Prolonged fasting significantly changes nutrient oxidation and glucose tolerance after a normal mixed meal

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Prolonged fasting significantly changes nutrient oxidation and glucose tolerance after a normal mixed meal

Tracy J. Horton and James O. Hill

Center for Human Nutrition and Department of Pediatrics, University of Colorado Health Sciences Center, Denver, Colorado 80262

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The aim of this study was to establish the experimental paradigm of fasting, followed by refeeding, to investigate individualdifferences in nutrient partitioning. Eight nonobese men werefed a normal meal (25% of daily energy requirements) on two occasions,after an overnight (13-h) fast and after a prolonged (72-h) fast.During the entire fasting period, subjects were resident in awhole room indirect calorimeter, and blood samples were drawnperiodically. Because no other food was consumed over the 12 hafter either meal, negative energy balance was observed afterthe overnight and prolonged fast. Postprandial carbohydrate oxidationwas significantly reduced after the 72- vs. 13-h fast (P < 0.0001),whereas fat oxidation was significantly increased (P < 0.0001).Interestingly, carbohydrate balance was positive after the prolongedfast but negative after the overnight fast (24 ± 17 vs. $-$ 57 ±16 g/12 h, respectively; P < 0.001), whereas fat balance was negativeunder both conditions ( $-$ 78 ± 7 vs. $-$ 47 ± 8 g/12 h, respectively;P < 0.002). With 72 h of fasting, the glucose and insulin excursionsin response to the mixed meal were significantly greater comparedwith the 13-h fast (P < 0.001). In conclusion, prolonged fastingresulted in a significant decrease in carbohydrate oxidation andan increase in fat oxidation, after a normal mixed meal, in healthymen. This was associated with a significant decrease in glucosetolerance. Because circulating free fatty acids were greatly elevatedat all times after the prolonged fast, these may be mediatingsome of the changes in postprandialmetabolism.

nutrient balance

	INTRODUCTION

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UNDERSTANDING FACTORS THAT determine the balance between fat and carbohydrate oxidation can ultimately improve our understandingof the development of obesity. The energy status of an individualis one important factor that influences the partitioning of ingestedlipid and carbohydrate between oxidation and storage. This isrelevant because people regularly undergo periods of fasting followedby refeeding. The severity of fasting and the degree of refeedingcan vary enormously from day to day and between different individuals.How an individual responds to such changes in energy and nutrientstatus may have important long-term consequences with respectto the retention of bodyfat.

Our laboratory previously showed that with excess energy intake (overfeeding) ingested carbohydrate is preferentially oxidizedover ingested fat (17). This results in a significantly positivefat balance by virtue of the prioritization of carbohydrate foroxidation. Fasting represents the opposite extreme of overfeeding,where energy requirements are satisfied predominantly throughthe oxidation of endogenous fat stores (5, 28). Consumptionof a meal after a typical overnight fast results in a rapid transitionfrom predominantly fat oxidation to carbohydrate oxidation (13).Prolonged fasting represents an even greater perturbation in energystatus. Because glycogen stores are almost completely depletedwith extended fasting, there is an even greater dependence onthe oxidation of endogenous fat stores (5, 28). Interestingly,ingestion of glucose under these conditions results in a decreasein carbohydrate oxidation compared with an overnight fast (11).Whether this decrease in carbohydrate oxidation is also observedwith ingestion of a normal mixed meal after prolonged fastingis not known. This is relevant to our understanding of factorsdetermining nutrient partitioning and ultimately energybalance.

The circulating substrate and hormonal milieu can play a role in determining the partitioning of ingested nutrients betweenoxidation and storage. After a prolonged fast, there are significantchanges in many circulating parameters that could affect postprandialnutrient metabolism. Specifically, extended fasting results insignificant elevations in circulating free fatty acids (FFAs),glycerol, and ketone bodies with a fall in blood glucose (5,28, 41). Lipolytic hormones increase (norepinephrine, cortisol,and growth hormone) (28, 30, 41), while there is an increasein gluconeogenesis (5, 12) and a significant impairment ofinsulin's action on lipolysis (19, 39) and glucose metabolism(5, 11, 12). Imposing a refeeding meal on this metabolicenvironment may, therefore, result in a very different nutrientand hormone response relative to an overnight fast. This couldsubsequently affect the pattern of postprandial fuel oxidationand nutrientbalance.

