This Article  • Abstract  • PDF  • Send to a friend  • Save in My Folder  • Save to citation manager  • Permissions  Citing Articles  • Citation map  • Citing articles on HighWire  • Citing articles on ISI (34)  • Contact me when this article is cited  Related Content  • Related letters  • Similar articles in this journal  Topic Collections  • Aging/ Geriatrics  • Obesity  • Randomized Controlled Trial  • Alert me on articles by topic  Social Bookmarking   What's this?

A Randomized Controlled Trial

Nicholas P. Hays, PhD; Raymond D. Starling, PhD; Xiaolan Liu, MD; Dennis H. Sullivan, MD; Todd A. Trappe, PhD; James D. Fluckey, PhD; William J. Evans, PhD

Arch Intern Med. 2004;164:210-217.

ABSTRACT
Background  The efficacy of ad libitum low-fat diets in reducing body weight and fat in overweight and obese adults remains controversial.

Methods  We examined the effect of a 12-week low-fat, high–complex carbohydrate diet alone (HI-CHO) and in combination with aerobic exercise training (HI-CHO + EX) on body weight and composition in 34 individuals with impaired glucose tolerance (20 women and 14 men; mean ± SEM age, 66 ± 1 years). Participants were randomly assigned to a control diet (41% fat, 14% protein, 45% carbohydrates, and 7 g of fiber per 1000 kcal), a HI-CHO diet (18% fat, 19% protein, 63% carbohydrates, and 26 g of fiber per 1000 kcal), or a HI-CHO diet plus endurance exercise 4 d/wk, 45 min/d, at 80% peak oxygen consumption (HI-CHO + EX). Participants were provided 150% of estimated energy needs and were instructed to consume food ad libitum. Total food intake, body composition, resting metabolic rate, and substrate oxidation were measured.

Results  There was no significant difference in total food intake among the 3 groups and no change in energy intake over time. The HI-CHO + EX and HI-CHO groups lost more body weight (–4.8 ± 0.9 kg [P = .003] and –3.2 ± 1.2 kg [P = .02]) and a higher percentage of body fat (–3.5% ± 0.7% [P = .01] and –2.2% ± 1.2% [P = .049]) than controls (–0.1 ± 0.6 kg and 0.2% ± 0.6%). In addition, thigh fat area decreased in the HI-CHO (P = .003) and HI-CHO + EX (P<.001) groups compared with controls. High carbohydrate intake and weight loss did not result in a decreased resting metabolic rate or reduced fat oxidation.

Conclusion  A high-carbohydrate diet consumed ad libitum, with no attempt at energy restriction or change in energy intake, results in losses of body weight and body fat in older men and women.

INTRODUCTION

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

THE INCREASING PREVALENCE of obesity in the adult US population^1-2 and the profound morbidity risks associated with this condition^3-4 provide a compelling rationale for the development of effective strategies to promote weight loss. The relationship between obesity and energy intake from fat is strong in a broad representative sample of countries.⁵ Low-fat, high–complex carbohydrate (HI-CHO) diets have been extensively recommended to prevent obesity and promote weight loss in overweight individuals, based on evidence suggesting that these diets reduce total energy intake, increase satiation, and are metabolized with less energetic efficiency compared with high-fat diets.^6-8 The efficacy of high-carbohydrate diets administered ad libitum and with no overt attempt at energy restriction remains uncertain, however.

Short-term intervention studies^9-11 have demonstrated significant weight loss after the administration of hypocaloric diets under rigidly controlled laboratory conditions. Outpatient studies^12-14 in which participants were provided dietary goals but were allowed to consume a self-selected diet have provided similar results. Although some data suggest that reduced energy intake may be a more important mediator of weight loss than a change in macronutrient composition specifically,¹⁵ the results of nutrient utilization studies indicate that dietary fat is metabolized more efficiently than dietary carbohydrate^16-17 and that high-fat diets may promote greater energy intake because of their higher palatability and energy density.^{6, 18} Thus, HI-CHO diets have gained prominence as a popular dietary intervention strategy for weight loss.

There is considerable uncertainty, however, regarding the efficacy of HI-CHO diets administered ad libitum with no overt attempt at energy restriction.^19-20 A meta-analysis by Astrup et al¹⁹ of controlled ad libitum low-fat studies of 2 months' duration or longer indicated that dietary fat reduction of approximately 11% (as percentage energy intake) is generally associated with modest weight loss in overweight individuals. Recently, Poppitt et al²¹ demonstrated moderate weight loss in middle-aged overweight individuals after administration of a HI-CHO diet. However, it has been suggested that ad libitum low-fat diets are not effective in promoting clinically relevant weight loss in obese individuals (body mass index [calculated as weight in kilograms divided by the square of height in meters] >30),²² despite a lack of well-controlled studies examining this issue in an obese population.¹⁹

The importance of exercise training in body weight and fat reduction programs has been emphasized for many years; however, previous evidence²³ suggests that losses of body weight attributable to exercise tend to be minimal, with perhaps a greater effect on fat mass reduction and fat-free mass maintenance during weight loss. There is little information on whether the addition of an aerobic exercise training program contributes to differing patterns of appendicular adipose tissue loss compared with consumption of an ad libitum low-fat diet without exercise.

