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Welcome to the Huberman Lab Podcast. I'm Andrew Huberman, a Professor of Neurobiology and Ophthalmology at Stanford. Today, we discuss fasting and its impact on health and wellbeing, including physical and mental aspects. Intermittent fasting, or time-restricted feeding, involves eating during specific periods each day. Most people unknowingly practice some form of intermittent fasting by not eating during sleep. We will explore how different fasting schedules affect weight loss, fat loss, muscle maintenance, organ health, inflammation, cognition, mood, and lifespan. A recent study published in Cell Metabolism found that higher resting blood glucose levels in humans correlate with increased mortality as people age. This contrasts with findings in mice, where lower blood glucose is associated with mortality. This highlights the importance of distinguishing between studies conducted in humans and those in animals. I aim to provide accessible information about science and health tools. Today, I will discuss mechanisms and practical tools for implementing fasting without strict adherence to feeding schedules. For instance, there are ways to mitigate negative effects of occasional deviations from a strict eating window. One key finding is that fasting can improve liver health and reduce inflammation. When we eat, blood glucose and insulin levels rise, while fasting lowers them. The timing of meals is crucial; eating during active phases of the day is beneficial, while late-night eating can be detrimental. Research indicates that restricting food intake to specific windows can enhance liver health and metabolic function. For example, studies show that mice on a time-restricted feeding schedule maintain or lose weight, while those with constant access to food become obese and unhealthy. The ideal feeding window is generally around eight hours, but individual preferences and lifestyles matter. It's essential to avoid food for at least one hour after waking and for two to three hours before bedtime. This allows for optimal metabolic health and supports the body's natural circadian rhythms. Recent literature suggests that time-restricted feeding can lead to improved insulin sensitivity and fat loss. However, shorter feeding windows may lead to overeating. The eight-hour window is often recommended for balancing health benefits and social schedules. For those focused on muscle maintenance, consuming protein early in the day may enhance muscle growth due to the timing of protein synthesis. Transitioning to a new feeding schedule should be gradual, allowing the body to adjust. In summary, the ideal intermittent fasting schedule involves an eight-hour feeding window, avoiding food after waking for at least one hour and before bed for two to three hours. Regularity in meal timing is crucial for maximizing health benefits. Individual variations exist, and some may require different approaches based on their lifestyle and health goals. For further exploration, I recommend resources like My Circadian Clock and the Zero app to help track feeding windows. Remember, the relationship between when you eat and your overall health is significant. Thank you for your interest in science and health.

Johnny Cole Dickson discusses fasting and its effects on the body, particularly focusing on fat utilization and ketone production. Fasting begins in the postabsorptive state, typically 6-12 hours after eating, where the body shifts from glucose to fat for energy. He highlights various fasting protocols, including 14-hour and 16-hour fasts, showing weight loss and improved health markers. Notably, alternate day fasting with zero calories on fasting days resulted in significant fat loss. He emphasizes that food habits, rather than food choices, play a crucial role in health outcomes, suggesting that combining fasting with healthier food options could enhance results.

Fasting is not merely a weight loss strategy; it fundamentally alters cellular mechanisms that promote longevity. When fasting, insulin levels drop, allowing the body to mobilize fat stores for energy, primarily through ketogenesis. This metabolic shift enhances energy production and can lead to improved physical and mental resilience. Fasting induces hormetic stress, which can stimulate the release of brain-derived neurotrophic factor, promoting neuroplasticity and cognitive function. Additionally, fasting increases growth hormone production, aids in muscle maintenance, and initiates autophagy, where the body cleans up cellular debris, including old mitochondria. The process of fasting can be challenging initially, as individuals may experience cravings and withdrawal symptoms from food addictions. Gradual adaptation is essential, starting with intermittent fasting or meal skipping, which empowers individuals to recognize their body's signals and build metabolic flexibility. For those with obesity, a structured approach to fasting, such as a three-day water fast, can be beneficial after they have acclimated to shorter fasting periods. Medical supervision is crucial for individuals on medications like insulin, as fasting can lead to hypoglycemia. Monitoring blood pressure and glucose levels is also recommended during fasting. The conversation around fasting should focus on its potential health benefits rather than the fear of starvation, as the body is designed to adapt to periods without food. Dietary changes, particularly reducing processed foods and increasing whole foods, are vital for successful fasting. The emphasis should be on nutrient-dense foods that support metabolic health. The concept of personalized nutrition is highlighted, as individual responses to foods can vary significantly. For instance, some may thrive on high-fat diets, while others may not. The discussion also touches on the importance of polyphenols and their role in health. Foods rich in polyphenols, such as fruits and vegetables, can positively influence gut health and overall well-being. The quality of food, including the sourcing of animal products, is emphasized, as it can affect nutrient density. Biological age, as opposed to chronological age, reflects the physiological state of an individual and can be influenced by lifestyle choices, including diet, exercise, and sleep. Interventions aimed at improving biological age can lead to enhanced health span and longevity. The study discussed involved a structured eight-week program focusing on diet, sleep hygiene, exercise, and stress management, with participants experiencing significant improvements in their biological age markers. Overall, the integration of fasting, personalized nutrition, and lifestyle modifications can lead to substantial health benefits, including improved metabolic function, cognitive health, and longevity.

