The importance of dietary composition and feeding patterns in aging remains largely unexplored, but was implicated recently in two prominent nonhuman primate studies. Here, we directly compare in mice the two diets used in the primate studies focusing on three paradigms: ad libitum (AL), 30% calorie restriction (CR), and single-meal feeding (MF), which accounts for differences in energy density and caloric intake consumed by the AL mice. MF and CR regimes enhanced longevity regardless of diet composition, which alone had no significant impact within feeding regimens. Like CR animals, MF mice ate quickly, imposing periods of extended daily fasting on themselves that produced significant improvements in morbidity and mortality compared with AL. These health and survival benefits conferred by periods of extended daily fasting, independent of dietary composition, have major implications for human health and clinical applicability.

CR experiments have been conducted in nonhuman primates (NHPs) including studies at the University of Wisconsin (WIS) () and the National Institute on Aging (NIA) (). A recent comparative analysis of these studies indicated that CR and its associated mechanisms are likely to be highly relevant to human health and longevity (). One of the most debated differences between the studies relates to dietary composition. NIA used a naturally sourced diet while WIS used a semi-purified diet, resulting in differences in the macronutrient content of the diets ( Table S1 ). At both locations, the diets contained ∼60% carbohydrates by weight; however, compared with the WIS diet, the NIA diet was higher in protein (17.3% versus 13.1% by weight), slightly higher in fiber (6.5%–9.0% versus 5.0% by weight), lower in fat (5.0% versus 10.6% by weight), and lower in sucrose (3.9% versus 28.5% by weight). Sucrose is a disaccharide of fructose and glucose that has been part of the human diet for centuries. Excessive consumption of sucrose has been linked to metabolic disorders beyond just weight gain, where elevated fructose in the presence of glucose favors lipogenesis in the liver, leading to fatty liver and associated pathologies (). To shed light on the interaction between diet composition and feeding paradigms, we tested the impact of these variables on health and longevity in a genetically homogeneous mouse model. We hypothesized that consumption of the NIA naturally sourced NHP diet would confer survival advantages over the WIS-purified NHP diet. Moreover, we investigated the effect of eating patterns on morbidity and mortality regardless of diet composition in the form of 30% CR and a daily single-meal feeding (MF) isocaloric to that of ad libitum (AL)-fed mice. The results show that the relationship between diet and healthy lifespan is influenced by the timing of food intake, an outcome that could have major implications for human health and clinical applicability.

Calorie restriction (CR) interventions, either as a reduction of the daily caloric intake or intermittent fasting (cyclic periods of food deprivation), have been shown to mitigate age-associated declines in most pathophysiological parameters and to extend maximum lifespan in various animal species (). In every form of CR, prolonged fasting periods represent a consistent, but frequently overlooked, variable in energy homeostasis. Most mammals have the ability to adapt to short-term loss of energy intake without a substantial impact on vitality (individuals with impaired glycemic control or impaired lipid mobilization are exceptions). Alternating cycles of feeding and fasting trigger specific biochemical processes mediated, at least in part, by nutrient-sensing pathways (). The length of post-absorptive periods, however, may well play an important role in the association between feeding regimens and longevity (). These periods of fasting evoke cellular maintenance and repair mechanisms that are intrinsic to the fast and refeed cycles (). Nearly every form of CR results in meal feeding, either because a reduced number of quickly consumed calories are provided in discrete meals or because days spent without food are interspersed with days in which food is provided, almost certainly triggering fasting mechanisms. In contrast, post-absorptive periods are likely to be absent in an AL feeding paradigm. In this way, two components must be considered in the comparison of CR with AL: first, the reduction in total calorie intake, and second, the introduction of periodic fasting. This raises the possibility that the benefits of restricting the timing of food intake are separable from those associated with overt caloric intake reduction. Thus, CR-associated mechanisms are likely relevant to human health and longevity (), and meal strategies mimicking the daily fasting periods that occur with CR might be readily translated to humans if clear health benefits are observed due to such periods of fasting.

Results and Discussion

Jang et al., 2007 Jang H.J.

Kokrashvili Z.

Theodorakis M.J.

Carlson O.D.

Kim B.J.

Zhou J.

Kim H.H.

Xu X.

Chan S.L.

Juhaszova M.

et al. Gut-expressed gustducin and taste receptors regulate secretion of glucagon-like peptide-1. Janssen and Depoortere, 2013 Janssen S.

