconut oil (saturated) or safflower oil (unsaturated). However, when offered a simultaneous choice of high fat diets and chow, nondiabetics and low dose (35 mg/kg) streptozotocin-diabetics showed a preference for the high fat diet: in contrast the high dose (65 mg/kg) streptozotocin diabetics developed a preference for chow. When pairs of isocaloric synthetic diets were offered, diabetics again preferred low fat/high CHO to high fat/low CHO diets, but the actual intake of fat was not constant across different diet pairs. Nondiabetics also selected away from the high fat diets in these synthetic diet pairs, even when saccharin was added to the high fat diet in an attempt to equate its sweetness with that of the paired low fat-high CHO diet. Plasma ketone levels of diabetics during obligatory high fat diet consumption were negatively correlated with their subsequent preference for the fat diet over simultaneously-offered chow. These data show that strong dietary preferences do not develop for fat in diabetics and suggest that high fat diets do not have net beneficial postingestional effects in these rats.     

Somatic and metabolic responses of mature female rats with dietary obesity to dorsomedial hypothalamic lesions: Effects of diet palatability

Caloric intake, body weight, obesity status (Lee Index) and incorporation of U-14 C-glucose into liver and retroperitoneal fat pad glycogen and lipid were studied in mature female rats that had received bilateral lesions or sham-operations in the dorsomedial hypothalamic nuclei (DMN) after dietary obesity was well established. Their diet consisted of a high-fat-sucrose chow mix, chocolate chip cookies and a drinking fluid of 32% sucrose in tap water. Comparable groups of DMN lesioned rats (DMNL rats) and sham-operated controls were maintained on lab chow pellets and tap water. Prior to the hypothalamic operation, the animals on the high-caloric regimen consumed significantly more calories than the rats on lab chow and also attained commensurately higher body weights and obesity indices. The bulk of the calories consumed during this time was derived from the cookies. Following DMNL, the animals maintained on lab chow became hypophagic and had lower body weights than the sham-operated rats, as has been previously reported. In rats on the high-caloric regimen, DMNL resulted in hyperphagia in comparison to all other groups. The greatest percentage of the calories during this time was derived from the high-fat-sucrose chow mix and sugar water. Correspondingly, DMNL rats on the high-caloric regimen had higher body weights and obesity indices than all other groups. At sacrifice, both a diet and lesion effect were noted in an elevated incorporation of U 14-C glucose in both fat pad and liver lipid and glycogen. The data are interpreted to mean that (1) when a highly palatable, high-caloric diet is available, DMNL do not exert their usual hypophagic and weight-lowering effects; (2) DMNL and control rats show excessive caloric intake when both groups are fed a highly palatable, high-caloric diet in comparison to their chow-fed counterparts. However, DMNL rats fed high-caloric diet also consume significantly more than controls fed this diet; (3) This excessive caloric intake of the DMNL rats possibly predisposes these animals to exaggerated lipogenesis in liver and adipose tissue; (4) the sham-operated controls on the high-caloric regimen also show greater lipogenesis but at a level intermediate between the chow-fed controls and the DMNL rats on the high-caloric diet.     

Differential Effects of High-carbohydrate and High-fat Diet Composition on Muscle Insulin Resistance in Rats

This study was conducted to evaluate whether the composition of carbohydrate or fat diet affects insulin resistance by measuring the muscle glucose transport rate. Both high-sucrose and high-starch diet with or without high-fat decreased insulin-stimulated glucose transport, but there were no significant differences among groups. Calorie intake in both high-sucrose and high-starch diet groups was higher than in chow group. The high-fat high-sucrose diet induced decrease in insulin-stimulated glucose transport was partially improved by supplement with fish oil. Calorie intake in high-fat high-sucrose and fish oil supplemented groups was higher than in chow group. The decreased insulin-stimulated glucose transport was accompanied by the increase in visceral fat mass, plasma triglyceride and insulin levels. These changes were improved by the supplement with fish oil. These results demonstrate that the composition of fat in diet is clearly instrumental in the induction of muscle insulin resistance. However, in high carbohydrate diet, it is likely that the amount of calorie intake may be a more important factor in causing insulin resistance than the composition of carbohydrate. Thus, the compositions of carbohydrate and fat in diet differentially affect on muscle insulin resistance.     