Visceral fat is not merely about looks; it’s a gateway to inflammation, insulin resistance, and heart disease, and a growing medical approach centers on fasting as the fastest route to shed it. A world-leading cardiologist with decades of experience explains how repeated carb intake keeps insulin high, promotes visceral fat, and fuels artery disease. He emphasizes that after about 12 hours of fasting, the body begins pulling stored fat from the belly first, a process he uses to reverse metabolic derangements. The conversation then shifts to how modern living disrupts fasting physiology, contributing to a cascade of inflammatory signals, fatty liver, and a skewed lipid profile that can culminate in heart attacks even in younger patients. He maps a chain from gut health to heart disease, highlighting how insulin-driven visceral fat and ectopic fat around organs inflame blood vessels. A key diagnostic thread is insulin testing, because many patients exhibit high insulin with normal glucose, a sign of insulin resistance that predates diabetes and accelerates cardiovascular risk. Fasting emerges as a powerful instrument: from 12-hour fasts to 18:6 schedules, with more aggressive regimens for those with diabetes or obesity, such as weekly 48-hour fasts or occasional three-day water fasts, followed by one meal a day. He also notes that ketosis and autophagy make cells more efficient, produce ketones as fuel, and can boost brain function and growth hormone, while the body cycles between fed and fasted states to preserve muscle when properly managed. The discussion then turns to the gut as the main driver of cardiovascular inflammation. A disrupted microbiome, leaky gut, and mold exposure are described as contributors to fatty liver and coronary plaque, with the liver and gut coordinates measured by inflammatory markers and coronary calcium scoring. Rebalancing the microbiome—through high-fiber diets, fermented foods, and specific prebiotic supplements—can dampen systemic inflammation and slow plaque progression. He advocates vitamin D3 and K2 to optimize calcium handling, cautions against routine calcium supplements, and endorses omega-3s and nattokinase to modulate clotting. Beyond diet, he explains vagus nerve hacks—breathing exercises, cold exposure, humming, and even eye movements—that enhance parasympathetic activity, improve heart rate variability, and support gut-brain communication. He stresses that sleep and stress management are essential for gut health and heart protection.

Fasting emerges as a powerful medical tool in this conversation, with Dr. Alan Goldhammer arguing that water-only fasting can reverse hypertension, rebalance insulin resistance, and reset the gut. Over four decades, he has guided thousands to health by using one of humanity’s oldest healing practices, including a landmark study in which 174 consecutive patients with high blood pressure normalized their readings without medication. He describes fasting as complete abstinence from all substances in a resting state, emphasizing that rest minimizes lean-tissue loss while maximizing fat loss. He distinguishes water fasting from juice fasting, noting that the latter is a modified diet, and he asserts that the most dramatic metabolic changes—BDNF increases, autophagy, and improved brain function—often accompany fasting just as they do with exercise. He also stresses that the goal is to avoid dietary excess, not merely to restrict calories. Mechanistically, the dialogue traces the fasting sequence from glycogen depletion after about a day to a brain that switches from glucose to ketones as a primary fuel, with beta-hydroxybutyrate supporting cognitive stability and elevated BDNF. Autophagy is introduced as housekeeping cellular cleanup, while visceral fat—tied to inflammation, heart disease, and diabetes—sheds first during a fasting window and continues to decline with refeeding. The conversation links these changes to a broader shift away from processed foods that load the brain with dopamine-boosting salt, oil, and sugar, and toward a whole-plant SOS-free diet. Intermittent fasting and time-restricted feeding are offered as practical tools: avoid eating within three to four hours of sleep, extend the fast to sixteen hours when possible, and tailor the feeding window to individual needs, activity, and caloric goals. Clinical outcomes anchor the discussion: hypertension can normalize with two weeks of fasting, and long-term follow-ups show many maintain normal blood pressure off medications after refeeding and lifestyle changes. Lymphoma and polycystic ovarian syndrome appear responsive, with case reports and series indicating tumor regression and improved reproductive function during and after fasting. Beyond disease, healthy individuals may gain reduced visceral fat and lower cholesterol, though shorter fasts are suggested for prevention. Safety remains essential: patients are screened, monitored, and refeed gradually to avoid refeeding syndrome, and long-duration fasts require supervision. The broader message is that fasting reshapes physiology and behavior, including taste perception and reward pathways, helping people reset habits toward a plant-based, SOS-free lifestyle.