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All Right Reserved
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HS Code |
466845 |
| Productname | Hyodeoxycholic Acid |
| Purity | 90% |
| Meltingpoint | 170°C |
| Molecularformula | C24H40O4 |
| Molecularweight | 392.57 g/mol |
| Casnumber | 83-49-8 |
| Appearance | White to off-white powder |
| Solubility | Slightly soluble in water, soluble in ethanol |
| Storagetemperature | 2-8°C |
| Odor | Odorless |
| Synonyms | Hyodeoxycholate; 3α,6α-Dihydroxy-5β-cholan-24-oic acid |
| Stability | Stable under recommended storage conditions |
As an accredited Hyodeoxycholic Acid - 90% (Melting Point 170℃) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Hyodeoxycholic Acid - 90%, 25g, comes in a sealed amber glass bottle with a tight screw cap, labeled with safety information. |
| Shipping | Hyodeoxycholic Acid – 90% (Melting Point 170℃) is shipped in tightly sealed containers to prevent moisture absorption and contamination. Store and transport at ambient temperature, away from light and incompatible substances. Handle with protective equipment per safety guidelines. Shipping complies with relevant chemical transport regulations to ensure safe delivery. |
| Storage | Store Hyodeoxycholic Acid - 90% (Melting Point 170℃) in a tightly sealed container, in a cool, dry, well-ventilated area away from incompatible substances such as strong oxidizers. Protect from moisture and direct sunlight. Keep the storage area at room temperature and avoid extreme heat. Ensure proper labeling and restrict access to trained personnel to maintain safety and chemical stability. |
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[Bile Acid Synthesis]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used in pharmaceutical research, where it serves as a key intermediate for synthesizing bile acid derivatives with high yield and purity. [Cholesterol Regulation]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used in metabolic studies, where its high purity supports the reliable assessment of cholesterol-lowering mechanisms. [API Formulation]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used in active pharmaceutical ingredient (API) formulation, where its defined melting point ensures consistent compound stability during processing. [Analytical Standard]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used as a reference material in chromatography, where precise purity enables accurate quantification in bile salt assays. [Biochemical Assay]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used in enzyme activity studies, where its controlled composition allows reproducible biochemical measurements. [Chemical Synthesis]: Hyodeoxycholic Acid - 90% (Melting Point 170℃) is used in laboratory-scale organic synthesis, where its high melting point supports thermal resistance during complex reaction conditions. |
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There’s nothing glamorous about a barrel of white powder, but step into any lab focusing on advanced pharmaceutical work, and a lot of folks light up when a tub of high-purity hyodeoxycholic acid shows up. I remember my own early days in the chemical trades, fresh out of school and sweating the details. High purity meant fewer headaches, fewer mystery peaks on the chromatogram, and less time wondering if the next step would bring a string of complications down the line. This upgraded version – refined to 90% purity and holding firm with a melting point of 170℃ – offers that sort of reliability. Quite a few chemists, myself included, have headaches eased by small details like this. It raises the bar compared to older, hazier grades and blends.
Hyodeoxycholic acid, recognized among bile acids for its structure and activity, is never just “another powder” on the shelf. The 90% grade isn’t just a number; reaching that level means trace impurities are chased out. This is crucial in work where even tiny contaminants change outcomes. Its melting point sits at a solid 170℃, giving a clear threshold. From a practical point of view, you catch fewer surprises during processing or application, whether refining for further chemistry or preparing batches for experimental use. In my time working with different lots, the difference in purity reflects directly in yield and confidence in results. What you open from the container behaves as expected – no fuss, no unexplained behavior at critical points.
Most people who reach for hyodeoxycholic acid put it to work in research settings or advanced manufacturing. This molecule stands out among bile acids. Its structure features a 6α-hydroxy group and delivers a balance of hydrophilic and hydrophobic properties. In the pharmaceutical world, that matters. The acid can act as a precursor in semi-synthetic pathways. Drug designers rely on it as a starting point to build more complex agents for treating liver or digestive disorders. In my experience watching bench chemists and industrial process engineers, one thing stands out – results depend on starting materials they trust. A 90% pure starting point tightens up margin for error and lets teams push forward with less second-guessing.
