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.
NMNH is more potent than NMN
when applied to cultured cells, the NMNH is shown to be more efficient than NMN as it was able to “significantly increase NAD+ at a ten times lower concentration (5 µM) than that needed for NMN”. Moreover, NMNH shows to be more effective, as at 500 µM concentration, it achieved “an almost 10- fold increase in the NAD+ concentration, while NMN was only able to double NAD+ content in these cells, even at 1 mM concentration.”.
Interestingly, NMNH also appears to act quicker and has a longer-lasting effect compared to NMN. According to the authors, NMNH induces a “significant increase in NAD+ levels within 15 minutes”, and “NAD+ steadily increased for up to 6 hours and remained stable for 24 hours, while NMN reached its plateau after only 1 hour, most likely because the NMN recycling pathways to NAD+ had already become saturated.”.
BONTAC NMNH product features and advantages
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
NADH powder manufacturing method
The main methods of NMNH powder preparation include extraction, fermentation, fortification, biosynthesis and organic matter synthesis. Compared with other preparations, the whole enzyme become the mainstream method owing to the advantages of pollution free, high level of purity and stability.
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NMNH also proved more effective than NMN in raising NAD+ levels in a variety of tissues when administered at the same concentration, confirming the results observed in cell lines. The data presented in this study also corroborate the evidence that NAD+ boosters protect against different models of acute kidney injury, and place NMNH as a great alternative intervention to other NAD+ precursors to reduce tubular damage and accelerate recovery.
To overcome the limitations of the current repertoire of NAD+ enhancers, other molecules with a more pronounced effect on the NAD+ intracellular pool are desired. This has stimulated us to investigate the use of the reduced form of nicotinamide mononucleotide (NMNH) as an NAD+ enhancer. There is very scarce information about the role of this molecule in cells. In fact, only one enzymatic activity has been described to produce NMNH. This is the NADH diphosphatase activity of the human peroxisomal Nudix hydrolase hNUDT1232 and the murine mitochondrial Nudt13.33 It has been postulated that, in cells, NMNH would be converted to NADH via nicotinamide mononucleotide adenylyl transferases (NMNATs).34 However, both NMNH production by Nudix diphosphatases and its use by NMNATs for NADH synthesis have only been described in vitro using isolated proteins, and how NMNH participates in cellular NAD+ metabolism remains unknown.
First, inspect the factory. After some screening, NMNH companies that directly face consumers pay more attention to brand building. Therefore, for a good brand, quality is the most important thing, and the first thing to control the quality of raw materials is to inspect the factory. Bontac company actually manufacturing NMNH powder of high quality with the caterias of SGS. Secondly, the purity is tested. Purity is one of the most important parameters of NMN powder. If high purity NMNH cannot be guaranteed, the remaining substances are likely to exceed the relevant standards. As the attached certificates demonstrates that the NMNH powder produced by Bontac reach the purity of 99%. Finally, a professional test spectrum is needed to prove it. Common methods for determining the structure of an organic compound include Nuclear Magnetic Resonance Spectroscopy (NMR) and high-resolution mass spectrometry (HRMS). Usually through the analysis of these two spectra, the structure of the compound can be preliminarily determined.