Depoortere I. Nutrient sensing in the gut: new roads to therapeutics?. A cohort of 292 male C57BL/6J (B6) mice was established, and at 4 months of age the mice were randomly divided into the two diet groups and maintained until their natural death. Mice were singly housed and fed either the low-sucrose NIA NHP diet or the sucrose-rich WIS NHP diet that were repelleted for mouse consumption. Lights were turned on at 6:00 a.m. and turned off at 6:00 p.m. in the vivarium. All groups of mice were fed at 3:00 p.m. (±1 hr) every day. Detailed descriptions of the study design (e.g., diet composition, intake measurement, and feeding protocols) can be found in STAR Methods . In brief, groups of AL (n = 90) and CR (n = 121; 30% reduction) were created, and to account for differences in energy density between the two diets, two additional groups of MF mice (n = 81) were introduced as controls. MF mice were fed once daily either NIA or WIS diet proportioned to match the caloric intake of the other diet AL group. This strategy was used to accommodate differences in calorie density between the diets and to separate longevity effects due to lower caloric intake from those due to the once-daily feeding paradigm of the CR mice. The MF mice learned quickly that food would not be continuously available and thus tended to gorge, spending hours each day without food. This behavior has been associated with “hyperactivation” of sweet-taste and fat receptors on enteroendocrine cells in the upper gastrointestinal tract ().

−5), while no significant difference was observed between WIS-MF and WIS-AL mice (p = 0.55) ( Figure 1 Effects of Diet Composition, Energy Density, and Feeding Patterns on Body Weight and Metabolism Show full caption (A and B) Trajectories of daily food intake per mouse over a period of 54 weeks expressed as grams (A) and kcal (B). n = 45 mice (NIA-AL), n = 44 (WIS-AL), n = 40 (NIA-MF), n = 41 (WIS-MF), n = 59 (NIA-CR), n = 62 (WIS-CR). See also Table S1 (C) Body-weight trajectories over a period of 96 weeks. See also Figure S1 (D) Upper two panels: respiratory exchange ratio (RER) at 41–42 weeks of age, n = 5–6. Bottom panel: representative schematic of the study showing the estimated fasting time for each of the two diets, and three feeding paradigms across the study with respect to the zeitgeber time, which is defined as any external clue, such as the 12:12-hr light/dark cycle that synchronizes common biological rhythms in an organism. This schematic was inferred using experimental evidence from (E). AL mice had constant access to food and so were not subjected to a daily fasting time. Arrow indicates start of the feeding (3:00 p.m.). CHO, carbohydrate; FA, fatty acids. See also Figure S2 (E) Scatterplot depicting the duration of eating in MF and CR mice at 113 weeks of age. The duration of eating (in hours) is expressed as the median and [5%–95% percentile]: NIA-MF, 14.63 [5.5–20.5]; NIA-CR, 4.875 [1.61–9.27]; WIS-MF, 11.75 [1–24]; WIS-CR, 1 [0.5–3.57]. Every data point represents the average of two independent determinations for each mouse. Because the NIA-CR and WIS-CR datasets did not pass the Shapiro-Wilk normality test, the non-parametric Kruskal-Wallis test combined with Dunn's multiple comparisons test was performed to establish statistical significance between groups. Variables with different letters are considered significantly different at p < 0.01. (F) Three-hour fasting blood glucose (FBG) levels in 41-week-old mice, n = 7–8 mice per cohort. (G–I) Blood was collected from 42-week-old mice after an overnight (16 hr) fasting, n = 6–8 per group. (G) serum insulin, (H) HOMA-IR index, (I) serum β-hydroxybutyrate. Data in (F)–(I) are presented as whisker plots, and analyzed using two-way ANOVA as a function of diet type (NIA and WIS diet) and feeding regimen (AL, MF, CR) with Tukey's post hoc analysis. Variables with different letters are considered significantly different at p < 0.05. See also Table S2 Table 1 Significance in Food Intake Differences between the Indicated Pairwise Comparisons Feeding Paradigm Diet Composition Caloric Content NIA versus WIS NIA-AL WIS-AL WIS-AL AL 1.9 × 10−8 NIA-MF 0.0015 – NIA-MF 0.22 MF 0.33 NIA-CR 1.16 × 10−33 – WIS-MF 0.87 CR 0.15 WIS-MF – 0.87 WIS-CR – 2.20 × 10−26 AL, ad libitum feeding; MF, meal-fed; CR, 30% calorie restriction. Daily food intake data under all experimental conditions were collected over a period of 54 weeks ( Figures 1 A and 1B; Table 1 ). Overall, mice on the NIA diet consumed significantly more grams of food than those on the WIS diet, irrespective of the feeding protocol (AL, 4.1 ± 0.2 versus 3.3 ± 0.2 g/day/mouse; MF, 3.9 ± 0.3 versus 3.3 ± 0.2 g/day/mouse; CR, 2.8 ± 0.1 versus 2.3 ± 0.2 g/day/mouse) ( Figure 1 A). However, when the amount of food eaten was normalized by the energy content of each diet, AL and MF mice were found to consume approximately the same number of calories each day (NIA-AL, 14.0 ± 0.7; NIA-MF, 13.2 ± 1; WIS-AL, 13.1 ± 0.7; WIS-MF, 12.9 ± 0.7 kcal/day/mouse) ( Figure 1 B). Although the NIA-AL group ate slightly more calories per day than any other group (p < 0.002), the WIS-AL, WIS-MF, and NIA-MF mice were not different in their caloric intake. Both groups of CR mice had ∼30% reduction in calorie intake compared with their AL controls, with intake equivalent for NIA and WIS animals (9.5 ± 0.5 and 9.2 ± 0.8 kcal/day/mouse, respectively) (p = 0.15) ( Figure 1 B). The longitudinal body-weight trajectory was evaluated in all six groups of mice over a period of 96 weeks ( Figure 1 C). The body-weight gain trajectory of NIA-MF mice was significantly lower compared with NIA-AL controls (p = 3.48 × 10), while no significant difference was observed between WIS-MF and WIS-AL mice (p = 0.55) ( Figure S1 , upper panels). Body-weight trajectories between diet types within each of the three feeding protocols (AL, MF, and CR) were not significantly different ( Figure S1 , lower panels). Mice on 30% CR weighed considerably less over the same period, regardless of diet ( Figures 1 C and S1 ).

