Advantages of NMNH
NMNH: 1. “Bonzyme” Whole-enzymatic method, environmental-friendly, no harmful solvent residues manufacturing powder. 2. Bontac is a very first manufacture in the world to produce the NMNH powder on the level of high purity, stability. 3. Exclusive “Bonpure” seven-step purification technology, high purity(up to 99%) and stability of production of NMNH powder 4. Self-owned factories and obtained a number of international certifications to ensure high quality and stable supply of products of NMNH powder 5. Provide one-stop product solution customization service
Advantages of NADH
NADH: 1. Bonzyme whole-enzymatic method, environmental-friendly, no harmful solvent residues 2. Exclusive Bonpure seven-step purification technology, purity up higher than 98 % 3. Special patented process crystal form, higher stability 4. Obtained a number of international certifications to ensure high quality 5. 8 domestic and foreign NADH patents, leading the industry 6. Provide one-stop product solution customization service
Advantages of NAD
NAD: 1. “Bonzyme” Whole-enzymatic method, environmental-friendly, no harmful solvent residues 2. Stable supplier of 1000+ enterprises around the world 3. Unique “Bonpure” seven-step purification technology, higher product content and higher conversion rate 4. Freeze drying technology to ensure stable product quality 5. Unique crystal technology, higher product solubility 6. Self-owned factories and obtained a number of international certifications to ensure high quality and stable supply of products
Advantages of MNM
NMN: 1. “Bonzyme”Whole-enzymatic method, environmental-friendly, no harmful solvent residues 2. Exclusive“Bonpure”seven-step purification technology, high purity(up to 99.9%) and stability 3. Industrial leading technology: 15 domestic and international NMN patents 4. Self-owned factories and obtained a number of international certifications to ensure high quality and stable supply of products 5. Multiple in vivo studies show that Bontac NMN is safe and effective 6. Provide one-stop product solution customization service 7. NMN raw material supplier of famous David Sinclair team of Harvard University
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Bontac Bio-Engineering (Shenzhen) Co., Ltd. (hereafter referred to as BONTAC) is a high-tech enterprise established in July 2012. BONTAC integrates R&D, production and sales, with enzyme catalysis technology as the core and coenzyme and natural products as main products. There are six major series of products in BONTAC, involving coenzymes, natural products, sugar substitutes, cosmetics, dietary supplements and medical intermediates.
As the leader of the global NMN industry, BONTAC has the first whole-enzyme catalysis technology in China. Our coenzyme products are widely used in health industry, medical & beauty, green agriculture, biomedicine and other fields. BONTAC adheres to independent innovation, with more than 170 invention patents. Different from the traditional chemical synthesis and fermentation industry, BONTAC has advantages of green low-carbon and high-value-added biosynthesis technology. What’s more, BONTAC has established the first coenzyme engineering technology research center at the provincial level in China which also is the sole in Guangdong Province.
In the future, BONTAC will focus on its advantages of green, low-carbon and high-value-added biosynthesis technology, and build ecological relationship with academia as well as upstream/downstream partners, continuously leading the synthetic biological industry and creating a better life for human beings.
What NMN Supplements Do?
NMN supplements are mainly used to increase NAD+ levels to improve metabolic diseases and slow down the aging process.
Improve metabolic diseases: Studies have shown that NMN can improve the symptoms of metabolic diseases such as diabetes, fatty liver and obesity.
Delay the aging process: NMN can increase the vitality of cells, improve the metabolic process of cells, and delay the aging process.
Protect DNA: NAD+ is an important metabolic substance in cells and participates in various biological processes such as cellular energy metabolism and DNA repair. Supplementing NMN can increase NAD+ levels and protect DNA.
Improves Athletic Capacity: NMN has been shown to improve athletic performance and increase fat burning ability
Improve neurodegenerative diseases: Studies have shown that NMN can improve neurodegenerative diseases, such as Alzheimer's disease
However, these studies were small, and NMN has not been shown to be effective in clinical trials, so further research is needed to determine the effectiveness of NMN supplements.
What diseases can NMN supplements treat?
NMN (Nicotinamide Mononucleotide) is a substance similar to vitamin B3, which can produce NAD+ (a key metabolic intermediate) in the body. Therefore, studies have shown that NMN may help improve aging-related health issues such as metabolism, immunity, cell repair, brain health, and more.
Currently, NMN supplements are mainly used to treat the following diseases:
Aging-related metabolic disorders such as diabetes, obesity, high cholesterol, etc.
Aging-related neurodegenerative diseases, such as Alzheimer's disease.
Aging-associated immune decline.
Aging-related cardiovascular disease.