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The Molecular Mechanisms Underlying the Interaction Between NAD+/NMN and DBC1
Introduction Oxidized form of nicotinamide adenine dinucleotide (NAD+) and its precursor nicotinamide mononucleotide (NMN) have been uncovered to restore DNA repair and prevent cancer progression via the deleted in breast cancer 1 (DBC1). This research is committed to deciphering the detailed molecular mechanisms. About DBC1 DBC1 is a nuclear protein initially cloned from a human chromosome 8p21 region, which can modulate diversified targets by protein-protein interaction, contributing to various cellular processes such as apoptosis, DNA repair, senescence, transcription, metabolism, circadian cycle, epigenetic regulation, cell proliferation, and tumorigenesis. The affinity and molecular binding mechanisms between NAD+/NMN and DBC1354–396 Under the help of nuclear magnetic resonance (NMR) and Isothermal titration calorimetry (ITC) experiments, it is verified that both NAD+ and NMN have a binding relationship with the NHD domain of DBC1. Specifically, NAD+ interacts with DBC1354-396 through hydrogen bonds, with a binding affinity (8.99 μM) nearly twice that of NMN (17.0 μM) and the key binding sites are primarily residues E363 and D372. The vital roles of E363 and D372 mutagenesis in ligand-protein interaction The N-terminal loop of DBC1354-396 encloses the small ligand within a local space, anchoring NAD+ and NMN to the protein through key amino acid residues E363 and D372 via hydrogen bonding. Conclusion Both NAD+ and its precursor NMN can bind to DBC1's NHD domain (DBC1354–396) at key sites E363 and D372, providing novel clues for the development of targeted therapies and drug research on DBC1-associated disease including tumors. Reference Ou L, Zhao X, Wu IJ, et al. Molecular mechanism of NAD+ and NMN binding to the Nudix homology domains of DBC1. Int J Biol Macromol. Published online February 12, 2024. doi:10.1016/j.ijbiomac.2024.130131 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 consisting of Doctors and Masters. BONTAC has rich R&D experience and advanced technology in the biosynthesis of NAD and its precursors (eg. NMN), with various forms to be selected (eg. endoxin-free IVD-grade NAD, Na-free or Na-containing NAD; NR-CL or NR-Malate). High quality and stable supply of products can be better ensured here with the exclusive Bonpure seven-step purification technology and Bonzyme Whole-enzymatic method. 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. 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.
The Prospect of the NAD+ Precursors in Age-related Diseases
1. Introduction Age-related NAD+ depletion affects physiological functions and contributes to various aging-related diseases. NAD+ precursors can significantly elevate NAD+ level in murine tissues, effectively mitigate metabolic syndrome, enhance cardiovascular health, protect against neurodegeneration, and boost muscular strength, with broad prospect in the anti-aging-related field. 2. The synthesis and metabolism of NAD+ in age-related pathologies NAD+ is synthesized from NAD+ precursors and amino acids tryptophan via three main pathways: De novo, Preiss-Handler, and Salvage. Supplementation of NAD+ precursors can be advantageous in maintaining normal cellular metabolism regulated by NAD+ and NAD+-dependent enzymes such as Sirtuins, PARP, CD38, and SARM1. NAD+ intermediates require conversion into NA to elevate NAD+ level. NAD+ and its metabolism-related enzymes have very important roles in biological processes such as cellular metabolic processes, gene expression, apoptosis and carcinogenesis. NAD+ repletion is drawing attention as an anti-aging intervention. NAD+ precursors, such as NA, NAM, NR, and NMN, provide beneficial effects in various preclinical disease models of age-induced deficits, including metabolic disorders, cardiovascular, neurodegenerative diseases, and musculoskeletal diseases. 3. Comparison on the efficacy of replenishing NAD precursors in pre-clinical studies and clinical studies in age-related pathologies The downregulation of NAD+ level in cells and tissues is not a universal phenomenon for aging-related pathologies. NAD+ merely decreases with age in certain tissues. The efficacy of NAD+ precursors in clinical studies has been limited in comparison with that in the pre-clinical studies. Noteworthily, this issue can be addressed as long as much attention has been paid to the metabolism of NAD. With regards to the oral supplementation of NAD+ precursors, there is obvious link between NAD metabolism and gut microbes. Specifically, oral consumption of NMN is converted into NAMN through interaction with the gut microbiome. In addition, dietary NAM and NR are converted into NA through gut microbiota. 4. Future research directions regarding the NAD+ metabolism It is fundamental to consider how the gut microbiome affects NAD+ metabolism, and changes in microbiome composition may affect the availability of NAD+ precursors. Future studies also require the comparative analysis of different precursors, and the role of gut microbiomes regarding various intermediaries needs to be investigated. Assessment of how NAD+ precursors affect microbiota and how their interaction with NAD+ metabolism benefits the physiological condition is essential for future preclinical and clinical studies. 5. Conclusion Supplementation of suitable NAD+ precursors or intervening in NAD+ metabolism can restore the body's NAD+ level, which is of great practical significance for effectively improving aging-related diseases and prolonging healthy life span is of great practical significance for effectively improving aging-related diseases and prolonging healthy life span. NAD metabolism involves gut microbiome, and in-depth research on their interaction is possibly an important breakthrough in the future to combat aging-related pathologies. Reference Iqbal T, Nakagawa T. The therapeutic perspective of NAD+ precursors in age-related diseases. Biochem Biophys Res Commun. Published online February 2, 2024. doi:10.1016/j.bbrc.2024.149590 About BONTAC 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 160 global patents as well as strong R&D team consisting of Doctors and Masters. BONTAC has rich R&D experience and advanced technology in the biosynthesis of NAD and its precursors (eg. NMN and NR), with various forms to be selected (eg. endoxin-free IVD-grade NAD, Na-free or Na-containing NAD; NR-CL or NR-Malate). High quality and stable supply of products can be better ensured here with the exclusive Bonpure seven-step purification technology and Bonzyme Whole-enzymatic method. 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. BONTAC holds no responsibility for any claims, damages, losses, expenses, costs or liabilities whatsoever resulting or arising directly or indirectly from your reliance on the information and material on this website.