Recently, increasing attention has been directed toward a constellation of risk factors, including obesity and impaired glucose tolerance, that makes up a metabolic condition known as syndrome X or insulin-resistance syndrome.²⁴ The incidence of this syndrome in adults has been estimated to be 24%,²⁵ and the combination of obesity and impaired glucose tolerance likely plays an important role in the high prevalence of disability, morbidity, and mortality in older individuals.

The present study was designed to examine the effect of an ad libitum HI-CHO diet alone and in combination with an aerobic exercise training program (HI-CHO + EX) on body weight, body composition, and appendicular fat distribution in older individuals with impaired glucose tolerance. In this study, we measured actual energy and nutrient intake and hypothesized that ad libitum consumption of this diet would result in a negative fat balance compared with controls with no change in total energy intake. We further hypothesized greater weight losses in individuals also undergoing aerobic exercise training and that those undergoing exercise training would experience significantly greater losses of appendicular fat and maintenance of appendicular lean tissue compared with those consuming the HI-CHO diet alone.

METHODS

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

PARTICIPANTS AND SCREENING PROCEDURES

Thirty-six men and women aged 55 to 80 years were recruited from the central Arkansas area between July 1, 1999, and August 31, 2001, using newspaper advertisements. Participants were overweight, nonsmoking, sedentary (2 d/wk of structured physical activity), and weight stable (±5 kg) during the past 6 months. Individuals with a plasma glucose concentration of 140 to 200 mg/dL (7.8-11.1 mmol/L) 2 hours after consumption of a 75-g oral glucose load, and who were not taking any medication known to affect glucose metabolism, were eligible for study participation. Participants also completed a comprehensive medical screening that included a medical history, a physical examination, and routine blood and urine chemical analysis. Two individuals withdrew from the study for personal or health reasons, and the remaining 34 individuals were assigned to the control (n = 12), the HI-CHO (n = 11), or the HI-CHO + EX (n = 11) group (Figure 1). A stratified random allocation strategy (stratified on sex) was used to assign individuals to each intervention group. Each participant provided written informed consent before study participation, and the study procedures were in accord with the ethics standards of the Human Research Advisory Committee of the University of Arkansas for Medical Sciences and the Research and Development Committee of the Central Arkansas Veterans Healthcare System.

View larger version (44K): [in this window] [in a new window] Figure 1. Study flow diagram. OGTT indicates oral glucose tolerance test; HI-CHO, low-fat, high–complex carbohydrate diet; and HI-CHO + EX, low-fat, high–complex carbohydrate diet plus aerobic exercise.

Participants who passed the initial screening were asked to return to the Nutrition, Metabolism, and Exercise Laboratory at a later date to complete a progressive exercise test to exhaustion. Briefly, individuals cycled at a warm-up intensity (50 W for men and 25 W for women) for 3 minutes on a cycle ergometer (Excalibur Sport; Lode, Groningen, the Netherlands), followed by another 3 minutes at a slightly higher intensity (+25 W), with incremental increases (+25 W) in intensity every subsequent minute until volitional fatigue. Concentrations of expired oxygen and carbon dioxide were analyzed (models S-3A/I and CD-3A, respectively; AEI Technologies, Pittsburgh, Pa), and gas volume was measured using a dry-gas meter (Rayfield Equipment, Waitsfield, Vt). This test was used to screen enrolled individuals for ischemic heart disease and to determine maximal aerobic capacity and heart rate. At this time, participants also received instruction in the assessment of dietary intake using a food record booklet and a food scale accurate to 25 g. Reported habitual dietary intake was measured for each participant on 3 weekdays and 2 weekend days, and diet records were coded and analyzed using Nutritionist Five software (version 2.0; First DataBank Inc, San Bruno, Calif).

STUDY DESIGN AND INTERVENTIONS

The study was a 14-week randomized intervention trial. During the baseline testing period (week 1), each participant was provided an isoenergetic mixed diet (35% fat, 20% protein, and 45% carbohydrates) designed to maintain body weight and adjusted to each individual's predicted energy requirements using the Harris-Benedict equation.²⁶ Participants were instructed to consume only those foods provided by our metabolic kitchen and to consume the entire amount of food provided each day to standardize dietary intake during this measurement period.

After baseline measures, participants were given either the control or the HI-CHO diet for 12 weeks (a list of the foods provided for the control and the HI-CHO diets is available from the authors). For each participant, allocation to the intervention group was performed after completion of baseline testing. Diets were designed to provide 150% of predicted energy requirements, and participants were instructed to consume foods ad libitum for the duration of the study. Participants were informed that the kitchen would provide excess food and that they should eat as much or as little of the foods provided until they were no longer hungry. Diets consisted of usual foods and beverages, and a guar gum supplement (Benefiber; Novartis, Minneapolis, Minn) was added to several beverages of the HI-CHO diet to increase the fiber content of this diet. Meals were served according to a 3-day rotational menu and consisted of breakfast, lunch, dinner, and a snack. Participants reported to the dining facility each weekday morning to obtain packed food for the day, and food for weekend days was obtained each Friday for consumption at home. Participants were also instructed to return to the kitchen each day any food that had not been consumed along with the empty food containers, and food consumption was measured by subtracting the weight of unconsumed food from the recorded weight of provided food. Dietary intake was assessed in this fashion for 4 to 6 consecutive days at weeks 3, 7, and 13 of the study. Postintervention testing was performed during week 14, with participants continuing to consume their assigned diets ad libitum through the completion of testing procedures.