Effects of estradiol on food intake and meal patterns for diets that differ in flavor and fat content

Apart from the well known inhibitory effects of estradiol on food intake, meal size, and body weight in female rats that have been documented over the past thirty years, a more recent report presents the opposite finding; that a large dose of estradiol can increase food intake and weight gain in gonadally intact female rats presented with a palatable diet. The purpose of the present experiment was to further examine this hypothesis by evaluating the ability of estradiol to influence feeding behavior in ovariectomized rats presented with diets that differ in flavor and fat content. Female rats were given a cyclic regimen of estradiol benzoate treatment (5.0 or 20.0 µg) or the oil vehicle and were presented with the standard chow diet or a diet with a higher fat content and chocolate flavor. Food intake, meal size, and meal number were monitored three days after the first injection of estradiol or oil. Compared to the chow diet, food intake increased when animals had access to the chocolate/fat diet during the vehicle treatment condition. Both doses of estradiol significantly decreased food intake, meal size, and body weight gain when animals were presented with either the standard chow diet or the chocolate/fat diet. These findings indicate that estradiol does not stimulate the intake of a palatable diet in ovariectomized rats, and suggest that previous results showing that estradiol enhanced eating and weight gain stemmed from a disruption of the hypothalamic-pituitary-gonadal axis when intact females received a large dose of exogenous estradiol.     

Sucrose-induced hyperphagia and obesity in rats fed a macronutrient self-selection diet

Adult female rats were allowed to self-select their diet from separate sources of fat, protein, and carbohydrate (starch). Other rats were fed a composite diet that matched the nutrient composition chosen by the self-selecting rats (50% fat, 28% protein, 22% carbohydrate) or a low-fat, high-carbohydrate chow diet. Half of the rats in each diet condition were given access to a 32% sucrose solution for 30 days. Sucrose availability increased total caloric intake (approximately 20%) and body weight gain in all three groups compared to control groups not fed the sucrose solution. The selection animals compensated for their sucrose intake by reducing their fat intake, and to a lesser degree, their starch intake; protein intake was the least affected by sucrose availability. The selection rats consumed less sucrose than the chow-fed rats and displayed a smaller increase in weight, relative to controls, than the chow-fed rats. These differences were attributed to the high-fat intake of the selection animals since similar results were obtained with the rats fed the composite diet. In particular, both the selection and composite diets produced mild obesity in the absence of sucrose. The results demonstrate that sucrose-induced overeating and overweight is not an artifact of restraining the diet choices of rats to a pure sugar and a nutritionally complete diet.     

Food intake and blood fuels after oil consumption: differential effects in normal and diabetic rats

The mechanisms by which fat feeding suppresses the hyperphagia of diabetic rats were examined. Rats that were allowed to consume a small amount (1.5 ml) of corn oil decreased subsequent food intake within 6 hr after ingesting. Diabetic rats decreased food intake much more than normal rats. Similar results were obtained when oil was given intragastrically. Analysis of blood samples revealed that diabetic rats showed greater increases in plasma ketones and triglycerides and smaller increases in plasma glycerol than normal rats following consumption of 1.5 ml corn oil. This difference between diabetic and normal rats appeared when rats were allowed to eat after oil ingestion as well as when they were fasted. Brief periods of food deprivation (2.5-4.5 hr) substantially increased plasma ketones and glycerol and decreased plasma triglycerides in both diabetic and normal rats. The results indicate that diabetic rats decrease food intake more than normal rats after fat feeding because they oxidize more of the ingested fat.     

Differential effects of chow and purified diet on the consumption of sucrose solution and lard and the development of obesity

Obesity has been associated with increased consumption of sweetened beverages and a high-fat diet. We determined whether the composition of the dry pellet offered with liquid sucrose (LS) and lard influenced the development of obesity. We hypothesized that animals offered LS or LS and lard (choice), in addition to chow or purified low fat diet pellet (LFD; 10% fat), would gain more body fat than controls. We compared the effects of LFD vs. chow on voluntary consumption of LS and lard, serum triglyceride (TG), glucose, and body fat over 21 days. Male Sprague Dawley rats (n=10/group) were offered chow, chow+LS, chow choice, LFD, LFD+LS, LFD choice or solid high-sucrose diet (70% sucrose). Energy intakes of rats fed chow, LFD, and high-sucrose diets were similar. Energy intake was increased by 16% in chow+LS, 15% in LFD+LS, 11% in LFD choice, and 23% in chow choice rats. Chow choice rats consumed 142% more lard than LFD choice rats. Fasting glucose increased in all choice rats compared with the chow and high-sucrose diet rats. Fasting TG increased in LFD choice rats and were ~75% higher than those of chow, LFD, or high-sucrose rats. Chow choice had higher carcass fat than chow, chow+LS, and LFD groups however LFD choice was not different from their controls. Another experiment confirmed rats consumed 158% more lard when given chow choice compared to LFD choice. The diet offered to rats with free access to LS and lard influenced the development of obesity, sucrose and lard selection, and TG.     

