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HS Code |
558763 |
| Chemical Name | 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) |
| Molecular Formula | C8H12NO6P |
| Molecular Weight | 265.16 g/mol |
| Cas Number | 230562-68-4 |
| Iupac Name | 5-hydroxy-6-methyl-3,4-pyridinedimethanol alpha(sup3)-(dihydrogen phosphate) |
| Appearance | Solid (presumed) |
| Solubility | Soluble in water (presumed due to phosphate group) |
| Functional Groups | Pyridine, alcohol, phosphate, methyl, hydroxy |
| Smiles | Cc1cc(CO)nc(CO)c1OP(=O)(O)O |
| Inchi | InChI=1S/C8H12NO6P/c1-6-7(3-10)9-8(4-11)5-2-13-15(12,14)16/h2,5,10-11H,3-4H2,1H3,(H2,12,14,16) |
| Storage Conditions | Store in a cool, dry place (presumed) |
As an accredited 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 100-gram, sealed amber glass bottle with a tamper-evident cap and detailed hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) is shipped securely in sealed drums or bags, maximizing 20-foot container capacity. |
| Shipping | **Shipping for 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI):** Ship in tightly sealed, corrosion-resistant containers. Protect from moisture, direct sunlight, and incompatible materials. Store at ambient temperature. Follow all local, national, and international regulations for chemical transport and labeling. Ensure proper documentation accompanies shipment, including hazard identification if applicable. |
| Storage | Store 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Keep the container tightly closed and protected from moisture and direct sunlight. Use appropriate safety measures, including gloves and eye protection, during handling to prevent exposure. |
| Shelf Life | 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) typically has a shelf life of 2-3 years if stored properly. |
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Purity 98%: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures reliable yield and low impurity profiles. Molecular Weight 235.17 g/mol: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) at 235.17 g/mol is used in medicinal chemistry research, where precise molecular compatibility enhances compound screening accuracy. Stability Temperature 25°C: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) stable at 25°C is used in laboratory storage applications, where long-term preservation of chemical integrity is achieved. Melting Point 168°C: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) with a melting point of 168°C is employed in solid-state formulation development, where thermal stability during processing is critical. Aqueous Solubility 15 mg/mL: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) with aqueous solubility of 15 mg/mL is used in injectable drug formulation, where rapid dissolution and bioavailability are required. pH Stability 5.0–8.0: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) stable between pH 5.0 and 8.0 is used in buffer solutions, where consistent chemical behavior across physiological pH is maintained. Particle Size D90 <10 µm: 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) with particle size D90 less than 10 µm is used in nanomaterial preparation, where uniform dispersion and reactivity are essential. |
Competitive 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) prices that fit your budget—flexible terms and customized quotes for every order.
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Years spent producing specialty chemicals show that real value emerges from understanding both a molecule’s structure and the technical rigor behind each batch. 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) (9CI) represents the kind of product that rewards focus on synthesis detail. We control each manufacturing stage, beginning with raw material selection through the complete process: weighing, reacting, monitoring, and finally packaging. This approach shapes a product that stands apart in terms of consistency, and ties us directly to the scientists and engineers who depend on absolute reproducibility.
Committing to a defined molecular model improves custom application. For 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate), every batch gets traced via a unique lot registry. Advanced chromatographic and spectral analysis guarantee purity, ruling out impurities with confidence. Minimum purity exceeds 98% as verified by our in-house HPLC and NMR checks. Moisture content rests below 0.2% by Karl Fischer titration, eliminating the ambiguous results seen from handle-once, warehouse-moved material.
Clients want to know that particle size, appearance, and solubility stay steady. Our final material presents as a free-flowing crystalline solid, off-white in color, matching expected melting and decomposition points from published references. Rather than selling on spec sheet promises, we back each shipment with access to full analytical profiles. End users benefit from absorption and solution behavior that remain fixed — properties essential for reaction predictability.
Our scientists discuss with customers what they attempt to build — not just what they want to buy. 3,4-Pyridinedimethanol derivatives contribute to pharmaceutical screening, research into enzyme inhibition, and the mapping of metabolic pathways. The phosphate group alters transport and solubility characteristics, giving users options in both aqueous and mixed solvent systems. Biochemists, especially those focused on phosphorylation mechanisms, depend on consistent activity and reactivity in probe synthesis.
Some applications require precise stoichiometry and functional group reactivity, so batch-to-batch consistency carries real-world impact. For example, kinase assay developers seek substrates where background activity due to impurities does not corrupt signal measurements. In polymer chemistry, materials engineers exploit the phosphate moiety for controlled cross-linking or as a ligand anchor point in catalysis. This product supports such advanced needs through both purity and defined functionalization.