Using a comprehensive lab animal monitoring system, we examined whether the diet type and feeding protocols were associated with differences in in vivo metabolism in 10-month-old mice ( Figures 1 D [upper panel] and S2 ). AL mice had access to food 24/7 while MF and CR mice were fed daily at 3:00 p.m. ( Figure 1 D, lower panel). For AL-fed mice, fluctuation of the respiratory exchange ratio (RER), calculated from the amount of carbon dioxide produced and oxygen consumed, was minimal between the light and dark cycles, irrespective of the diet composition ( Figures 1 D [upper and middle panels] and S2 ). MF and CR mice on either diet exhibited large RER fluctuations (maximum ∼1.0) upon feeding, consistent with metabolic flexibility and preferential use of carbohydrates in the fed state before slowly returning to fatty acid oxidation as primary fuel source post-prandially (RER ∼0.75) ( Figure 1 D, upper panel). Larger amplitudes and shorter duration of postprandial carbohydrate fuel utilization were present in WIS-fed versus NIA-fed mice, as might be expected considering the differences in diet composition, i.e., the sucrose-rich WIS diet that is readily absorbed and metabolized in contrast to the NIA diet composed of complex carbohydrates that, in principle, requires time to be processed and metabolized ( Figure S2 ).

The duration of eating varied dramatically based on diet type and feeding protocol, thus resulting in differences in the length of the fasting period. A consequence of the once-daily isocaloric MF paradigm was that NIA-MF mice took ∼15 hr to consume their daily allotment of food while WIS-MF mice needed only ∼12 hr (p < 0.0001; Figures 1 D and 1E), leaving them to fast for the rest of the day. CR mice on NIA and WIS diet completed their meals within ∼5 and 1 hr, respectively, resulting in prolonged fasting for both CR groups (p < 0.0001; Figures 1 D and 1E).

Together, the data show that unlike in mice under AL, the MF and CR groups had extended periods of daily fasting associated with high-amplitude daily rhythms in RER (∼0.75 up to ∼1.0) consistent with high metabolic flexibility.

Solon-Biet et al., 2015 Solon-Biet S.M.

Mitchell S.J.

Coogan S.C.

Cogger V.C.

Gokarn R.

