Alcohol

On Ethanol, the Gut Microbiome, Hormones and much more.

2 drink per night whisky drinker for over 10 years. This is the video that convinced me to quick drinking permanently. After several months of zero alcohol consumption, I personally experience the following benefits: Triglyceride levels returned to normal BNP levels returned to normal Blood pressure returned to normal Skin improved in appearance Former IBS issues completely disappeared Sleep pattern returned to a state of what would be considered normal 12 year battle with anxiety and depression completely subsided and was able to discontinue daily use of 20mg Lexapro Increase energy level Increase in sexual desire Weight loss Overall heathier appearance and feeling Last but not lease, a fatter wallet and satisfaction that I will not give my money to these companies that hide the truth. Good luck to all! - massawakening6232

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I’ve never been a big drinker. I’ll have the occasional social drink, but that’s it.

So, I’m hardly an expert on the subject.

And I’ve certainly never thought about it from a health perspective. I knew it was “bad for your liver”, that’s about it. But I’m meant to know that much at least…it’s in the movies after all.

So, when my son put me onto the Huberman podcast on Alcohol, I thought, ok, let me see what all the fuss is about. Turns out there’s far more than just a “liver” story.

I think the liver is a limited hangout.

We are back to “constructed ignorance” again.

How could there not be.

It is a regulated chemical, taxed by the government, sold all over the world with Oligarchical Transnational interests.

Big Alcohol was always going to be a Reality™ creator. Silly me.

Huberman’s 2-hour discussion really took me by surprise.

I certainly had no idea that the alcohol (ethanol) I drink is the same ethanol we put in our cars. Yes, you read that right. More details to follow.

But even more importantly, I had no idea that alcohol destroys the gut microbiome. I guess it is obvious after the fact, but I had no idea. I suspect most are like me and would never think of taking probiotics, or eating pickles, after a Scotch. To think that alcohol and antibiotics could be discussed in the same sentence was an awakening for me. Again, more on this later.

And then there is the hormone discussion.

First, here is Huberman’s podcast that is definitely worth listening to.

But I will also provide a detailed summary, and I will do something new which is a series of topical deep dives and questions that I was particularly interested in, and then answer them based on how Huberman covered the subject in the podcast.

Here is a timestamp¹ to navigate the discussion.

Comprehensive Summary:

Introduction

• Alcohol is one of the most commonly consumed substances globally, with around 80% of adults in countries like the US consuming it.

• Humans and animals consume alcohol for recreational enjoyment, medical purposes, or to change their internal state/feelings.

• This episode discusses the biological effects of alcohol on cells, organs, brain, and behavior ranging from individual drinks to chronic heavy consumption.

Alcohol Metabolism & “Empty Calories”

• Alcohol (ethanol) can enter cells throughout the body as it’s water- and fat-soluble. This explains its widespread effects and toxicity.

• In the body, alcohol is converted to acetaldehyde², which is toxic, damaging cells indiscriminately. This is then converted to acetate to be used as fuel.

• This process uses NAD³, is stressful for the body, and the liver takes most of the damage.

• The feeling of being drunk comes from acetaldehyde's toxic effects disrupting neural circuits.

• Alcohol calories are considered “empty” as this process is metabolically costly but provides no nutrients.

Inebriation: Effects on Brain Function

• Initially, alcohol mildly suppresses prefrontal cortex activity, reducing top-down behavioral inhibition. This leads to increased impulsivity.

• Brain areas controlling flexible decision-making also shutdown, causing more impulsive, habitual behavior and speech without forethought.

• Alcohol severely disrupts memory formation, causing “blackouts.”

• With repeated/chronic drinking, changes occur in neural circuits controlling impulsivity, causing more impulsive behavior even when sober. This is reversible with abstinence.

Gut-Liver-Brain Effects

• Alcohol disrupts gut microbiome health, causing inflammation and “leaky gut⁴.” This allows harmful bacterial products to enter circulation.

• Inflammatory signals then reach the brain, further disrupting neural circuits promoting alcohol consumption in a vicious cycle. This drives dependence.

• Potentially replenishing the gut microbiome with probiotics⁵/fermented foods could help counteract this.

Hangover

• Alcohol disrupts sleep architecture⁶. The poor sleep contributes to hangover feelings.

• Gut inflammation also plays a role. Again, fermented foods may help alleviate this.

• Alcohol causes drops in dopamine. Cold exposure may help elevate catecholamines (dopamine, adrenaline) to counteract this.

• Alcohol is dehydrating due to increasing urine excretion. Hydrating well and replenishing electrolytes can mitigate this.

Alcohol Tolerance

• With repeated exposure, alcohol’s positive mood enhancing effects decrease while negative effects increase, altering the brain’s chemical signaling. This causes people to drink more to try to achieve positive effects again.

Health Effects

• Even light drinking reduces cortical thickness/gray matter in dose-dependent manner.

• Alcohol increases cancer risk, especially breast cancer, by 4-13% per 10g consumed daily. This is due to DNA methylation changes. Folate supplementation may partially mitigate increased risk.

