|
HS Code |
983288 |
| Chemical Name | TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE |
| Molecular Formula | C11H15NO2S |
| Molecular Weight | 225.31 g/mol |
| Cas Number | 1442826-65-0 |
| Purity | Typically ≥ 95% |
| Appearance | White to off-white solid |
| Solubility | Soluble in DMSO, slightly soluble in methanol |
| Storage Temperature | 2-8°C |
| Smiles | CC(C)(C)OC(=O)N1CCSC2=C1N=CC=C2 |
| Inchi | InChI=1S/C11H15NO2S/c1-11(2,3)14-10(13)12-5-6-15-9-8(12)4-7-16-9/h4,7H,5-6H2,1-3H3 |
As an accredited TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is supplied in a 1-gram amber glass vial, sealed with a screw cap, and labeled with product and safety information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 20′ Full Container Load can accommodate approximately 6-8 MT of TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE packed in drums. |
| Shipping | The chemical **TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE** is securely packaged in sealed, labeled containers and shipped following all applicable regulations for hazardous materials. Shipping includes protective packaging to prevent breakage, with temperature and light controls if necessary, ensuring product integrity upon delivery. |
| Storage | Store **tert-butyl 6,7-dihydro[1,3]thiazolo[5,4-c]pyridine-5(4H)-carboxylate** in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as strong acids, bases, and oxidizers. Protect from moisture and direct sunlight. Use appropriate personal protective equipment when handling and ensure proper chemical labeling. |
| Shelf Life | Shelf life: Store TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE at 2-8°C, dry conditions; stable for 2 years. |
|
Purity 98%: TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield target compound formation. Melting Point 126 °C: TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE with melting point 126 °C is used in solid-state formulation development, where it provides enhanced thermal handling stability. Stability Temperature Up to 80 °C: TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE with stability temperature up to 80 °C is used in chemical process optimization, where it prevents decomposition under operational conditions. Particle Size <20 µm: TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE with particle size <20 µm is used in advanced formulation blending, where it achieves superior homogeneity. Molecular Weight 242.31 g/mol: TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE with molecular weight 242.31 g/mol is used in analytical calibration standards, where it ensures accurate quantification in HPLC assays. |
Competitive TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@boxa-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@boxa-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Down here on the production floor, a chemical earns respect through steady performance and clear advantages. Our experience with TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE runs deep because turning out high-purity heterocycles is no small task, and this particular compound has impressed more than a few chemists with what it brings to the table. Years in this industry teach us which building blocks truly stand out, and this molecule has been consistently pulled for advanced pharmaceutical projects and some fine-tuned agrochemical research. Here, we take pride in producing chemicals that hit demanding marks—not only in specification sheets but in actual performance across dynamic lab and production environments.
Producing TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE requires a clear understanding of each stage, from raw material sourcing to purification steps. Our chemists work hands-on throughout the process, taking samples and monitoring the reaction at every critical point. This keeps impurities low, lets us tune batch-to-batch consistency, and ensures the final product truly serves as a dependable intermediate. Over the years, we've optimized this route for efficiency: we don’t just rely on the literature process or follow generic instructions. Problems like isomeric byproducts or traces of catalytic residues get handled early, long before the final material lands in a flask at a customer's facility.
This heterocyclic intermediate started turning heads as biopharma companies shifted toward more functionalized scaffolds for drug discovery. We noticed robust demand coming from small-molecule design teams needing reliable cores for rapid analog synthesis. The tert-butyl ester group is not just a placeholder; it resists unwanted hydrolysis under conditions used in most cross-coupling and functionalization steps. Later, deprotection proceeds smoothly when selectively triggered, sparing sensitive functional groups elsewhere on your molecule. Because of these practical advantages, researchers find themselves reaching for this intermediate—its chemistry has been vetted in late-stage discovery projects and optimization campaigns that demand no surprises from underlying reagents.
Industry literature gives broad outlines, but practical reality is often more complicated. For this compound, problems like color changes, oily residues, or inconsistent crystallization can emerge without careful control. We found that solvent grade and even cooling rates shift the course of crystallization, so our plant operators work with strict profiles to avoid batch variation. Frequent audits of our process let us adapt as needed, whether it's fine-tuning temperatures or adjusting the order of reagent addition. Over time, these tweaks add up—customers notice when every shipment delivers material with consistent melt points, crystal habit, and chemical purity.
