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.     

Effect of diet consistency, taste and calories on food intake of weanling rats with dorsomedial hypothalamic lesions

Male weanling Sprague-Dawley rats with dorsomedial hypothalamic lesions (DMNL rats) primarily destroying the dorosomedial hypothalamic nuclei (DMN) showed significant hypophagia on lab chow chunks compared to sham-operated controls. When given a choice between lab chow in the form of chunks or powder, both controls and DMNL rats ate similar amounts of lab chow powder while DMNL rats ate less lab chow chunks. Total caloric consumption was the same as on chunks alone. When returned to lab chow chunks as the only source of calories, the pattern and magnitude of intake was again depressed for the DMNL rats. When offered a choice between Ginger Snaps cookies in chunk form versus powder, DMNL rats remained hypophagic in terms of chunk consumption while the intake from powder was similar in both controls and DMNL rats. When offered a choice between chunks of lab chow and Ginger Snaps, DMNL rats were again hypophagic on lab chow chunks, ate the same as the controls of the cookies, and the total caloric intake was of the same magnitude and pattern as observed in previous tests. The data suggest, but do not conclusively show, that DMNL rats are not hypophagic because they have an aversion to chewing hard food and that, when offered a diet similar in hardness to lab chow chunks i.e., hard cookies, will prefer the less tasty but nutritionally complete lab chow. They are apparently capable of choosing a diet for complete nutrition and, as previously reported, can meter calories competently.     

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.     

Feed efficiency in growth-retarded rats with ventromedial and dorsomedial hypothalamic lesions produced shortly after weaning

Weanling male rats received electrolytic lesions (L) in the ventromedial (VMN) and dorsomedial (DMN) hypothalamic nuclei; sham-operated rats served as controls. The animals were maintained for various periods up to 50 postoperative days on lab chow under standard conditions. In a short-term study, food intake and body weights were measured daily and body weight gain was divided by the food eaten to obtain the efficiency of food utilization. Also, gains in metabolic size ($\text{kg}\text{3}\text{4}$) were divided by food eaten. Both manipulations showed that DMNL rats, except for the first two postoperative days, utilized food normally. The same changes were obtained for weanling VMNL rats, except that they did not show a decline in utilization during the first two postoperative days. Computation of efficiency of food utilization for both VMNL and DMNL rats over postoperative durations ranging from 7 to 50 days showed that among 12 out of 14 experiments DMNL rats utilized food as well as controls. Out of 8 experiments, rats with VMNL utilized food better for weight gained than controls in one and poorer than controls also in one experiment; in reference to metabolic size they utilized food normally. The foregoing data, gathered from 225 DMNL, 64 VMNL and 181 control rats show quite convincingly that food utilization in both types of experimental animals is unimpaired despite profound reductions in ponderal and linear growth and food intake in the DMNL rat and reduced circulating growth hormone levels in the VMNL rat.     

Long-term effects of insulin in weanling rats with dorsomedial hypothalamic hypophagia: Food intake,efficiency of food utilization,body weight and composition

Twenty-five day-old Sprague-Dawley rats received electrolytic lesions in the dorsomedial hypothalamic nuclei (DMNL rats); sham-operated rats served as controls. Two weeks after the operation the DMNL rats showed reduced (p<0.001) body weight and food intake but normal body composition (Lee Index) and efficiency of food utilization (EFU). During the following 32 days subcutaneous administration twice daily of intermediary-acting insulin in increasing doses (mean daily dose 2.64 IU/kg) caused highly significant increases in food intake in both groups. Injection for the subsequent 14 days of higher doses of insulin (mean daily dose 5.64 IU/kg) caused dramatic increase in both food intake and Lee Index and equalized the rate of weight gain with that of the controls. However, in absolute terms the DMNL rats remained consistently hypophagic and weighed significantly less than the controls. Both DMNL rats and controls showed the same EFU during both periods of insulin administration. On discontinuation of hormone treatment during the subsequent 20 days, food intake and body weight gains returned to pretreatment values and the insulin-induced increased Lee Index returned into the low-normal range. However, EFU was significantly (p<0.05) decreased during this period. At sacrifice, plasma glucose, glycerol, free fatty acids and total protein and carcass lipid and protein were normal in the DMNL rats. Absolute and relative (per 100 g body weight and per metabolic size) weight of epididymal fat pads, pituitaries, adrenals and kidneys were normal in the DMNL rats but testes weight per 100 g body weight was higher (p<0.05) in the DMNL rats. Although DMN lesions may remove some glucose-sensitive elements within the hypothalamus, the animals are still capable of responding to the food intake and weight-promoting properties of insulin, as do intact animals.     

