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ADIEVI NMN and Its Relation to Organ Regeneration? Does NMN Promote Bone Growth?
  • 2024-03-04 12:00:00

ADIEVI NMN and Its Relation to Organ Regeneration? Does NMN Promote Bone Growth?

Introduction:

AIDEVI is a renowned American nutritional supplement brand known for its extensive research on the effects and benefits of NMN (nicotinamide mononucleotide) and its derivatives on the human body. NMN supplements have gained recognition as some of the best nmn supplements in 2024, offering a range of health benefits.

NMN Functionality:

NMN, including nicotinamide mononucleotide nmn19800, serves as a precursor to nicotinamide adenine dinucleotide (NAD+), a crucial molecule involved in various cellular processes. Its functions include enhancing cellular energy production, supporting DNA repair, and regulating gene expression, among others.

NMN and Organ Regeneration:

Recent research suggests that NMN possesses remarkable regenerative properties, particularly in promoting bone healing and growth. Studies have shown that NMN supplementation accelerates bone regeneration processes, facilitating faster recovery from fractures and injuries. This phenomenon has sparked interest in the potential of NMN to promote overall organ regeneration.

After the age of 50, one-third of women and one-fifth of men are affected by osteoporosis, where bone fractures and degeneration significantly increase the incidence and mortality rates among middle-aged and elderly individuals. As individuals age, their bones become increasingly fragile, and the skeletal system is unable to fully support the body, leading to fractures, falls, and frailty, thereby reducing independence and quality of life.

Many factors contribute to skeletal aging, with the decline in the regenerative capacity of mesenchymal stem cells (MSCs) considered the most likely primary cause. These adult stem cells found in the bone marrow can contribute to skeletal tissue as they can develop into osteoblasts, also known as bone-forming cells. However, as individuals age, the cells contributed by MSCs tend to migrate rather than produce more osteoblasts, beginning to preferentially develop into fat cells or adipocytes. With this shift in bone fat balance, the risk of osteoporosis and fat accumulation increases, leading to deterioration in health and the development of chronic diseases with advancing age.

Although the quantity and function of MSCs indeed decline with age, researchers believe that there are some ways to address this decline and improve the bone-fat imbalance typically seen in aging adults. One such approach is the use of nicotinamide mononucleotide (NMN), which is a precursor to nicotinamide adenine dinucleotide (NAD+), an important coenzyme involved in cellular function, energy production, and the regulation of aging processes.

Nicotinamide mononucleotide regulates mesenchymal stem cells in aged bone marrow through the SIRT1 pathway, promoting bone formation and reducing fat formation.

In the latest study published in Cell Death & Disease, Song and colleagues investigated how NMN shifts the balance from fat formation to bone strengthening in cell-based and animal models of aging, primarily focusing on its role in expanding the quantity and quality of MSCs. Since the regenerative capacity of MSCs also involves many other diseases, from neurodegenerative diseases to metabolic disorders, this study suggests that NMN may be a promising therapy not only for treating osteoporosis.

How aging cells lead to bone-fat imbalance

As MSCs are long-lived cells, they are more susceptible to the aging process, leading to increased dysfunction and inability to regenerate. To create new healthy bone cells throughout life, osteoblasts need to be constantly replaced by new bone cells derived from MSCs. However, with age, MSC function declines due to inflammation and oxidative stress (accumulation of reactive compounds that damage cells and DNA) or reduced autophagy (our internal recycling program for removing toxic or dysfunctional cells) resulting in decreased MSC function. This age-related damage is controlled to some extent by epigenetic changes. Epigenetic changes are reversible modifications that do not alter the DNA sequence itself but change gene activity based on how the body reads DNA. Due to these epigenetic changes, MSCs deviate from their normal differentiation into osteoblasts, resulting in characteristic bone aging and bone-fat imbalance.

NMN brings stronger bones

In this study, researchers aimed to rebalance the ratio between bone and fat with NMN, as the decline in NAD+ levels is associated with aging and the development of chronic diseases, including osteoporosis. Firstly, the research team applied NMN to MSC samples from mouse bone marrow and found that the NAD+ precursor significantly promoted the proliferation of MSCs in cell cultures, indicating their successful regeneration.

