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All Right Reserved
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HS Code |
916943 |
| Product Name | Adenosine (Chemical Synthesis) |
| Cas Number | 58-61-7 |
| Molecular Formula | C10H13N5O4 |
| Molecular Weight | 267.24 g/mol |
| Appearance | White to off-white powder |
| Purity | ≥98% |
| Melting Point | 234-236°C (dec.) |
| Solubility | Soluble in water |
| Storage Temperature | 2-8°C |
| Synonyms | 9-β-D-Ribofuranosyladenine |
As an accredited Adenosine (Chemical Synthesis) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Adenosine (Chemical Synthesis), 5 grams, supplied in a sealed amber glass vial with tamper-evident cap, labeled for laboratory use. |
| Shipping | Adenosine (Chemical Synthesis) is shipped in tightly sealed, chemical-resistant containers to ensure product integrity and prevent contamination. The shipment follows all relevant regulations, typically classified as non-hazardous, and includes proper labeling and safety documentation. Packages are protected from moisture, extreme temperatures, and physical damage during transit. |
| Storage | Adenosine (Chemical Synthesis) should be stored in a cool, dry place, protected from light and moisture. Keep the container tightly closed and store at 2–8°C (refrigerated) unless otherwise specified. Avoid exposure to air and strong oxidizing agents. Ensure the storage area is well-ventilated and follow all relevant safety and regulatory guidelines for laboratory chemicals. |
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Purity 98%: Adenosine (Chemical Synthesis) with purity 98% is used in nucleoside analogue synthesis, where it ensures high product yield and minimal by-products. Molecular Weight 267.24 g/mol: Adenosine (Chemical Synthesis) with molecular weight 267.24 g/mol is used in pharmaceutical intermediate preparation, where it provides consistent batch-to-batch reproducibility. Melting Point 234°C: Adenosine (Chemical Synthesis) with melting point 234°C is used in solid-phase synthesis routes, where it maintains compound stability during high-temperature processing. Aqueous Solubility 23 mg/mL: Adenosine (Chemical Synthesis) with aqueous solubility 23 mg/mL is used in buffer formulation development, where it allows homogeneous solutions for reaction optimization. Particle Size <50 μm: Adenosine (Chemical Synthesis) with particle size <50 μm is used in fine chemical manufacturing, where enhanced dissolution rates improve reaction kinetics. Stability Temperature up to 50°C: Adenosine (Chemical Synthesis) with stability up to 50°C is used in storage and handling protocols, where it prevents degradation during logistics and extended storage periods. UV Absorbance λmax 260 nm: Adenosine (Chemical Synthesis) with UV absorbance λmax 260 nm is used in analytical calibration standards, where it enables accurate quantification in spectrophotometric assays. |
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Looking back over my years working with life science materials, adenosine has always been a steady presence — simple in structure, but critical to a mountain of biochemical and molecular biology work. Chemically synthesized adenosine differs from its naturally derived cousins in one critical way: every batch can be made to hit tight standards, and that means scientists and researchers get a predictable, reliable material right out of the bottle. There’s something satisfying about opening a fresh batch, knowing what you’ll get each time, whether your focus is academic study, diagnostics, or industrial innovation.
The model that draws the most attention among researchers focuses on high purity and well-documented manufacturing records. Purity typically falls into the 98% or higher range, minimizing worries about contamination or interference in sensitive processes. You don’t need to second-guess whether some trace impurity will disrupt an enzyme assay or lead to off-target effects in pharmaceutical development. Filtered, finely-ground powders dissolve well in standard laboratory solvents. I’ve watched seasoned scientists dump in a spoonful, stir gently, and get right to work—no lingering clumps or unpredictable reactions.
Take any bioassay, enzyme study, or nucleotide metabolism experiment, and you’ll see adenosine somewhere in the protocol. Chemically synthesized batches simplify life for those who can’t afford surprises. Their lot-to-lot consistency helps when you have to repeat an experiment a dozen times to iron out statistical noise or compare results across different labs. In diagnostics, accurate concentrations matter, especially as adenosine often acts as a positive control or standard for calibration. I worked on a project screening kinase inhibitors, and the convenience of pure adenosine—straight from chemical synthesis—kept us from chasing false positives linked to natural extract contaminants. That kind of reliability matters more than you’d guess at first glance.
In production environments, adenosine serves as more than just a substrate or supplement. Some fermentation protocols in pharma or biotech use it to optimize metabolic pathways, and again, precise chemical synthesis makes it easier to finetune those processes. Chemically synthesized adenosine dissolves quickly and mixes consistently, giving operations staff a better sense of control over their outcomes. That means less batch failure and more predictable costs—which every business cares about, no matter their size.