• Drinking during pregnancy can lead to permanent embryonic developmental problems. No alcohol type is safer than others.

Hormonal Effects

• Alcohol increases conversion of testosterone to estrogen in both males and females via liver aromatase enzymes. This can negatively impact hormone levels/health.

Conclusions

• Alcohol is toxic to the body’s cells and drinking any amount induces negative changes in brain, hormone, and microbiome function.

• However, recovery is possible with abstinence. For those who continue drinking, mitigation strategies like microbiome support may help counteract some negative effects.

Excerpts:

• "Inebriation is actually a poison-induced disruption in the way that your neural circuits work."

• "When you ingest alcohol, it can pass into all the cells and tissues of your body, causing damage due to its toxic effects."

• "Even low to moderate amounts of alcohol consumption can cause thinning of the neocortex, leading to brain degeneration."

• "Chronic drinking doesn't necessarily mean every day and every night. It could be the person that simply drinks every Thursday or every Friday or just once a week has three or four drinks or maybe even a few more."

• "For the person that drinks, say, every Thursday night or every Friday night or goes out only on Saturdays but every Saturday, there's evidence that there are changes in the very circuits that underlie habitual and impulsive behavior."

• "Serotonin is a neuromodulator. It changes the activity of neural circuits and many neural circuits, in particular, those involved in mood and feelings of well-being."

• "People who start drinking at a younger age are at great risk of developing alcohol dependence regardless of family history."

• "Alcohol disrupts the gut microbiome, leading to leaky gut and inflammation, affecting the gut-liver-brain axis."

• "Alcohol lowers core body temperature, making people more susceptible to hypothermia if exposed to cold water while intoxicated."

• "Cold exposure, such as ice baths or cold showers, can increase adrenaline and dopamine, potentially speeding up hangover recovery if done safely."

• "Hangover is a multifaceted phenomenon, requiring a comprehensive approach involving gut microbiome replenishment, proper electrolyte balance, and abstaining from further alcohol consumption."

• "The PD-1 pathway seems to be upregulated, and there's a downregulation in some of the anti-inflammatory molecules that help suppress this proliferation of cancers."

• "Epidemiologists and health specialists compare alcohol consumption with smoking, stating that 10 grams of alcohol a day equals 10 cigarettes a day in terms of cancer risk."

• "Consumption of folate and B12 has been shown to decrease cancer risk in people who ingest alcohol, but not completely offset it."

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About ethanol.

Huberman discusses ethanol as one of the three main types of alcohol, alongside isopropyl and methyl alcohol. He emphasizes that only ethyl alcohol, or ethanol, is fit for human consumption. However, he also notes that ethanol is toxic and can cause substantial damage to cells.

Ethanol's toxicity is due to its need to be converted into other substances by the body, as it is inherently harmful. The conversion process involves a molecule called NAD, which is part of a biochemical pathway that transforms ethanol into acetaldehyde, and then eventually into acetate. Acetaldehyde is particularly harmful and can kill cells, leading to significant damage. The liver plays a crucial role in this conversion process, bearing the brunt of the alcohol metabolism, which can have detrimental effects on liver cells.

Is this the same ethanol used in cars and how does it differ?

Yes, the ethanol mentioned by Dr. Andrew Huberman in the podcast is chemically the same as the ethanol used as a fuel in cars. Ethanol, or ethyl alcohol, is a type of alcohol compound with the chemical formula C2H5OH.

However, the key differences between ethanol used for human consumption (as in alcoholic beverages) and ethanol used as a fuel lie in their purity, concentration, and the additives present:

1. Purity and Concentration: Ethanol in alcoholic beverages is mixed with water and other components (like sugars, flavors, etc.), and its concentration varies depending on the type of drink. For instance, beers have a lower ethanol concentration compared to spirits like vodka. Automotive ethanol, particularly the type used in fuel like E85 (a blend of 85% ethanol and 15% gasoline), is much more concentrated.

2. Additives: Ethanol for consumption is carefully produced and processed to be safe for human ingestion, albeit with the mentioned health effects as discussed by Dr. Huberman. Ethanol used in cars often contains additives to prevent human consumption, improve combustion, or to meet other automotive requirements. These additives make automotive ethanol toxic and unsafe for human consumption.

3. Denaturing: Ethanol for industrial or automotive use is often 'denatured', which means chemicals are added to make it undrinkable. This is done to avoid beverage taxes and regulations applied to drinking alcohol and to prevent misuse.

What is the effect on the gut microbiome?

Huberman discusses the impact of alcohol, specifically ethanol, on the gut microbiome. He explains that alcohol consumption can disrupt the balance of the gut microbiome in several ways:

1. Killing Good Bacteria: Alcohol, particularly its toxic metabolites like acetaldehyde, can kill beneficial bacteria in the gut. This disrupts the normal, healthy balance of the gut microbiome. The gut microbiome is crucial for various aspects of health, including digestion, immune function, and even mental health, so its disruption can have wide-ranging effects.