Chronic stress, energy balance and adiposity in female rats

Stress preferentially increases the consumption of high fat foods in women, suggesting the interaction of these two factors may disproportionately predispose women toward excess weight gain. In the present study, female rats were exposed to a chronic high fat or chow diet and were exposed to 4 weeks of chronic variable stress (CVS) or served as home cage controls. Control females exposed to a high fat diet displayed many symptoms of the metabolic syndrome including increased body weight gain, total and visceral adiposity and insulin and leptin concentrations relative to all groups. However, CVS-high fat, CVS chow and control chow groups had similar body weight gain and caloric efficiency. This finding suggests that CVS increases energy expenditure much more in females exposed to a high fat diet relative to those fed a standard chow diet. The CVS-high fat group had increased adiposity and increased circulating leptin and insulin concentrations, despite the fact that their body weight did not differ from the controls. These results underscore the importance of assessing the degree of adiposity, rather than body weight alone, as an index of overall metabolic health. Overall, the data indicate that in female rats, chronic stress prevents high fat diet related increases in body weight, but does not prevent high fat diet induced increases in adiposity when compared to chow-fed females.     

Liquid diet preference in weanling rats with dorsomedial hypothalamic lesions

Two groups of weanling rats received bilateral electrolytic lesions in the ventromedial and dorsomedial hypothalamic nuclei, respectively. Sham-operated animals served as controls. During 14 days post-operation, the intake of standard laboratory chow was measured. The rats then received, in addition to laboratory chow and tap water, a sweet, eggnog-type liquid diet for 17 days, during 14 of which food intake from both diets was measured daily. The liquid diet was then withdrawn and for two weeks laboratory chow was again the sole source of calories. During the availability of the liquid diet, both groups of rats with hypothalamic lesions profoundly reduced their intake of laboratory chow but conspicuously increased their consumption of liquid diet. The rats with dorsomedial lesions consumed as much liquid diet as the controls, while on laboratory chow alone they were highly significantly hypophagic compared with the controls. During the availability of the liquid diet the rats with dorsomedial lesions also became obese, but after the return to a period in which laboratory chow was the sole source of calories they lost this extra fat while again being hypophagic.It is suggested that the hypophagia observed in rats lesioned in the dorsomedial hypothalamic nucleus is not due to a deficiency in caloric metering but rather, alternatively, to (a) aversion to dry food, (b) taste preference for a sweet, liquid diet, (c) a motivational deficit or (d) a motor deficit.     

Diverse basal and stress-related phenotypes of Sprague Dawley rats from three vendors

Based on observed phenotypic differences in growth and ACTH responses to stress in Sprague Dawley rats obtained from different vendors, we ran head-to-head comparisons on rats obtained from three different vendors, Harlan, Charles River, and Simonsen, with respect to baseline phenotypic differences and a metabolic feedback hypothesis of hypothalamo-pituitary-adrenal (HPA) regulation. Charles River and Harlan rats gained weight faster than Simonsen rats, but chow intake standardized for body weight was not increased, consistent with their greater caloric efficiency. Weight gain was inversely related with mean daily temperatures, without differences in activity levels. Half of the animals given lard and 32% sucrose solutions in addition to chow increased caloric intake and core temperature, decreased caloric efficiency, and increased fat depots, leptin, and in Simonsen rats, insulin. A 5-day regimen of once-daily 2-h restraint decreased feeding and caloric efficiency. Rats from two vendors with the availability of sucrose and lard, Charles River and Simonsen, showed blunted HPA responses to restraint compared to chow controls, whereas the Harlans exhibited no adrenocorticotropin (ACTH) response and an amplified adrenocortical response on the high-energy diet compared to chow controls. Substantial phenotypic differences exist between Sprague Dawley rats from different vendors with respect to metabolism and HPA function. The metabolic feedback hypothesis was supported in two of the three vendors' rats.     