The purpose of this study, therefore, was to characterize the changes in 1) nutrient oxidation and nutrient balance and 2)the circulating substrate and hormone environment in responseto refeeding a normal mixed meal after a 72-h fast vs. an overnightfast (13 h). This study was performed in a group of normal healthymen to establish the experimental paradigm and provide a dataset for future comparison to other populationgroups.

	METHODS

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Subjects

Eight male subjects, aged 20-40 yr, were recruited for the study. Subjects were excluded if they smoked; had a history ofdiabetes, cardiovascular disease, or other major health problems;had a body mass index of >27 kg/m²; and/or had percent body fat >27%. The study protocol was approvedby the University of Colorado Committee Institutional Review Boardfor the Protection of Human Subjects. All subjects read and signeda subject consent form before admission into the study. Subjectcharacteristics are shown in Table 1.

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Table 1. Subject characteristics

Preliminary assessments. BODY COMPOSITION. Body composition was determined by measuring body density using underwater weighing as previously described(18). Percent body fat was estimated from body density usingthe revised equation of Brozek et al. (4).

RESTING METABOLIC RATE. Resting metabolic rate (RMR) was measured using indirect calorimetry via a metabolic cart system (model 2900, Sensormedics,Yorba Linda, CA). Subjects were tested in the morning after a12-h fast. After 30 min of rest, a 15- to 20-min measurement ofmetabolic rate was made using a ventilated canopy. Gas concentrationswere measured in the air exiting the hood. O₂ consumption ( $V$ O₂)and CO₂ production were used to calculate metabolic rate (40).The RMR value was used to determine energy intake of subjectsduring the period of prestudy dietcontrol.

HEALTH AND PHYSICAL EXAMINATION. A health and physical examination was performed on subjects to confirm that there was no medical reason for their exclusionfrom thestudy.

INTRAVENOUS GLUCOSE TOLERANCE TEST . A frequently sampled intravenous glucose tolerance test (FSIGTT), using the tolbutamide protocol, was administered to subjectsafter an overnight fast (42). After baseline blood sampling,a glucose bolus was administered (0.3 g/kg body wt), followed20 min later by the tolbutamide bolus (100 mg). Twenty-seven bloodsamples were drawn over the next 3 h for measurement of glucoseand insulin concentrations. The FSIGTT gives both the insulinsensitivity index and glucose effectiveness as calculated fromthe MINIMOD computer program (29).

PRESTUDY DIET AND EXERCISE CONTROL. Subjects were fed a controlled diet for 5 days before the study. All food was prepared by the General Clinical Research Center(GCRC) diet kitchen at the University of Colorado Health SciencesCenter, and subjects were required to consume breakfast in theGCRC with other food prepared to take away. No other food waspermitted, and subjects were required to consume all the foodgiven. The only optional part of the diet was two food modules(840 kJ each), one or both of which the subjects could eat ifthey were hungry. The diet composition was 30% fat, 15% protein,and 55% carbohydrate, and initial energy intake was calculatedat 1.6 × RMR and adjusted, if necessary, to maintain a stablebody weight. Subjects were allowed to follow their usual activityroutine for the first 4 days of the diet, and on the last daythey refrained from plannedexercise.