2. Promoting Leaky Gut Syndrome: The disruption of the gut microbiome by alcohol can lead to an increased permeability of the intestinal lining, a condition often referred to as "leaky gut syndrome." This allows harmful substances and bacteria to "leak" from the gut into the bloodstream, potentially leading to inflammation and other health issues.

3. Inflammation: The metabolization of alcohol in the liver and its impact on the gut can lead to the release of proinflammatory molecules and cytokines. These substances can contribute to systemic inflammation and may exacerbate the effects of a disrupted gut microbiome.

What should we know about alcohol metabolism, "empty calories" and key points about how alcohol affects the body?

Alcohol Metabolism & Its Impact

1. Water and Fat Solubility of Ethanol: Ethanol, the type of alcohol found in alcoholic beverages, is both water- and fat-soluble. This characteristic allows it to easily penetrate cell membranes and enter various types of cells throughout the body. This widespread accessibility is a major factor in ethanol's broad and potent effects, contributing to its toxicity.

2. Conversion to Acetaldehyde: Once ethanol enters the body, it undergoes metabolic processing, initially being converted into acetaldehyde. This conversion is a critical step in alcohol metabolism. Acetaldehyde is highly toxic and can cause significant damage to cells. It does not discriminate between cell types, meaning it can harm various tissues and organs.

3. Acetaldehyde to Acetate Transformation: The body cannot sustain high levels of acetaldehyde due to its toxicity. Therefore, acetaldehyde is further metabolized into acetate. This conversion is a defensive mechanism to reduce harm. Acetate is less harmful and can be used by the body as a fuel source. However, this process involves complex biochemical pathways and places a considerable metabolic burden on the body.

4. Role of NAD in Metabolism: The conversion of ethanol to acetaldehyde and then to acetate involves nicotinamide adenine dinucleotide (NAD), a crucial molecule in cellular energy metabolism. This process impacts the balance of NAD in the body and can influence various metabolic processes.

5. Liver Stress: The liver is the primary site for alcohol metabolism. Given the toxic nature of acetaldehyde and the metabolic demands of converting ethanol to safer compounds, the liver experiences significant stress and potential damage. Chronic alcohol consumption can lead to liver diseases such as fatty liver, hepatitis, and cirrhosis.

6. Effects on Neural Circuits: The inebriated state or the feeling of being drunk primarily arises from the disruptive effects of acetaldehyde on neural circuits in the brain. The toxin alters normal neural function, leading to the behavioral and cognitive changes associated with drunkenness.

Alcohol as "Empty Calories"

• Metabolic Cost Without Nutritional Benefit: The term "empty calories" refers to the fact that while alcohol provides energy (calories), it lacks nutritional value. The metabolic process of breaking down alcohol is energetically costly for the body but doesn't provide essential nutrients like vitamins, minerals, fatty acids, or amino acids.

• Comparison with Other Energy Sources: Unlike other energy sources such as carbohydrates, proteins, or fats, which contribute to various bodily functions and maintenance, the calories from alcohol offer little to no health benefit. This aspect is particularly important in the context of dietary choices and managing caloric intake, especially for those concerned with nutritional balance and health.

In summary, alcohol metabolism involves the conversion of ethanol to acetaldehyde and then to acetate, a process that is harmful to cells, particularly in the liver, and disrupts normal brain function. Despite providing calories, alcohol is considered nutritionally empty due to its lack of essential nutrients and the metabolic burden it places on the body.

What should we know about the gut-liver-brain axis in relation to alcohol consumption?

Gut-Liver-Brain Axis and Alcohol

1. Disruption of Gut Microbiome: Alcohol consumption negatively impacts the health of the gut microbiome, the community of microorganisms living in the digestive tract. Alcohol can kill beneficial bacteria and disrupt the balance of the gut ecosystem. This imbalance is detrimental because a healthy gut microbiome is crucial for digestion, immune function, and overall health.

2. Inflammation and Leaky Gut Syndrome: The alteration of the gut microbiome by alcohol can lead to increased gut permeability, often referred to as "leaky gut." This condition allows bacteria and bacterial products, which are normally contained within the gut, to enter the bloodstream. This translocation can trigger an immune response, leading to systemic inflammation.

3. Impact on the Liver and Brain: The liver, being a primary detoxification organ, tries to manage and process these bacterial products and the byproducts of alcohol metabolism. This adds stress to the liver, potentially exacerbating liver-related health issues. Moreover, the inflammatory signals that result from gut permeability and liver stress can cross the blood-brain barrier and impact brain function.

4. Neural Circuit Disruption: In the brain, these inflammatory signals can disrupt neural circuits. Notably, they may affect brain areas involved in reward, motivation, and decision-making. This disruption can enhance cravings and drive the desire for more alcohol, contributing to a cycle of dependence. Essentially, the initial consumption of alcohol leads to changes in the gut and liver, which then feed back to the brain, promoting further alcohol consumption.