Participants who were randomized to the HI-CHO + EX group trained 4 d/wk during weeks 2 to 13 on a cycle ergometer (model 818E; Monarch, Varberg, Sweden). The exercise intensity was set at 80% to 85% of maximal heart rate (determined during the aerobic capacity test performed at screening), and the duration of each training session was 45 minutes. Each training session was supervised, and heart rate was continuously monitored (Vantage XL; Polar Electro, Woodbury, NY).

TESTING PROCEDURES

Fasting body weight, with participants wearing a hospital gown or other minimal clothing, was measured to the nearest 0.1 kg using an electronic scale (Ohaus Corp, Pine Brook, NJ). Standing height without shoes was measured using a wall-mounted stadiometer (Novel Instruments, Rockton, Ill). Height was measured at baseline, and weight measurements were obtained at baseline and at weeks 3, 5, 7, 9, 11, 13, and 14.

Total body density was estimated using air displacement plethysmography (BOD POD; Life Measurement Instruments, Concord, Calif). After calibration and explanation of the testing procedures, each participant entered the BOD POD while wearing a swimsuit and a bathing cap. Raw body volume was determined, and body density was calculated using this value, body weight, predicted thoracic gas volume, and calculated surface area artifact. Body density was measured in the fasting state in duplicate at baseline, week 7, and week 14, and the mean of each duplicate was used in subsequent analyses. Percentage of body fat was calculated from body density using the Siri equation.²⁷ Fat and fat-free masses were calculated from the body weight and percentage of body fat data.

A computed tomographic scan of the thigh was obtained at weeks 1 and 14 to assess muscle and adipose tissue cross-sectional area using a HiSpeed scanner (General Electric Medical Systems, Waukesha, Wis) at 120 kV (peak), 280 mA, a 512 x 512 matrix, and a scanning duration of 1 second. Participants rested supine for 1 hour before each scan to minimize muscle size changes due to posturally related fluid shifts.²⁸ A scout image was obtained to establish orientation of skeletal landmarks, and a single 10-mm slice was subsequently obtained at the midpoint between the right iliac crest and the patella of the dominant leg (with a scan of both legs simultaneously obtained). Digitized computed tomographic images were stored on magnetic tape and then transferred to a personal computer and analyzed using medical imaging software (SliceOmatic version 4.2; TomoVision, Montreal, Quebec). Muscle, adipose, and bone areas were determined by ranges of attenuation values (fat, –250 to –40 Hounsfield units; muscle, –25 to +145 Hounsfield units; and bone, >+150 Hounsfield units).

Resting energy expenditure was measured at weeks 1 and 14 by open circuit indirect calorimetry using the ventilated hood technique (Vmax 29N; Sensormedics, Yorba Linda, Calif). Measurements of oxygen consumption and carbon dioxide production were obtained under thermoneutral conditions in fasting individuals according to our usual protocol.²⁹ Reported physical activity was assessed at weeks 1 and 14 using the Yale Physical Activity Questionnaire.³⁰

One-way analysis of variance was used to examine differences in participant characteristics and dietary intake among groups at baseline and to assess whether changes in variables over time differed significantly among groups. For post hoc comparisons of means, a Student-Newman-Keuls adjustment was used to control overall type I error. In addition, a mixed 2-factor analysis of variance with interaction term (dietary group x time) was used to examine differences in dietary intake, body weight, body composition, physical activity, and resting energy expenditure variables among groups and changes in these variables over time. Change over time within each group was assessed if the group x time interaction term was significant at the P<.05 level. Statistical analyses were performed using statistical software (SPSS 11.0, SigmaStat 2.0; SPSS Inc, Chicago, Ill), and graphs were constructed using a spreadsheet program (Excel 97; Microsoft Corp, Redmond, Wash).

RESULTS

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

Participant characteristics for the control, HI-CHO, and HI-CHO + EX groups are given in Table 1. There were no significant differences in demographic characteristics among groups at baseline, and the proportion of men and women within each group was approximately equal. Blood glucose concentrations after an overnight fast and 2 hours after administration of an oral glucose load were also not significantly different among groups (data not shown).

View this table: [in this window] [in a new window] Table 1. Baseline Characteristics of 34 Individuals Who Completed the 14-Week Dietary Intervention*

Reported dietary energy and macronutrient intakes (expressed as a percentage of energy intake) of participants at baseline are given in Table 2. Differences in reported energy, protein, fat, carbohydrate, and fiber intakes among groups at baseline were not significant. Baseline dietary differences were also examined in the subset of participants (n = 26) classified as accurate dietary reporters (individuals were deemed to be accurate reporters if their reported energy intake was >1.2 times their resting metabolic rate), and results were similar (data not shown). For dietary intake during the study intervention (Table 3), the macronutrient composition of the diet consumed by the HI-CHO and HI-CHO + EX groups was significantly different (by design) from the diet consumed by controls (P<.001). Mean energy intake during the intervention did not significantly differ among groups (similar results were obtained when energy intake was expressed per kilogram of body weight). There were no significant time x group interactions for any variable, and although monounsaturated fat intake increased over time in all groups (time effect, P = .03), the change was minimal. These differences suggest that when instructed to consume food ad libitum, energy intake among participants was approximately equal, despite significant differences in macronutrient dietary composition. The apparent discrepancy between baseline energy intake and energy intake during the study intervention is most likely due to methodologic differences between the 2 intake assessment periods (ie, food record data at baseline and food weigh-back data during the intervention).

