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
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
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
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
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.
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
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.
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.
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.
Introduction Rare ginsenoside Rg3, an active extract from Panax ginseng, is reported to possess a wide range of pharmacological properties including anti-angiogenesis and anti-cancer, with high lipophilicity (estimated log P4) and a low water solubility at pH7.4. Nevertheless, its permeability and bioavailability are relatively low, and production procedures are complex. Remarkably, the metabolites of Rg3 have similar and even stronger activity than Rg3, opening up new opportunities for future adjuvant cancer therapy. The association of ginsenoside Rg3 and its metabolites There are two epimers of ginsenoside Rg3, which can be subsequently deglycosylated into epimers of ginsenoside Rh2 (S-Rh2 and R-Rh2) and protopanaxadiol (S-PPD and R-PPD). The anti-cancer properties of Rg3 metabolites Angiogenesis and tumor cell proliferation are both interdependent factors in tumor progression. In terms of anti-proliferation, Rg3 metabolites, who induce S-phase arrest and necroptosis in a human triple negative breast cancer cell line MDA-MB-231 as well as G0/G1 arrest and apoptosis in human umbilical vein endothelial cells (HUVECs), are more potent than Rg3. The clinically relevant target of Rg3 metabolites are the endothelial cells. Anti-angiogenic effects are evaluated using loop formation assay. Among Rg3 metabolites, S-Rh2 is the most potent inhibitor of loop formation. VEGFR2 and AQP1 as the targets of Rh2 According to the prediction by in silico molecular docking, there is a good binding score between Rh2/PPD and the ATP-binding pocket of VEGFR2, a dominant regulator controlling both physiological and pathological angiogenesis. Through VEGF bioassay, it is discovered that S-Rh2 is a most potent anti-angiogenic candidate with allosteric modulatory action on VEGFR2 function. In addition, Rh2 and PPD have the potential of blocking AQP1 and AQP5, two members of the aquaporin family with vital roles in proliferation, migration, invasion and angiogenesis. Moreover, Rg3 is more selective for AQP1 and does not show a good binding score with AQP5. In light of this, blocking the water channel function of AQP1 may have an immediate role in inhibition of loop formation and anti-angiogenic effects of Rh2. Conclusion Metabolites of Rg3 could potentially increase the anti-cancer properties of Rg3. The application of these molecules alone or together may be potent alternatives for future adjuvant cancer therapy. Reference Nakhjavani M, Smith E, Yeo K, et al. Differential antiangiogenic and anticancer activities of the active metabolites of ginsenoside Rg3. J Ginseng Res. 2024;48(2):171-180. doi:10.1016/j.jgr.2021.05.008 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 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.
1. Introduction Heart failure is a serious condition in the development of cardiovascular disease. In particular, diastolic heart failure, as one of the most common manifestations of heart failure in the elderly, has always been viewed as a classic aging-related terminal illness due to its high prevalence and lack of effective treatment. Nicotinamide mononucleotide (NMN) raises the hope for the treatment of this illness. NMN can restore the functions of heart and blood vessels, protect the heart from damage after a heart attack, prevent heart failure by promoting the health of the mitochondria, and restore cardiovascular, cognitive, and metabolic decline. This study is dedicated to deciphering another mechanism of action for NMN administration, namely improving lysosomal ferroptosis to prevent heart failure. 2. The key pathogenesis of diastolic heart failure The effect of NMN on improving cardiac function is mainly realized by elevating the level of myocardial nicotinamide adenine dinucleotide (NAD+), an important coenzyme in the tricarboxylic acid cycle. The mitochondrial dysfunction and decreased ability of NAD+ biosynthesis are the key pathogenesis of diastolic heart failure. 3. Restoration of lysosomal function and autophagic function by NMN administration Lysosomal function is impaired owing to decreased NAD+ biosynthesis in vivo. NMN administration improves lysosomal function and activates amino acid metabolism in the mice with cardiomyocyte-specific knockout of p32 (p32cKO), yet barely affects the lysosomal morphology. Additionally, NMN administration improves the degradation mechanism of autophagy, as evidenced by the restoration of autophagic function post NMN administration. 4. The detailed mechanism of action for NMN administration on heart failure NMN administration does not restore functional mitochondrial damage caused by the inhibition of mitochondrial translation. These findings suggest that NMN administration improves heart failure by improving lysosomal function without improving mitochondrial function. 5. The involvement of ferroptosis in heart-specific mitochondrial translation defect The suppression of ferroptosis ameliorates heart failure. The expression levels of ferroptosis-related factors (Chac1, GPX4, and Ho1) are also diminished by NMN, indicating that ferroptosis in the p32cKO heart is improved by NMN administration. 6. The improvement of mitochondrial dysfunction-induced ferroptosis by NMN administration The ferroptosis is induced in the p32 knockdown cells, as attested by the mitochondrial translation defect and the downregulation of intracellular NAD+ and NADH levels. The induction of ferroptosis in lysosome is closely related to the amount of NAD+ biosynthesis. When intracellular NAD+ level is lowered, the intracellular iron deposition and lipid peroxide are induced, which however are ameliorated by NMN administration. 7. Conclusion Mechanically, NMN administration can prevent heart failure by improving lysosomal ferroptosis, opening up new insight for the treatment of this illness. Reference Yagi, Mikako et al. “Improving lysosomal ferroptosis with NMN administration protects against heart failure.” Life science alliance vol. 6,12 e202302116. 4 Oct. 2023, doi:10.26508/lsa.202302116 BONTAC NMN product features and advantages * “Bonzyme” Whole-enzymatic method (environmental-friendly; no harmful solvent residues) * Exclusive “Bonpure” seven-step purification technology, with high purity (up to 99.9%) and stability * Industrial leading technology: 15 domestic and international NMN patents * Self-owned factories and a number of international certifications to ensure high quality and stable supply of products * One-stop customized service for product solution * NMN raw material supplier of famous David Sinclair team of Harvard University 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.
