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HS Code |
941557 |
| Productname | Nicotinic Ribose |
| Chemicalformula | C11H15NO6 |
| Molecularweight | 257.24 g/mol |
| Appearance | White to off-white powder |
| Solubility | Soluble in water |
| Purity | ≥98% |
| Casnumber | 13345-26-1 |
| Storagetemperature | 2-8°C |
| Synonyms | Nicotinamide riboside |
| Phrange | 5.0 - 7.0 (10 mg/mL in water) |
| Stability | Stable under recommended conditions |
| Usage | Biochemical research, NAD+ precursor |
As an accredited Nicotinic Ribose factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 5 grams of Nicotinic Ribose, securely sealed, labeled with safety information, chemical formula, and batch number. |
| Shipping | Nicotinic Ribose is shipped as a stable solid, typically in a sealed container to prevent moisture and contamination. It should be handled with standard laboratory precautions. During transit, the chemical is protected from excessive heat and direct sunlight. Ensure compliance with local and international regulations for safe chemical transportation. |
| Storage | Nicotinic ribose should be stored in a cool, dry, and well-ventilated area, away from direct sunlight and moisture. Keep the container tightly closed and properly labeled. Store at 2-8°C (refrigerated) for best stability. Avoid exposure to heat, oxidizing agents, and incompatible materials. Ensure proper laboratory safety protocols are followed when handling and storing this chemical. |
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Purity 99%: Nicotinic Ribose with Purity 99% is used in high-purity pharmaceutical synthesis, where it ensures minimal by-products and maximizes yield efficiency. Molecular Weight 378.31 g/mol: Nicotinic Ribose with Molecular Weight 378.31 g/mol is used in metabolic pathway studies, where it provides precise substrate quantification for accurate biochemical assays. Aqueous Solubility >100 mg/mL: Nicotinic Ribose with Aqueous Solubility >100 mg/mL is used in injectable formulation development, where it enables rapid dissolution and homogeneous distribution. Melting Point 147°C: Nicotinic Ribose with Melting Point 147°C is used in controlled thermal processing, where it maintains chemical stability during formulation compounding. Stability Temperature up to 40°C: Nicotinic Ribose with Stability Temperature up to 40°C is used in ambient storage conditions, where it preserves chemical integrity and extends shelf life. Particle Size <20 µm: Nicotinic Ribose with Particle Size <20 µm is used in micronized powder formulations, where it improves dissolution rate and enhances bioavailability. Optical Purity >98%: Nicotinic Ribose with Optical Purity >98% is used in enantiomer-specific biocatalysis, where it ensures regioselective activity and reproducible product outcomes. Endotoxin Level <0.1 EU/mg: Nicotinic Ribose with Endotoxin Level <0.1 EU/mg is used in cell culture media preparation, where it avoids cytotoxic effects and supports high viability. pH Stability 5–8: Nicotinic Ribose with pH Stability 5–8 is used in buffered biochemical assays, where it retains molecular structure and guarantees consistent assay performance. Residual Solvent <0.01%: Nicotinic Ribose with Residual Solvent <0.01% is used in critical pharmaceutical ingredient manufacturing, where it reduces toxicity risk and complies with regulatory standards. |
Competitive Nicotinic Ribose prices that fit your budget—flexible terms and customized quotes for every order.
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Nicotinic ribose production holds a unique place in our daily operation. On paper, it’s a ribosylated form of nicotinate, and sometimes known as nicotinic acid riboside. From the chemist’s view, the compound brings together a beta-D-ribofuranosyl moiety with nicotinic acid, forming an unusual but useful building block. We see this molecule not as a generic raw material, but as a bridge between research-driven innovation and the realities of scaling chemical synthesis.
Each batch of nicotinic ribose comes out the reactor after thoughtful synthesis, purification, and batch control. We run every lot through HPLC, confirming purity greater than 98% before powder lands in storage. Our standard grade takes the form of a pale, off-white solid, stable in sealed containers kept out of strong light and moisture. Moisture content for our material routinely holds under 1%, and our attention to end-to-end handling makes a difference that researchers and product developers notice very quickly.
