Although we recommend 2-4%, even for the same person, the amount of reactive oxygen generated differs between a day spent relaxing and a day running 20km, so the required amount will be different.
@@shigekihealthywealthy thanks for the reply. I mean, the flow rate of the machine. There are machine producing < 300 ml/min. So what is the recommended machine flow rate?
Hydrogen inhalers don't reduce HbA1c (hemoglobin A1c) because HbA1c is a measure of average blood glucose levels over the past two to three months, reflecting long-term glucose control rather than short-term effects. While hydrogen gas (H₂) is known for its antioxidant and anti-inflammatory properties, the mechanisms behind HbA1c formation and blood sugar regulation involve complex pathways that hydrogen gas doesn’t directly impact. Hydrogen gas might reduce oxidative stress and inflammation, which can be beneficial for overall cellular health. However, it does not directly lower blood glucose levels or affect the mechanisms that produce HbA1c, which relies heavily on insulin function, glucose uptake, and glycation processes. To impact HbA1c, treatments need to influence blood sugar regulation over an extended period, typically through dietary changes, physical activity, or medications that improve insulin sensitivity and glucose metabolism. Patients with metabolic disorders, such as diabetes, obesity, or metabolic syndrome, may not experience significant benefits from hydrogen inhalation devices because these disorders involve complex biochemical pathways that hydrogen inhalation alone may not address. Here are a few reasons why: 1. **Limited Impact on Blood Glucose Regulation**: Metabolic disorders often involve insulin resistance, impaired glucose metabolism, or dysfunctional lipid processing. Hydrogen inhalation may reduce oxidative stress and inflammation to a degree, but it doesn’t directly improve insulin sensitivity or help regulate blood sugar. 2. **Complex Pathways Involved**: Metabolic disorders stem from various genetic, hormonal, and environmental factors, making them difficult to manage with a single treatment. Hydrogen has antioxidant effects but doesn’t address the underlying dysregulation in metabolism, such as insulin function or lipid accumulation, which are critical in these conditions. 3. **Lack of Evidence for Long-Term Benefits**: While hydrogen inhalation shows some promise in reducing oxidative stress markers in research, long-term studies on its impact specifically for metabolic disorders are limited. For patients with these disorders, proven lifestyle interventions (like diet and exercise) and medications are usually required to manage symptoms effectively. 4. **Insufficient Impact on Key Metabolic Hormones**: Hydrogen inhalation doesn’t directly influence key metabolic hormones like insulin, leptin, or adiponectin, which play crucial roles in conditions like obesity and diabetes. Without affecting these hormones, hydrogen alone isn’t likely to provide substantial benefits. In summary, hydrogen inhalation might offer some antioxidant and anti-inflammatory benefits, but it doesn’t address the core metabolic dysfunctions involved in these disorders. Effective management usually requires a more comprehensive approach targeting blood glucose, insulin resistance, and lifestyle factors. Hydrogen inhalation devices are often marketed for their potential health benefits, including antioxidant effects and anti-inflammatory properties. However, there are several reasons why they may not significantly benefit metabolic pathways: 1. **Limited Research Evidence**: While some studies suggest that hydrogen gas can exert antioxidant effects, the evidence is still limited and sometimes inconclusive regarding its direct benefits to metabolic pathways. 2. **Mechanism of Action**: The proposed mechanisms by which hydrogen might influence metabolism are not fully understood. While hydrogen may reduce oxidative stress, the exact biochemical interactions with metabolic pathways require further exploration. 3. **Bioavailability**: The effectiveness of inhaled hydrogen in reaching tissues and cells where metabolic processes occur is uncertain. The delivery method may not ensure adequate concentrations at the target sites. 4. **Individual Differences**: The impact of hydrogen inhalation can vary widely among individuals due to factors like genetics, existing health conditions, and overall lifestyle, making it difficult to generalize its metabolic benefits. 5. **Regulatory and Safety Concerns**: Hydrogen inhalation devices are not universally regulated, leading to variability in product quality and safety, which can further complicate their efficacy. 6. **Complementary Role**: Hydrogen inhalation might serve more as a complementary therapy rather than a primary intervention for metabolic issues, making it less impactful when not combined with other healthy lifestyle choices. In summary, while there is potential for hydrogen inhalation to offer some health benefits, its role in enhancing metabolic pathways is not well-established and requires further scientific investigation. Oxidative stress occurs when there is an imbalance between free radicals (reactive oxygen species) and antioxidants in the body. This imbalance can significantly impact overall health and wellness in several ways: 1. **Cellular Damage**: Free radicals can damage cellular components such as DNA, proteins, and lipids, leading to impaired cell function and increased risk of mutations that can contribute to diseases, including cancer. 2. **Aging**: Oxidative stress is linked to the aging process. Accumulation of oxidative damage over time can lead to age-related decline in cellular function and contribute to the development of age-associated diseases. 3. **Inflammation**: Oxidative stress can trigger inflammatory responses in the body. Chronic inflammation is associated with a variety of health issues, including autoimmune diseases, cardiovascular diseases, and neurodegenerative disorders. 4. **Chronic Diseases**: High levels of oxidative stress have been implicated in the development and progression of chronic diseases such as diabetes, heart disease, and neurodegenerative diseases like Alzheimer's and Parkinson's disease. 5. **Compromised Immune Function**: Oxidative stress can impair immune system function, making the body more susceptible to infections and reducing the effectiveness of immune responses. 6. **Mental Health**: Some studies suggest a link between oxidative stress and mental health conditions, such as depression and anxiety, highlighting its potential role in affecting mood and cognitive function. 7. **Metabolic Disorders**: Oxidative stress can disrupt metabolic processes, contributing to insulin resistance and metabolic syndrome, which can further lead to obesity and type 2 diabetes. 8. **Skin Health**: Oxidative stress can accelerate skin aging, leading to wrinkles, loss of elasticity, and other skin issues due to damage to skin cells and collagen. Overall, managing oxidative stress through a balanced diet rich in antioxidants, regular physical activity, and healthy lifestyle choices can help mitigate its negative impacts on health and promote overall wellness.