What are the purposes of NMN supplements?
NMN supplements are mainly used to increase NAD+ levels to improve metabolic diseases and slow down the aging process.
Improve metabolic diseases: Studies have shown that NMN can improve the symptoms of metabolic diseases such as diabetes, fatty liver and obesity.
Delay the aging process: NMN can increase the vitality of cells, improve the metabolic process of cells, and delay the aging process.
Protect DNA: NAD+ is an important metabolic substance in cells and participates in various biological processes such as cellular energy metabolism and DNA repair. Supplementing NMN can increase NAD+ levels and protect DNA.
Improves Athletic Capacity: NMN has been shown to improve athletic performance and increase fat burning ability
Improve neurodegenerative diseases: Studies have shown that NMN can improve neurodegenerative diseases, such as Alzheimer's disease
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Frequently Asked Question
Do you have any question?
NMN supplements may cause side effects such as upset stomach, diarrhea, and nausea. There is also research showing that NMN supplements may affect insulin sensitivity and insulin levels, so people with diabetes should consult their doctor before taking them.
NMN supplements have not yet undergone large-scale clinical trials to verify their effectiveness. Currently, research on NMN supplements is mainly focused on animal and in vitro experiments. These studies show that NMN can improve the symptoms of metabolic diseases such as diabetes, fatty liver and obesity, and can delay the aging process.
The long-term health effects of NMN supplementation are not well studied. Existing studies mainly focus on animal and in vitro experiments, which show that NMN can improve the symptoms of metabolic diseases such as diabetes, fatty liver and obesity, and can delay the aging process. However, the results of these studies do not represent the long-term effects of NMN on human health.
Our updates and blog posts
The latest research proves: Coenzyme NAD+ can enhance tumor immunity! Expert Comment from Chinese Academy of Sciences
On August 10, 2021, researchers from Shanghai University of Science and Technology published an article titled NAD+ supplement potentiates tumor killing function by rescuing defective TUBBY-mediated NAMPT transcription in tumor infiltrated T cells in Cell Reports, revealing that NAD+ in supplemented during CAR-T therapy and immune checkpoint inhibitor therapy, it can improve the anti-tumor activity of T. At present, the supplementary precursor of NAD+, as a nutritional product,has been verified for human consumption safety.This achievement provides a simply and feasible new method for improving the anti-tumor activity of T cells. Cancer immunotherapies including the adoptive transfer of naturally occurring tumor-infiltrating lymphocytes (TILs) and genetically engineered T cells, as well as the use of immune checkpoint blockade (ICB) to boost the function of T cells, have emerged as promising approaches to achieve durable clinical responses of otherwise treatment-refractory cancers (Lee et al., 2015; Rosenberg and Restifo, 2015; Sharma and Allison, 2015). Although immunotherapies have been successfully used in the clinic, the number of patients benefiting from them is still limited (Fradet et al., 2019; Newick et al., 2017). Tumor microenvironment (TME)-related immunosuppression has emerged as the major reason for low and/or no response to both immunotherapies (Ninomiya et al., 2015; Schoenfeld and Hellmann, 2020). Therefore, efforts to investigate and overcome TME-related limitations in immune therapies are of great urgency. The fact that immune cells and cancer cells share many fundamental metabolic pathways implies an irreconcilable competition for nutrients in TME (Andrejeva and Rathmell, 2017; Chang et al., 2015). During uncontrolled proliferation, cancer cells hijack alternative pathways for more rapid metabolite generation (Vander Heiden et al., 2009). As a consequence, nutrient depletion, hypoxia, acidity, and generation of metabolites that can be toxic in the TME may hinder successful immunotherapy (Weinberg et al., 2010). Indeed, TILs often experience mitochondrial stress within growing tumors and become exhausted (Scharping et al., 2016). Interestingly, multiple studies also indicate that metabolic changes in TME could re-shape T cell differentiation and functional activity (Bailis et al., 2019; Chang et al., 2013; Peng et al., 2016). All these evidences inspired us to hypothesize that metabolic reprogramming in T cells might rescue them from a stressed metabolic environment, thereby reinvigorating their anti-tumor activity (Buck et al., 2016; Zhang et al., 2017). In this current study, by integrating both genetic and chemical screens, we identified that NAMPT, a key gene involved in NAD+ biosynthesis, was essential for T cell activation. NAMPT inhibition led to robust NAD+ decline in T cells, thereby disrupting glycolysis regulation and mitochondrial function, blocking ATP synthesis, and dampening the T cell receptor (TCR) downstream signaling cascade. Building on the observation that TILs have relatively lower NAD+ and NAMPT expression levels than T cells from peripheral blood mononuclear cells (PBMCs) in ovarian cancer patients, we performed genetic screening in T cells and identified that Tubby (TUB) is a transcription factor for NAMPT. Finally, we applied this basic knowledge in the (pre) clinic and showed very strong evidence that supplementation with NAD+ dramatically improves the anti-tumor killing activity both in adoptively transferred CAR-T cells therapy and immune check point blockade therapy, indicating their promising potential for targeting NAD+ metabolism to better treat cancers. 