View this table: [in this window] [in a new window] Table 2. Reported 5-Day Energy and Macronutrient Intakes at Baseline*

View this table: [in this window] [in a new window] Table 3. Energy and Macronutrient Intake of Food Consumed at Weeks 2, 6, and 12 of the 12-Week Dietary Intervention*

Reported physical activity, aerobic capacity, and resting energy expenditure data are given in Table 4. Total physical activity at baseline and change in activity over time, as assessed using the Yale Physical Activity Questionnaire,³⁰ did not significantly differ among groups. However, individuals in the HI-CHO + EX group reported a significantly greater increase in vigorous activity score (P<.001) compared with the other 2 groups. A similar result was observed for peak oxygen consumption and exercise duration assessed during the maximal aerobic capacity test, with individuals in the HI-CHO + EX group demonstrating significant increases in these variables over time compared with the other 2 groups (P<.001). These results suggest that the exercise intervention in the HI-CHO + EX group was of sufficient intensity to promote increased cardiovascular fitness in these individuals and that individuals in the control and HI-CHO groups did not substantially alter their physical activity during the study.

View this table: [in this window] [in a new window] Table 4. Reported Physical Activity, Aerobic Capacity, and Resting Energy Expenditure at Baseline (Week 1) and Week 14*

Mean changes in body weight, body mass index, and percentage of body fat during the study intervention are shown in Figure 2. Changes over time were significantly different among groups (time x group interaction, P<.001 for body weight and body mass index analyses; interaction P = .01 for percentage of body fat analysis). When groups were analyzed separately, significant losses of body weight and body mass index were observed in the HI-CHO (week 1 to week 14 comparison, P<.001 for both analyses) and HI-CHO + EX (week 1 to week 14 comparison, P<.001 for both analyses) groups, with changes in the control group not significant during the 14-week period. Percentage of body fat also decreased significantly over time in the HI-CHO + EX (week 1 to week 14 comparison, P<.001) and HI-CHO (week 1 to week 14 comparison, P = .01) groups, but changes were not significant in the control group.

View larger version (50K): [in this window] [in a new window] Figure 2. Mean changes in body weight, body mass index (BMI), and percentage of body fat relative to baseline (week 1) in participants consuming the control diet; the low-fat, high–complex carbohydrate diet (HI-CHO); and the low-fat, high–complex carbohydrate diet plus aerobic exercise (HI-CHO + EX). The time x group interaction term was significant for all 3 outcome variables (P<.001, P<.001, and P= .01, respectively). *Significant decrease over time in this group (week 1 to week 14 comparison, P<.001). Significant decrease over time in this group (week 1 to week 14 comparison,P= .01). Error bars represent SEM.

Changes in fat and lean tissue cross-sectional areas in the thigh are shown in Figure 3. Thigh fat area in the HI-CHO and HI-CHO + EX groups significantly decreased compared with that of the control group (P = .008 and P<.001, respectively). Changes in thigh lean tissue area did not significantly differ among groups.

View larger version (14K): [in this window] [in a new window] Figure 3. Mean changes in the fat and lean tissue cross-sectional area at the thigh relative to baseline in participants consuming the control diet; the low-fat, high–complex carbohydrate diet (HI-CHO); and the low-fat, high–complex carbohydrate diet plus aerobic exercise (HI-CHO + EX). Differences among groups were significant for thigh fat area; bars with different superscript letters are significantly different. *P= .008. P<.001. Error bars represent SEM.

COMMENT

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

In this study, ad libitum consumption of a HI-CHO diet for 12 weeks, with no attempt at energy restriction, resulted in significant decreases in body weight. The addition of aerobic exercise training seemed to augment weight loss and loss of body fat. These data further show that body weight and percentage of body fat were reduced on this low-fat diet, even with no measurable decrease in total energy intake. Participants were informed that the purpose of the present study was to examine the effects of a heart healthy diet on general disease risk, and thus there was little overt motivation for participants to lose weight via voluntary energy restriction. The stable weight observed in individuals randomized to the control group suggests that weight loss did not occur owing to intentional energy restriction or because of reduced food intake attributable to boredom with the meals provided to participants. Bias in previous studies demonstrating weight loss with a reduction in fat intake may be present when individuals are informed that they are participating in a weight loss study.

These results are consistent with previous examinations of ad libitum high-carbohydrate diets and weight loss.^20-21,31-38 It has been previously reported that the magnitude of weight loss in longer-term studies^{21, 31-33,37} (6-12 months in duration) is relatively modest, with decreases in body weight 3 to 4 kg greater in dietary intervention groups than in controls. Schaefer and coworkers³⁶ also demonstrated that an ad libitum high-carbohydrate diet resulted in significant weight loss in men and women with chronic hyperlipidemia and that the amount of weight loss experienced by their participants was positively related to initial weight. Shorter-term studies^39-40 (2-3 weeks in duration) typically report smaller weight losses of approximately 1 kg or less. However, one shorter-term study,⁴¹ in which individuals were fed a very–low-fat (12% of energy), high–complex carbohydrate (77% of energy) diet ad libitum for 21 days, demonstrated a mean weight loss of 4.9 kg. Overall, previous studies indicate that ad libitum low-fat diets produce weight losses of approximately 1.6 g/d for each 1% reduction in energy supplied by dietary fat.⁴² According to this formula, we would expect weight losses of approximately 2.5 kg in our study, an amount slightly less than the actual loss observed.