The Regulatory Targets and Mechanisms of Ginsenoside Rh2 for NSCLC
Introduction In the presence of oxygen, tumors produce adenosine triphosphate (ATP) through glycolysis instead of mitochondrial oxidative phosphorylation, a phenomenon known as the “Warburg effect”. Aerobic glycolysis caused by an altered tumor microenvironment is an important factor contributing to malignant tumor progression. Ginsenoside Rh2 (Rh2) can specifically reverse the shift from tumor aerobic glycolysis to oxidative phosphorylation to modulate the metabolic behavior of non-small cell lung cancer (NSCLC), ultimately promoting the “benignization” of NSCLC. The suppressive impacts of Rh2 on the malignant progression of NSCLC Rh2 inhibits the proliferation, invasion and migration, while promoting the apoptosis of NSCLC cells. Meanwhile, Rh2 treatment represses tumor lymph angiogenesis, as manifested by the obviously reduced expression of CD31. Moreover, Rh2 hinders the metastasis of NSCLC by inhibiting the epithelial mesenchymal transition (EMT), as evidenced by the upregulation of E-cadherin and downregulation of N-cadherin in lung tissues post Rh2 treatment. Underlying targets and mechanisms of Rh2 against NSCLC Rh2 hampers NSCLC aerobic glycolytic capacity, including glucose uptake and lactate production, through the HIF1-α/PDK4 pathway. Specifically, Rh2 targets hypoxia-inducible factor HIF-1α to downregulate its expression, subsequently reducing the expression of PDK4, a pivotal enzyme during the glucose oxidation process. By this way, Rh2 further suppresses aerobic glycolysis, promotes mitochondrial aerobic oxidative process, and stimulates the production of reactive oxygen species (ROS), thereby promoting tumor cells to enter the normal apoptotic program. The efficacy of Rh2 combined with DCA in NSCLC Sodium dichloroacetate (DCA), an inhibitor of pyruvate dehydrogenase kinase (PDKs), has been commonly used in clinical practice as an anticancer drug targeting glycolysis, yet it has hepatotoxicity and neurotoxicity at high doses. Notably, the combination of Rh2 with DCA dramatically reverses the biometabolic behaviors of tumors, and further reduces the dosage of DCA, which decreases the toxicity of DCA, greatly increasing the drug efficacy. Conclusion Rh2 shifts tumor metabolism from aerobic glycolysis to oxidative phosphorylation through regulating the HIF1-α/PDK4 axis in NSCLCs. It activates the apoptotic program of NSCLCs and exerts a potentiating and toxicity-reducing effect when used in combination with chemotherapeutic agents DCA, hinting its potential as an adjuvant against tumors. Reference Liu X, Li J, Huang Q, et al. Ginsenoside Rh2 shifts tumor metabolism from aerobic glycolysis to oxidative phosphorylation through regulating the HIF1-α/PDK4 axis in non-small cell lung cancer. Mol Med. 2024;30(1):56. Published 2024 Apr 26. doi:10.1186/s10020-024-00813-y BONTAC Ginsenosides 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 rare ginsenosides Rh2/Rg3, with pure raw materials, higher conversion rate and higher content (up to 99%). One-stop service for customized product solution is available in BONTAC. With unique Bonzyme enzymatic synthesis technology, both S-type and R-type isomers can be accurately synthesized here, with stronger activity and precise targeting action. Our products are subjected to strict third-party self-inspection, which are worth of trustworthy. 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. Under no circumstances will BONTAC be responsible for any claims, damages, losses, expenses, or costs arising directly or indirectly from your reliance on the information and material on this website.