Sex differences in the effects of voluntary activity on sucrose-induced obesity

Sedentary, adult rats of both sexes fed Purina chow and a 32% sucrose solution overate, gained excess weight and had higher Lee Indexes of obesity than control animals fed only Purina chow. The magnitude of these effects was similar in the males and females. Animals of both sexes fed the sucrose diet showed a slower rate of weight loss during food deprivation than the chow controls. Access to an activity wheel led to a reduction in caloric intake and the elimination of obesity in male rats. In the chow fed male rats activity led to a smaller, transient suppression in caloric intake and a slightly lower level of body weight than the sedentary chow controls. Access to activity did not affect body weight in the female rats in either dietary condition. Rather, both active groups of female rats appeared to compensate for the energy cost of voluntary activity by a small increase in food consumption. Long-term exposure to activity was associated with more rapid weight loss during food deprivation in both males and females. These data reveal that high levels of activity and obesity can co-exist when normal female rats are fed a palatable diet but that activity eliminates this form of obesity in the male rat.     

Somatic, metabolic and endocrine correlates of set point recovery in food-restricted and ad lib-fed weanling rats with dorsomedial hypothalamic lesions

Male Sprague-Dawley rats received either electrolytic lesions in the dorsomedial hypothalamic nuclei (DMNL rats) or sham-operations (CON), and were fed lab chow ad lib for 41 post-operative (POP) days. Subsequently one lesioned (DNML-AL) and one control group (CON-AL) continued to receive lab chow ad lib until the end of the experiment (POP day 78). A second lesioned (DMNL-RE) and control group (CON-RE) were given 80% of the amount of food eaten by their ad lib-fed counterparts for 28 days. At this time several rats from each group were killed. The remaining animals were then given lab chow ad lib for nine days and then also killed. Both DMNL-RE and CON-RE recovered their lowered body weight, food intake and feeding efficiency and showed the same pattern and relative magnitude as their ad lib-fed counterparts. Similarly, carcass lipid, epididymal fat pad lipid, incorporation of glucose-U-C14 into fat pad saponifiable lipid, total lipid, total glycogen (DPM/protein), liver protein, incorporation of glucose into liver CO2 and concentrations of plasma glucose, glycerol, triglycerides and free fatty acids normalized on refeeding to the same extent and in the same pattern in DMNL-RE as in CON-RE. In contrast to previous studies, plasma insulin was lower in DMNL-AL than in CON-AL but DMNL-RE and CON-RE had similar levels on refeeding. Also on refeeding, both DMNL-RE and CON-RE showed the same enhanced glucose incorporation into liver total lipid. The data show that DMNL rats, although smaller in size and hypophagic in absolute terms, recovered lost body weight--at least under our relative mild reduction of 80% of their ad lib-fed controls--with the same competence and in the same time interval as sham-operated controls. It is quite possible that a more severe restriction of body weight would have uncovered some deficits in DMNL rats, however. Under the constraints of the present experimental arrangement, the data strengthen previous evidence for the existence in DMNL rats of an "organismic" set point that makes for a "scaled-down" but homeostatically normal animal.     

The dorsomedial hypothalamic nucleus and its role in ingestive behavior and body weight regulation: lessons learned from lesioning studies

This review article discusses the well-established role of the dorsomedial hypothalamic nucleus (DMN) in feeding, drinking and body weight (BW) regulation. DMN lesions (L) in both weanling and mature rats of both sexes produce hypophagia, hypodipsia and reduced ponderal and linear growth in the presence of normal body composition. The growth reduction is not due to a deficient secretion of growth hormone, insulin-like growth factor-1, thyroxine, triiodothyronine or insulin. DMNL rats actively defend their lower BW (BW settling point) by becoming either hyper- or hypophagic, depending on the experimental manipulation, thereby defending both lean and fat mass. They also regulate their 24-h caloric intake, but they may overeat during the first hour of refeeding following a fast, possibly due to a reduced ability to monitor blood glucose or to respond to cholecystokinin (CCK). 2-Deoxy-D-glucose (2DG) increases c-fos expression in orexin-A neurons in the DMN, and DMNL eliminated the orexigenic effect of 2DG. DMNL rats on high-fat diets do not get as obese as controls, which may be due to a reduction of DMN neuropeptide Y (NPY). Rats lacking DMN CCK-A receptors are obese and have increased expression of NPY in the DMN, supporting earlier data that CCK may act at the DMN to suppress food intake. Excitotoxin studies showed that loss of DMN cell somata, and not fibers of passage, is important in the development of the DMNL syndrome. The DMN is a site where opioids increase food intake and knife-cut studies have shown that fibers traveling to/from the DMN are important in this response. An interaction of glucose and opioids in DMN may also be involved in the control of food intake. DMN knife cuts interrupting fibers in the posterior and ventral directions additively produce the hypophagia and reduced linear and ponderal growth observed after DMNL. Ventral cuts may interrupt important connections with the arcuate nucleus. Lateral and posterior DMN cuts additively produce the hypodipsic effect seen after DMNL, but DMNL rats respond normally to all water-regulatory challenges, i.e., the hypophagia is not due to a primary hypodipsia. The DMN has been shown to be involved in the rat's feeding response to an imbalanced amino acid diet. These data show the DMN has an important role in many processes that control both food intake and BW regulation.     