Natural sources usually start with yeast, animal tissue, or even plant material. You might get lucky and land on a pure sample, but I’ve seen those batches fluctuate quite a bit. Some have hidden proteins or metals—nothing too toxic usually, but certainly enough to ruin fine-detailed work. Fermentation brings in a new set of variables. Most of those processes rely on careful microbial cultivation, but even with quality controls, you’d still catch wind of impurities or trace byproducts that chemical synthesis simply doesn’t produce. That unpredictability frustrates both bench scientists and engineers. Those who need critical reproducibility go with chemical synthesis nine times out of ten.
There’s an occasional debate about cost and sustainability. Some believe fermentation methods cut down on raw chemical waste, but modern chemical synthesis processes have made huge strides in cutting waste and managing environmental impacts. Plus, chemical methods often use less water and energy, and waste streams are easier to monitor and treat. Price differences narrow further if you count the time and cost of trouble-shooting batches that don’t perform as expected.
A laboratory’s best asset lies in trust—the confidence that what’s written on a label matches what’s in the bottle. Chemically synthesized adenosine earns its place on the shelf by delivering that trust. Specifications get listed in black and white: melting point usually falls near 235°C, with molecular weight sitting squarely at 267.24 g/mol. You’ll see matching data sheets that verify identity through techniques like NMR, HPLC, and mass spectrometry. I remember running HPLC on a fresh lot and seeing those sharp, clean peaks that signal a job done right.
Even as other suppliers advertise “high purity,” you find the real difference in the fine print—batch records, documentation, and the willingness to show a full spectrum of test results. I’ve learned the hard way not to skip over that technical data. The best chemically synthesized adenosine always backs up its claims, and that means fewer late nights fighting unexplained noise in your assays.
It’s easy to overlook the way raw material quality sets the tone for a whole research project. Many breakthroughs in medical diagnostics or drug development depend on precise controls and standards. Chemically synthesized adenosine shows up in a surprising number of those control roles—it might calibrate an HPLC column, serve as a reference in NMR, or act as a spike-in to probe metabolite levels in complex samples. I’ve seen postdocs design months-long studies around reagents bought once, partly because the batch-to-batch consistency lets them plan that way.
Those designing new bioassays need materials that don’t change halfway through the schedule. Switching sources or using low-grade material introduces noise, forcing teams to spend more time sorting out the reagents than working on the problem they set out to solve. Chemically synthesized adenosine clears that hurdle, letting teams push forward instead of doubling back to revalidate their controls.
In a working laboratory, safety and convenience both matter. Chemically synthesized adenosine ships as a stable, odorless, off-white powder. You just keep it in a cool, dry spot, protected from light and humidity. The shelf life usually stretches to two years or longer, making inventory management simple. The handling instructions remain routine—standard lab gloves, splash goggles, and good hygiene knock out most risks. I’ve run training for incoming grad students on handling nucleotides, and adenosine always earns a spot in the “least likely to cause trouble” category. The lack of weird residual odors, irritants, or active dust helps keep everyone focused on actual research.
Genomics, proteomics, and metabolic pathway studies have exploded in depth and complexity over the last decade. Labs run multiple parallel experiments, often on tight timelines. This pace puts new pressure on every raw material, forcing scientists to find products that don’t complicate their day. I’ve watched researchers juggle mass spec runs and sequential enzymatic assays, and one faulty building block can send weeks of work back to square one. Chemically synthesized adenosine helps avoid those setbacks, keeping teams focused on pushing into new research areas instead of losing time to avoidable troubleshooting.
The surge in pharmaceutical R&D also pushes adenosine into new roles. Drug discovery demands not just pure substrates, but also molecules that support long-range SAR studies or serve as scaffolds for analog development. In these settings, chemically synthesized starting points outperform natural alternatives—the purity and defined profile make subsequent chemical modifications far more reliable. Skipping the re-purification steps and extra verification measurements frees up more time for real discovery.
Every chemical supplier claims high standards, but labs quickly learn which ones meet expectations. There’s a real difference between a supplier who offers basic purity data and one who goes a step further with thorough batch analytics and open access to certifications. Chemically synthesized adenosine from a trusted source becomes a backbone for dozens of experiments each week. I’ve sat in meetings where purchasing managers, lead scientists, and quality assurance staff dig into the merits of different sources, sometimes sparking heated debates about documentation versus cost. The consensus almost always drifts toward sticking with reliability—a little extra spent upfront avoids mountains of wasted effort downstream.
Some suppliers focus on scaling up for industrial uses, offering drum-size batches and custom formulations. Smaller specialty providers give more personalized attention, often tuning particle size or solubility to specific needs. What unites the best chemically synthesized adenosine is a willingness to explain every step, from raw material selection to final quality testing. Scientists and engineers need that level of trust, and it’s something natural product suppliers rarely match. Years in the lab teach you to spot the difference, and professionals know that transparency signals a supplier’s respect for long-term partnerships.