Study period. Subjects spent the evening before the study in the GCRC and consumed their last meal by 2000. On the morning of the study,subjects were awakened at ~0700. An intravenous flexible catheter(18-20 gauge) was placed in a forearm vein and flushed with normalsaline. At ~0755, subjects emptied their bladder and then collectedall their urine for the remainder of the study. Subjects entereda whole room indirect calorimeter, located on the GCRC, at ~0800and remained resident for the next 84 h (3.5 days). Between 0700and 0800 each day, subjects exited the calorimeter and were allowedto shower but not to leave the GCRC. Calorimetry instrumentationwas recalibrated during this time. At 0900 of the first day [time(t) = 0 h; 13-h fasted], subjects received a breakfast meal composedof real food. The energy content of the meal was 25% of each subjectsnormal daily energy intake and averaged 3,150 ± 953 kJ. Nutrientcomposition was 15% protein, 54% carbohydrate, and 31% fat. Themeal was consumed within 15 min. No further food was consumedfor the next 72 h. Consumption of water was encouraged, and noncaloric,noncaffeinated beverages were permitted. Subjects occupied themselveswith sedentary pursuits during the calorimeter stay and performedspecified light walking and stepping activities in the afternoonand early evening. At 0900 of the fourth day (t = 72 h), subjectsreceived the same exact breakfast meal they consumed on the firstday. This was again consumed within 15 min. At 2300 that evening,subjects exited the calorimeter and the study wasended.

WHOLE ROOM INDIRECT CALORIMETER. This has been previously described in detail (37). The calorimeter allows continuous measurement of whole body $V$ O₂ andCO₂ expiration over the duration of stay. Accuracy of the differentialO₂ and CO₂ analyzers is verified by the combustion of propanegas. Propane tests are performed one to two times per month. Measurementof O₂ concentrations are accurate to within ±4%, and CO₂ measurementsare accurate to within ±3%.

Energy expenditure and the oxidation of carbohydrate and fat were calculated from respiratory gas exchange (20) from 0900to 2300 on days 1 and 4. The 1-h preprandial measurements (0800-0900)were excluded because this period allowed for equilibration ofthe room air in the calorimeter and stabilization of the CO₂ concentration.Respiratory gas calculations were made over the 12-h postprandialperiod (0900-2300). It was necessary to correct the total $V$ O₂over the 12 h for the accumulation of ketones (35). The accumulationof the most abundant ketone, $beta$ $-$ hydroxybutyrate ( $beta$ -HOB), in bloodand urine, was used to estimate the quantity of O₂ that was usedto generate ketones that were not subsequently oxidized (35).The corrected total $V$ O₂ values were then used in the calculationof energy expenditure and nutrient oxidation. Protein oxidationwas estimated from urinary nitrogen excretion measured over therespective calorimeter stay. Results of the indirect calorimetryover the duration of the entire study are not presented. Thispaper only includes indirect calorimetry measurements coincidingwith the monitoring of the systemic postprandialresponse.

The calorimeter has a port constructed in the wall that allows for drawing blood samples. This port is sealed on both theinner and outer sides of the calorimeter wall by detachable perspexplates connected by a screw post. In between the plates is a seriesof rubber iris ports. When the perspex plates are removed, theperson inside the calorimeter can put his forearm through therubber iris ports. The layering of these iris ports ensures minimalexchange of air between the calorimeter and theoutside.

DETERMINATION OF CIRCULATING HORMONE AND SUBSTRATE LEVELS. Blood was sampled immediately before the meal on the first day (t = 0 h) and then every hour up to 6 h postprandially. Subsequentsampling occurred every 12 h up to the refeeding meal on day 4.Blood samples were drawn every 1 h for the next 6 h and then immediatelybefore the subjects exited the calorimeter. Blood samples weredrawn from a forearm vein; therefore, the circulating measurementsrepresent both arterial concentrations and venous drainage fromthe local muscle bed. Approximately 7 ml whole blood were allowedto clot, and the serum was separated after spinning. Whole blood(2.5 ml) was added to 40 µl of preservative (3.6 mg EGTA plus2.4 mg glutathione in distilled water) for plasma catecholaminedeterminations. These samples were immediately placed on ice andspun. All plasma and serum samples were stored at $-$ 70^°C until analysis. Serum glucose was measured enzymatically, insinglecate, using the hexokinase method on an automated RocheCOBAS Mira Plus glucose analyzer [intra-assay coefficient of variation(CV) of 0.7%]. Enzymatic assays were used to determine serum glycerol(Boehringer Mannheim Diagnostics, Indianapolis, IN) and FFAs (WakoChemical USA, Richmond, VA) in singlecate (intra-assay CVs of7.8 and 1.2%, respectively) using the automated Roche COBAS MiraPlus analyzer. $beta$ -HOB (Sigma Diagnostics, St. Louis, MO) was measuredin duplicate with intra-assay CV of 10.8%. Catecholamines weredetermined in duplicate by radioenzymatic assay (intra-assay CVsof 16 and 8% for norepinephrine and epinephrine, respectively)(24). Radioimmunoassays were used to determine serum insulin(Kabi Pharmacia, Piscataway, NJ), cortisol (Diagnostic Products,Los Angeles, CA), and glucagon (Linco Research, St. Louis, MO).Samples were run in duplicate with intra-assay CVs of 10, 6.7,and 9.4%,respectively.