McMahon A.C.

Raubenheimer D.

de Cabo R.

Simpson S.J.

Le Couteur D.G. Dietary protein to carbohydrate ratio and caloric restriction: comparing metabolic outcomes in mice. Anson et al., 2003 Anson R.M.

Guo Z.

de Cabo R.

Iyun T.

Rios M.

Hagepanos A.

Ingram D.K.

Lane M.A.

Mattson M.P. Intermittent fasting dissociates beneficial effects of dietary restriction on glucose metabolism and neuronal resistance to injury from calorie intake. Mitchell et al., 2016 Mitchell S.J.

Madrigal-Matute J.

Scheibye-Knudsen M.

Fang E.

Aon M.

Gonzalez-Reyes J.A.

Cortassa S.

Kaushik S.

Gonzalez-Freire M.

Patel B.

et al. Effects of sex, strain, and energy intake on hallmarks of aging in mice. To investigate the role of diet composition and feeding protocols on insulin sensitivity, we determined circulating glucose and insulin, and the homeostatic measure of insulin resistance (HOMA-IR) in fasted animals after 6 months on their respective diets. The day before blood collection, animals were fed as usual at 3:00 p.m. and allowed to eat for ∼2 hr before fasting overnight. Bleeds were then started at 9:00–10:00 a.m. CR-fed mice exhibited a significant improvement in insulin sensitivity in terms of fasting glucose and insulin levels and the HOMA-IR measurement ( Figures 1 F–1H) independent of diet composition, consistent with prior reports (). In contrast, no significant differences were observed for any glucoregulatory parameters between the AL and MF mice on either diet. CR feeding was associated with a significant increase in circulating β-hydroxybutyrate ( Figure 1 I), consistent with prior studies (), but not in MF or AL, where β-hydroxybutyrate levels remained unchanged.

2 = 45.5, p < 0.001) and WIS diet (χ2 = 45.2, p < 0.001) (2 = 85.83, p < 0.001) ( Solon-Biet et al., 2014 Solon-Biet S.M.

McMahon A.C.

Ballard J.W.

Ruohonen K.

Wu L.E.

Cogger V.C.

Warren A.

Huang X.

Pichaud N.

Melvin R.G.

et al. The ratio of macronutrients, not caloric intake, dictates cardiometabolic health, aging, and longevity in ad libitum-fed mice. Figure 2 Implications of Diet Composition and Feeding Patterns on Survival, Tumor Pathology, and Nontumor Pathology Show full caption (A) Kaplan-Meier survival curves for mice fed either NIA diet (left panel) or WIS diet (middle panel) ad libitum (AL), meal-fed (MF), or maintained on 30% calorie restriction (CR). (B) Survival curves when the two diet groups were combined. (C) Kaplan-Meier survival curves for mice on NIA or WIS diet fed either AL (left panel), MF (middle panel), or 30% CR (right panel). n = 44–45 mice each for AL, n = 40–41 mice for MF, and n = 59–62 mice for CR. Stacked bars depict the relative composition of the NIA and WIS diets, expressed as %kcal. P, protein; F, fat; CHO, carbohydrates other than sucrose (S). See also Tables S1 and S3–S5 The impact of diet composition and feeding protocol on median and maximum lifespan was assessed ( Figures 2 A–2C; Tables S3–S5 ). Kaplan-Meier survival analyses were performed to determine the effects of the feeding protocol within each diet (NIA, n = 45 [AL], 40 [MF], and 59 [CR]; WIS, n = 45 [AL], 41 [MF], and 62 [CR]). Survival curves were significantly different among feeding paradigms by the log-rank test for mice on NIA diet (χ= 45.5, p < 0.001) and WIS diet (χ= 45.2, p < 0.001) ( Figure 2 A). A multiple comparison procedure (Holm-Sidak method) was used to compare longevity effects of feeding paradigms independent of diet type. As in the individual diet analysis, all comparisons were statistically significant (χ= 85.83, p < 0.001) ( Tables S3–S5 ), with mean lifespan extensions of 11% and 28% by MF and CR, respectively. Our original hypothesis was that diet composition would affect longevity; however, lack of differences in metabolic indices between diets for each of the feeding paradigms suggested that the outcomes might be otherwise. When survival was analyzed by diet type there were no significant differences between curves for AL, MF, or CR, indicating that diet composition had no impact on survival ( Figure 2 C) despite the differences in diet composition and caloric content. The results of this study reveal that eating pattern rather than diet composition is a primary determinant in longevity regulation. Although unexplored in this study, it is important to emphasize that macronutrient composition has been reported to play a role in late-life health and lifespan under AL feeding conditions ().