1.NAD+ regulates the activation of T cells by affecting energy metabolism After antigen stimulation, T cells undergo metabolic reprogramming, from mitochondrial oxidation to glycolysis as the main source of ATP. While maintaining sufficient mitochondrial functions to support cell proliferation and effector functions.Given that NAD+ is the main coenzyme for redox, the researchers verified the effect of NAD+ on the level of metabolism in T cells through experiments such as metabolic mass spectrometry and isotope labeling. The results of in vitro experiments show that NAD+ deficiency will significantly reduce the level of glycolysis, TCA cycle and electron transport chain metabolism in T cells. Through the experiment of replenishing ATP, the researchers found that the lack of NAD+ mainly inhibits the production of ATP in T cells, thereby reducing the level of T cell activation. 2.The NAD+ salvage synthesis pathway regulated by NAMPT is essential for T cell activation The metabolic reprogramming process regulates the activation and differentiation of immune cells. Targeting T cell metabolism provides an opportunity to modulate the immune response in a cellular way. Immune cells in the tumor microenvironment, their own metabolic level will also be correspondingly affected. The researchers in this article have discovered the important role of NAMPT in the activation of T cells through genome-wide sgRNA screening and metabolism-related small molecule inhibitor screening experiments. Nicotinamide adenine dinucleotide (NAD+) is a coenzyme for redox reactions and can be synthesized through the salvage pathway, de novo synthesis pathway, and Preiss-Handler pathway. The NAMPT metabolic enzyme is mainly involved in the NAD+ salvage synthesis pathway. Analysis of clinical tumor samples found that in tumor-infiltrating T cells, their NAD+ levels and NAMPT levels were lower than other T cells. Researchers speculate that NAD+ levels may be one of the factors that affect the anti-tumor activity of tumor-infiltrating T cells. 3.Supplement NAD+ to enhance the anti-tumor activity of T cells Immunotherapy has been exploratory research in cancer treatment, but the main problem is the best treatment strategy and the effectiveness of immunotherapy in the overall population. Researchers want to study whether enhancing the activation ability of T cells by supplementing NAD+ levels can enhance the effect of T cell-based immunotherapy. At the same time, in the anti-CD19 CAR-T therapy model and anti-PD-1 immune checkpoint inhibitor therapy model, it was verified that supplementation of NAD+ significantly enhanced the tumor-killing effect of T cells. The researchers found that in the anti-CD19 CAR-T treatment model, almost all mice in the CAR-T treatment group supplemented with NAD+ achieved tumor clearance, while the CAR-T treatment group without NAD+ supplemented only about 20 % Of mice achieved tumor clearance. Consistent with this, in the anti-PD-1 immune checkpoint inhibitor treatment model, B16F10 tumors are relatively tolerant to anti-PD-1 treatment, and the inhibitory effect is not significant. However, the growth of B16F10 tumors in the anti-PD-1 and NAD+ treatment group could be significantly inhibited. Based on this, NAD+ supplementation can enhance the anti-tumor effect of T cell-based immunotherapy. 4.How to supplement NAD+ The NAD+ molecule is large and cannot be directly absorbed and utilized by the human body. The NAD+ directly ingested orally is mainly hydrolyzed by brush border cells in the small intestine. In terms of thinking, there is indeed another way to supplement NAD+, which is to find a way to supplement a certain substance so that it can synthesize NAD+ autonomously in the human body. There are three ways to synthesize NAD+ in the human body: Preiss-Handler pathway, de novo synthesis pathway and salvage synthesis pathway. Although the three ways can synthesize NAD+, there is also a primary and secondary distinction. Among them, the NAD+ produced by the first two synthetic pathways only accounts for about 15% of the total human NAD+, and the remaining 85% is achieved through the way of remedial synthesis. In other words, the salvage synthesis pathway is the key to the human body to supplement NAD+. Among the precursors of NAD+, nicotinamide (NAM), NMN and nicotinamide ribose (NR) all synthesize NAD+ through a salvage synthesis pathway, so these three substances have become the body's choice for supplementing NAD+. Although NR itself has no side effects, in the process of NAD+ synthesis, most of it is not directly converted into NMN, but needs to be digested into NAM first, and then participate in the synthesis of NMN, which still cannot escape the limitation of rate-limiting enzymes. Therefore, the ability to supplement NAD+ through oral administration of NR is also limited . As a precursor for supplementing NAD+, NMN not only bypasses the restriction of rate-limiting enzymes, but is also absorbed very quickly in the body and can be directly converted into NAD+. Therefore, it can be used as a direct, rapid and effective method to supplement NAD+. Expert Reviews: Xu Chenqi (Excellence and Innovation Center of Molecular Cell Science, Chinese Academy of Sciences, Immunology Research Expert) Cancer treatment is a problem in the world. The development of immunotherapy has made up for the limitations of traditional cancer treatment and expanded the treatment methods of doctors. Cancer immunotherapy can be divided into immune checkpoint blocking therapy, engineered T cell therapy, tumor vaccine, etc. These treatment methods have played a certain role in the clinical treatment of cancer. At the same time, this also makes the current focus of immunotherapy research on how to further enhance the effect of immunotherapy and expand the beneficiaries of immunotherapy.
