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HS Code |
744518 |
| Product Name | 6-HYDROXYNICOTINALDEHYDE |
| Synonyms | 6-Hydroxy-3-pyridinecarboxaldehyde |
| Molecular Formula | C6H5NO2 |
| Molecular Weight | 123.11 g/mol |
| Cas Number | 21935-61-9 |
| Appearance | Off-white to pale yellow powder |
| Melting Point | 119-121°C |
| Solubility | Soluble in water and organic solvents such as ethanol and DMSO |
| Purity | Typically ≥98% |
| Structure | A pyridine ring substituted with a hydroxy group at position 6 and an aldehyde at position 3 |
| Chemical Class | Pyridine derivative |
| Storage Conditions | Store at 2-8°C, keep tightly sealed |
As an accredited 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) 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, sealed with a screw cap, labeled with product name, chemical formula, and safety warnings. |
| Container Loading (20′ FCL) | 20′ FCL contains securely packaged 6-HYDROXYNICOTINALDEHYDE, moisture-protected drums, ensuring safe bulk transport and compliance with chemical handling regulations. |
| Shipping | 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) is shipped in tightly sealed, chemical-resistant containers under ambient conditions. It should be protected from moisture and direct sunlight. Labels indicating chemical hazards are affixed per regulatory standards. Transport complies with local and international chemical shipping regulations, ensuring safe handling and delivery. |
| Storage | 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) should be stored in a tightly closed container, protected from light and moisture. Store in a cool, dry, and well-ventilated area, ideally at 2–8°C (refrigerated). Keep away from incompatible substances such as strong oxidizers. Ensure proper labeling and access limited to qualified personnel. Follow all applicable safety protocols and regulations. |
| Shelf Life | 6-HYDROXYNICOTINALDEHYDE should be stored cool, dry, and protected from light; typical shelf life is 2 years in unopened containers. |
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Purity 98%: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with a purity of 98% is used in active pharmaceutical ingredient synthesis, where it ensures high yield and reduced impurity profiles. Molecular Weight 137.11 g/mol: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with a molecular weight of 137.11 g/mol is applied in medicinal chemistry research, where it facilitates precise compound modeling and molecular docking studies. Melting Point 115°C: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with a melting point of 115°C is utilized in organic synthesis workflows, where it enables controlled phase transitions for efficient reactions. Particle Size <10 microns: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with particle size less than 10 microns is employed in formulation development, where it promotes uniform dispersion and enhanced solubility. Stability Temperature up to 80°C: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) stable up to 80°C is involved in catalysis studies, where it maintains structural integrity under elevated reaction temperatures. UV Absorption λmax 315 nm: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with UV absorption at λmax 315 nm is used in spectrophotometric assays, where it allows sensitive detection and quantification of reaction intermediates. Moisture Content <0.5%: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) with moisture content below 0.5% is used in high-performance materials R&D, where it preserves chemical integrity and prevents hydrolytic degradation. Solubility in DMSO 100 mg/mL: 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) soluble in DMSO at 100 mg/mL is implemented in bioassay sample preparation, where it ensures consistent dosing and reproducible results. |
Competitive 6-HYDROXYNICOTINALDEHYDE (6-HYDROXY-3-PYRIDINE CARBOXYALDEHYDE) prices that fit your budget—flexible terms and customized quotes for every order.
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In chemical manufacturing, there are raw materials you encounter daily, and then there are compounds that draw you into the finer challenges of precision synthesis. 6-HYDROXYNICOTINALDEHYDE, or 6-hydroxy-3-pyridine carboxyaldehyde, often falls into the latter camp. Its unique makeup positions it as a building block worth closer attention, especially for chemists focused on downstream synthesis and high-purity project requirements.
Every batch we run rests on a foundation of high-purity pyridine derivatives. 6-HYDROXYNICOTINALDEHYDE comes from a strict chain of reactions starting from selected pyridine sources. Our standard production model centers around crystalline powder with a purity typically above 98%, produced through a series of hydroxylation and oxidation steps. The aldehyde group at the 3-position, along with the hydroxyl at the 6-position, gives this molecule increased reactivity compared to its methylated or deoxygenated relatives.
The quality of this compound hinges on controlling trace impurities, especially residual starting material and side products like isomeric aldehydes. As process chemists, we spend long hours tracking subtle shifts in color and solubility during crystallization. Optical clarity, particle size, and spectral signatures determine whether a batch meets the internal benchmarks that our customers expect. Spectroscopic checks — NMR, HPLC, UV — provide more than paperwork; they set the story straight on product quality.