The results of previous studies have been difficult to interpret because it has been unclear whether the weight loss observed was due to total energy restriction or to decreased fat intake. Dietary intervention studies in which individuals consume food ad libitum are, by definition, less fully controlled than studies that provide a fixed, low-calorie diet. Accurate fat and energy intake information is therefore difficult to obtain in individuals who are allowed to consume a self-selected diet while following general low-fat dietary guidelines or in participants who are provided a selection of foods from a laboratory-run grocery store system. One strength of this study is our ability to more accurately assess dietary intake through the use of food weigh-back measurements (ie, by subtracting the weight of food returned to the metabolic kitchen from the weight of food provided); our dietary intake data indicate that participants did not change total energy intake despite significant reductions in total fat. However, since the successful pattern of weight loss in the HI-CHO group cannot be explained by any differential in reported energy intake between this group and the control group, our data suggest either bias in this method of food intake assessment or the existence of metabolic differences attributable to dietary macronutrient composition differences among groups.

It has been suggested that high-carbohydrate diets may contribute, over time, to excess body fat storage owing to reduced fat oxidation and increased de novo lipogenesis.¹⁵ In contrast, the results of the present study support the hypothesis that fat balance is maintained not by total energy intake but by total fat intake.⁴³ Previous studies^44-45 have clearly demonstrated that overconsumption of carbohydrates does not result in lipogenesis to any great extent. The few studies^46-47 that have demonstrated a significant increase in lipogenesis have involved massive carbohydrate overfeeding in amounts that do not occur in daily life. Concerning the effect of a high-carbohydrate diet on substrate oxidation, we did not observe a significant increase in the respiratory exchange ratio during the dietary intervention in the present study. Hughes et al⁴⁸ previously demonstrated that a eucaloric high-carbohydrate diet resulted in a substantial increase in the rate of total body carbohydrate oxidation and a suppression of fat oxidation. It is possible that the suppression of fat oxidation did not occur as expected in the present study as a result of participants being in negative fat balance subsequent to consuming a low-fat diet. Further research is needed to examine the specific substrate oxidation and lipogenic responses to an ad libitum high-carbohydrate diet.

Exercise is known to result in increased fat oxidation. The results of the present study demonstrate that compared with the HI-CHO group, a trend toward greater loss of body weight and body fat was experienced in the HI-CHO + EX group, which is consistent with many previous studies.⁴⁹ It is unclear, however, whether aerobic exercise training enhances the effect of weight loss on metabolic risk factors such as insulin resistance. Hughes et al⁴⁸ reported that aerobic exercise without weight loss is ineffective in improving insulin sensitivity in older individuals. More recently, Janssen et al⁵⁰ reported that although weight loss was associated with an improved metabolic profile in premenopausal obese women, this improvement was not augmented by the addition of either aerobic or resistance exercise. These results are in contrast to findings in older men published by the same group.⁵¹ Further research is needed to examine the effect of exercise in combination with dietary-induced weight loss on the metabolic profile in older men and women.

Low-fat, high-carbohydrate diets may reduce body weight via reduced food intake, since complex carbohydrate–rich foods are more satiating and less energy dense than higher-fat foods.^{6, 52} Hughes et al⁴⁸ demonstrated that a similar high-carbohydrate diet fed to individuals to maintain body weight resulted in a slight decrease in weight along with a significant decline in the high-density lipoprotein concentration and a significant increase in circulating triacylglycerols. Despite being fed to maintain body weight, individuals complained that they were given too much food and were never hungry.

Recently, low-carbohydrate diets have become popular for individuals attempting to lose weight.⁵³ The proponents of these diets claim that because dietary carbohydrates stimulate insulin production, de novo lipogenesis results in positive fat balance. As described herein, however, little evidence exists to support this idea. Our data provide a potentially useful intervention for body weight and body fat loss. Hypocaloric diets often result in metabolic adaptations consistent with weight maintenance or even weight gain, such as a significant reduction in resting metabolic rate, although specific findings have been mixed.^54-55 The individuals consuming the HI-CHO diet in our study did not demonstrate a metabolic adjustment resulting in a decreased metabolic rate, possibly owing to our observation that energy intake was not compromised with the ad libitum diet. In addition, participants never complained of feeling hungry, an important consideration in the formulation of dietary strategies to promote weight loss and long-term maintenance of a healthy body weight. In conclusion, our data support the alteration of dietary macronutrient composition without emphasis on caloric restriction as an effective means of promoting weight loss in an older, at risk, population.

AUTHOR INFORMATION

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

Corresponding author and reprints: William J. Evans, PhD, Nutrition, Metabolism, and Exercise Laboratory, Donald W. Reynolds Department of Geriatrics, University of Arkansas for Medical Sciences, 4301 W Markham, Slot 806, Little Rock, AR 72205 (e-mail: evanswilliamj{at}uams.edu).