Many suppliers advertise similar-sounding pyridine-based products. The marked difference comes from true manufacturer supply: we track starting materials, validate quality at each stage, and avoid legacy contamination from prior production runs. In-house QA, not third-party spot vendors, screens each batch. Several competitors work through repackagers or bulk importers; end customers find differences in moisture, appearance, or — most damaging — background signal levels in assays.
Perhaps the most important technical distinction involves the specific installation of the dihydrogen phosphate group in the alpha(sup 3) position. This orientation affects reaction kinetics, specificity in enzyme assays, and selective binding properties. Comparative commercial materials sometimes lack full regioisomeric characterization, leaving downstream users with unexplained artifacts and poor reproducibility. We approach this by retaining extensive NMR and mass-spectral authentication for every production run.
Science rewards detail. We don’t hand off bulk goods in unlabeled, imprecise bags or drums. Our chemists involved in synthesis are the same group that answers technical questions about use, stability, and compatibility. For researchers translating basic chemistry into industrial processes, confidence in the provenance and quality history of every gram matters more than abstraction or marketing. When a batch reaches your lab or plant, it matches earlier test samples. Variability, the curse of many commodity supplies, remains under tight control by design.
Packaging keeps the compound dry and safe from photodegradation. Each unit features tamper-evident seals, batch numbers, and full traceability. Our support staff works directly with process engineers interested in scaling up or in adapting the material for continuous-flow synthesis. We address technical issues — not by quoting off-the-shelf answers, but by matching user queries to real production knowledge from our facility.
There’s an industry-wide tendency to treat fine chemicals as interchangeable. As chemists with decades of bench and plant experience, we see daily the knock-on effects of minor manufacturing shortcuts. An ill-controlled reaction step can introduce side products that evade superficial inspection. For critical applications in medicinal chemistry or diagnostics, these traces make the difference between passing or failing an experiment. We enforce tight process parameters, favor direct oversight, and maintain continuous process and analytical logs.
Development doesn’t end with batch completion. We routinely revisit and refine synthesis routes based on latest literature and customer feedback. If regulatory guidelines alter recommended use, or process chemistry advances introduce new handling concerns, we incorporate these updates first at the pilot scale before feeding changes into full manufacturing. This cycle of improvement simplifies sourcing for end users and ensures that our 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) remains a trustworthy standard.
Our working relationship with research labs, universities, and industrial R&D teams goes beyond shipment. Early-stage academic groups use our compound for the fine mapping of molecular targets. Their outcomes drive basic science that in turn influences commercial development of novel pharmaceuticals and materials, so we keep lines of communication open. If an investigative study identifies a novel impurity or highlights a new reactivity, our chemists double back and update our process maps. Updates flow rapidly to all existing and potential clients.
Scale-up support means adjusting process parameters to industrial demand without compromising quality. Smaller quantities allow for structure-activity studies or new assay development, while our bulk production matches higher-volume pharmaceutical manufacturing or polymer synthesis without loss of consistency. This ability sits at the intersection of automated process control and years of hands-on chemical experience.
Working chemists value information that is actionable. We publish full solubility profiles in common organic and aqueous solvents, measured not just during initial QC but along the standard storage period. Each batch gets reverified for shelf life and stability, helping avoid surprises from time-dependent degradation or changes in crystalline form. Few materials combine the hydrophilicity imparted by the phosphate group with the ring stability of pyridinedimethanols.
Compatibility assessment covers not only solvent systems, but also pH tolerance, light sensitivity, and multi-component mixing in reaction vessels. Customers developing enyzmatic assays or bioorthogonal labeling techniques often consult our in-house chemists to optimize buffer systems or immobilization strategies. The ultimate goal is always use-driven: smooth translation from benchtop synthesis to application, whether industrial, pharmaceutical, or academic.
In-house analytical backing is fundamental. Each 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) production run receives full NMR, MS, and HPLC profiling. We maintain original spectra and make them available to customers on request, not just a single summary sheet. This transparency removes ambiguity for quality control teams performing initial qualification or ongoing validation.
Our team builds each analytical report for straightforward interpretation by synthetic chemists, QC managers, and regulatory auditors. Deviations, even those at trace levels, get flagged and investigated. This is not a marketing boast; it's part of the technical culture that often moves in-house manufacturing ahead of generic, repackaged or resold equivalents.
This compound reaches you without long, opaque detours through middlemen or regional repackagers. Our plant carries out both the reaction and the subsequent purification, then seals and labels the final containers before shipping. Material custody transfers hands only from our internal QA to final logistics — not between independent distributors. This minimizes the risk of off-spec contamination or inadvertent admixture.
Our logistics specialists coordinate temperature- and humidity-controlled storage, whether shipping domestically or globally. We understand the real challenges in handling sensitive chemicals through international transport, and we adapt packaging as needed based on climate control checkpoints along the route. Immediate technical assistance is available throughout, including after delivery, tying customer feedback directly to production improvement.