5. Potential for Microbiome Replenishment: Given the role of gut health in this cycle, there's a potential strategy to mitigate some of alcohol's negative effects by focusing on the gut microbiome. Consuming probiotics (beneficial bacteria) and fermented foods (rich in probiotics and often prebiotics) can help restore a healthy balance in the gut microbiome. This, in turn, could potentially reduce the systemic inflammation caused by alcohol and break the cycle that leads to increased alcohol consumption and dependence.

Implications for Health and Recovery

• Strategies for Recovery: For individuals seeking to recover from alcohol dependence or to mitigate the effects of alcohol consumption, focusing on gut health could be a crucial part of their strategy. This might involve dietary changes, including incorporating probiotic-rich foods or supplements into their diet.

• Broader Health Considerations: The gut-liver-brain axis discussion underscores the interconnectedness of different body systems. It highlights how a substance like alcohol, often thought to primarily affect the liver and brain, can have broader systemic implications due to its impact on the gut microbiome.

In summary, alcohol's disruption of the gut microbiome, leading to inflammation and leaky gut syndrome, plays a significant role in its overall impact on health. This disruption affects not only the gut but also the liver and brain, creating a cycle that can drive alcohol dependence.

What is the link between alcohol consumption and an increased risk of cancer?

Alcohol and Increased Cancer Risk

1. Risk Increase with Consumption: Research indicates that for every 10 grams of alcohol consumed daily, there's a 4-13% increased risk of developing cancer, especially breast cancer. This statistic is particularly alarming given that 10 grams of alcohol is roughly equivalent to a small glass of wine or a single beer. The risk is dose-dependent, meaning the more alcohol consumed, the higher the risk.

2. Mechanism - DNA Methylation Changes: The mechanism behind this increased cancer risk involves changes in DNA methylation. DNA methylation is a biochemical process that adds a methyl group to DNA. It is crucial in regulating gene expression - turning genes on or off. Alcohol consumption can alter these methylation patterns, leading to inappropriate activation or suppression of genes, including those involved in cancer development.

3. Breast Cancer Risk: Alcohol's impact on DNA methylation is particularly relevant for breast cancer. Breast tissue is sensitive to hormonal changes and genetic mutations, both of which can be influenced by alcohol. This sensitivity contributes to the higher incidence of breast cancer linked to alcohol consumption.

Role of Folate in Mitigating Risk

1. Folate's Protective Role: Folate, a B-vitamin, is known for its role in DNA synthesis and repair. It's also involved in methylation processes. Adequate folate levels in the body can help maintain normal DNA methylation patterns, potentially offsetting some of the harmful effects of alcohol on DNA.

2. Supplementation and Diet: To counteract the risks associated with alcohol consumption, folate supplementation or increased dietary intake of folate-rich foods (like leafy greens, legumes, and some fruits) may be beneficial. This approach is especially important for individuals who consume alcohol regularly, as it might help reduce the risk of alcohol-induced cancer, particularly breast cancer.

3. Partial Mitigation: It's important to note that while folate can play a protective role, it might only partially mitigate the increased risk of cancer due to alcohol consumption. The best approach for reducing cancer risk is to limit or avoid alcohol.

4. Implications for Public Health: Understanding the link between alcohol consumption, DNA methylation, and cancer risk is vital for public health messaging. While moderate alcohol consumption is often considered socially acceptable, awareness of its potential long-term health impacts, such as increased cancer risk, is crucial.

In summary, regular alcohol consumption increases the risk of certain cancers, notably breast cancer, through changes in DNA methylation. Folate, due to its role in DNA processes, may help mitigate this risk, but it does not completely eliminate it. The best strategy for reducing cancer risk related to alcohol is to limit or abstain from alcohol consumption. However, for those who do consume alcohol, maintaining a diet rich in folate or considering folate supplementation could be beneficial for reducing some of the associated risks.

Does ethanol kill the good and the bad bacteria in the gut microbiome?

Yes, ethanol can negatively affect the gut microbiome by killing both the harmful and beneficial bacteria. When you consume alcohol, it can disrupt the delicate balance of the gut ecosystem in several ways:

1. Destruction of Beneficial Bacteria: Ethanol has antibacterial properties, which means it can kill bacteria. This property is not selective to harmful bacteria alone; it can also destroy beneficial bacteria in the gut. These beneficial bacteria are crucial for digestion, synthesizing certain vitamins, supporting immune function, and maintaining overall gut health.

2. Promotion of Harmful Bacteria: The imbalance created by the loss of beneficial bacteria can lead to an overgrowth of harmful bacteria. This can disrupt the gut flora balance further, potentially leading to digestive issues and other health problems.

3. Impact on Gut Barrier Function: Alcohol consumption, particularly excessive consumption, can damage the cells lining the gut, leading to increased intestinal permeability, often referred to as "leaky gut." This condition allows toxins and bacterial products to enter the bloodstream, which can trigger inflammation and other negative health effects.