Bile acids span a wide spectrum. Cholic, deoxycholic, ursodeoxycholic – each plays a slightly different role in science and medicine. Not all batches arrive with the same attention to detail, and hyodeoxycholic acid often comes in at different grades. I’ve worked with technical grades before: lower cost, lower purity, lots of unwanted byproducts. They tend to be good enough for basic applications where little depends on outcome. Lab-grade or “research grade” purity, like the 90% variety with a locked-in melting point, enters the conversation for anyone who can’t afford unknown side reactions or contaminated results.
This isn’t just navel-gazing over purity numbers, either. A well-documented melting point means you spot issues earlier. When you run a batch and see a depression in melting point, you pick up on cross-contamination that much sooner. Past a certain level, these small differences multiply across production and show up in every yield calculation. People often forget that even a 5% bump in purity can turn a few months’ worth of data from questionable to publishable. I’ve seen projects shift from struggle to smooth over one small spec change.
Over the years, it’s become clear that specifying a product to 90% purity isn’t academic pedantry. In pharma settings, even subclinical research depends on reproducibility — every batch needs to support consistent outcomes. Messy starting materials do more than waste time; they hobble entire research cycles. Pharmacologists working on bile acid pathways or looking at solubility and metabolism bank a lot on good reliable material. Hyodeoxycholic acid with high purity slips into protocols without the need for elaborate workarounds. In my own stints handling standards and controls, getting the right melting point is the difference between jumping hurdles and running straight.
Consider studies on its cholagogue effect and the way it interacts with cholesterol absorption, or the influence on gut flora and metabolism. Controlling for purity lets researchers trust their downstream observations. That level of control nudges a project from maybe to yes, and trust in the data translates to fewer roadblocks in the path from benchtop findings to something publishable or patentable.
Comparisons between different bile acids usually land on solubility, reactivity, and ease of modification. Hyodeoxycholic acid shows up for its selective hydroxylation pattern, which lends itself especially well to derivatization. I’ve seen biochemists with a lineup of closely-related acids reach for this particular one when exploring targeted enzyme pathways or crafting specialized molecule libraries. A 90% pure compound takes some of the unpredictability out of enzymatic tests and opens doors for clinical screening.
Attempting similar transformations with lower grades, or using other bile acids with different hydroxylation, often means backtracking to troubleshoot product purity, rinse out byproducts, and isolate your target. Not every process needs this, but for those developing medicines or working on absorption and solubility studies, the edge is noticeable.
Cost is always a sticking point in research and industrial procurement. It’s easy to get lured by lower prices for “good enough” grades. In my own early career, our group nearly lost weeks to impure batches. We would chase down erratic spectra, only to find a batch didn’t meet its label claims. High-purity batches help prevent those runarounds. In regulated industries, getting caught short in a validation or inspection costs far more in delays than a tiny saving up front.
Any seasoned process chemist can recount stories involving lost time, abandoned runs, or failed syntheses due to lower grade starting material. When there’s a focus on trace levels of residual solvents, unknowns, or random isomers, running off a batch with a reliable 90% hyodeoxycholic acid feels like a reset switch. Time saved in troubleshooting adds up — and over long runs, reproducible results pay off in product consistency.
In drug discovery, hyodeoxycholic acid often becomes a parent molecule. Scientists redesign and re-engineer it for better bioavailability or targeted therapeutic effect. Clinics exploring liver protection or improved fat digestion run clinical trials demanding batch-to-batch consistency for both safety and effect. Nutritional scientists, too, dig into its interaction with cholesterol transport. All these areas depend on tight specs.
Industrial bioprocessing sometimes uses bile acids as surfactants or co-factors in fermentation. Here, the biggest gain from a 90% pure option comes in setting up predictable reactions. High purity cuts down losses from unreactive or problem material, helping to control costs through increased efficiency. Technicians spend less effort on cleanup and more time pushing innovation.
I know one group focusing on microbiome research — their protocols only worked right after switching to a higher grade supply. They hit reliable endpoints faster, saw clearer microbial shifts, and published results that held up under scrutiny. In cases like these, nobody misses the old stock.
Trying to run a side-by-side with lower grades usually highlights the differences right away. Lesser grades spill over with side products, unresolved peaks, and often change color or texture with minor temperature shifts. The 170℃ melting point isn’t just a number in a book — in every run I’ve made with tight control, it matches up, signaling that processing won’t blindside you partway through. Other bile acids can fall short, melting at lower points or refusing to play along during downstream purification.