Prolonging lateral hypothalamic anorexia by tube-feeding

Male rats sustaining lateral hypothalamic (LH) lesions were anorexic for approximately one week following surgery. They then maintained their body weight at a reduced level (approximately 20% below controls) for the remainder of an 8-week postlesion period of observation. By tube-feeding another group of LH animals, their body weight was held at a control level for the first week postlesion. Following tube-feeding, these animals were anorexic for several weeks while their body weights declined to the same reduced level as that of the LH animals not tube-fed. For both groups of LH animals, achievement of a lowered weight level, rather than a time-dependent recovery process, appeared to underlie the return of food intake to levels sufficient for maintaining body weight. By impeding the loss of body weight, tube-feeding can thus prolong the duration of LH anorexia.     

Regulation of calorie intake in rats with rostral zona incerta lesions: effects of caloric density or palatability of the diet

Following an initial period of hypophagia, the body weights of rats with zona incerta lesions approached asymptotic levels that were significantly lower than those of controls although daily food intake was not reliably depressed. In spite of persisting deficits in feeding efficiency, the ad libitum food intake of the ZI-lesioned rats (relative to body weight) recovered to preoperative levels and was regulated accurately with respect to the caloric density of the diet. However, rats with ZI lesions were finicky eaters and did not maintain stable calorie intake when given unpalatable diets. The water intake of ZI-lesioned rats remained consistently below that of neurologically intact rats but was normal relative to their own food intake and lowered body weight.     

Aphagia and adipsia after kainic acid lesioning of the dorsomedial hypothalamic area

Unlike rats which have electrolytic dorsomedial hypothalamic area lesions and are hypophagic and hypodipsic, the rats of the present study with dorsomedial hypothalamic area, kainic acid lesions (KAL) were postoperatively aphagic and adipsic. Subsequently, KAL rats rejected chow or a high-fat diet but ate a 30% sucrose-chow diet. Similarly the KAL rats were adipsic but drank a 30% sucrose solution. Slowly most of the KAL rats began to eat chow and drink tap water but remained hypophagic and hypodipsic. When tested for glucoprivic-induced feeding using 2-deoxy-D-glucose (200 or 400 mg/kg) the KAL rats, in contrast to the sham-operated controls, did not increase their food intake. During water deprivation the recovered KAL rats that would drink tap water ate, and following it they responded with an adequate increase in water consumption. During food deprivation the KAL rats, whether eating chow or sucrose-chow diet, drank, and subsequently the normally hypophagic rats actually ate more than the controls. Although the growth rate (linear and ponderal) of KAL rats was reduced compared with that of the controls, their body composition by indirect measurement was normal. The present data indicate that most of the dorsomedial hypothalamic syndrome results from damage to DMHA neurons and not to fibers of passage.     

Disruption of diurnal feeding and weight gain cycles in weanling rats by ventromedial and dorsomedial hypothalamic lesions

At the age of 28 days, male Sprague-Dawley rats received bilateral electrolytic lesions in the ventromedial (VMN) and dorsomedial (DMN) hypothalamic nuclei, repectively. Sham-operated rats served as controls. Food intake and body weight gains were measured for 13 days at the beginning of the light period (0800–2000 hr) and prior to the start of the dark period (2000-0800 hr). Both types of hypothalamic lesions caused a disruption of the naturally occurring diurnal feeding and weight gaining cycles. In accordance with previous data, the VMN rats remained normophagic and made normal weight gains while DMN animals were hypophagic and gained weight subnormally; linear growth was reduced in both types of lesioned animals, but only the VMN rats became obese. The data suggest the existence in the medial hypothalamus of an area that is involved in feeding and weight gaining cycles. From the standpoint of overall-caloric intake, this area consists of two types of neuronal assemblies that differ fuctionally as profoundly as they are anatomically separate.     