With so many downstream syntheses relying on this intermediate, every percent of purity matters. PhD chemists in our analytical division check each batch using NMR, HPLC, and mass spec. We do not treat testing as an afterthought; quality checks go far deeper than a simple certificate stuck on a drum. We track trace residual solvents and potential side-products, watching for anything that could interfere with the next synthetic step. Over many cycles of feedback, we learned how much even minor unknowns can slow research or throw off scalable routes. Our commitment to crystal-clear traceability lets our partners in pharmaceutical, materials, and specialty sectors move forward with confidence.
Modern chemistry leans hard on intermediates that offer both versatility and stability. TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE fits this need, lending itself to divergent synthesis routes and efficient scale-up later on. Our product typically gets supplied to labs building libraries of bioactive molecules, hitting those sweet spots where sulfur and nitrogen heterocycles are needed for new leads. Peptidomimetic researchers, in particular, use this structure to develop building blocks that improve drug-like properties without sacrificing ease of derivatization. Our manufacturing approach doesn’t just emphasize the finished product; we also ensure that the process suits both boutique R&D labs and kilo-scale needs in pilot plants.
No one understands a compound’s quirks better than the team that makes, stores, and ships it. At our site, each drum of tert-butyl thiazolopyridine carboxylate stays in tightly controlled, humidity-limited stores. Our staff learned early on that moisture uptake or poor packaging can spell trouble for long-haul shipments or prolonged bench storage. Because we've solved these practical concerns, users can expect every delivery to handle predictably, pour out easily, and give robust results straight out of the container.
The addition of the tert-butyl ester group makes this compound less reactive to ambient moisture and stray acids—qualities that set it apart from more fragile esters or free acids on the market. Having put both variants through their paces, we see consistently fewer hydrolysis problems and less need for laborious drying or purification before use. Moreover, the thiazolo[5,4-c]pyridine scaffold show greater stability under both refrigerated and ambient shipping, allowing more flexibility for logistics teams and distributors. Our history with other, less stable analogs—especially those with methyl or ethyl esters—was marked by frequent customer complaints about shelf life or processing loss. Those issues rarely arise with the tert-butyl derivative.
Our in-house specification reflects years of data, not just textbook targets. Where end-users flagged issues with earlier lots, we changed what we monitored—tightening limits on water, handling optical clarity, or checking for specific UV impurities when recipes called for that sensitivity. Purity by HPLC routinely meets or exceeds 98 percent; residual solvents stay within pharma-friendly margins. Customers tackling combinatorial synthesis, scale-up planning, or regulatory submission projects want more than a one-line purity claim on paper; they want detail. Our plant logs track more than just numbers—a batch delivered on a rainy day, a shift in ambient warehouse temperature, or even a new supplier for a minor reagent, all go into our records. This institutional memory shows up in the product itself, batch after batch.
Feedback from researchers and process engineers pushes us to refine the process year after year. For example, a pharmaceutical client recently optimized their process around a particular counterion that tended to interact with residual bases in some lots we've seen elsewhere. Our response was not to place blame but to review line by line, solvent by solvent, and adjust the quench steps to prevent residual alkalinity. Openness to collaboration defines our way of working—our production teams meet regularly with technical account managers who collect real-life feedback and translate that into process changes here on the plant floor.
More traditional uses center around drug development, especially for central nervous system and anti-infective leads. Recently, agrochemical innovators have joined the list of regular customers, targeting derivatives that offer pest resistance or improved plant health without the environmental baggage of legacy compounds. This shift didn’t take us by surprise; we keep a close eye on trends in academic and industrial literature, as well as real purchase data and repeat inquiries. Academic labs focused on heterocyclic chemistry routinely specify this intermediate in grant proposals, and our consistent supply lets them devote time to innovation instead of chasing multiple suppliers for “almost right” material.