Fat and sugar flavor preference and acceptance in C57BL/6J and 129 mice: experience attenuates strain differences

C57BL/6J (B6) mice display stronger preference and acceptance for various sweeteners than do 129 mice (129P3/J, 129X1/SvJ). The present experiment compared the preference of these strains for fat flavor as well as sweet taste using 24-h two-bottle preference tests. Fat flavor preference was evaluated using non-nutritive (olestra) and nutritive (Intralipid) oil emulsions. In initial oil vs. water tests olestra preference and intake were greater in B6 mice than 129 mice. Similar strain differences were obtained with low (0.313%-5%) but not high (10%-20%) Intralipid concentrations. When retested with Intralipid the B6 and 129 mice showed strong (>90%) preferences for the nutritive oil although B6 mice still consumed more oil at low concentrations. A second olestra test revealed increased oil preference and acceptance in B6 and 129X1/SvJ mice while 129P3/J mice still did not prefer olestra to water. Sweetener tests revealed stronger saccharin and sucrose preferences in B6 mice than in 129 mice. These strain differences in sweetener preference disappeared when the mice were retested with sucrose and saccharin. However, B6 mice continued to consume more saccharin and sucrose (at low concentrations) than did 129 mice. The profile of strain differences for non-nutritive and nutritive oils was similar to those observed for non-nutritive and nutritive sweeteners. The differential sweetener preferences of B6 and 129 mice is explained by differences in their sweet taste receptors but why the strains also differ in their initial fat flavor preference is not clear. The experientially-induced increases in oil and sweetener preferences displayed by the mice are attributed to the post-oral actions of Intralipid and sucrose. These findings along with intragastric infusion data suggest that B6 and 129 mice differ in their oral but not their post-oral response to fat and sugar.     

Review of the effects of dilution of dietary energy with olestra on energy intake

The non-absorbable substitute for dietary triacylglycerol, olestra, has been marketed in the United States for fifteen years. Olestra is comprised of sucrose with six to eight of its hydroxyl groups forming ester links with long-chain fatty acids. Because olestra is not hydrolyzed by fat-splitting enzymes in the small intestine, it is not absorbed from the small intestine into blood and tissues, and therefore provides no energy that can be utilized by the body. The hedonic properties of olestra with a specific fatty acid composition are similar to those of a triacylglycerol with the same fatty acid composition. Its use by consumers has been restricted by federal regulation to the commercial preparation of savory snack food items, principally as a frying medium for potato chips. An important question about the substitution of olestra for absorbable fat in the diet is whether the consumer will sense that a smaller amount of energy has been ingested. If it is sensed, thereby providing no satiation, then consuming additional energy in later meals will compensate for the removal of absorbable energy from the diet. If it is not sensed at all, then there is no compensation, and the person reduces caloric intake. This review first summarizes studies with olestra that have focused on its effect on the physiology of appetite. In general these studies have demonstrated that olestra does not influence signals of satiation including cholecystokinin and stomach emptying. The review then discusses studies of food consumption in experimental animals in which olestra was substituted for fat in the diet. Rodents have been repeatedly observed to compensate completely for the substitution of olestra for normal fat by eating more total diet. Most studies of the effect of olestra on human satiation have found incomplete or no compensation through additional energy consumption when olestra was substituted for dietary fat. In two clinical studies, however, complete compensation was observed, suggesting that experimental conditions and individual variability influence the ability to sense the substitution of olestra for absorbable fat. There is no evidence that dietary olestra causes consumption of more energy than would have been consumed without olestra in the diet. The data from animals and humans strongly suggest that the rodent is not a satisfactory model for the human in the determination of the extent of compensation by substitution of olestra for dietary fat.     

Ovarian hormones inhibit fat intake under binge-type conditions in ovariectomized rats

Binge eating is more common in females than in males. This study investigated the effects of ovarian hormones on binge-eating behavior in a diet-related rat model. Six groups of ovariectomized Sprague-Dawley rats were used (n = 13/group). All rats had continuous access to chow and water throughout the study. One half of the rats were injected every fourth day with estradiol benzoate (2 µg/100 µl sesame oil) and progesterone (500 µg/100 µl sesame oil); the other half received only the sesame oil vehicle. Three feeding protocols were tested in each hormone injection condition: (1) chow only: no additional dietary fat access; (2) low-restriction: 1-h fat access every day; (3) high-restriction: 1-h fat access on Monday, Wednesday, and Friday. As previously reported in intact male and female rats, the high-restriction groups exhibited binge-like increases in 1-h energy intake during fat access. The major new finding of this study is that 1-h energy intake was tonically, but not cyclically, reduced in the hormone-treated high-restriction (binge) rats. Specifically, both low- and high-restriction hormone-treated rats consumed significantly less energy than did the oil-treated rats during the 1-h fat period (p < 0.0001) and overall (p < 0.0001), indicating a tonic inhibition of eating. However, food intake during the 1-h fat access period was also cyclically reduced in the hormone-treated low-restriction rats, but not in the hormone-treated high-restriction rats. These results indicate that the normal cyclic inhibitory influence of ovarian hormones on eating, but not their normal tonic inhibitory influence, is disrupted by conditions leading to binge-type eating.