4. Overall Disruption of Gut Health: The combined effect of killing beneficial bacteria, promoting harmful bacteria, and damaging the gut lining contributes to a disrupted gut microbiome. This disruption can have wide-ranging effects on overall health, including increased inflammation, impaired immune function, and potentially contributing to the development of various diseases.

For maintaining a healthy gut microbiome, moderating alcohol intake or abstaining from it, especially heavy or frequent consumption, is advisable. Additionally, incorporating probiotics and prebiotics into the diet can help support and replenish the gut microbiome.

How would you compare its effect to antibiotics on the gut microbiome?

Both can significantly alter the gut's bacterial composition, but they do so in different ways:

Ethanol (Alcohol) and the Gut Biome:

1. Non-Selective Bacterial Destruction: Ethanol has broad antibacterial properties, meaning it can kill both beneficial and harmful bacteria in the gut. This property can lead to a reduction in the diversity of the gut microbiome.

2. Gut Lining Damage: Ethanol can damage the cells lining the gut, leading to increased intestinal permeability, known as "leaky gut." This allows harmful substances to enter the bloodstream, potentially causing inflammation and other health issues.

3. Promotion of Dysbiosis: The imbalance created by ethanol can favor the growth of harmful bacteria, leading to a condition called dysbiosis. This can disrupt digestion, immune function, and overall gut health.

Antibiotics and the Gut Biome:

1. Targeted Bacterial Destruction: Antibiotics are designed to kill or inhibit the growth of specific bacteria causing infections. However, they often also affect beneficial bacteria, leading to a decrease in microbial diversity.

2. Rapid and Significant Impact: Antibiotics can cause a rapid and significant change in the gut microbiome. The extent of this change depends on the type of antibiotic, dosage, and duration of treatment.

3. Potential for Long-Term Changes: The effects of antibiotics on the gut microbiome can sometimes be long-lasting. Some beneficial bacteria might not fully recover even months after antibiotic treatment, potentially leading to long-term gut health issues.

Key Differences:

• Selectivity: While both ethanol and antibiotics disrupt the gut microbiome, antibiotics are more targeted in their action against specific bacteria. In contrast, ethanol's antibacterial effect is more generalized and non-selective.

• Recovery: Post-antibiotic recovery of the gut microbiome can be a slow process and might require probiotic or prebiotic interventions. The gut microbiome's recovery from ethanol exposure might also need similar interventions, but the patterns of recovery can differ.

• Secondary Effects: Ethanol has additional effects like damaging the gut lining and promoting leaky gut, which is not typically a direct consequence of antibiotic use.

Conclusion:

Both ethanol and antibiotics can significantly disrupt the gut microbiome, but their mechanisms of action and the extent of their effects differ. Ethanol's impact is more generalized and includes damage to the gut lining, while antibiotics have a targeted but sometimes profound impact on microbial diversity.

What is alcohol’s effect on testosterone and estrogen in both males and females?

Alcohol's impact on hormone levels, particularly the conversion of testosterone to estrogen, is a significant aspect of its effects on the body, affecting both males and females. This process involves liver enzymes called aromatase enzymes. Here's a more detailed explanation:

Alcohol and Hormone Conversion:

1. Aromatase Enzymes: Aromatase is an enzyme that converts androgens (like testosterone) into estrogens. It's naturally present in various body tissues, including the liver, fat tissue, and gonads (ovaries and testes).

2. Alcohol's Effect on Aromatase: Alcohol consumption can increase the activity of aromatase enzymes. This heightened activity leads to a higher conversion rate of testosterone to estrogen.

3. Impact on Hormone Levels:

   • In Males: The increased conversion can lead to a reduction in testosterone levels and an increase in estrogen levels. This hormonal imbalance can result in several health issues, such as decreased muscle mass, increased body fat, reduced libido, and potential fertility issues. In some cases, it can lead to the development of gynecomastia (enlargement of breast tissue in males).

   • In Females: While estrogen is a primary female hormone, an excessive increase due to alcohol-induced aromatization can disrupt the normal hormonal balance. This can affect menstrual cycles, potentially leading to irregular periods or fertility issues. Additionally, high estrogen levels are linked to an increased risk of certain cancers, such as breast cancer.

Health Implications:

• Liver Health: Since the liver is a key site for aromatase activity and alcohol metabolism, chronic alcohol consumption can lead to liver damage, exacerbating hormonal imbalances.

• Cancer Risk: The alteration in estrogen levels, particularly in females, can increase the risk of estrogen-dependent cancers, like breast cancer. This is compounded by alcohol's other carcinogenic effects.

• Overall Hormonal Health: Hormones like testosterone and estrogen have wide-ranging effects beyond reproductive health, influencing mood, energy levels, bone density, and cardiovascular health. Thus, alcohol-induced hormonal imbalances can have broad health implications.

Mitigation and Management:

• Moderation or Abstinence: Reducing alcohol intake or abstaining altogether can help normalize hormone levels and reduce the risk of associated health issues.