1. Introduction On July 2023, the World Health Organization (WHO) has classified the soda sweetener aspartame as a possible carcinogen, but said that aspartame is safe to consume within a daily limit of 40 milligrams per kilogram of a person’s body weight according to the latest assessment results regarding the impacts of the non-sugar sweetener aspartame upon the health. How about another sweetener stevioside? Is stevioside a sugar reducer or a health killer? 2. Current situation on stevioside Stevioside (also termed stevia glycoside) has been regarded as “the third largest source of natural sugar across the world” by virtue of its low calorie, high sweetness, good stability and low price, which is widely used in medicine, daily chemicals, beverage, food, brewing and other industries. 3. Regulatory application and control of stevioside The aforementioned report of WHO on the possible carcinogenesis of soda sweetener aspartame is based on high intake. An adult weighing 70 kilograms or 154 pounds would have to drink more than 9 to 14 cans of aspartame-containing soda daily to exceed the limit and potentially face health risks. There is no need to be worry about the risk of carcinogenesis in the case of healthy intake. The same situation is applicable to another sweetener stevioside. Stevioside is approved to be sweetener in food in countries like Mainland China, Japan, Korea, Australia, New Zealand, the USA and European Union. In China, there are detail specifications on the food additive stevioside (GB 2760-2014). 4. The therapeutic properties of stevioside 4.1 Antitumor effect Stevioside can be applied as a valuable chemotherapy candidate to be further investigated for cancer therapy. The activity of the well-known tumor promoter, 12-O-tetradecanoylphorbol-13-acetate (TPA), is successfully inhibited with stevioside in a murine skin-cancer model. In addition, stevioside can reduce mammary adenoma incidence in F344 rats. 4.2 Anti-hypertensive activity The hypotensive effect observed in rats after chronic oral administration (30 days) of 2.67 g stevia leaves/day has been confirmed in spontaneously hypertensive rats. In that murine model, stevioside (100 mg/kg; i.v.) is able to reduce blood pressure with no change in serum epinephrine, norepinephrine, or dopamine levels. 4.3 Anti-diabetics In diabetic rats, stevioside (0.2 g/kg; i.v. administration) decreases glucose blood levels, yet increases insulin responses and reactions to an intravenous glucose tolerance test (IVGT). Also, stevioside enhances insulin levels above basal during the IVGT, without altering blood glucose response, in normal rats, hinting its potential as a drug candidate for type 2 diabetes. 4.4 Inhibition of pathogenic bacteria Stevioside has demonstrated antibacterial action on various foodborne pathogenic bacteria, including Escherichia coli, a wellknown etiologic agent of severe diarrhea. Regarding antiviral properties, stevioside seems to impede binding of rotavirus to host cells. Rotavirus is commonly associated with pediatric gastroenteritis. 4.5 Anti-inflammatory property In lipopolysaccharide (LPS)-stimulated THP1 cells, stevioside (1mM) inhibits NF-κB. Moreover, stevioside prevents in vitro upregulation of genes involved in liver inflammation. In addition, silico assays demonstrate its antagonistic action in two proinflammatory receptors: tumor necrosis factor receptor (TNFR)-1 and Toll-like receptor (TLR)-4-MD2. 4.6 Antioxidant capability The antioxidant effects of stevioside and rebaudioside A have been confirmed in a fish model, both of which effectively control lipoperoxidation and protein carbonylation. Furthermore, stevioside prevents oxidative DNA damage in the livers and kidneys of a type 2 diabetes murine model. 5 Conclusion As long as the intake is properly controlled, stevioside can be very useful. Stevioside holds a great promise in the clinical treatment and daily health care. Reference Orellana-Paucar A. M. (2023). Steviosides from Stevia rebaudiana: An Updated Overview of Their Sweetening Activity, Pharmacological Properties, and Safety Aspects. Molecules (Basel, Switzerland), 28(3), 1258. https://doi.org/10.3390/molecules28031258 BONTAC Stevioside Reb-D product features and advantages BONTAC possesses the international application and authorized patents on Stevioside Reb-D (US11312948B2 & ZL2018800019752), where the product quality (purity and stability) can be better ensured. Disclaimer BONTAC shall hold no responsibility for any claims arising directly or indirectly from your reliance on the information and material on this website.