For scientists who rely on structural certainty, we back every order with NMR and MS data. In our lab, reproducibility drives our choices—no one wants surprises halfway through a critical formulation or cell study. Each shipment includes a copy of the lot’s spectral fingerprint, so users have real assurance; that’s a practice rooted in years of troubleshooting.
Applications for nicotinic ribose have grown over the past decade. Our clients span pharmaceutical biotech, nutritional science, enzyme study, and metabolic pathway research. Outside of the academic world, there’s interest from developers working on functional foods, anti-aging formulations, and advanced fermentation.
Nicotinic ribose serves as a starting compound for producing higher derivatives—especially NAD+ and related cofactors essential for redox reactions and energy metabolism. Traditional routes for NAD+ synthesis use either direct enzymatic conversion or multi-step chemical transformations from simpler nucleosides. Introducing pure, well-characterized nicotinic ribose as a feedstock makes these processes faster and more controllable.
While most molecular biologists think of NAD+ as their workhorse, they tend to realize the upstream constraints only when their NAD+ yields start falling short. We’ve fielded calls from universities and pilot plant operators frustrated by impurity problems or batch-to-batch inconsistency. Direct synthesis of higher-order nucleotides from our ribosylated precursor streamlines the chain, cutting risk of side reactions and unwanted isomers.
One pattern stands out year after year. It’s not only the molecule’s formula that matters but the manufacturing discipline behind it. We weigh every gram, log reaction temperatures, and keep tight control on solvent quality. If you have spent time investigating unsuccessful couplings or unexpected chromatography results, you start seeing why “just having a source” isn’t enough.
A clear signal appears in analytical outcomes. Reliable nicotinic ribose supports smooth phosphorylation and cofactor assembly, even in environments crowded with competitive side chemistry. Researchers have told us that pre-filtered, low-endotoxin batches reduce background “noise” in cell-based assays and boost statistical confidence in their endpoints.
It’s not unusual for someone to order just a few grams for a pilot experiment and wind up coming back for kilogram quantities. That journey—from benchtop to production scale—only works if every lot maintains the expected purity and stability. We stock higher-quantity material for these cases, keeping reserve under monitored storage, so users don’t lose weeks to procurement bottlenecks.
We’ve heard plenty from customers comparing our material to alternatives sourced from trading houses or non-specialized vendors. Many difference makers trace back to care at the manufacturing level. Spotty attention to input reagents or weak purification shows up as off-color, hygroscopic material, or residual solvent signals in mass spectra. The surface looks chalky, or the product cakes after exposure—and that’s just the visible side of trouble.
Waste product from inattentive synthesis holds up downstream transformations and makes scale-up a headache. A single unvetted kilogram batch that falls short of specification carries hidden frustration and cost. Process engineers know that cutting corners on input material often means burning time and budget later. That’s why a meticulous and facility-driven approach to synthetic chemistry—one where lot numbers and chain of custody matter—matters more than price per gram.
In-house, we manage everything from milligram research-scale vials to kilogram process runs. Customers ask about custom packaging, same-day shipments, and freeze-dried alternatives for specialty processes. Satisfying these requests takes real people walking the floor, not just supply chain automations. Internal traceability means that we stand behind what ships out. If a deviation ever arises, we contact our clients directly, pull the associated batch, and run new analyses. It’s rarely needed, but the infrastructure—logs, trackbacks, cold storage—has to be there every day.
Technical groups often query us about different forms for their projects. Some need the free acid; others want the sodium salt or a protected riboside version. Instead of running off a prefab spec sheet, we review current process needs, cross-check available synthetic routes, and decide together which form fits the workflow. Feedback from users has led us to optimize and sometimes even redesign a reaction step, improving the practicality for others down the line.
Years of fielding technical service emails have revealed a recurring confusion: distinguishing nicotinic ribose from its cousins, like nicotinamide riboside or nicotinic acid alone. From the chemical side, the difference comes down to the linkage at the five-membered sugar ring and the base attached. Where nicotinamide riboside feeds the salvage pathway with a different nitrogen base, nicotinic ribose sits upstream with the acid functionality. For NAD+ engineering or cofactor reconstitution, picking the right precursor makes a significant difference in yield and purity.