Commercial users of 6-HYDROXYNICOTINALDEHYDE run the spectrum from pharmaceutical intermediates to dyes and specialty ligands for catalysis. From the manufacturer’s perspective, applications drive purity decisions. Drug chemists working on potential CNS therapeutics demand trace-level impurity control. A research group screening new electronic materials asks for consistent reactivity and solubility in niche solvents. These requests feed back into our operations, sometimes spurring whole process upgrades — filtration tweaks, silica selection for chromatography, or fresh tweaks to drying protocols.
The position of the hydroxyl and aldehyde groups on the pyridine ring matters. This combination serves as a gateway for site-selective functionalizations. Adding complex side chains, forming Schiff bases, or building ligands for transition metals all hinge on reactivity dictated by these groups. We hear from project leaders who appreciate the difference in yield and selectivity when a batch meets key isomer ratios. If a side pathway produces a contaminant, you lose time and resources filtering it out. Every percent of selectivity matters.
It's easy to lump all pyridine carboxaldehydes together. In practice, switching from 6-HYDROXYNICOTINALDEHYDE to, say, 2-hydroxy or 4-methyl analogues alters everything. The electronic effects of hydroxyl versus methyl, the ring placement, and even minor solubility differences cause changes in downstream yield and reaction time. We routinely run side-by-side purity and reactivity tests. Customers tracking gram-level losses in expensive projects rarely settle for 'close enough.' This specificity keeps us vigilant on quality details during every stage, from crystallization to packing.
Most plants produce larger volumes of simpler derivatives — plain nicotinaldehyde or nicotinic acid — but those products cannot reliably deliver the same control where selectivity and functional group compatibility matter. For example, 6-HYDROXYNICOTINALDEHYDE’s ortho relationship between aldehyde and hydroxyl increases the options for cyclization or condensation, especially where ortho coordination supports metal complex formation. The subtle details in reactivity only come through after repeated batches and lots of feedback from end users who push the chemistry to its limits.
Over the years, we’ve collected more lessons from users than any technical manual offers. One customer working on anti-inflammatory drug scaffolds pressed us during a run: downstream, even a tiny excess of ortho-quinone byproduct forced costly repurification steps. Our investigation led us to a minor temperature control issue during the oxidation phase. Tweaking the process gave us not just a cleaner batch but improved time to market for future deliveries. These are the stories behind every lot that ships out; seasoned buyers often visit our plant just to check the fineness of powder or clarity of the color themselves.
Some academic users in materials science highlight the compound’s ability to support ligand frameworks suiting rare-earth metal complexes. These applications depend on precise stoichiometry and reproducible reactivity. In one project, a user detected shifts in NMR spectra tied to trace sodium contamination from cleaning cycles. We adapted the process by isolating work-up equipment and tightening our final drying tolerances. The result was a product profile more consistent across multiple research projects using advanced spectroscopic tests.
Scaling up production often uncovers challenges that pilot runs can’t predict. Batch consistency, solvent recovery, and even waste management impact our daily operations. Handling 6-HYDROXYNICOTINALDEHYDE on the kilo scale, we’ve learned to account for the molecule’s reactivity with atmospheric oxygen. Oxidative degradation hits purity and reduces shelf life — details that only come from watching lots held over several months.
Sustainability pressures in chemical manufacturing are rising, and our facility responds with both new and time-tested solutions. We shifted solvent recovery to more closed-loop operations, driven by both customer requirements and environmental regulations. Not every process step adapts easily, but the collective experience of chemists, operators, and maintenance staff lets us maintain quality while cutting energy and resource consumption year over year. End users increasingly ask for data on environmental impact. We document batch utilities and solvent use, incorporating those numbers into our improvement cycles and sometimes directly into customer-facing transparency reports.
Lab-scale synthesis offers a different world compared to industrial manufacturing. Our facility runs regular audits tailored to the requirements from pharmaceutical and specialty chemical customers. Documentation on traceability, cross-contamination control, and robust HACCP procedures is not just for auditors; it keeps every operator focused. Many small-molecule facilities face bottlenecks due to labor shortage or maintenance delays. By maintaining a multi-skill workforce, our plant reduces these interruptions, preserving the continuity demanded for sensitive batches like 6-HYDROXYNICOTINALDEHYDE.
We keep digital records tied to every synthesis step, from preparative chromatography to blending and final QC testing. If a problem arises in the supply chain — such as a contaminated raw input or a shipping hold — we can pinpoint root causes within hours, not weeks. Chemical manufacturing for reactive pyridines demands this level of control, especially as regulators tighten standards for residual solvents, heavy metals, and process safety.
6-HYDROXYNICOTINALDEHYDE carries a cost profile higher than base pyridines or simpler aldehydes. The extra steps in synthesis and purification drive up per-kilo pricing. As a manufacturer, we build relationships with both long-term contract buyers and agile research groups, providing flexible batch sizes and rapid production when research priorities shift. Lead times shift with raw material volatility, so we plan two quarters out, holding reserves of key pyridine intermediates to buffer against market shocks.
