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
We Have The Best Solutions for Your Business
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.
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.
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.”.
User Reviews
What users say about BONTAC
Frequently Asked Question
Do you have any question?
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.
Our updates and blog posts
NR as a Driver of Macrophage Migration to Boost Chronic Wound Healing
Introduction Wound healing is a sophisticated process responding to tissue damage, which is associated with numbers of interaction of various cell types, cytokines, growth factors, and other molecules. Strikingly, increasing the nicotinamide adenine dinucleotide (NAD) pool by nicotinamide riboside (NR) can accelerate wound healing and macrophage migration, which is partially achieved through PGE2 synthesis and signaling as well as the function of the NAD+-dependent sirtuin, SIRT3. Regulatory effects of NR on the expression of M1 macrophage markers in human MDMs. NR could modulate the expression levels of canonical M1 (inflammatory phenotype) and M2 (reparative phenotype) cell surface markers during macrophage polarization. With a great detail, a significant downregulation in CD64 and a obvious upregulation of CD197/CCR7 are viewed in the polarized M1 cells incubated with NR. Furthermore, NR increases CD197/CCR7-mediated M1 macrophage migration. The significance of chemotaxis mediator PGE2 in NR-regulated macrophage migration NR-mediated upregulation of macrophage migration through CCL19/CCR7 is dependent on the synthesis of PGE2, an inflammatory lipid mediator in the eicosanoid family. Concretely, NR administration increases the PGE2 level in cultured human monocytes, MDMs, and human serum. In addition, NR-mediated increases in CCR7 expression and CCL19-induced migration are attenuated by PGE2 synthesis blockers. NR/SIRT3/migration axis in human M1 MDMs NR facilitates collective cell migration at a SIRT3-dependent manner in human M1 MDMs during wound healing. Simply put, the degree of wound healing is compared on Day 0 and Day 2 in vehicle- or NR-treated human M1 MDMs. It is found that NR increases the relative degree of migration (relative wound healing) and the rate of wound confluence in the presence of CCL19. Besides, the relative degree of wound density (migration) is blunted by SIRT3 knockdown, while being enhanced by SIRT3 overexpression. Application prospect of NR in wound healing Chronic diabetes is often accompanied with poor wound healing. For instance, diabetic foot ulcers, one of the chief cause of amputations, affect 15% of people with diabetes. Given that NR can drive the macrophage migration to boost chronic wound healing, it may have a broad application prospect in treating the wounds including but not limited to diabetic patients. Conclusion In human macrophages, NR induces surface expression of the chemotaxis CD197/CCR7 receptor and levels of its lipid mediator PGE2 via upregulation of cyclooxygenase 2 and functionally increases macrophage migration and wound healing in a SIRT3-dependent manner. Reference Wu J, Bley M, Steans RS, et al. Nicotinamide Riboside Augments Human Macrophage Migration via SIRT3-Mediated Prostaglandin E2 Signaling. Cells. 2024;13(5):455. Published 2024 Mar 5. doi:10.3390/cells13050455 BONTAC NR BONTAC is one of the few suppliers in China that can launch mass production of raw materials for NR, with self-owned factory and professional R&D team. Up till now, there are 173 BONTAC patents. BONTAC provides one-stop service for customized products. Both malate and chloride salt forms of NR are available. By dirt of unique Bonpure seven-step purification technology and Bonzyme Whole-enzymatic method, the product content and conversion rate can be maintained in a higher level. The purity of BONTAC NR can reach above 97%. 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 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 Significance of NAD+ in Intestinal Senescence Caused by Elevated mtDNA Mutations
1.Introduction The senescence in mammals is generally concomitant with the dysregulation of intestinal homeostasis and the accumulation of mitochondrial DNA (mtDNA) mutations. High-burden mtDNA mutations lead to NAD+ depletion and activate the transcription factor ATF5-dependent UPRmt, which in turn promotes and exacerbates the intestinal senescence phenotype. By supplementation with the NAD+ precursor NMN, this intestinal senescence phenotype can be rescued to some extent, as evidenced by the recovery of intestinal organoid differentiation and the increased number of intestinal stem cells. 2. NAD+ depletion during intestinal senescence caused by mtDNA mutations There is impairment of NADH/NAD+ redox in Mut/Mut*** intestines, as manifested by the enriched NADH dehydrogenase complex assembly pathway. Through transfection of intestinal crypt cells with SoNar (a NADH/NAD+ sensor), a higher NADH/NAD+ ratio is observed in Mut/Mut*** mice, hinting the perturbed redox potential. Likewise, following transfection of intestinal crypt cells with FiNad (a NAD+ sensor), less NAD+ content is discovered in the Mut/Mut*** cells. All of these findings mirror NAD+ depletion in the intestinal senescence triggered by mtDNA mutations. Note: mtDNA mutations are classified into four types: negligible (WT/WT), low (WT/WT*), moderate (WT/Mut**) and high (Mut/Mut***). 3. The link between mtDNA mutation content and physiological intestinal senescence The small intestine of aged mouse intestine is characterized by decreased intestinal crypt number, increased villus length, higher expression of CDKN1A/p21 (a well-known senescence marker) and shorter telomere length, which is accompanied by accumulation of mtDNA mutations, primarily low-frequency (less than 0.05) point mutations. 