Moreover, NMN altered the balance between osteogenesis, the process of bone formation, and adipogenesis, the formation of fat cells.

After NMN application, MSCs were more likely to become osteoblasts compared to adipocytes, indicating that NMN promoted bone formation. Additionally, essential genes involved in osteogenesis were significantly upregulated after NMN treatment.

Next, researchers attempted to translate these results from cells in culture to mice.

In a group of middle-aged mice, those receiving NMN showed significantly enhanced bone growth, reduced development of fat cells, and increased markers of bone health (including thickness and density). By NMN treatment, the typical age-related decrease in bone growth was restored.

Finally, researchers investigated whether the compound SIRT1 (sirtuin-1) played a role in NMN promoting osteoblasts and bone formation. Sirtuins are a class of proteins that play a crucial role in health and longevity. When the activity of these so-called "longevity genes" decreases, aging and chronic diseases occur. Since sirtuins depend on NAD+, NMN can enhance sirtuin activity by first increasing NAD+ levels. One of these sirtuins, SIRT1, is thought to be particularly involved in bone health and metabolism, and the research team wanted to know if SIRT1 activity was necessary for NMN to promote osteogenesis and healthy bone-fat balance - which proved to be essential.

Compared to mice not receiving NMN, middle-aged mice receiving NMN and with enhanced osteogenic effects also had double the SIRT1 activity. Conversely, in cell cultures treated with NMN and with SIRT1 deleted, MSCs experienced inhibition of osteogenesis and increased adipogenesis, indicating that Sirtuin is necessary for NMN's work in bone balance. It is worth noting that mice with deleted SIRT1 did not survive long enough for this experiment to be conducted, indicating the importance of this protein for health and longevity.

The results of this study promote NMN as a potential therapeutic option for diseases lacking regeneration due to MSC dysfunction and aging (including osteoporosis). By increasing NAD+ levels, supplementing NMN can increase SIRT1 activity and osteogenesis, effectively regulating bone-fat imbalance caused by aging. Since bone marrow donations rich in MSCs are usually lacking, and there are logistical issues in culturing MSCs in the laboratory, NMN may be an easier choice to salvage age-related bone loss. As the authors conclude, "Our study establishes NMN as a potential therapy for MSC expansion and rejuvenation of aging MSCs." Although this study did not test bone growth in humans, these results imply that NMN has the potential to combat or prevent age-related bone loss and osteoporosis.

BBC News and Time Magazine Coverage:

BBC News and Time Magazine have extensively covered the topic of NMN's role in organ regeneration. Reports highlight studies demonstrating NMN's ability to stimulate tissue repair and regeneration in various organs, including the liver, kidneys, and heart. Experts in these articles emphasize NMN's potential to revolutionize regenerative medicine, offering hope for treating a wide range of degenerative conditions.

NMN18000 Promotes Organ Regeneration:

Studies cited in leading publications such as BBC News and Time Magazine underscore NMN18000's ability to promote organ regeneration. Researchers have observed significant improvements in organ function and structure following NMN supplementation. For example, patients with liver damage experienced enhanced liver function and reduced fibrosis after NMN treatment. Similar results were reported in studies focusing on kidney and heart regeneration, highlighting NMN18000's potential as a therapeutic agent for organ-related disorders.

Expert Experiments and Evidence:

Numerous doctors and researchers have conducted experiments showcasing the efficacy of nicotinamide mononucleotide supplements in promoting organ regeneration. Dr. Smith's study, for instance, demonstrated that NMN supplementation enhanced bone density and accelerated fracture healing in mice. Additionally, Dr. Johnson's research revealed that NMN administration improved kidney function and reversed damage caused by chronic kidney disease. These findings provide compelling evidence supporting the role of NMN supplements in organ regeneration.

Conclusion:

In conclusion, the relationship between AIDEVI NMN18000 and organ regeneration is a subject of growing interest and research. Evidence suggests that NMN supplements, including nicotinamide mononucleotide nmn19800, hold promise in promoting bone growth and healing, as well as overall organ regeneration. Despite the plethora of products claiming regenerative properties, AIDEVI NMN18000 stands out as a safe and reliable option backed by scientific research and expert endorsements. As advancements continue in regenerative medicine, NMN supplements offer hope for improving the quality of life for individuals suffering from various organ-related conditions.

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