Accepted for publication February 24, 2003.

This study was supported in part by grants R01AG15385 (Dr Evans) and F32AG21374 (Dr Hays) from the National Institutes of Health, Bethesda, Md; the General Clinical Research Center (grant MO1RR14288 from the National Institutes of Health) at the University of Arkansas for Medical Sciences; and the facilities of the John L. McClellan Memorial Veterans Hospital, Little Rock.

This study was presented in part at Experimental Biology; April 21, 2002; New Orleans, La.

We thank Amanda Wells, MS, RD, for dietary planning and food intake assessments, Arlene Sullivan, APN-CS, for nursing support, Latasha Briscoe for assistance with data collection, and the staff of the General Clinical Research Center for expert study assistance.

From the Nutrition, Metabolism, and Exercise Laboratory, Donald W. Reynolds Department of Geriatrics, University of Arkansas for Medical Sciences and Central Arkansas Veterans Healthcare System, Little Rock. Dr Starling is now with Pfizer Global Research and Development, Groton, Conn. The authors have no relevant financial interest in this article.

REFERENCES

Jump to Section  • Top  • Introduction  • Methods  • Results  • Comment  • Author information  • References

1. Mokdad AH, Bowman BA, Ford ES, Vinicor F, Marks JS, Koplan JP. The continuing epidemics of obesity and diabetes in the United States. JAMA. 2001;286:1195-1200. 2. Mokdad AH, Serdula MK, Dietz WH, Bowman BA, Marks JS, Koplan JP. The spread of the obesity epidemic in the United States, 1991-1998. JAMA. 1999;282:1519-1522. FREE FULL TEXT 3. Hu FB, van Dam RM, Liu S. Diet and risk of type II diabetes: the role of types of fat and carbohydrate. Diabetologia. 2001;44:805-817. FULL TEXT | ISI | PUBMED 4. Must A, Spadano J, Coakley EH, Field AE, Colditz G, Dietz WH. The disease burden associated with overweight and obesity. JAMA. 1999;282:1523-1529. FREE FULL TEXT 5. Bray GA, Popkin BM. Dietary fat intake does affect obesity. Am J Clin Nutr. 1998;68:1157-1173. ABSTRACT 6. Yao M, Roberts SB. Dietary energy density and weight regulation. Nutr Rev. 2001;59:247-258. ISI | PUBMED 7. Lucas F, Sclafani A. Differential reinforcing and satiating effects of intragastric fat and carbohydrate infusions in rats. Physiol Behav. 1999;66:381-388. FULL TEXT | PUBMED 8. Stubbs RJ, Mazlan N, Whybrow S. Carbohydrates, appetite and feeding behavior in humans. J Nutr. 2001;131:2775S-2781S. FREE FULL TEXT 9. Piatti PM, Pontroli AE, Saibene A, et al. Insulin sensitivity and lipid levels in obese subjects after slimming diets with different complex and simple carbohydrate content. Int J Obes Relat Metab Disord. 1993;17:375-381. ISI | PUBMED 10. Rabast U, Vornberger KH, Ehl M. Loss of weight, sodium and water in obese persons consuming a high- or low-carbohydrate diet. Ann Nutr Metab. 1981;25:341-349. ISI | PUBMED 11. Lewis SB, Wallin JD, Kane JP, Gerich JE. Effect of diet composition on metabolic adaptations to hypocaloric nutrition: comparison of high carbohydrate and high fat isocaloric diets. Am J Clin Nutr. 1977;30:160-170. FREE FULL TEXT 12. Low CC, Grossman EB, Gumbiner B. Potentiation of effects of weight loss by monounsaturated fatty acids in obese NIDDM patients. Diabetes. 1996;45:569-575. ABSTRACT 13. Racette SB, Schoeller DA, Kushner RF, Neil KM, Herling-Iaffaldano K. Effects of aerobic exercise and dietary carbohydrate on energy expenditure and body composition during weight reduction in obese women. Am J Clin Nutr. 1995;61:486-494. FREE FULL TEXT 14. Powell JJ, Tucker L, Fisher AG, Wilcox K. The effects of different percentages of dietary fat intake, exercise, and calorie restriction on body composition and body weight in obese females. Am J Health Promot. 1994;8:442-448. PUBMED 15. Shah M, Garg A. High-fat and high-carbohydrate diets and energy balance. Diabetes Care. 1996;19:1142-1152. ABSTRACT 16. Hill JO, Peters JC, Reed GW, Schlundt DG, Sharp T, Greene HL. Nutrient balance in humans: effects of diet composition. Am J Clin Nutr. 1991;54:10-17. FREE FULL TEXT 17. Abbott WGH, Howard BV, Ruotolo G, Ravussin E. Energy expenditure in humans: effects of dietary fat and carbohydrate. Am J Physiol. 1990;258:E347-E351. 18. Stubbs RJ, Murgatroyd PR, Goldberg GR, Prentice AM. Carbohydrate balance and the regulation of day-to-day food intake in humans. Am J Clin Nutr. 1993;57:897-903. FREE FULL TEXT 19. Astrup A, Grunwald GK, Melanson EL, Saris WHM, Hill JO. The role of low-fat diets in body weight control: a meta-analysis of ad libitum dietary intervention studies. Int J Obes Relat Metab Disord. 2000;24:1545-1552. FULL TEXT | ISI | PUBMED 20. Saris WHM, Astrup A, Prentice AM, et al. Randomized controlled trial of changes in dietary carbohydrate/fat ratio and simple vs complex carbohydrates on body weight and blood lipids: the CARMEN study. Int J Obes Relat Metab Disord. 2000;24:1310-1318. FULL TEXT | ISI | PUBMED 21. Poppitt SD, Keogh GF, Prentice AM, et al. Long-term effects of ad libitum low-fat, high-carbohydrate diets on body weight and serum lipids in overweight subjects with metabolic syndrome. Am J Clin Nutr. 2002;75:11-20. FREE FULL TEXT 22. National Institutes of Health. Clinical Guidelines on the Identification, Evaluation, and Treatment of Overweight and Obesity in Adults: The Evidence Report. Obes Res. 1998;6:51S-209S. 23. Votruba SB, Horvitz MA, Schoeller DA. The role of exercise in the treatment of obesity. Nutrition. 2000;16:179-188. FULL TEXT | ISI | PUBMED 24. Reaven GM. Role of insulin resistance in human disease (syndrome X): an expanded definition. Annu Rev Med. 1993;44:121-131. FULL TEXT | ISI | PUBMED 25. Ford ES, Giles WH, Dietz WH. Prevalence of the metabolic syndrome among US adults: findings from the Third National Health and Nutrition Examination Survey. JAMA. 2002;287:356-359. FREE FULL TEXT 26. Harris JA, Benedict FG. A Biometric Study of Basal Metabolism in Man. Washington, DC: Carnegie Institute Publishers; 1919. 