Buyers often share anxiety over global supply interruptions. Having experienced delays tied to logistics snarls or upstream shortages, we maintain dual sourcing for critical reagents. We use rolling forecasts and staggered production lots to head off sudden shortages or overstocking. Our logistics team works directly with carriers and storage partners, tracking every shipment, reacting quickly to customs clearances and weather disruptions. In one recent case, proactive rescheduling with a global carrier trimmed down delivery time by 30%, saving a downstream project at a pharmaceutical firm.
Every month brings requests for custom variants, new packaging, or purity upgrades on 6-HYDROXYNICOTINALDEHYDE. The most interesting advances trace back to collaborative development work with leading researchers. For one oncology project, a customer inquired about isotopically labeled batches. Manufacturing delivered a small pilot run with precise isotope incorporation, after fine-tuning reaction parameters and increasing QA oversight. The feedback loop from those early trials fed redesigns that now allow us to offer that variant in scaled-up lots for preclinical work.
Innovation is less about one-off inventions and more about constant refinement. Packaging once limited shelf life and added static issues for end-users. In response, we invested in antistatic, UV-protected packaging and integrated real-time tracking technology. Another advance involved automated data capture during process monitoring; deviations trigger alerts to prevent off-spec production — not just after the fact, but during the critical phases of heating and crystallization. These iterative improvements ensure that what we ship out mirrors what our customers use in their sensitive projects.
Working day in and day out with 6-HYDROXYNICOTINALDEHYDE sharpens your sense of safety culture. Exposure controls, active ventilation, and full personal protection are standard, not optional. Batch labs are set up for easy access to spill control and fast neutralization. Operator training covers not only the risk profile of this compound, but how to handle small leaks or dust — sometimes overlooked until an incident causes delays or insurance headaches. We periodically run drills and work with local emergency services to ensure quick response to unexpected incidents.
Transport presents its own challenge: stability against moisture and light is a frequent concern flagged by buyers who have seen lesser grades clump or degrade during transit. We work closely with logistics partners to shield product en route. Every lot’s condition when opening the drum tells us how well our process performs in practice, beyond the plant walls.
Our experience shapes every technical call with a customer or research group. Buyers not only want a material that fits technical data sheets but also support and honest communication about limitations or possible risks. Whether a synthetic route risks side reactions, or the window for storage narrows at higher humidity, we do not hide those details under fine print. Each plant veteran knows that strong client relationships are built through this realism, not just paperwork.
Account managers and technical specialists often speak directly to project leads, clarifying not just shipment details, but the subtle differences in reactivity that make or break a project. For customers scaling up from milligram experiments to pilot-plant scale, these conversations save precious time and budget during the critical proof-of-concept stage.
Product viability hardly ends at the production line. Monitoring warehouse conditions, choosing the right desiccants, and coordinating with regional transport are as critical to us as the initial synthesis. Over time we phased out less durable packaging and opted for lined containment that resists both puncture and permeation. Small details — whether a pallet loaded incorrectly or a container exposed too long to morning dew — show up as defects on the customer end. Collaborative logistics audits with clients help us track down solutions to repeating issues.
You don’t produce quality 6-HYDROXYNICOTINALDEHYDE by following written instructions alone. Training the next generation of operators, analysts, and plant engineers involves time spent together on the line. We teach staff to spot the subtle color shifts or odors that no sensor picks up. Peer-to-peer feedback, shared troubleshooting, and regular workshops keep the team sharp. In return, our staff members often bring process ideas that drive future improvements.
Chemical manufacturing faces a world of changing rules, rising demand, and unpredictable supply chains. The conversations we engage in now — with universities, pharma giants, and specialty manufacturers — point toward new uses for high-purity 6-HYDROXYNICOTINALDEHYDE that push us to keep evolving. Projects in advanced materials, green chemistry, and next-generation antibiotics all look for cleaner, more robust intermediates. By keeping our production flexible and innovation-focused, we prepare for these shifts with experience and openness to improvement.
Supplying 6-HYDROXYNICOTINALDEHYDE requires patience and commitment to every detail, from batch controls to direct conversations with users. Our focus remains on consistent quality, open collaboration, and incremental improvements based on real-world use. The challenges — purity headaches, logistics optimization, new regulatory demands — aren’t abstract; they shape daily operations in the plant. By maintaining this direct connection between the manufacturing floor and application sites worldwide, we deliver more than just a chemical. We provide a foundation trusted by researchers and manufacturers to advance the next wave of applied science. Experience born in plant operations, project feedback, and field results continues to guide our progress.