• Monitoring Hormone Levels: Individuals with heavy alcohol consumption histories, particularly those experiencing symptoms of hormonal imbalance, may benefit from medical evaluation and monitoring of hormone levels.

• Lifestyle Adjustments: Incorporating a healthy diet, regular exercise, and stress management can also support hormonal health and mitigate some of the negative impacts of alcohol.

In summary, alcohol's effect on increasing the conversion of testosterone to estrogen through liver aromatase enzymes is a crucial factor in understanding its broader health implications. This process can lead to significant hormonal imbalances in both males and females, affecting various aspects of health and well-being.

Ten short Q&As on Alcohol's Impact on Health

1. What is Ethanol and How is it Similar to the Ethanol Used in Cars?

Answer: Ethanol, also known as ethyl alcohol, is the type of alcohol found in alcoholic beverages. It's a clear, colorless liquid that's produced by the fermentation of sugars by yeasts. This is the same chemical compound used in cars as a biofuel. However, the ethanol in alcoholic drinks is made for consumption, while the ethanol used as fuel often contains additives to prevent ingestion.

2. Does Consuming Ethanol Have the Same Impact as Antibiotics on Our Gut Biome?

Answer: Ethanol consumption can negatively impact the gut microbiome, but its effects differ from antibiotics. While antibiotics specifically target bacteria, often reducing both harmful and beneficial bacteria, ethanol can cause an imbalance by promoting inflammation and weakening gut barriers. This leads to a condition known as 'leaky gut', where harmful substances can enter the bloodstream. The overall impact is a disrupted gut microbiome, which can have various health implications.

3. How Does Ethanol Consumption Affect Hormone Levels, Particularly Testosterone and Estrogen?

Answer: Ethanol consumption can alter hormone levels by increasing the conversion of testosterone to estrogen in both men and women. This process, driven by liver enzymes called aromatase, can lead to imbalanced hormone levels, affecting health and physical attributes. For instance, in men, increased estrogen can result in symptoms like gynecomastia (enlarged breasts).

4. What is the Connection Between Alcohol Consumption and Cancer Risk?

Answer: Alcohol consumption has been linked to an increased risk of several types of cancer, including breast, liver, and colorectal cancer. Ethanol is metabolized into acetaldehyde, a toxic compound that can damage DNA and proteins, leading to cancerous changes in cells. Regular alcohol consumption, even at moderate levels, can significantly elevate this risk.

5. Is There a Safe Level of Alcohol Consumption Regarding Cancer Risk?

Answer: There's no "safe" level of alcohol consumption completely free from cancer risk. However, risk increases with the amount consumed. Light to moderate drinking poses a lower risk compared to heavy drinking, but even small amounts can contribute to a heightened risk of certain cancers.

6. How Does the Body Process Ethanol and Why are its Calories Considered 'Empty'?

Answer: The body processes ethanol by first converting it to acetaldehyde and then to acetate, which can be used as a fuel source. However, this process is metabolically expensive and provides no nutritional benefits, hence the term 'empty calories'. Alcohol calories don't contribute beneficial nutrients like vitamins, minerals, or fiber.

7. What are the Long-Term Effects of Alcohol on the Brain and Cognitive Function?

Answer: Long-term alcohol consumption can have significant detrimental effects on the brain. It can lead to cognitive impairments, memory loss, and even irreversible brain damage in severe cases. Chronic alcohol use can shrink brain matter and disrupt neurotransmitters, which are essential for healthy brain function.

8. Can the Negative Effects of Alcohol on the Gut Biome be Counteracted?

Answer: Some negative effects of alcohol on the gut biome can be mitigated with dietary changes and supplements. Consuming probiotics and fermented foods can help restore a healthy gut microbiome balance. These foods promote beneficial bacteria, countering some of the disruptive effects of alcohol.

9. What Role Does Alcohol Play in Altering DNA and Increasing Cancer Risk?

Answer: Alcohol, especially its metabolite acetaldehyde, can alter DNA through processes like DNA methylation. These changes can disrupt normal cell functions and lead to uncontrolled cell growth or cancer. Regular alcohol consumption increases the likelihood of these DNA alterations.

10. How Does Alcohol Consumption Influence Our Stress and Anxiety Levels?

Answer: Alcohol initially acts as a depressant on the nervous system, which can temporarily reduce stress and anxiety. However, chronic consumption can lead to an increased baseline level of stress hormones like cortisol, making individuals more susceptible to anxiety and stress in the long term, especially during periods of withdrawal or reduced intake.