Data Analysis

Fasting blood parameters were compared after the 13- vs. 72-h fast, with a paired t-test. The pattern of the postprandialchange in blood variables was compared between the 2 days usinga repeated-measures analysis of variance with time and day (13-or 72-h fast) as grouping factors. For substrates and hormones,the incremental or decremental area under the curve (AUC) wascalculated and compared between meals using a paired t-test. Totalenergy expenditure, fat, carbohydrate and protein oxidation, andcorresponding balances were calculated over the 12-h postmealand compared between days using a paired t-test.

	RESULTS

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Body Weight

Subjects maintained a stable body weight during the period of diet control. Average weight change during this period was <2%of initial body weight (0.65 ± 0.26 kg). All subjects had a significantdecrease in body weight from day 1 to day 4 of the fast (averagechange $-$ 3.6 ± 0.5kg).

Energy Expenditure and Nutrient Oxidation

Energy expenditure was not significantly different over the 12-h postprandial period after the prolonged vs. overnight fast(5,792 ± 508 vs. 6,031 ± 462 kJ/12 h, respectively). Because thetest meal was the only food consumed during this time, energybalance was negative under both conditions ( $-$ 2,877 ± 483 vs. $-$ 3,079± 273 kJ/12 h, respectively). Nutrient oxidation and nutrientbalances are shown in Figs. 1 and 2, respectively. There was nodifference between the two periods in protein oxidation or proteinbalance. Carbohydrate oxidation after the 13-h fast plus mealwas significantly greater compared with after the 72-h fast (P< 0.001). Consequently, carbohydrate balance was significantlydifferent between the two conditions (P < 0.001), being negativewith the 13-h fast ( $-$ 57 ± 16 g) and positive after the 72-h fast(24 ± 17 g). Postprandial fat oxidation was significantly greaterafter the prolonged vs. overnight fast (P < 0.002). Fat balancewas negative under both conditions but more so after the 72-hfast plus meal than after the 13-h fast plus meal (P < 0.002; $-$ 78 ± 7 vs. $-$ 47 ± 8 g, respectively).

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Fig. 1. Postprandial nutrient oxidation calculated over the 12 h after consumption of the meal. A: protein oxidation. B: Carbohydrate oxidation. C: fat oxidation. # P < 0.001. * P < 0.002.

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Fig. 2. Postprandial nutrient balance calculated over the 12 h after consumption of the meal. Nutrient balance = meal nutrient intake $-$ nutrient oxidation. A: protein balance. B: carbohydrate balance. C: fat balance. # P < 0.001. * P < 0.002.

Circulating Hormone and Substrate Levels

Table 2 shows the circulating substrate and hormone concentrations after the 13- and 72-h fast. Premeal levels of glucoseand insulin were significantly reduced after the 72- fast vs.13-h fast, whereas FFA, glucagon, cortisol, norepinephrine, and $beta$ -HOB were significantly increased.