4. LONP1 protein as a candidate marker for intestinal senescence caused by accumulated mtDNA mutations Mitochondrial unfolded protein response (UPRmt) is activated by a variety of mitochondrial stresses, including protein imbalances between mitochondria and the nucleus as well as impaired mitochondrial protein transport. The hallmarks of UPRmt are increased protein expression levels of LONP1, HSP60 and ClpP. Noteworthily, only LONP1 protein is specifically upregulated in senescent UPRmt activation triggered by accumulated mtDNA mutations, which may be a candidate biomarker for intestinal senescence. 5. The role of NAD+ in intestinal senescence induced by elevated mtDNA mutations. NAD+ repletion in vivo alleviates the small intestine senescent phenotypes caused by mtDNA mutation burden, and rescues the decreased colony formation efficiency in Mut/Mut*** intestinal organoids. NAD+-dependent UPRmt triggered by mtDNA mutations regulates intestinal senescence. These data further indicate that NAD+ depletion functions as a key mediator of the intestinal senescence induced by accumulated mtDNA mutations. 6. The role of NAD+ in the signal pathways regulating intestinal senescence caused by increased mtDNA mutations NAD+ repletion rescues the Foxl1 downregulation and Notch1 upregulation in Mut/Mut*** mice, suggesting that mtDNA mutation burden can regulate the function or number of niche cells through NAD+ depletion. In addition, NAD+ depletion caused by increased mtDNA mutation burden induces the decline of LGR5-positive intestinal cells via impairment of the Wnt/β-catenin pathway. 7. Conclusion NAD+ repletion is significant for the regulation of intestinal homeostasis, playing a critical role in rescuing the intestinal senescence phenotype caused by accumulated mtDNA mutations. Reference Yang, Liang et al. “NAD+ dependent UPRmt activation underlies intestinal aging caused by mitochondrial DNA mutations.” Nature communications vol. 15,1 546. 16 Jan. 2024, doi:10.1038/s41467-024-44808-z About BONTAC 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. BONTAC has over 160 domestic and foreign patents, leading the industry of coenzyme and natural products. BONTAC has rich R&D experience and advanced technology in the biosynthesis of NAD and NMN. High quality and stable supply of products can be ensured here. 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.
20(S)-Ginsenoside Rh2: A Promising Adjuvant Treatment for Acute Promyelocytic Leukemia
Introduction Acute promyelocytic leukemia (APL), the M3 type of acute myeloid leukemia (AML), typically relies on all-trans retinoic acid (ATRA) as its primary treatment. While APL patients treated with ATRA exhibit a high bone marrow complete remission rate, ATRA resistance severely limits its efficacy and contributes to a poor prognosis. Recent research underscores the potential of 20(S)-ginsenoside Rh2 (GRh2) as a lactylation-modified METTL3 inhibitor to ameliorate ATRA-resistance in APL, providing a new direction for the development of novel drugs for APL. About APL APL, constituting 10-15% of all AML cases, is characterized by abnormal promyelocyte proliferation, with associated complications such as bone marrow dysfunction and anemia. In the 1960s and 1970s, APL is a medical emergency with high mortality rate, and API-related death is often attributed to bleeding due to coagulation disorders. With the invention and evolution of new drugs, the prognosis of APL patients has been greatly improved. The 10-year survival rate for APL patients today is estimated to be about 80-90%. Differentiation-inducing agent, such as ATRA, is an essential part for the treatment of APL. Leukemic stem cells (LSCs) and ATRA-resistant APL cells primary contributors to leukemia recurrence post-remission. Addressing these residual issues is of great importance in the pursuit of improved treatment outcomes. The association between METTL3 and ATRA-resistance in APL METTL3 is a promising therapeutic target for ATRA resistant APL. Upregulation of METTL3, which is driven by lactylation modifications, promotes ATRA-resistance in APL, as indicated by the increased number of CD45+ leukemia cells and Giemsa positive cells in the METTL3-OE group. The suppressive impact of GRh2 upon ATRA-resistance in APL In vitro, GRh2 increases histone acetylation levels and considerably inhibits the lactylation level in ATRA-resistant APL cells, and promotes the apoptosis of ATRA-resistance LSCs, acting as a histone lactylation inhibitor. In addition to repressing the enzyme activity of METTL3, GRh2 dose-dependently inhibits the expression levels of METTL3 and MEETL3 and its downstream reading protein YTHDF2, YTHDF1 and YTHDC1 in ATRA-resistant APL cells. Molecular docking analysis shows that GRh2 can directly bind with METTL3. In vivo, GRh2 suppresses METTL3 expression, tumor weight and volume, yet enhances the sensitivity to ATRA differentiation therapy in mice with ATRA-resistant APL xenograft tumors. Moreover, GRh2 treatment considerably elevates the survival of ATRA-resistant APL xenograft mice. Conclusion Mechanically, GRh2 can reduce ATRA resistance in APL by repressing lactylation-driven METTL3. Further exploration of this interaction could lead to the development of more effective and personalized treatment strategies for APL patients, ultimately improving their prognosis and quality of life. Reference Cheng S, Chen L, Ying J, et al. 20(S)-ginsenoside Rh2 ameliorates ATRA resistance in APL by modulating lactylation-driven METTL3. J Ginseng Res. 2024;48(3):298-309. doi:10.1016/j.jgr.2023.12.003 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.