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1

Timestamps

00:00:00 Effects of Alcohol Consumption

00:02:25 Momentous Supplements

00:03:19 Low to Moderate Alcohol Consumption & Neurodegeneration

00:06:52 Levels, Eight Sleep, ROKA

00:10:46 Historical Context & Uses of Alcohol

00:13:28 Alcohol Metabolism, “Empty Calories”

00:18:23 Inebriation: Top-Down Inhibition, Impulsivity & Memory Formation

00:24:23 Long-Lasting Effects & Impulsivity, Neuroplasticity & Reversibility

00:27:55 Food & Alcohol Absorption

00:30:07 Alcohol & Serotonin, SSRIs & Depression, Risk for Alcoholism, Blackouts

00:37:39 Predisposition for Alcoholism; Chronic Consumption, Cortisol & Stress

00:44:53 AG1 (Athletic Greens)

00:46:07 Genetic Predisposition for Alcoholism, Consuming Alcohol Too Young

00:52:27 Gut-Liver-Brain Axis: Alcohol, Gut Microbiome, Inflammation & Leaky Gut

00:59:46 Tool: Improving/Replenishing Gut Microbiome

01:02:44 Reducing Alcohol Consumption & Stress

01:04:25 Hangover: Alcohol & Sleep, Anxiety, Headache

01:12:11 Hangover Recovery, Adrenaline & Deliberate Cold Exposure

01:17:16 Hangover Recovery, Dehydration & Electrolytes

01:20:45 Types of Alcohol & Hangover Severity, Congeners 

01:25:25 Alcohol Tolerance, Dopamine & Serotonin, Pleasure-Pain Balance  

01:33:36 Are There Any Positive Effects of Alcohol?, Resveratrol

01:35:42 Alcohol & Brain Thickness

01:37:11 Alcohol & Cancer Risk: DNA Methylation, Breast Cancer Risk

01:44:31 Mitigating Cancer Risk, Folate, B Vitamins

01:46:54 Alcohol & Pregnancy, Fetal Alcohol Syndrome

01:50:58 Hormones: Testosterone & Estrogen Balance

01:55:09 Negative Effects of Alcohol Consumption

2

Acetaldehyde is a chemical compound with the formula CH₃CHO. It's an organic chemical that occurs naturally in various plants, ripe fruits, vegetables, and is also produced by some types of fungi and bacteria. However, it's most commonly recognized for its role in the metabolism of alcohol in the human body. When you consume alcoholic beverages, the ethanol (alcohol) is first metabolized into acetaldehyde by the liver enzyme alcohol dehydrogenase.

Acetaldehyde is highly reactive and toxic, and it's a known carcinogen, meaning it has the potential to cause cancer. Its toxicity is one reason why overconsumption of alcohol can lead to acute and chronic health issues, including liver damage, hangover symptoms, and increased cancer risk. The body further metabolizes acetaldehyde into acetic acid (a component of vinegar), which is less harmful and can be eliminated from the body. This second conversion step is primarily facilitated by another enzyme, aldehyde dehydrogenase.

In summary, acetaldehyde is a significant intermediate in the metabolic breakdown of alcohol, playing a crucial role in the physiological effects and health risks associated with alcohol consumption.

3

NAD, or Nicotinamide Adenine Dinucleotide, is a crucial coenzyme found in all living cells. It plays a vital role in metabolic processes, particularly in redox reactions, where it acts as a carrier for electrons and hydrogen ions. These reactions are essential for the production of energy within cells.

NAD exists in two forms:

1. NAD+: This is the oxidized form of NAD. It functions as an electron acceptor in metabolic reactions, particularly in the processes of glycolysis, the citric acid cycle, and oxidative phosphorylation, which are key parts of cellular respiration and energy production.

2. NADH: The reduced form of NAD, carrying electrons and hydrogen, which it can donate to other molecules. NADH is primarily involved in the production of ATP, the energy currency of the cell, during the electron transport chain in mitochondria.

NAD is also involved in non-redox roles, such as acting as a substrate for enzymes like sirtuins and poly(ADP-ribose) polymerases, which are involved in various cellular processes including DNA repair, gene expression regulation, and aging.

In the context of alcohol metabolism, NAD plays a critical role. The enzyme alcohol dehydrogenase uses NAD+ to convert ethanol (alcohol) to acetaldehyde, with NAD+ being reduced to NADH in the process. This reaction is part of the body's mechanism for metabolizing and eliminating alcohol, but it also highlights the intricate balance of redox states within cells, which is crucial for maintaining overall cellular health and function.

4

"Leaky gut syndrome" is a term used to describe a condition where the lining of the small intestine becomes damaged, leading to increased intestinal permeability. This means that substances like toxins, undigested food particles, and bacteria can "leak" through the intestinal walls into the bloodstream. It's important to note that leaky gut is not a medically recognized condition in the conventional sense, but the concept of increased intestinal permeability and its potential health consequences is a topic of ongoing research and debate in the medical community.

Here's a more detailed look at the concept:

1. Intestinal Barrier Function: The gut lining serves as a barrier controlling what gets absorbed into the bloodstream. It's selectively permeable to allow nutrients to pass through while keeping harmful substances out.

2. Disruption of the Barrier: Factors like chronic stress, poor diet, excessive alcohol consumption, infections, and certain medications can potentially disrupt this barrier function. The tight junctions holding the gut cells together can become loose, leading to increased permeability.