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Table 2. Circulating substrate and hormone concentrations before meal consumption

Postprandial substrate and insulin changes. After the same mixed meal, the glucose and insulin excursions were significantly greater with 72 vs. 13 h of fasting (Fig.3; incremental AUC, P < 0.001 for both insulin and glucose, Table3). In addition, the glucose-to-insulin ratio was significantlylower (P < 0.001) after the 72- vs. 13-h fast. As expected, therewas a significant decrease in both circulating FFA and glycerolconcentrations in response to meal consumption (Fig. 4). The postprandialdecremental AUC for FFA was significantly greater after the 72-fast vs. 13-h fast (Table 3; P < 0.01), whereas there was nosignificant difference in the decremental AUC for glycerol. Althoughthe absolute postprandial concentrations of FFA fell after themeal after the 72-h fast, the absolute concentrations remainedelevated for the entire period, relative to the 13-h fast. Thepattern of change in $beta$ -HOB, and differences between days, paralleledthe changes in circulating FFAs, being elevated postprandiallyafter the 72- vs. 13-h fast (Fig. 4)

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Fig. 3. A: postprandial changes in circulating glucose. There was significant effect of time (P < 0.0001), day (P < 0.009), and day-by-time interaction (P < 0.0001). B: postprandial changes in circulating insulin. There was significant effect of time (P < 0.0009), day (P < 0.0001), and day-by-time interaction (P < 0.0002). C: postprandial changes in the circulating glucose-to-insulin ratio. There was significant effect of time (P < 0.03), day (P < 0.0001), and day-by-time interaction (P < 0.0002).

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Table 3. Postprandial area under the curve for circulating substrate and hormones

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Fig. 4. A: postprandial changes in circulating free fatty acids. There was significant effect of time (P < 0.001), day (P < 0.0001), and day-by-time interaction (P < 0.0001). B: postprandial changes in circulating glycerol. There was significant effect of day (P < 0.0001). C: postprandial changes in blood $beta$ -hydroxybutyrate. There was significant effect of time (P < 0.01), day (P < 0.0001), and day-by-time interaction (P < 0.0001).

Postprandial hormone changes. The elevated glucagon, cortisol, and norepinephrine, after 72 h of fasting, decreased postprandially (Figs. 5 and 6). Thiscontrasted to the postprandial changes after 13 h of fasting wherethere was little change in cortisol and norepinephrine. Glucagondeclined and then increased with the prolonged fast, whereas theopposite was observed after the overnight fast. The insulin-to-glucagonratio (Fig. 5) increased significantly more after the meal afterthe 72-h fast compared with the 13-h fast. Although epinephrinelevels were higher, both pre- and postprandially after the prolongedvs. overnight fast, results were not significantly different betweenthe two measurements (Fig. 6) because of the high variabilityin concentrations.

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Fig. 5. A: postprandial changes in circulating glucagon. There was significant effect of time (P < 0.03) and day-by-time interaction (P < 0.0001). B: postprandial changes in the insulin-to-glucagon ratio. There was significant effect of time (P < 0.001), day (P < 0.0001), and day-by-time interaction (P < 0.0002).

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Fig. 6. A: postprandial changes in cortisol. There was significant effect of day (P < 0.01). B: postprandial changes in norepinephrine. There was significant effect of time (P < 0.0009), day (P < 0.0001), and day-by-time interaction (P < 0.0002). C: postprandial changes in epinephrine (nonsignificant differences).

	DISCUSSION

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This study demonstrated that both the nutrient balance and the substrate and hormone response to a normal mixed meal are profoundlyaffected by the duration of fasting. Compared with an overnightfast, 72 h of fasting resulted in a significant reduction in postprandialcarbohydrate oxidation but a significant increase in fat oxidation.Despite a similar degree of negative energy balance, over the12 h after each meal, carbohydrate balance was positive afterthe 72-h fast compared with negative after the 13-h fast. In addition,the prolonged fast resulted in a profound elevation in the postprandialglucose and insulin responses. This demonstrated that subjectshad become glucose intolerant and suggested a decrease in insulinaction.