Dorsomedial hypothalamic lesions at weaning and ovariectomy after maturity: Somatic and metabolic changes

Weanling Sprague-Dawley rats received lesions in the dorsomedial hypothalamic nuclei or sham operations. Analysis of variance revealed a significant lesion-induced depression of body weight (BW) and food intake (FI). After sexual maturity, bilateral ovariectomy (OVX) and/or sham-ovariectomy (S-OVX) were performed in each of the above groups. OVX produced a significant increase in BW in both lesioned and non-lesioned rats without changes in food intake. Following DMN lesions efficiency of food utilization (EFU) was greater than normal and OVX caused a further significant increase, irrespective of hypothalamic manipulation. DMN lesions, as previously shown, were followed by a reduction in linear growth; subsequent OVX exerted a growth-promoting effect in both DMN-lesioned and sham-lesioned rats. However, OVX did not alter plasma growth hormone or insulin levels. When calculated on the basis of per gram tissue protein, DMN lesions significantly diminshed the incorporation of glucose into lipids of diaphragm and fat pad, but not of liver. DMN lesions had no effect on the incorporation of glucose into glycogen of diaphragm, fat pad or liver. OVX did not produce significant changes in lipogenesis from glucose or incorporation of glucose into glycogen in either sham-lesioned OVX or DMN-lesioned OVX rats. The data support the concept that increased weight gain following OVX can be attributed to factors other than increased food intake. They also support previous findings that DMN lesions lower the BW “settling point” (i.e., both lean body mass and fat commensurately). The data also suggest that the DMNL rat is responsive to various manipulations—in this case OVX—of the adipose tissue mass “settling point”.     

Meal patterns of rats with dorsomedial hypothalamic nuclei lesions or sham operations

Rats with bilateral dorsomedial hypothalamic electrolytic lesions (DMNL rats) are hypophagic, hypodipsic and have reduced linear and ponderal growth when compared to sham operated controls (SCON). Nevertheless, previous studies have shown that DMNL rats eat and drink adequate amounts for their size and have normal body composition. In the present study we investigated meal parameters: meal size, and frequency (both light and dark period), total intake and meal size per metabolic size (body weight 0.75). Compared to SCON, DMNL rats at twelve days post surgery weighed less, were shorter, but had a normal body composition as determined by the Lee Index, and were hypophagic (grams eaten/day). The animals were placed into individual, self-contained feeding modules and given powdered chow. After familiarization to the modules, meal parameters were recorded continuously by a computer for an eight day period. While dark phase meal frequency did not differ significantly between groups, the lesioned rats took more meals during the light period. Over the eight-day measurement period DMNL rats were hypophagic compared to SCON in absolute terms. However, when total intake and meal size were normalized to metabolic size, these two parameters did not differ significantly between groups. Upon refeeding, after a one-day fast, the initial meal size of the normally hypophagic DMNL rats exceeded that of SCON. Rats with DMNL have previously been shown to have deficits in some hypothesized short-term food intake control mechanism (e.g., cholecystokinin, glucose sensing). Thus overeating by the lesioned rats after a fast could possibly result from a specific short term control deficit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Naloxone suppression of food and water intake and cholecystokinin reduction of feeding is attenuated in weanling rats with dorsomedial hypothalamic lesions

In Experiment 1, sham operated (SCON) and dorsomedial hypothalamic nuclei (DMN) lesioned (L) rats were given saline or naloxone (0.1, 1.0 or 2.0 mg/kg) just prior to the onset of the dark cycle, lights out. Compared to saline injections, naloxone at all doses suppressed the cumulative food intake of the SCON during the second and third hr of measurement. Naloxone was without significant effect on the food intake of DMNL rats. Similar results were obtained in Experiment 2, except that naloxone at 2.0 mg/kg significantly suppressed the DMNL rats' food intake by the fourth hr of measurement. Cumulative water intake of both groups was significantly suppressed by naloxone in both experiments but its effects appeared to be attenuated in the DMNL group. In a preliminary trial cholecystokinin octapeptide (3.0 and 6.0 micrograms/kg) given at the onset of the dark cycle significantly suppressed the food intake of the SCON group but had no significant effect on the DMNL rats. The possibility exists that the reduced food intake and lower body weight of DMNL rats may partially result from damage to an opioid system. The data also tentatively suggest that DMN may play a role in cholecystokinin-induced satiety.     