27. Siri WE. Body composition from fluid spaces and density: analysis of methods. In: Brozek J, Henschel A, eds. Techniques for Measuring Body Composition. Washington, DC: National Academy Press; 1961:223-244. 28. Berg HE, Tedner B, Tesch PA. Changes in lower limb muscle cross-sectional area and tissue fluid volume after transition from standing to supine. Acta Physiol Scand. 1993;148:379-385. ISI | PUBMED 29. Starling RD, Liu X, Sullivan DH. Influence of sibutramine on energy expenditure in African American women. Obes Res. 2001;9:251-256. ISI | PUBMED 30. DiPietro L, Caspersen CJ, Ostfeld AM, Nadel ER. A survey for assessing physical activity among older adults. Med Sci Sports Exerc. 1993;25:628-642. ISI | PUBMED 31. Kasim-Karakas SE, Almario RU, Mueller WM, Peerson J. Changes in plasma lipoproteins during low-fat, high-carbohydrate diets: effects of energy intake. Am J Clin Nutr. 2000;71:1439-1447. FREE FULL TEXT 32. Skov AR, Toubro S, Ronn B, Holm L, Astrup A. Randomized trial on protein vs carbohydrate in ad libitum fat reduced diet for the treatment of obesity. Int J Obes Relat Metab Disord. 1999;23:528-536. FULL TEXT | ISI | PUBMED 33. Pritchard JE, Nowson CA, Wark JD. A worksite program for overweight middle-aged men achieves lesser weight loss with exercise than with dietary change. J Am Diet Assoc. 1997;97:37-42. FULL TEXT | ISI | PUBMED 34. Siggaard R, Raben A, Astrup A. Weight loss during 12 week's ad libitum carbohydrate-rich diet in overweight and normal-weight subjects at a Danish work site. Obes Res. 1996;4:347-356. ISI | PUBMED 35. Raben A, Jensen ND, Marckmann P, Sandstrom B, Astrup A. Spontaneous weight loss during 11 weeks' ad libitum intake of a low fat/high fiber diet in young, normal weight subjects. Int J Obes Relat Metab Disord. 1995;19:916-923. ISI | PUBMED 36. Schaefer EJ, Lichtenstein AH, Lamon-Fava S, et al. Body weight and low-density lipoprotein cholesterol changes after consumption of a low-fat ad libitum diet. JAMA. 1995;274:1450-1455. FREE FULL TEXT 37. Shah M, McGovern P, French S, Baxter J. Comparison of a low-fat, ad libitum complex-carbohydrate diet with a low-energy diet in moderately obese women. Am J Clin Nutr. 1994;59:980-984. FREE FULL TEXT 38. Schlundt DG, Hill JO, Pope-Cordle J, Arnold D, Virts KL, Katahn M. Randomized evaluation of a low fat ad libitum carbohydrate diet for weight reduction. Int J Obes Relat Metab Disord. 1993;17:623-629. ISI | PUBMED 39. Marckmann P, Raben A, Astrup A. Ad libitum intake of low-fat diets rich in either starchy foods or sucrose: effects on blood lipids, factor VII coagulant activity, and fibrinogen. Metabolism. 2000;49:731-735. FULL TEXT | ISI | PUBMED 40. Stubbs RJ, Johnstone AM, Harbron CG, Reid C. Covert manipulation of energy density of high carbohydrate diets in "pseudo free-living" humans. Int J Obes Relat Metab Disord. 1998;22:885-892. FULL TEXT | ISI | PUBMED 41. Shintani TT, Beckham S, Brown AC, O'Connor HK. The Hawaii Diet: ad libitum high carbohydrate, low fat multi-cultural diet for the reduction of chronic disease risk factors: obesity, hypertension, hypercholesterolemia, and hyperglycemia. Hawaii Med J. 2001;60:69-73. PUBMED 42. Astrup A. Dietary approaches to reducing body weight. Baillieres Best Pract Res Clin Endocrinol Metab. 1999;13:109-120. FULL TEXT | PUBMED 43. Flatt JP. Dietary fat, carbohydrate balance, and weight maintenance. Nutr Rev. 1992;50:267-270. ISI | PUBMED 44. McDevitt RM, Bott SJ, Harding M, Coward WA, Bluck LJ, Prentice AM. De novo lipogenesis during controlled overfeeding with sucrose or glucose in lean and obese women. Am J Clin Nutr. 2001;74:737-746. FREE FULL TEXT 45. Hellerstein MK, Schwarz JM, Neese RA. Regulation of hepatic de novo lipogensis in humans. Annu Rev Nutr. 1996;16:523-557. ISI | PUBMED 46. Acheson KJ, Schutz Y, Bessard T, Anantharaman K, Flatt JP, Jequier E. Glycogen storage capacity and de novo lipogenesis during massive carbohydrate overfeeding in man. Am J Clin Nutr. 1988;48:240-247. FREE FULL TEXT 47. Pasquet P, Brigant L, Froment A, et al. Massive overfeeding and energy balance in men: the Guru Walla model. Am J Clin Nutr. 1992;56:483-490. FREE FULL TEXT 48. Hughes VA, Fiatarone MA, Fielding RA, Ferrara CM, Elahi D, Evans WJ. Long-term effects of a high-carbohydrate diet and exercise on insulin action in older subjects with impaired glucose tolerance. Am J Clin Nutr. 1995;62:426-433. FREE FULL TEXT 49. Miller WC, Koceja DM, Hamilton EJ. A meta-analysis of the past 25 years of weight loss research using diet, exercise or diet plus exercise intervention. Int J Obes Relat Metab Disord. 1997;21:941-947. FULL TEXT | ISI | PUBMED 50. Janssen I, Fortier A, Hudson R, Ross R. Effects of an energy-restrictive diet with or without exercise on abdominal fat, intermuscular fat, and metabolic risk factors in obese women. Diabetes Care. 2002;25:431-438. FREE FULL TEXT 51. Rice B, Janssen I, Hudson R, Ross R. Effects of aerobic or resistance exercise and/or diet on glucose tolerance and plasma insulin levels in obese men. Diabetes Care. 1999;22:684-691. FREE FULL TEXT 52. Howarth NC, Saltzman E, Roberts SB. Dietary fiber and weight regulation. Nutr Rev. 2001;59:129-139. ISI | PUBMED 53. Eisenstein J, Roberts SB, Dallal GE, Saltzman E. High-protein weight-loss diets: are they safe and do they work? a review of the experimental and epidemiologic data. Nutr Rev. 2002;60:189-200. FULL TEXT | ISI | PUBMED 54. Leibel RL, Rosenbaum M, Hirsch J. Changes in energy expenditure resulting from altered body weight. N Engl J Med. 1995;332:621-628. FREE FULL TEXT 55. Weinsier RL, Nagy TR, Hunter GR, Darnell BE, Hensrud DD, Weiss HL. Do adaptive changes in metabolic rate favor weight regain in weight-reduced individuals? an examination of the set-point theory. Am J Clin Nutr. 2000;72:1088-1094. FREE FULL TEXT