Some vendors send blends that drift in purity from batch to batch, or include unusual crystalline forms that throw off chromatography prep. High-purity hyodeoxycholic acid lines up against published references. For work demanding structure-activity relationship studies, or research tracing minor metabolites, every reliable characteristic makes a difference. Pharmaceutical advances often hinge on details many overlook. It takes experience to realize where small upgrades offer major downstream benefits.
Distinct advantages play out over the long arc of projects, too. Consistent melting point means easy verification and less time sorting out inconsistencies. Certainty in purity takes a weight off teams focused on endpoint analytics and FDA submissions. I’ve met regulatory staff who zero in on melting points as a sign of solid manufacturing — if you get that right, chances are the upstream and downstream work holds up.
In academia, high-quality material builds trust between labs and ensures fair play in replication. More than one major paper rests on the back of trusted starting points. Sharing samples becomes straightforward when both sides match specifications with confidence. In cross-institutional collaborations, nothing slows things down like variant qualities and unclear documentation.
This clarity proves equally important outside pharma. Material science studies benefit when a single, known variant underpins early experimentation. Biotechnologists shifting to enzyme engineering want to know that the substrate under test isn’t coloring their results. In all these cases, starting with a 90% hyodeoxycholic acid means more accurate conclusions and higher chances of making real advances.
With high-value chemicals, transparency counts. Reliable suppliers back high-grade materials with certificates of analysis, and documentation extends well beyond a surface label. This ensures traceability, which underpins confidence not only in research, but in any move toward commercial development. Practitioners can line up batch numbers, receipts, and reports for future audits or inspections.
I’ve dealt with enough audits to recognize how traceability chains snap when a batch doesn’t have proper paperwork. Getting this piece right supports confidence, and companies willing to meet that bar attract trust from both big and small operators. Knowing what's in each container puts everyone at ease — from researchers to production workers and end users in clinical settings.
As laboratories and companies raise their benchmarks, demand for consistent high-purity reagents will only grow. Solutions often start with procurement — investing in quality materials up front. In practice, groups do best when they build vendor relationships based on honest reporting, frequent quality checks, and real-time feedback on use in the field.
Training younger staff to recognize signs of poor-quality material stands out as another improvement. In my career, I’ve watched experienced chemists drill new hires on batch-specific quirks: change in melting point, odd coloration, unexpected solubility. Fostering this culture means less downtime and more long-term reliability.
Establishing communal databases of outcomes and sharing knowledge about successful runs lowers the learning curve for the next generation. Sharing best practices becomes a habit, not just a chore. It leads to fewer repeated mistakes and better overall outcomes for the scientific community.
Supply chain challenges can crop up in this sector, especially when global disruptions push the sourcing of raw materials into question. My advice from the field has always been to build resilience with backup suppliers who can verify specs without playing games. Peer-to-peer evaluation or group procurement can balance budgets while keeping standards intact. Collaborative ordering sometimes pushes suppliers to clean up their offerings and focus on reliable documentation.
In the face of sudden shortages, confidence in the specification – and the ability to cross-check melting points and purity – makes switching batches less fraught. Consumer demand for traceable, well-verified chemicals means subpar batches will find fewer buyers as expectations rise.
Looking past the minutiae, the core reason for focusing on products like 90% hyodeoxycholic acid comes down to trust. In a world where even small inconsistencies derail projects, reliability gains real tangible value. The communities depending on this acid – biochemists, pharmacologists, process engineers – all need that steady foundation to build meaningful results.
It’s easy to gloss over purity as a bureaucratic hurdle. Those who spend long hours at the bench or decide the fate of expensive batches understand the stakes and welcome clarity. Years of working with varied materials have shown me that a material’s real value lies less in its basic availability and more in how many problems it solves through careful processing and reliable documentation.
Forging ahead, focusing on strong vendor relationships and professional networks pays dividends. Many lessons learned in the field reflect a hard-won understanding of how purity translates into real results: from skipped troubleshooting to faster research cycles. Staying current on best practices and teaching new lab members to catch warning signs makes a difference. Technology aids this too, with improved analytics for checking melting point and composition now routine in many labs.
As expectations lift, both suppliers and laboratories can drive steady improvement by investing in high-quality standards and meticulous checks. Those adopting a forward-thinking approach toward documentation, verification, and team training find themselves at the forefront, delivering stronger, cleaner science to the field.
In all, hyodeoxycholic acid at 90% with a stable melting point is more than a chemical entry in a database — it’s a way to get ahead without looking over your shoulder at every step, building stronger results on a bedrock of trust and experience.