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)     

The effect of increased adiposity on food intake of juvenile rats

The regulation of feeding by body adiposity, as proposed by the lipostatic theory, has been well demonstrated in adult animals. However, mechanisms controlling long-term feeding in juvenile animals have not been well defined. In this study, increased adiposity was induced in young rats through oral gavage. Four-week-old rats were divided into three groups; ad lib feeding (100%-AL), tubefed 100% (100%-TF) or 150% (150%-TF) of ad lib intake. Animals were tube-fed these levels for one week. At the end of this period, one third of each group were killed and all remaining animals were returned to ad lib feeding for either 4 or 29 days later. During this recovery period, the 150%-TF group had significantly depressed food intakes for the first 4 days in comparison to the 100%-TF group. Afterwards, there were no significant differences between these two groups for the remainder of study. Overfeeding induced significant increases in total body fat in the 150%-TF group (24.8 grams) in comparison to the 100%-AL group (11.0 grams) and the 100%-TF group (14.0 grams). By day five of recovery, only the 150% group exhibited a significant loss of body fat. Total carcass protein and ash were not different between groups at any period. At day 29 of recovery, there were no treatment differences in carcass weight or fat content. Loss of body fat from the 150%-TF rats was associated with the decline in caloric intake. It appears that food intake is affected by relative adiposity during the dynamic phase of growth.     

Regulation of feeding behavior in the prepubertal female rat.

Responses to challenges of long-term regulation of feeding behavior were compared between adult and weanling female rats. Adulteration of a high fat diet with NaCl caused both adult and weanling rats to reduce their food intake, but neither group refused to eat. Food deprivation for 24 hr was followed by an increase in feeding for both adult and weanling animals during a period when food intake is normally very low. Continued limited food access to 2 hr during the light period was compensated for by an increase in the normal food intake for this period for both adult and young female rats. It was observed that both adult and weanling rats showed a marked preference for the more dilute glucose solution when given a choice. In addition, both groups maintained a constant caloric intake during presentation of the glucose solutions by adjusting their intake of a solid food source. In each challenge of long-term regulation of feeding behavior, the response of weanling animals was as good or superior to that shown by adults. It is concluded that weanling female rats regulate their feeding just as adults to maintain long-term energy balance. It was also observed that bilateral lesions placed in the ventromedial hypothalamus (VMH) at 21 days of age resulted in reduced daily food intake and retarded body weight gain. Furthermore, young rats with VMH lesions failed to respond to 24 hr of food deprivation or limited food access. These data suggest an important role for the VMH in the long-term regulation of feeding in young rats.     

Hyperactivity and obesity: The interaction of social isolation and cafeteria feeding

Rats were reared in social isolation or in social groups of 4 or 5 rats per cage from weaning and were fed either a lab chow diet or a diet of 4 palatable foods (cafeteria diet), in addition to the lab chow. The hyperactivity of isolation-reared rats appears to be a reactivity to novel environmental stimuli, since it was seen only in the 0.5 hr tests and not in the near 24 hr test. It was found that hyperactivity and increased body weight can develop within as few as 7 to 10 days in rats reared in isolation from weaning. Cafeteria feeding enhanced activity in isolation-reared rats, but suppressed it in group-reared rats. Isolation-reared rats fed a cafeteria diet had strong, stable preferences for their most preferred food over the 25 days of measurement. Rats reared in isolation had significantly different food preferences, as compared with rats reared in groups. Cafeteria fed rats had a significantly greater calorie intake and body weight than rats fed lab chow. On analysis, cafeteria fed rats had significantly greater carcass energy and an increased amount of parametrial white adipose tissue as compared with rats fed only lab chow. The interscapular brown adipose tissue (IBAT) weights of cafeteria fed rats were also greater. However, as there was no difference between the cafeteria and chow fed rats in the total amount of protein in the IBAT, it was concluded that the increased weight of the IBAT did not reflect a genuine hypertrophy of the tissue.     

Dietary obesity and exercise in young rats

Food intake, body weight, body composition, resting metabolic rate (RMR) and the thermic effect of food (TEF) were measured in young rats, some of which were fed a high energy (HE) diet and some of which were forced to swim daily. In general, high energy feeding as compared to chow feeding, resulted in higher food intake, higher body weight, higher body fat, and a slightly lower TEF. In many cases, however, the specific effects varied with the age and sex of the animals. Animals forced to swim weighed less; were leaner; and had higher RMR and TEF than sedentary animals. The effects of exercise on energy balance were greatest in males, while the effects of the high energy diet on energy balance were greatest in females. All HE-fed rats were switched to lab chow at 104 days of age. Body weights of sedentary HE-fed rats returned to control levels but those of exercised HE-fed rats did not. Both HE-fed groups remained fatter than chow-fed controls, even two months after the diet switch.