It appears that the extent to which ingested carbohydrate promotes its own oxidation is partly dependent on the energy statusof an individual. In contrast to what is observed with overfeeding(17), or with individuals who have been in energy balance (13,34), prolonged fasting resulted in a decreased total carbohydrateoxidation after a normal mixed meal. It is unlikely that the reducedcarbohydrate oxidation after the 72-h fast was due to a decreasein the oxidation of endogenous carbohydrate, because glycogenolysisand gluconeogenesis would have been depressed. Our present observationsare supported by data from measurements after an oral glucosetolerance test (OGTT) where tracer-determined exogenous glucoseoxidation was shown to be significantly decreased after extendedfasting (11). Because energy expenditure and protein oxidationwere not significantly reduced during the 12-h postprandial measurementafter the prolonged fast, this meant that fat oxidation compensatedfor the decrease in carbohydrate oxidation. Whether ingested fatcan promote its own oxidation under conditions of extended fastingcould not be determined because we had no direct measure of theproportion of the total fat oxidized derived from exogenous vs.endogenous sources. Nevertheless, the consequence of maintaininga high rate of postprandial lipid oxidation after the 72-h fastwas the sparing of ingested carbohydrate. This meal-derived carbohydratemust therefore have been disposed of nonoxidatively and suggestsincreased direct glycogen storage and/or increased Cori cycling.Indeed, in humans (11), dogs (14), and rats (16), extendedfasting has been shown to increase hepatic glycogen storage aftera glucose load. Muscle glycogen may also be increased when carbohydrateis refed (26). A decrease in oxidative but not nonoxidativeglucose disposal after extended fasting (23) would preserveglucose and possibly increase glucose stores in the event thatfurther nutrient ingestion did not occur. How long it takes, withresumption of a regular meal pattern, for the metabolic responseto a meal to be normalized would be ofinterest.

Factors responsible for the different pattern of postprandial lipid and carbohydrate oxidation after the prolonged fast vs.overnight fast likely relate to differences in the circulatingsubstrate and hormonal milieu and the metabolic environment inoxidative tissues. Significantly elevated circulating FFAs wereobserved both before and after the mixed meal after the 72- vs.13-h fast. This suggests increased oxidation of endogenous FFAsbefore, and possibly after, the meal. Under conditions of elevatedinsulin, for example, during a euglycemic clamp (2, 33) orduring an OGTT (22), it has been observed that acutely increasingcirculating FFAs significantly decrease whole body carbohydrateoxidation. The elevated FFAs after a prolonged fast and preexistinghigh rates of lipid oxidation in tissues may therefore promotehigh rates of postprandial lipid oxidation and thus decrease theneed for carbohydrate to be used as a fuel. Effectively, thisrepresents the glucose-fatty acid cycle as first proposed by Randleet al. (32). In the context of the preceding metabolic state,conservation of carbohydrate would seem a priority with refeedingafter prolonged fasting. Increased FFA oxidation may thereforefacilitate glycogen storage. This is supported by data under hyperinsulinemic-euglycemicclamp conditions where acutely elevating FFAs had no effect onnonoxidative glucose disposal (2), whereas glycolysis was decreased(21).

One of the other significant observations made in this study was the dramatically elevated postprandial glucose and insulinexcursions after the prolonged vs. overnight fast. Previous studieshave utilized either the hyperinsulinemic-euglycemic clamp techniqueor an OGTT to investigate the effect of prolonged fasting on glucosemetabolism. These studies have shown that insulin-mediated glucosedisposal (7, 23) and oral glucose tolerance (5, 11,15) are both impaired with prolonged fasting. The results ofthe present investigation also demonstrate a significant impairmentof glucose tolerance in the context of a normal mixed meal. Thegreater postprandial insulin excursion after the prolonged fastalso indirectly suggests impaired insulin action with respectto glucose metabolism. Adding further to the concept of the glucose-fattyacid cycle (32) is the fact that elevated FFAs and/or elevatedlipid oxidation can inhibit insulin action (2, 22, 33)due to effects on insulin signaling and/or glucose transport (10,33). Therefore, the significantly increased FFA concentrationand/or fat oxidation with the prolonged fast, both pre- and postprandially,could be mediating the impaired glucose tolerance, and potentialinsulin resistance, after the mixedmeal.