Bronson and Lipman, 1991 Bronson R.T.

Lipman R.D. Reduction in rate of occurrence of age related lesions in dietary restricted laboratory mice. Lipman et al., 1993 Lipman R.D.

Gaillard E.T.

Harrison D.E.

Bronson R.T. Husbandry factors and the prevalence of age-related amyloidosis in mice. Mustonen et al. (2013) Mustonen A.M.

Kärjä V.

Kilpiö M.

Tammi R.

Tammi M.

Rouvinen-Watt K.

Halonen T.

Nieminen P. Manifestations of fasting-induced fatty liver and rapid recovery from steatosis in voles fed lard or flaxseed oil lipids. Figure 3 Heatmap of the Average Score of Pathologies in Various Tissues and Organs in Each Experimental Group of Mice Show full caption The number of animals tallied and percentage of total study mice were as follows: NIA-AL, 33 (73.3%); NIA-MF, 31 (77.5%); NIA-CR, 42 (71.2%); WIS-AL, 28 (63.6%); WIS-MF, 30 (73.2%); WIS-CR, 41 (66.1%). For a detailed breakdown of the histopathology data, see Table S6 The distribution of pathologic lesions in mice that died spontaneously was examined by board-certified veterinary pathologists ( Table S6 Figure 3 ). AL mice died 25–28 weeks earlier than mice fed under CR. Similarly, tissues of MF mice were collected 13–15 weeks later than AL controls. As indicated here, CR and MF mice exhibited the same pathologies at death as the AL groups, but at a significantly later date. Heart, liver, kidneys, spleen, lungs, and pancreas were examined. The major non-neoplastic lesion was amyloidosis, with greater incidence in the percent rate of occurrence for mice fed the NIA diet. Among the feeding paradigms, mice under MF saw a reduction in the rate of amyloidosis deposits while mice under CR had the highest occurrence of the lesion in most tissues, likely stemming from the longer lifespan of CR mice as compared with the AL controls (132–135 weeks versus 104–110 weeks, respectively). Mineralization and glomerulonephritis of the kidneys, total lymphoid nodules of various tissues and organs, and lymphocytic infiltration of the lungs and kidneys were commonly found regardless of the diet type or eating pattern. MF and 30% CR appear to reduce and/or delay the rate of occurrence of amyloidosis deposits and other age-related pathologies at death, as previously reported (). A greater incidence of spontaneous hepatocellular carcinoma and lipidosis in the liver of mice on the WIS versus NIA diet was found. With aging, fatty liver and hepatocellular carcinoma are two of the most common lesions occurring in B6 male mice. The increased lipidosis in WIS-fed mice under MF versus AL is somewhat reminiscent of the study of, who reported that in rodents 18 hr of fasting induced fatty liver possibly by promoting hepatic fat storage.

Roberts et al., 2017 Roberts M.N.

Wallace M.A.

Tomilov A.A.

Zhou Z.

Marcotte G.R.

Tran D.

Perez G.

Gutierrez-Casado E.

Koike S.

Knotts T.A.

et al. A ketogenic diet extends longevity and healthspan in adult mice. Newman et al., 2017 Newman J.C.

Covarrubias A.J.

Zhao M.

Yu X.

Gut P.

Ng C.P.

Huang Y.

Haldar S.

Verdin E. Ketogenic diet reduces midlife mortality and improves memory in aging mice. Roberts et al., 2017 Roberts M.N.

Wallace M.A.

Tomilov A.A.

Zhou Z.

Marcotte G.R.

Tran D.

Perez G.

Gutierrez-Casado E.

Koike S.