3. Consequences of Increased Permeability: When larger, potentially harmful particles enter the bloodstream, it can lead to an immune response, inflammation, and may contribute to various health issues. These can range from gastrointestinal problems like bloating and gas to systemic issues like allergies, skin conditions, autoimmune diseases, and possibly chronic diseases.

5

Probiotics are live microorganisms, typically bacteria and sometimes yeast, that are believed to provide health benefits when consumed in adequate amounts. These microorganisms are similar to beneficial microorganisms found in the human gut, commonly referred to as the gut microbiome. Probiotics are often called "good" or "friendly" bacteria because they help keep the gut healthy.

Here are some key points about probiotics:

1. Types of Probiotics: There are many different types of probiotic bacteria, but the most common are from the groups Lactobacillus and Bifidobacterium. Each group comprises different species, and each species has many strains. Different probiotics serve different purposes.

2. Sources of Probiotics: Probiotics can be found in fermented foods such as yogurt, kefir, sauerkraut, tempeh, and kimchi. They are also available as dietary supplements in the form of capsules, tablets, and powders.

3. Health Benefits: Probiotics are believed to restore the natural balance of bacteria in the gut when it has been disrupted by illness or treatment (like antibiotics). They're also associated with a wide range of health benefits, including improved digestion, enhanced immune function, healthier skin, and a reduced risk of some diseases. Some specific benefits attributed to certain strains include relief from irritable bowel syndrome (IBS), improved lactose tolerance, and mitigation of diarrhea.

4. Mechanism of Action: While the exact mechanisms by which probiotics exert their effects are not fully understood, they may include outcompeting harmful bacteria for food and space, producing substances that inhibit or kill pathogens, and interacting with the immune system to enhance its response to disease-causing microorganisms.

6

Sleep architecture refers to the structure and pattern of sleep cycles that occur during a typical night's rest. Understanding sleep architecture involves looking at the different stages of sleep and how they are sequenced and repeated throughout the night. Sleep is typically divided into several stages, which are characterized by different brain wave activities and physiological responses.

The main stages of sleep are:

1. NREM (Non-Rapid Eye Movement) Sleep: This phase is further divided into three stages:

   • Stage N1 (Light Sleep): This is the transition from wakefulness to sleep. It's a short period (lasting a few minutes) where you're somewhat awake and somewhat asleep. During this stage, muscle activity slows down, and you can be easily awakened.

   • Stage N2 (True Sleep): This is where you spend most of your sleep time. Body temperature drops, heart rate and breathing become regular, and you become less aware of your surroundings. Brain waves slow down further, but there are brief bursts of electrical activity known as sleep spindles and K-complexes.

   • Stage N3 (Deep Sleep or Slow-Wave Sleep): This is the deepest stage of sleep and is crucial for feeling refreshed in the morning. During this stage, the body repairs tissues, builds bone and muscle, and strengthens the immune system. Brain waves are at their slowest, with high amplitude delta waves.

2. REM (Rapid Eye Movement) Sleep: This stage occurs about 90 minutes after falling asleep and recurs several times a night, lasting longer with each cycle. REM sleep is characterized by rapid eye movements, increased brain activity, vivid dreams, and temporary muscle paralysis (to prevent acting out dreams). It plays a crucial role in memory consolidation and mood regulation.

A typical night's sleep will cycle through these stages several times. The order usually goes from N1 to N2, N3, then back to N2 before entering REM sleep. As the night progresses, the duration of REM sleep increases and deep N3 sleep decreases.

Comments

[Justin daws]

Ok..next up, how does one stop drinking?

I was an alcoholic for 35 years.

1. It is not a disease.

2. I couldn't give up because my brain was wired to repeat the same behaviour due to rutting of the neural pathways.

3. I didn't want to give up because I knew from a very young age that there was something terribly wrong with world, and when I stopped drinking for any length of time I would start seeing the wrongness again and the people around me became seemingly more stupid.

4. Being sober is lonely. So to drop drinking I had to engage with people and cut all ties with people I used to drink with. I severed friendships of 45 years, and within 12 months realised that they were not friends, just sad, lonely people unable to change.

My friends now are my neighbours, local people and the people I communicate with on substack are my family now as my blood family is poisoned.

This book shows that if you totally stop drinking ( or other addiction), you can not only recover you memory and repair your damaged brain, something unexplained happens... Your brain surpasses what it was at its prior best... Read the book...

" The biology of desire" by Mark Lewis.

[Steve]

I stopped drinking fully 19 years ago, was a big binge drinker on the odd social occasion... After an initial period of discomfort at social settings with friends urging you to drink, that soon settled down and people accepted my decision.

I noticed better health within six months, any puffy weight I had went, social occasions didn't require thinking about how much I had, and if I could drive home, I was more relaxed in social settings too (I used to have a drink to loosen up, but found I actually just needed to relax)... and now 19 years have gone by, I think I have spared my liver and body a bonus 19 years of all that stress my binge drinking used to cause. I may very well have done some damage earlier in my youth and ignorance but so far my health has been very good...

This was a great article thank you and I've saved and filed it !