Targeting NAD+ Salvage Pathway as a Potential Approach to Combat Obesity
Introduction Mar 4th is determined as the World Obesity Day. World Obesity Federation, UNICEF and WHO have hosted a global youth-led webinar to talk about obesity & youth. The obesity crisis has gradually attracted much attention. The latest report by the Lancet suggests that one billion people are bothered by obesity (2022), with 650 million adults, 340 million adolescents and 39 million children. Recently, etiological studies and interventions for obesity have been progressively focused on the central nervous system, with an attempt to curb the onset of obesity at its source. Notably, targeting NAD+ salvage pathway in hypothalamic astrocytes may be a potential approach to combat obesity. The association of hypothalamic astrocytes and obesity The hypothalamus functions as the appetite regulation center, which receives and integrates the neuroendocrine factors produced by the central nervous system and peripheral tissues to promote or suppress appetite, so as to affect body weight. Noteworthily, aypothalamic astrocytes can apparently decrease glucose clearance and increase plasma insulin levels, playing an essential role in modulating energy metabolism, which are expected to be a new target for obesity treatment. Alleviation of high-fat diet (HFD)-induced obesity by repressing astrocyte NAD+ salvage pathway Under conditions of excessive fat intake, the NAD+ salvage pathway is specifically activated in hypothalamic astrocytes, which restrains the energy expenditure (EE) and fat oxidation in adipose tissues by downregulating sympathetic nerve innervation, eventually resulting in the accumulation of adipose tissue fat and the development of obesity. CD38 as a downstream mediator of astrocyte inflammation induced by the NAD+ salvage pathway. CD38 functions downstream of the NAD+ salvage pathway in hypothalamic astrocytes burdened with excess fat. CD38 knockdown in arcuate nucleus astrocytes diminishes the weight gain, reduces fat mass, increases EE, and lowers RER during HFD consumption. Cd38 depletion in hypothalamic astrocytes may improve hypothalamic inflammation by increasing NAD+ level. Hypothalamic inflammation can not only lead to energy imbalances, but also exacerbate central insulin resistance and leptin resistance, which can lead to the accumulation of fat in peripheral tissues. The role of nicotinamide phosphoribosyltransferase (NAMPT)–NAD+–CD38 axis in obesity In mammals, the salvage pathway represents the primary means of maintaining cellular NAD+ level. A crucial step in the NAD+ salvage pathway is catalyzed by NAMPT. In response to fat overload, the activation of the astrocytic NAMPT-NAD+-CD38 axis induces pro-inflammatory responses in the hypothalamus, eliciting aberrantly activated basal Ca2+ signals and compromised Ca2+ responses to metabolic hormones such as insulin, leptin, and glucagon-like peptide 1, ultimately resulting in dysfunctional hypothalamic astrocytes and contribute to the development of obesity. Conclusion Mechanically, inhibition of hypothalamic astrocytic NAD+ salvage pathway, along with its downstream CD38, mitigates hypothalamic inflammation and attenuates the development of HFD-induced obesity in male mice. Reference Park, J.W., Park, S.E., Koh, W. et al (2024). Hypothalamic astrocyte NAD+ salvage pathway mediates the coupling of dietary fat overconsumption in a mouse model of obesity. Nat Commun 15, 2102. https://doi.org/10.1038/s41467-024-46009-0 BONTAC NAD BONTAC has been dedicated to the R&D, manufacture and sale of raw materials for coenzyme and natural products since 2012, with self-owned factories, over 170 global patents as well as strong R&D team. BONTAC has rich R&D experience and advanced technology in the biosynthesis of NAD and its precursors (eg. NMN and NR). There are various types of NAD to be selected, encompassing NAD ER Grade (endoxin removal), NAD Grade I (IVD/dietary supplement/cosmetics raw powder), NAD Grade II (API/intermediates) and NAD Grade IV (if any higher requirement on the solubility), which can be provided in the form of lyophilized powder or crystalline powder. The purity of BONTAC NAD can reach above 98%. Disclaimer This article is based on the reference in the academic journal. The relevant information is provided for sharing and learning purposes only, and does not represent any medical advice purposes. If there is any infringement, please contact the author for deletion. The views expressed in this article do not represent the position of BONTAC. BONTAC holds no responsibility for any claims, damages, losses, expenses or costs resulting or arising directly or indirectly from your reliance on the information and material on this website.