Knotts T.A.

et al. A ketogenic diet extends longevity and healthspan in adult mice. A new perspective of the relationship between diet, health, and longevity has emerged in recent years whereby the beneficial effects of dietary regimens, including CR, on metabolic health and survival may not be due to calories alone but rather to a combination of total caloric intake, the length of fasting periods, and their interaction. In our study, we found that the fasting period experienced by the MF mice led to a significant increase in mean survival of 11%–14% even in the absence of CR. An important observation in this study is that the difference in time spent eating (gorging versus slower-paced intake) was dependent on diet composition and on the amount of food provided, raising the possibility that time-limited food intake may also be contributing to longevity under other circumstances. The unanticipated prolonged daily fasting in MF mice was accompanied by a modest increase in lifespan and delayed onset of pathologies even in the absence of differences in body weight or glucoregulatory responses compared with the AL-fed group and without ketosis. These observations are a departure from the CR-induced health benefits that are associated with weight loss, a reduction in HOMA-IR, and an increase in the levels of ketone bodies. One distinction between AL and MF was the daily rhythm in RER that was similarly responsive to MF and CR. A recent study in which mice were fed a ketogenic diet did not show this daily rhythm despite having several health benefits (), implying that mechanisms underlying ketogenic and MF paradigms are different. Two recent studies indicated that mice on ketogenic diets exhibited either a weight gain and slight reduction in midlife mortality, or a slight decrease in weight and increase in healthspan and lifespan (). Although ketogenic diets, when given in a paired feeding paradigm, extended lifespan, it is unclear whether periods of fasting may have been a contributing factor.

Mattison et al., 2017 Mattison J.A.

Colman R.J.

Beasley T.M.

Allison D.B.

Kemnitz J.W.

Roth G.S.

Ingram D.K.

Weindruch R.

Cabo R.d.

Anderson R.M. Caloric restriction improves health and survival of rhesus monkeys. Marinac et al., 2015 Marinac C.R.

Natarajan L.

Sears D.D.

Gallo L.C.

Hartman S.J.

Arredondo E.

Patterson R.E. Prolonged nightly fasting and breast cancer risk: findings from NHANES (2009-2010). Marinac et al., 2016 Marinac C.R.

Nelson S.H.

Breen C.I.

Hartman S.J.

Natarajan L.

Pierce J.P.

Flatt S.W.

Sears D.D.

Patterson R.E. Prolonged nightly fasting and breast cancer prognosis. Gill and Panda, 2015 Gill S.

Panda S. A Smartphone app reveals erratic diurnal eating patterns in humans that can be modulated for health benefits. Gupta et al., 2017 Gupta N.J.

Kumar V.

Panda S. A camera-phone based study reveals erratic eating pattern and disrupted daily eating-fasting cycle among adults in India. Even though the original NHP studies were designed to investigate CR and not patterns of feeding behavior (), the differences in diet composition and feeding regimens between the two studies have been a point of interest. The WIS NHPs had food removed overnight, ensuring a period of fasting for both control and CR groups. Within the WIS study the impact of CR on health and survival is not explained by differences in fasting. At NIA, NHPs had food available around the clock; however, it seems unlikely this played a role in survival since monkeys, like humans, sleep at night, and the NIA study included some of the longest-lived monkeys on record. In light of our findings in mice, it would seem unlikely that differences in diet composition explain the impact of either study on survival. Apart from shedding new light on the NHP studies, the current study has some important translational ramifications. Daily feeding-fasting schedules in humans that are synchronized with sleep-wake cycles have profound metabolic consequences that are highly relevant to the incidence of cancer. Recent studies in humans found that in patients with breast cancer, a fasting period greater than 13 hr resulted in lower risk of breast cancer recurrence compared with those that fasted less than 13 hr (). Erratic feeding behaviors and associated lifestyles among adults, such as spreading caloric intake over 15 hr or longer, can have detrimental health consequences ().

Chaix et al., 2014 Chaix A.

Zarrinpar A.

Miu P.

Panda S. Time-restricted feeding is a preventative and therapeutic intervention against diverse nutritional challenges. Overall, our results highlight the importance of incorporating fasting time into a feeding protocol as a potentially practical strategy to augment the beneficial effects attributed to CR. Increasing the fasting time may provide benefits similar to CR without the need to dramatically reduce the amount of calories, which ultimately may prove more attractive for clinical implementation. Time-restricted feeding has been reported to offer protection against diet-induced metabolic diseases, and these health benefits appear proportional to the length of the fasting period (). Dietary composition does seem to have an impact on indices of feeding behavior and liver health as evidenced by the tissue pathology. The gorging-like pattern of the MF and CR mice on the WIS diet, whereby mice ate their food quicker than those on the NIA diet, may be attributed to the increased sucrose and fat content relative to the NIA diet.