It is possible that factors other than the elevated FFA and/or fat oxidation could have caused the decrease in postprandialglucose tolerance after the prolonged fast. In this context, theincreased lipid oxidation after meal consumption could be a consequenceof rather than a contributory factor to, the impairment in insulinaction. Other possible mediators of impaired insulin action afterthe 72-h fast include the elevated cortisol (25) and ketonebodies (38). However, the cortisol concentration declined rapidlyafter the refeeding meal such that similar postprandial levelswere observed after the 72- and 13-h fast. $beta$ -HOB levels remainedsomewhat elevated throughout the postprandial period after the72-h fast. Although we did not measure growth hormone concentrations,it is likely that these would also have been elevated by the prolongedfast and could have decreased insulin action. Future studies,therefore, are required to define the mechanism causing the decreasedglucose tolerance after mixed-meal consumption after extendedfasting.

It has been reported that insulin's suppression of lipolysis is also impaired after a prolonged fast (19, 39). In thepresent study, there was a significant decrease in the postprandialFFA and glycerol concentrations after the mixed meal under bothfasting conditions, suggesting suppression of lipolysis. However,we observed no difference between the two fasting periods in thepostprandial decline (decremental AUC) in glycerol concentrations,despite the much greater insulin response after the extended fast.Circulating glycerol concentrations are considered indicativeof changes in whole body lipolysis (3) because there is littlereutilization of glycerol within adipose tissue (6) (the majorsite of glycerol release). This contrasts to FFAs, which can bereesterified within adipocytes. Although data show that musclecan potentially reutilize glycerol produced from intramuscularlipolysis (6), this is likely a very minor contributor to wholebody lipolysis under fasting conditions. The present study, therefore,would suggest impairment of insulin's antilipolytic action basedon circulating glycerol changes. However, circulating concentrationsdo not indicate rates of substrate production and removal andonly represent the balance between the two. This can only be addressedwith the use of isotopic-tracertechniques.

The present study demonstrated a significant increase in the insulin-to-glucose ratio after the mixed meal after the prolongedvs. overnight fast. This suggests that, for a given change inglucose concentration, there was a greater insulin secretion.However, we only measured insulin at hourly intervals and didnot measure C-peptide concentrations, a better marker of insulinsecretion (31). An alternative explanation for the greater insulinconcentrations could be a decrease in insulin clearance. The elevatedFFA concentrations before the meal after the 72- vs. 13-h fastcould have impacted either insulin secretion and/or clearance.Indeed, elevated FFAs have been shown to be important for bothnon-glucose- (1, 9) and glucose-stimulated (9, 36)insulin secretion, especially after fasting (8, 36). Theelevated $beta$ -HOB could also contribute to an increased insulin secretion(27). It could be postulated that the FFAs act as a "signal,"indicating that a greater insulin secretion is required to overcomethe impairment in insulin action that has developed as a resultof the prolonged fasting. Because elevated FFAs may be an importantfactor causing the impaired insulin action, they may play an importantrole in determining both the substrate and hormone response tofasting andrefeeding.

The typical hormonal changes resulting from a prolonged fast were observed in the present study, that is, an increase in norepinephrine,cortisol, and glucagon with a decrease in insulin (28, 30,41). We did not observe a significant increase in epinephrine,although levels were elevated. However, it has been reported thatthe sensitivity to the lipolytic action of epinephrine is increasedafter prolonged fasting (41), therefore diminishing the needfor a large increase in this catecholamine. Postprandially, therewas a decrease in the hormones associated with substrate mobilization,that is, norepinephrine, cortisol, and glucagon. Interestingly,postprandial norepinephrine and epinephrine were still somewhatelevated after the 72- vs. 13-h fast. This elevation in catecholaminescould have helped maintain a higher rate of postprandial lipolysisafter the 72-h fast, thus opposing the antilipolytic action ofthe greatly elevatedinsulin.

The use of respiratory gas-exchange data to calculate nutrient oxidation assumes that all the O₂ and CO₂ consumed and produced,respectively, are derived from the oxidation of fat, carbohydrate,and protein. In the context of prolonged fasting, this may notbe true because of the generation and utilization of ketones andincreased gluconeogenesis (5, 12, 27). This is mainly aproblem when there is an imbalance between the production of substratesand their oxidation (35). With respect to ketones, we measuredthe blood and urine accumulation of the main ketone body, $beta$ -HOB,and corrected the postprandial $V$ O₂ values based on these measurements.The actual $V$ O₂ estimated to be diverted to this process was small,even after the 72-h fast. Therefore, not measuring acetoacetatelikely had minimal effects on the $V$ O₂ data. With respect to gluconeogenesis,we had no ability to estimate rates of this during the refeedingperiod. However, it is unlikely that this process would have significantlyimpacted the respiratory gas-exchange values after the 72-h fastplus meal because gluconeogenesis would have been rapidly suppressed.This is supported by the greatly elevated insulin-to-glucagonratio after the meal after the prolongedfast.