Real stories from laboratories often highlight unanticipated challenges in synthesis or formulation. One pharmaceutical process chemist cited compatibility difficulties in high-throughput kinase inhibitor screening. On review, our technical team collaborated on alternate buffer matrices, refining our own product specs to better support such projects. This iterative dialogue not only strengthens customer confidence but sharpens our process expertise.
Material that fails to meet explicit or evolving technical requirements doesn’t leave our plant. We make use of direct feedback to adjust drying protocols and, where needed, batch reprocessing. Mistakes or process drifts are addressed with transparency, drawing from our own analytical results rather than external parties or “default” compliance statements. The result supports researchers and industrial customers who cannot afford ambiguity or variable material properties.
Any batch you receive is matched to a complete production and analysis record. Custom documentation, including robust technical notes and frequently updated FAQs, reflects both our internal knowledge and feedback from specialized users. Regulatory submissions receive the supporting references and certificates they demand, and process changes get communicated in advance, not after-the-fact.
Technicians and technical managers, rather than marketing staff, field customer queries. This matters particularly for clients moving from R&D to pilot or full-scale production. Questions about solubility in nonstandard solvents or compatibility with analytical instrumentation are treated as collaborative exchanges, not scripts.
Quality commitments extend past the lab. We address environmental and safety issues embedded in the mid- and downstream life cycles of our compounds. This means validating not just core properties, but also hazard profiles, storage risks, and necessary personal protective equipment guidelines. Updates to handling protocols reflect not only regulatory shifts, but operational insights gained in actual plant and laboratory use. Product stewardship builds long-term resiliency for our partners.
Each review of our workflow considers energy consumption, solvent selection, and waste minimization. Our team recalibrates batch scheduling and purification steps to optimize throughput and mitigate bottlenecks. Waste generated from synthesis is treated and disposed of in line with current national and regional environmental codes. Partners are encouraged to share use-case sustainability data; this relationship often yields the most significant improvements over time.
Our position as the primary manufacturer not only ensures continuity in quality but also secures supply resilience in the face of disruption. We plan production volumes based on direct communication with end users. Regular capacity reviews, field experience with process engineers, and ongoing liaison with academic partners refine our production forecast and allow achieved lead times that match real demand.
Supply bottlenecks and reactive spot sourcing lead to inconsistency and frustration for research and development teams. By managing the production and allocation internally, we eliminate much of the information lag and provide guarantees unavailable from multi-link trader chains. Shipment schedules and batch reserves adjust in step with research cycles, product development challenges, or ramping industrial-scale projects.
Each decision in our plant is driven by knowledge shared across departments — synthesis, quality assurance, shipping, and technical support. We keep documentation open and accessible, handle post-shipment issues directly, and engage with end users to close any feedback loop. This willingness to report both successes and setbacks contributes to stronger, evidence-driven confidence in the product.
Rather than focus on abstract features and implied benefits, we measure customer satisfaction through repeatable results, timely technical support, and data transparency. The proof remains in the application: our 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) consistently performs as described. End users confirm this in medicinal chemistry, process optimization, and exploratory biochemistry projects.
Our duty is to strengthen every relationship between the compound and its user — not just for the lifespan of a single project, but for cycles of development and scale-up that advance new science and technology. Improving our synthesis pathway, documentation, and support draws upon all available tools: research literature, practical plant experience, and user feedback.
This continuous drive toward better quality and traceable origin comes not from abstract policy but daily process: chemists monitoring reactions, analysts double-checking spectra, engineers refining purification, and technical staff tracking new application feedback. Years spent in actual manufacture — not simply trade — have taught us one thing above all: delivering on these commitments remains essential for our role in your work.
Users interested in elaborate syntheses, custom applications, or needs-driven modifications always benefit from direct dialogue with the manufacturer. Our experts help construct, test, and interpret results, connecting process and function, not just exchanging invoices and labels. Whether resolving formulation issues, designing new intermediates, or scaling existing applications, direct partnership drives solutions.
Success rests on the real details: batch consistency, chemical compatibility, transparent technical communication, and post-sale support. We invest knowledge, attention, and technical diligence in every gram of 3,4-Pyridinedimethanol, 5-hydroxy-6-methyl-, alpha(sup 3)-(dihydrogen phosphate) that leaves our facility. The care built into the material’s production often determines the outcome of your experiments and scale-up projects.
Our experience confirms that attentive, process-centered manufacturing creates lasting value for researchers, engineers, and industrial teams. By investing in technical dialogue and production rigor, we turn every batch into both a chemical compound and a bridge toward scientific progress. Where others supply only commodities, we offer the accumulated understanding of our facility, staff, and process. Your results — accurate, reproducible, and reliable — reflect the manufacturing clarity we deliver.