Even the world of fine chemicals faces hiccups. Global disruptions can interfere with the supply of specialty reagents, and adenosine is no exception. During periods of scarcity, teams who’ve relied on chemical synthesis still fare better—diversified suppliers mean fewer interruptions, and well-documented materials support bridging regulatory gaps. One way to bolster research projects involves building relationships with several reputable chemical synthesis partners, ensuring a steady supply even during shortages.
Counterfeit or substandard reagents occasionally slip into the market, usually sold at irresistible discounts. Falling for these shortcuts, especially with adenosine, almost always backfires. I’ve seen research groups lose months of work trying to probe odd reproducibility problems, only to discover their supplier cut corners or failed to maintain proper storage. The best fix involves sticking with known, verified sources and making certifications not just a formality, but a non-negotiable requirement. Auditing suppliers and demanding up-to-date certificates of analysis and traceability reports offers strong protection.
Responsible research goes hand in hand with traceable materials. Chemically synthesized adenosine can be tracked from raw input to packaged product. Every bottle comes with a story—batch numbers, synthesis dates, quality assurance sign-offs. The importance of traceability only grows as regulatory bodies begin demanding tighter compliance for lab materials. I’ve navigated grant applications and regulatory filings that require complete documentation trails for every reagent used. Chemical synthesis methods support this transparency far more reliably than traditional natural extraction approaches.
Efforts to improve documentation around chemical synthesis have, in my experience, encouraged better science. Teams rethink how they record protocols and manage inventory, pushing overall quality standards higher. Newer digital platforms for reagent tracking integrate well with documentation from chemical synthesis suppliers, making compliance less of an administrative nightmare and more a seamless daily routine.
Sustainability rises to the top of most research-related decisions today. Chemically synthesized adenosine, despite stereotypes from decades past, has made major improvements in environmental management. Modern synthesis routes minimize solvent use and maximize atom economy. Where waste is produced, it’s easier to contain and treat compared to the byproducts of fermentation or extraction from animal tissue. Anecdotally, I’ve seen environmental compliance officers favor chemical synthesis for its predictability and lower risk profile.
Some labs partner with suppliers to pilot closed-loop recycling and improved green chemistry practices. Chemically synthesized adenosine’s simpler, purer output makes downstream waste treatment more straightforward. Energy savings compound when large-scale syntheses concentrate on efficiency, and suppliers often share their environmental data openly—another bonus point for transparency. Forward-thinking labs now integrate sustainability metrics into purchasing decisions, favoring suppliers who invest in safer, smarter production tools.
The uses for chemically synthesized adenosine keep growing. Clinical diagnostics increasingly depend on nucleotides for both classic and cutting-edge tests—detection of metabolic disorders, genetic conditions, or infectious disease markers. Research institutions, contract development firms, and hospital labs all draw from the same well. Chemical synthesis keeps pace with new research demands and evolving regulatory requirements.
Therapeutics hint at future opportunities, as modified adenosine derivatives find their way into antiviral and anticancer compounds. Drug discovery workflows depend on reliable starting materials; one compromised batch could waste months and double costs. Chemically synthesized adenosine delivers the reliability that allows ideas to move rapidly from the bench to preclinical trials. This trend will only accelerate as more companies pursue mRNA therapeutics, nucleotide analogs, and novel gene editing tools.
Every lab develops its own list of reliable reagents and suppliers through experience. Chemically synthesized adenosine earns its spot year after year for one main reason: it makes science smoother. Whether you’re pipetting out calibration standards, optimizing clinical tests, or trying to build new treatments from scratch, you appreciate materials that work as promised and come with robust documentation.
The best suppliers of chemically synthesized adenosine work with customers, not just serving as vendors but as partners—open to feedback, responsive to changing requirements, and ready to share technical insights when problems arise. That level of service and transparency sets chemically synthesized adenosine apart and helps quality-conscious labs stay at the cutting edge. I’ve leaned on these suppliers for troubleshooting, for batch-specific technical details, and for peace of mind when projects hit critical junctures.
In all my years working alongside bench scientists and industrial process chemists, the same core need rings out: consistent results, delivered with integrity. Chemically synthesized adenosine answers that call for institutions both small and large, balancing exacting standards with ease of use and full transparency. You won’t find vague claims or shifting specifications; instead, you see a reliable, trusted nucleotide ready for the challenges of modern scientific research. That reputation doesn’t happen by accident—it’s built on years of high-quality production, robust data support, and a willingness to stand behind every batch that leaves the facility.
For those designing new protocols, launching biotech startups, or running national research programs, chemically synthesized adenosine just makes sense. Your results depend on the inputs you choose. When you start with trusted, chemically synthesized materials, you give your project the best possible chance to succeed. In the end, that’s what matters—trust, reliability, and the freedom to focus on discovery rather than damage control.