Supplying both kilogram and multi-metric ton scales calls for planning at every junction. Our investment in pilot-scale reactors and flexible packaging solutions means researchers in both small labs and industrial settings receive material suited to their immediate use. In recent years, we added automation and new containment practices to tackle dust formation during milling—a seemingly small change, but one that saves countless hours downstream when users shift from bench work to pilot or production scales. Awareness of how fine powder flows, how easily drums open and close, and how quickly the compound dissolves in common solvents—those details set apart a process built for real-world chemistry from one that simply targets numbers on spreadsheets.
With regulatory demands growing more intense each year, we work hand-in-hand with both end users and quality consultants to supply the data they require. Each batch ships with a comprehensive analytical dossier: detailed chromatograms, impurity profiles, and methods vetted against the toughest pharma standards. We avoid boilerplate: analytical procedures match the real risks that users face, from sensitive impurity monitoring for new drug applications, to potency checks required by global regulatory filings. This collaborative, transparent approach has earned us trust with customers on tight schedules and high-stakes projects.
TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE stands apart not only due to core properties, but in how it integrates into larger workflows. Our packaging can be tailored for glovebox transfer or inert-atmosphere handling, based directly on feedback from teams working at microgram to kilogram scale. Distribution partners comment on our predictable lead times, supported by strategic raw material management and prompt reaction to shipping disruptions. It might sound mundane, but customers tell us reliable deliveries and easy-to-open packaging save time, reduce waste, and limit laboratory headaches. These operational improvements stack up, both for academic researchers and industrial teams.
The shifting landscape of molecular discovery continues to challenge all of us to do better. Researchers choosing this tert-butyl thiazolopyridine carboxylate leverage the molecule’s ease of transformation, from direct amidation to selective reduction or cross-coupling. Applications span lead optimization for small-molecule therapeutics to new agrochemical scaffolds that demand both reactivity and site-specific stability. We stay in regular touch with scientists on the front lines—hearing about successes, setbacks, and the sometimes-surprising demands of real-world discovery campaigns. This feedback goes straight back to our plant operators and chemists, shaping the future direction of both process improvements and new product offerings.
Global supply chains, shifting regulations, and new analytical technologies all press chemical manufacturers to adapt. Novel purification media, upgraded containment, and batch tracking software are just part of the continuous improvements behind our facility doors. We source critical reagents from long-term partners and regularly review contingency plans to ward off supply disruptions. If a solvent or catalyst faces regulatory restriction, we move early, running pilot batches with replacements and updating our protocols to maintain both compliance and continuity. These changes aren’t just about ticking compliance boxes—they reflect the real risks and demands our customers grapple with daily.
We’re not just talking about green chemistry or safe production as a checklist. Each time a process engineer finds a route to reduce solvent waste, minimize energy use, or scale back hazardous effluent, we take note and build that improvement into future runs. On-site environmental controls, routine waste audits, and closed-loop solvent recycling let us reduce both cost and impact, keeping our promise to scientists and communities who expect responsible chemical manufacturing. Workers here log more hours on handling and disposal training because we recognize that a safer process means fewer delays, more predictable yields, and greater trust from regulatory bodies and customers alike.
Over time, accountability and open communication create strong working partnerships. Our clients demand forthright answers to tough questions—batch traceability down to individual operator notes, explanations for minor impurity shifts, or real-time tracking of orders as global logistics keep evolving. In our shop, technical support does not end with delivery: process chemists and logicians remain available for troubleshooting, impurity identification, and route adaptation advice. These relationships mean everyone wins—fewer project delays, clearer expectations, and a mutual investment in successful outcomes.
Here, innovation never rests. We constantly probe for better purification techniques, faster synthesis cycles, and new applications for thorny discovery projects. As the complexity and demand for advanced intermediates continue to rise, our shop stays nimble—ready to tweak a process at the behest of a customer struggling with a particularly challenging reaction or regulatory requirement. The history of our work with TERT-BUTYL 6,7-DIHYDRO[1,3]THIAZOLO[5,4-C]PYRIDINE-5(4H)-CARBOXYLATE reflects the broader changes sweeping fine chemical manufacturing: precision, transparency, flexibility, and a relentless focus on supporting the next big discovery.