Handling also differs. Nicotinic acid alone is robust and tolerant of poor storage. Once ribosylated, though, the molecule becomes more sensitive to hydrolysis and oxidation. Some substitutes degrade in warm or damp warehouses, changing their physical properties and leaving users with inconsistent assay readouts or ruined fermentations. We shield our product early post-synthesis and finish every lot with multi-stage vacuum drying, which matters for stability.
Custom requests can open new avenues in both chemistry and business. We took on several collaborative projects where a client required isotopically labeled or chirally pure forms of nicotinic ribose to support high-resolution metabolic tracing. Producing labeled carbon in the ribose ring led us to refine separation steps and establish a new partnership with a local spectroscopy lab. These technical pivots bring downstream benefits for everyone sourcing from us, enabling better mass balance and quantification in finished projects.
Partnership with downstream teams allows us to spot and solve bottlenecks early. Sometimes, customers need material for GMP production or a late-stage clinical study. While our usual process meets research-grade standards, we’ve built out support for full documentation and expanded quality control. Supporting regulatory filings takes more than “good-enough” material; it’s about detailed batch records, robust cleaning validation, and readiness for an auditor’s visit.
Demands for traceability and reproducible performance have increased across the chemical supply chain. Publication retractions and market recalls have made researchers more vigilant in picking their input materials. We’ve responded by tightening batch tracking, updating MSDS libraries, and installing more frequent calibration cycles for our analytical equipment. It means more hours and more up-front investment, but feedback from users—“no surprises, every time”—tells us the time goes to good use.
As regulatory frameworks become more rigorous, product developers and scientists will expect not just technical performance but transparency about source and handling. Our internal procedures adjust in real time as new guidelines appear. We consult with accredited auditors and listen when users report issues from other vendors—turning competitor mistakes into improved internal protocols.
Our roots are in hands-on chemistry and day-to-day plant operation. Several team members have spent years running in-process analytics, pilot scale vessels, and final product packaging. Their experience shapes each update to our SOPs. We value the input of every technician who flags an anomaly or proposes a refinement, and our internal culture rewards vigilance as much as it does efficiency or productivity.
Communicating real facts—down to how a batch smells, flows, or responds to an open drum—helps us flag deviations before they become field problems. We catalog this “nonstandard” data along with third-party certificates, since experience says such concrete details foreshadow actual performance trends.
Chemical manufacturing rests on a careful balance: delivering material that meets spec, in a form that real teams can use, and responding to both common and unexpected challenges. Technology shifts don’t halt, and neither do user requirements. We continually refine our purification steps and look for ways to minimize solvent usage or streamline final packaging. Environmental responsibility drives process upgrading, and we invest in waste minimization gear and effluent reduction. Not because it’s trendy, but because the same skills that prevent a runaway reaction also keep our community and staff safer.
Feedback loops with end-users—sometimes intense, often technical—push us to improve. Learning about an unanticipated excipient reaction or a missed stability window, we adapt recipes and update training. In practice, this means fewer failed runs for researchers and better consistency for contract manufacturers.
Nicotinic ribose isn’t a commodity for us; it represents years of practical experience, process refinement, and daily diligence from the lab bench to the final bottle. Whether a customer is screening for a new nutraceutical, restoring metabolic cofactors in a rare cell model, or scaling up an enzymatic reaction, our role is to deliver precisely what works—every time, at every scale, for any application.
We see each order as a partnership, not just a transaction. Our phones and inboxes remain open—engineers, project leads, and formulators find it valuable to discuss details before and after shipment. That ongoing commitment—rooted in real-world experience—is what differentiates our offering in the crowded landscape of specialty chemicals.
Everything written above draws on the actual routines, challenges, and successes of our manufacturing site. Science isn’t static, and neither are the real-world needs of chemical professionals working to bring trusted results. Reliable nicotinic ribose starts from careful foundation, solid verification, and the willingness to learn from every batch—qualities we uphold daily. We share our experience because good chemistry travels best when it’s made, handled, and supported by people who understand its journey from start to finish.