CiteULike    Connotea    Del.icio.us    Digg    Reddit    Technorati     What's this?

RELATED LETTERS

A Calorie by Any Name Is Still a Calorie
Prakash Seshadri
Arch Intern Med. 2004;164(15):1702-1703.
EXTRACT | FULL TEXT  

All Calories Are Not Equal
William J. Evans and Nicholas P. Hays
Arch Intern Med. 2005;165(9):1069.
EXTRACT | FULL TEXT  

THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES

Intake of fried foods is associated with obesity in the cohort of Spanish adults from the European Prospective Investigation into Cancer and Nutrition
Guallar-Castillon et al.
Am. J. Clin. Nutr. 2007;86:198-205.
ABSTRACT | FULL TEXT  

Eating behavior and weight change in healthy postmenopausal women: results of a 4-year longitudinal study.
Hays et al.
Journals of Gerontology Series A: Biological Sciences and Medical Sciences 2006;61:608-615.
ABSTRACT | FULL TEXT  

Effects of an ad libitum, high carbohydrate diet and aerobic exercise training on insulin action and muscle metabolism in older men and women.
Hays et al.
Journals of Gerontology Series A: Biological Sciences and Medical Sciences 2006;61:299-304.
ABSTRACT | FULL TEXT  

Effects of variation in protein and carbohydrate intake on body mass and composition during energy restriction: a meta-regression 1
Krieger et al.
Am. J. Clin. Nutr. 2006;83:260-274.
ABSTRACT | FULL TEXT  

All Calories Are Not Equal
Evans and Hays
Arch Intern Med 2005;165:1069-1069.
FULL TEXT  

A Calorie by Any Name Is Still a Calorie
Seshadri
Arch Intern Med 2004;164:1702-1703.
FULL TEXT