The equipment we use has an outlet that uses 666.666% hydrogen. When mixed with the air you breathe, it becomes a theoretical value of 4%. In other words, high concentrate hydrogen cannot be taken into the body in its entirety.
Hydrogen therapy doesn’t work in people with the following; high HbA1c, obesity, already had cancer, metabolic problems, history of smoking, alcohol consumption and unhealthy eating etc. there are only a small amount of benefits in healthy people. However hydrogen did work, I would think the doctor would look healthier and not be fat. Doctors are selling hope! 水素療法は、次の人には機能しません。高HbA1c、肥満、すでに癌、代謝の問題、喫煙歴、アルコール消費、不健康な人には少量の利益しかありません。水素がうまくいったとしても、医者はより健康に見え、太っていないと思います。医者は希望を売っている!
What is the best flow ml/min for 1 person?
Although we recommend 2-4%, even for the same person, the amount of reactive oxygen generated differs between a day spent relaxing and a day running 20km, so the required amount will be different.
@@shigekihealthywealthy thanks for the reply. I mean, the flow rate of the machine. There are machine producing < 300 ml/min. So what is the recommended machine flow rate?
@@shigekihealthywealthy thank you
it depend on the patient . if u cant you can get via drinkuing water diffused h2 gas .
@@KeyMarkableThank you for your comment☺️
how to get in india
Hydrogen inhalers don't reduce HbA1c (hemoglobin A1c) because HbA1c is a measure of average blood glucose levels over the past two to three months, reflecting long-term glucose control rather than short-term effects. While hydrogen gas (H₂) is known for its antioxidant and anti-inflammatory properties, the mechanisms behind HbA1c formation and blood sugar regulation involve complex pathways that hydrogen gas doesn’t directly impact. Hydrogen gas might reduce oxidative stress and inflammation, which can be beneficial for overall cellular health. However, it does not directly lower blood glucose levels or affect the mechanisms that produce HbA1c, which relies heavily on insulin function, glucose uptake, and glycation processes. To impact HbA1c, treatments need to influence blood sugar regulation over an extended period, typically through dietary changes, physical activity, or medications that improve insulin sensitivity and glucose metabolism.
Patients with metabolic disorders, such as diabetes, obesity, or metabolic syndrome, may not experience significant benefits from hydrogen inhalation devices because these disorders involve complex biochemical pathways that hydrogen inhalation alone may not address. Here are a few reasons why: 1. **Limited Impact on Blood Glucose Regulation**: Metabolic disorders often involve insulin resistance, impaired glucose metabolism, or dysfunctional lipid processing. Hydrogen inhalation may reduce oxidative stress and inflammation to a degree, but it doesn’t directly improve insulin sensitivity or help regulate blood sugar. 2. **Complex Pathways Involved**: Metabolic disorders stem from various genetic, hormonal, and environmental factors, making them difficult to manage with a single treatment. Hydrogen has antioxidant effects but doesn’t address the underlying dysregulation in metabolism, such as insulin function or lipid accumulation, which are critical in these conditions. 3. **Lack of Evidence for Long-Term Benefits**: While hydrogen inhalation shows some promise in reducing oxidative stress markers in research, long-term studies on its impact specifically for metabolic disorders are limited. For patients with these disorders, proven lifestyle interventions (like diet and exercise) and medications are usually required to manage symptoms effectively. 4. **Insufficient Impact on Key Metabolic Hormones**: Hydrogen inhalation doesn’t directly influence key metabolic hormones like insulin, leptin, or adiponectin, which play crucial roles in conditions like obesity and diabetes. Without affecting these hormones, hydrogen alone isn’t likely to provide substantial benefits. In summary, hydrogen inhalation might offer some antioxidant and anti-inflammatory benefits, but it doesn’t address the core metabolic dysfunctions involved in these disorders. Effective management usually requires a more comprehensive approach targeting blood glucose, insulin resistance, and lifestyle factors.
