The Power of Caloric Restriction and Optimal Nutrition - Varalife®

The Power of Caloric Restriction and Optimal Nutrition

Introduction:

Longevity, the dream of living a long and fulfilling life, has captivated human imagination for centuries. As we strive to uncover the secrets of aging and enhance our healthspan, the role of diet has emerged as a pivotal factor in shaping our longevity. With each passing day, scientific research unveils new insights into the profound impact of dietary choices on our overall well-being and lifespan. In this quest to unravel the connection between longevity and diet. One of the most promising non-pharmacological interventions in this pursuit is Caloric Restriction (CR): reducing daily food intake by around 30% without malnutrition or starvation. CR has shown remarkable potential in improving lifespan in model organisms.[1] Although the precise mechanisms behind its benefits remain elusive , recent research has shed light on how the timing of food intake and the composition of macronutrients play crucial roles in supporting longevity.[2]

The Power of Caloric Restriction and Optimal Nutrition

The Power of Timing — Circadian Alignment

Emerging research indicates that the timing of food intake can have profound effects on physiology. Our best exploration in this emerging technique makes use of the robust mice model. In mice, timed food administration can entrain circadian clocks in peripheral tissues such as the liver.[3] Additionally, studies have shown that mice fed a high-fat diet only during their active feeding time (night) gain significantly less weight compared to mice fed during the day.[4] Furthermore, when fed a high-fat diet; restricted to an 8-hour window at night, mice were protected against obesity, hepatic steatosis, hyperinsulinemia, and inflammation. These findings demonstrate the importance of temporally restricted feeding at night, aligning with the natural circadian phase of feeding in mice, to reap the benefits of CR.[5]

Moreover, the timing and frequency of feeding have been explored in mice under CR to compare behavioral, metabolic, and molecular outcomes throughout their lifespan. Results from various CR protocols using automated feeders showed that a fasting interval of more than 12 hours, combined with time-restricted feeding aligned with the nocturnal circadian phase, optimally extended lifespan. These findings not only reaffirm the benefits of CR but also emphasize the crucial role of circadian alignment in promoting longevity.[6]

Macronutrient Composition and Levels

Beyond timing, the type and levels of macronutrients in our diet significantly influence healthspan and lifespan. High-calorie diets, especially those rich in saturated fats and sugars, contribute to obesity, insulin resistance, and age-related diseases.[7] On the other hand, low carbohydrate and ketogenic diets have gained attention due to their potential health benefits. Animal studies have shown that ketogenic diets can extend lifespan, improve cognitive function, and enhance metabolic health.[8]

Protein intake has been closely associated with mortality and longevity in both animals and humans. Low protein diets have been linked to extended lifespan in mice, reducing levels of IGF-1 and pro-growth signalling.[9] The ketogenic diet, in particular, has been found to activate nutrient signalling pathways and preserve neuronal architecture, leading to cognitive benefits.[10] Furthermore, methionine restriction has shown promising results in increasing lifespan and reducing cancer risk in mice.[11]

Conclusion:

As we uncover more about the complex interactions between caloric restriction, timing of food intake, and macronutrient composition, the key to unlocking longevity seems to lie in a multifaceted approach. Caloric restriction, aligned with the natural circadian phase of feeding, holds great promise for extending lifespan and promoting health in both animals and humans. Additionally, understanding the role of specific macronutrients, such as protein and amino acids, can further enhance the benefits of a balanced diet.

While there is still much to learn, the evidence overwhelmingly suggests that proper nutrition, along with the strategic timing of food intake, can significantly impact longevity and age-related diseases. As we continue to explore these avenues, personalized dietary interventions tailored to individual age, sex, genetics, and lifestyle may hold the key to maximizing healthspan and extending our journey through life. By adopting these science-backed dietary practices, we can take a proactive approach towards a longer and healthier life.

Varalife® is dedicated to providing science-backed longevity supplements containing synergistic ingredients such as NMN, Resveratrol, Vitamin D3, Vitamin K2, and Omega-3 Fatty Acid in VaraSpan®, our daily longevity capsule. Our VaraCare® daily longevity sachet contains Quercetin, Glycine, Glucosamine, Hyaluronic Acid, L-Theanine, Vitamin C, Ginger L-Citrulline, Malate, and Calcium. Varalife®’s longevity supplements are scientifically backed and manufactured only in GMP certified facilities. We remain committed to supporting your journey toward a longer, healthier, and more vibrant life.

Disclaimer: Remember to consult with your healthcare professional to customize your approach and embark on this transformative path to longevity to embrace the possibilities and discover the beauty of a life well-lived.

References:

  1. R. Weindruch, R. L. Walford, S. Fligiel, D. Guthrie, The retardation of aging in mice by dietary restriction: Longevity, cancer, immunity and lifetime energy intake. J. Nutr. 116, 641–654 (1986)
  2. A. Di Francesco, C. Di Germanio, M. Bernier, R. de Cabo, A time to fast. Science 362, 770–775 (2018)
  3. F. Damiola, N. Le Minh, N. Preitner, B. Kornmann, F. Fleury-Olela, U. Schibler, Restricted feeding uncouples circadian oscillators in peripheral tissues from the central pacemaker in the suprachiasmatic nucleus. Genes Dev. 14, 2950–2961 (2000)
  4. D. M. Arble, J. Bass, A. D. Laposky, M. H. Vitaterna, F. W. Turek, Circadian timing of food intake contributes to weight gain. Obesity (Silver Spring) 17, 2100–2102 (2009)
  5. M. Hatori, C. Vollmers, A. Zarrinpar, L. DiTacchio, E. A. Bushong, S. Gill, M. Leblanc, A. Chaix, M. Joens, J. A. J. Fitzpatrick, M. H. Ellisman, S. Panda, Time-restricted feeding without reducing caloric intake prevents metabolic diseases in mice fed a high-fat diet. Cell Metab. 15, 848–860 (2012).
  6. A. Chaudhari, R. Gupta, K. Makwana, R. Kondratov, Circadian clocks, diets and aging. Nutr. Healthy Aging 4, 101–112 (2017)
  7. Janssen JAMJL (2021). Hyperinsulinemia and Its Pivotal Role in Aging, Obesity, Type 2 Diabetes, Cardiovascular Disease and Cancer. Int J Mol Sci 22, 7797
  8. Newman JC, Covarrubias AJ, Zhao M, Yu X, Gut P, Ng CP, Huang Y, Haldar S, and Verdin E (2017). Ketogenic Diet Reduces Midlife Mortality and Improves Memory in Aging Mice. Cell Metabolism 26, 547–557.e8.
  9. Solon-Biet SM, McMahon AC, Ballard JW, Ruohonen K, Wu LE, Cogger VC, Warren A, Huang X, Pichaud N, Melvin RG, et al. (2014). The ratio of macronutrients, not caloric intake, dictates cardiometabolic health, aging, and longevity in ad libitum-fed mice. Cell Metab 19, 418–430
  10. Wahl D, Solon-Biet SM, Wang Q-P, Wali JA, Pulpitel T, Clark X, Raubenheimer D, Senior AM, Sinclair DA, Cooney GJ, et al. (2018). Comparing the Effects of Low-Protein and High-Carbohydrate Diets and Caloric Restriction on Brain Aging in Mice. Cell Rep 25, 2234–2243.e6.
  11. Gao X, Sanderson SM, Dai Z, Reid MA, Cooper DE, Lu M, Richie JP, Ciccarella A, Calcagnotto A, Mikhael PG, et al. (2019). Dietary methionine influences therapy in mouse cancer models and alters human metabolism. Nature 572, 397–401
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