Further Discussion on the Potential Mechanism of NMN Affecting Neuromuscular Junction
1. Introduction In mammalian cells, the majority of NAD+ is produced from metabolites entering the NAD+ salvage pathway. Nicotinamide phosphoribosyltransferase (NAMPT) is the rate-limiting enzyme of the salvage pathway, which can convert nicotinamide (NAM) into nicotinamide mononucleotide (NMN). Neuronal NAMPT is important for pre-/post-synaptic NMJ function, and maintaining skeletal muscular function and structure. 2. The involvement of NAMPT in NAD+ salvage pathway NAMPT activity has a pivotal role in energy metabolism and homeostasis. NAMPT can condense nicotinamide (NAM) and 5-phosphoribosyl pyrophosphate (PRPP) into nicotinamide mononucleotide (NMN). NMN is subsequently synthesized into NAD+ by nicotinamide mononucleotide adenylyltransferase (NMNAT), the enzyme immediately after NAMPT. 3. The effect of NMN on partially reversing the NMJ impairments in NAMPT-/- cKO mice In the presence of NMN treatment, vesicle endocytosis/exocytosis is improved and endplate morphology is restored in Thy1-NAMPT-/-conditional knockout (cKO) mice. Also, loss of NAMPT in projection neurons impairs the endocytosis and exocytosis of synaptic vesicles at NMJs, but NMN can largely prevent these impairments. Furthermore, NMN treatment restores sarcomere alignment rather than mitochondrial morphology. 4. The underlying mechanism of NMN affecting NMJs The ameliorating effects of NMN on NMJs may be realized via NAMPT-mediated NAD+ salvage pathway, and this speculation is confirmed by the ameliorated synaptic vesicle cycling, endplate morphology, and muscle fiber structure and function post 2-week administration of the NAD+ precursor, NMN. 5. Conclusion Mechanically, the effects of NMN improving NMJ function, endplate morphology and muscular structure and contractility possibly involves NAMPT-mediated NAD+ salvage pathway. NMN holds a great promise as a therapeutic agent for skeletal muscle diseases. Reference Lundt S, Zhang N, Wang X, Polo-Parada L, Ding S. The effect of NAMPT deletion in projection neurons on the function and structure of neuromuscular junction (NMJ) in mice. Sci Rep. 2020;10(1):99. Published 2020 Jan 9. doi:10.1038/s41598-019-57085-4 BONTAC NMN BONTAC is the pioneer of NMN industry and the first manufacturer to launch NMN mass production, with the first whole-enzyme catalysis technology around the world. At present, BONTAC has become the leading enterprise in niche areas of coenzyme products. Notably, BONTAC is the NMN raw material supplier of famous David Sinclair team at the Harvard University, who uses the raw materials of BONTAC in a paper titled “Impairment of an Endothelial NAD+-H2S Signaling Network Is a Reversible Cause of Vascular Aging”. Our services and products have been highly recognized by global partners. Furthermore, BONTAC has the first national and the only provincial independent coenzyme engineering technology research center in Guangdong, China. The coenzyme products of BOMNTAC are widely used in fields such as nutritional health, biomedicine, medical beauty, daily chemicals and green agriculture. Disclaimer This article is based on the reference in the academic journal. The relevant information is provide for sharing and learning purposes only, and does not represent any medical advice purposes. If there is any infringement, please contact the author for deletion. The views expressed in this article do not represent the position of BONTAC. Under no circumstances will BONTAC be held responsible or liable in any way for any claims, damages, losses, expenses, costs or liabilities whatsoever (including, without limitation, any direct or indirect damages for loss of profits, business interruption or loss of information) resulting or arising directly or indirectly from your reliance on the information and material on this website.