Hydrogen inhalation devices are often marketed for their potential health benefits, including antioxidant effects and anti-inflammatory properties. However, there are several reasons why they may not significantly benefit metabolic pathways: 1. **Limited Research Evidence**: While some studies suggest that hydrogen gas can exert antioxidant effects, the evidence is still limited and sometimes inconclusive regarding its direct benefits to metabolic pathways. 2. **Mechanism of Action**: The proposed mechanisms by which hydrogen might influence metabolism are not fully understood. While hydrogen may reduce oxidative stress, the exact biochemical interactions with metabolic pathways require further exploration. 3. **Bioavailability**: The effectiveness of inhaled hydrogen in reaching tissues and cells where metabolic processes occur is uncertain. The delivery method may not ensure adequate concentrations at the target sites. 4. **Individual Differences**: The impact of hydrogen inhalation can vary widely among individuals due to factors like genetics, existing health conditions, and overall lifestyle, making it difficult to generalize its metabolic benefits. 5. **Regulatory and Safety Concerns**: Hydrogen inhalation devices are not universally regulated, leading to variability in product quality and safety, which can further complicate their efficacy. 6. **Complementary Role**: Hydrogen inhalation might serve more as a complementary therapy rather than a primary intervention for metabolic issues, making it less impactful when not combined with other healthy lifestyle choices. In summary, while there is potential for hydrogen inhalation to offer some health benefits, its role in enhancing metabolic pathways is not well-established and requires further scientific investigation.
Oxidative stress occurs when there is an imbalance between free radicals (reactive oxygen species) and antioxidants in the body. This imbalance can significantly impact overall health and wellness in several ways: 1. **Cellular Damage**: Free radicals can damage cellular components such as DNA, proteins, and lipids, leading to impaired cell function and increased risk of mutations that can contribute to diseases, including cancer. 2. **Aging**: Oxidative stress is linked to the aging process. Accumulation of oxidative damage over time can lead to age-related decline in cellular function and contribute to the development of age-associated diseases. 3. **Inflammation**: Oxidative stress can trigger inflammatory responses in the body. Chronic inflammation is associated with a variety of health issues, including autoimmune diseases, cardiovascular diseases, and neurodegenerative disorders. 4. **Chronic Diseases**: High levels of oxidative stress have been implicated in the development and progression of chronic diseases such as diabetes, heart disease, and neurodegenerative diseases like Alzheimer's and Parkinson's disease. 5. **Compromised Immune Function**: Oxidative stress can impair immune system function, making the body more susceptible to infections and reducing the effectiveness of immune responses. 6. **Mental Health**: Some studies suggest a link between oxidative stress and mental health conditions, such as depression and anxiety, highlighting its potential role in affecting mood and cognitive function. 7. **Metabolic Disorders**: Oxidative stress can disrupt metabolic processes, contributing to insulin resistance and metabolic syndrome, which can further lead to obesity and type 2 diabetes. 8. **Skin Health**: Oxidative stress can accelerate skin aging, leading to wrinkles, loss of elasticity, and other skin issues due to damage to skin cells and collagen. Overall, managing oxidative stress through a balanced diet rich in antioxidants, regular physical activity, and healthy lifestyle choices can help mitigate its negative impacts on health and promote overall wellness.
why not 50% H2
The equipment we use has an outlet that uses 666.666% hydrogen.
When mixed with the air you breathe, it becomes a theoretical value of 4%.
In other words, high concentrate hydrogen cannot be taken into the body in its entirety.
@@JURAKU_Clinic isnt it because hydrogenation would occur right? thats when the H2 gas gets in the fat?
Hydrogen therapy doesn’t work in people with the following; high HbA1c, obesity, already had cancer, metabolic problems, history of smoking, alcohol consumption and unhealthy eating etc. there are only a small amount of benefits in healthy people. However hydrogen did work, I would think the doctor would look healthier and not be fat. Doctors are selling hope! 水素療法は、次の人には機能しません。高HbA1c、肥満、すでに癌、代謝の問題、喫煙歴、アルコール消費、不健康な人には少量の利益しかありません。水素がうまくいったとしても、医者はより健康に見え、太っていないと思います。医者は希望を売っている!