The present study suggests that the pattern of postprandial nutrient oxidation, after refeeding after a fast, may be partlydetermined by changes in the substrate and hormone environment.In addition, it could be related to differences in prefastinginsulin sensitivity. Thus it could be hypothesized that the lesserthe impairment of glucose tolerance after fasting, the smallerthe decrease in carbohydrate oxidation and the smaller the increasein fat oxidation. In the present study, however, we observed nosignificant correlation between the initial insulin sensitivityindex, as measured by Bergman's minimal model, and measures ofnutrient oxidation, nutrient balance, and postprandial substrateand hormone responses. However, these data were collected on asmall group of male, nondiabetic, relatively nonobese (body fat<27%) subjects. This gave a limited range in the insulin sensitivityof subjects and in the insulin and glucose responses to the meal.It would be of interest to determine the substrate and hormoneresponse to refeeding a mixed meal in other populations, includingobese individuals and individuals with Type 2 diabetes. Such individualsdiffer markedly from their lean counterparts in indexes of insulinaction as well as the circulating substrate and hormone environment.Imposing a prolonged fast on an obese person and/or an individualwith Type 2 diabetes may thus result in a very different patternof change in the postprandial nutrient oxidation. Indeed, it hasbeen reported that the reduction in intravenous glucose tolerance,observed in normal subjects after fasting, is less severe in obeseindividuals (15) and not present in diabetic subjects (5).

The extent to which individuals change from predominantly fat oxidation (after fasting) to predominantly carbohydrate oxidation(with consumption of a meal) may be very different after long-vs. short-term fasting. An individual who maintains a higher rateof carbohydrate oxidation after refeeding may be more prone tonet fat accumulation. Individual variation in this response maynot be detectable after a normal overnight fast but may be exaggeratedafter a more extended fasting period. Ultimately, retention ofbody fat requires a positive energy balance, but this could beexacerbated in an individual who favors a higher rate of carbohydrateoxidation between and after meals. Indeed, a greater fasting or24-h respiratory quotient has been reported to be predictive ofweight gain (24, 43). If this were a constitutive characteristicof the preobese individual, rather than a consequence of the obesestate, then it may exacerbate body fat accumulation. Such individualsmay be more prone to fat accumulation, especially when undergoingprolonged periods between meals. This may be particularly exacerbatedif most of the daily energy intake was consumed in one, large,high-fatmeal.

In conclusion, this study showed that, in normal healthy men, prolonged fasting resulted in a significant decrease in postprandialcarbohydrate oxidation and an increase in fat oxidation. Thiswas associated with a significant impairment in glucose toleranceand a significant elevation in the postprandial insulin excursion.Because circulating FFAs were significantly elevated at all timesafter the prolonged fast, this could be one factor determiningthe differences in postprandial nutrient oxidation, and glucoseand insulinresponses.

	ACKNOWLEDGEMENTS

We thank all the subjects who volunteered for this study and greatly appreciate their time and cooperation. We also thankall the GCRC staff at University Hospital for help with thestudy.

	FOOTNOTES

This investigation was supported by National Institute of Diabetes and Digestive and Kidney Diseases Grants DK-42549 and DK-48520,and by National Institute of Health Division of Research ResourcesGrant 5-01-RR-00051.

Address for reprint requests and other correspondence: T. J. Horton, Center for Human Nutrition, Box C225, Univ. of ColoradoHealth Sciences Center, 4200 East 9th Ave., Denver, CO 80262 (E-mail:Tracy.Horton{at}uchsc.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 26 October 1999; accepted in final form 3 August 2000.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

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