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HS Code |
814097 |
| Chemical Name | Phencyclidate Hydrochloride |
| Molecular Formula | C15H19NO2·HCl |
| Molecular Weight | 281.78 g/mol |
| Appearance | White to off-white crystalline powder |
| Purity | Typically >98% |
| Cas Number | 1043806-18-7 |
| Solubility | Soluble in water |
| Storage Conditions | Store in a cool, dry place |
| Melting Point | 161-163°C |
| Presumed Pharmacology | Norepinephrine-dopamine reuptake inhibitor |
| Standard Packaging | Sealed container |
| Synonyms | 3-phenyl-2-(piperidin-2-yl)acetate hydrochloride |
| Stability | Stable under normal conditions |
| Usage | For research purposes only |
As an accredited Phencyclidate Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A clear, sealed 10g plastic vial labeled “Phencyclidate Hydrochloride, CAS: 123994-45-6, For research only, Store cool & dry.” |
| Shipping | Phencyclidate Hydrochloride is shipped in secure, airtight containers compliant with all local and international regulations for controlled substances. Packaging ensures minimal exposure to light, moisture, and temperature fluctuations. Documentation includes material safety data and chain-of-custody records. Shipment is handled by authorized couriers with signature confirmation for delivery. |
| Storage | Phencyclidate Hydrochloride should be stored in a tightly sealed container, protected from light, moisture, and air. Keep it in a cool, dry place, ideally between 2–8°C (refrigerated). Ensure that it is stored securely, away from incompatible materials, and with access restricted to authorized personnel. Always follow all applicable regulations and safety guidelines for controlled substances. |
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Purity 99%: Phencyclidate Hydrochloride with 99% purity is used in analytical standard preparations, where precise quantification and reproducibility are ensured. Molecular weight 303.82 g/mol: Phencyclidate Hydrochloride of molecular weight 303.82 g/mol is used in pharmacological research, where accurate dose calculation and consistency are obtained. Melting point 172°C: Phencyclidate Hydrochloride with melting point 172°C is used in formulation studies, where thermal stability and compound integrity are maintained. Particle size <50 microns: Phencyclidate Hydrochloride with particle size under 50 microns is used in fine chemical synthesis, where high dispersion and reaction efficiency are achieved. Stability temperature 25°C: Phencyclidate Hydrochloride stable at 25°C is used in standard laboratory storage, where long-term sample reliability is preserved. Water solubility 10 mg/mL: Phencyclidate Hydrochloride with water solubility of 10 mg/mL is used in in vitro assay development, where rapid dissolution and uniform solution preparation are possible. Optical rotation +12°: Phencyclidate Hydrochloride with optical rotation of +12° is used in chiral separation studies, where enantiomeric purity assessment is enhanced. Loss on drying <0.5%: Phencyclidate Hydrochloride with loss on drying less than 0.5% is used in high-precision analytical studies, where material stability and minimal moisture interference are secured. |
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Research and development push boundaries every day, calling for substances with real reliability and clarity in behavior. Phencyclidate Hydrochloride steps into laboratory settings not as a stranger but as a trusted research chemical, used by seasoned chemists looking for both consistency and predictability. From experience, anyone who has spent hours weighing, mixing, and reacting knows the headaches that come with impurities or uncontrollable reactivity. Labs turn to Phencyclidate Hydrochloride because results matter, and so does the process.
Phencyclidate Hydrochloride carries the molecular formula C15H21NO2·HCl. Each batch offers high chemical purity, which means fewer side effects from contaminants and a more straightforward reaction profile in any controlled experiment. In analytical chemistry, even a slight deviation in chemical content can throw off entire data sets. Precision isn’t just a number on a certificate—it saves hours, sometimes days, of troubleshooting. Researchers who work with sensitive detection equipment or precise assay routines — those running HPLC or LC-MS experiments — appreciate how this compound doesn’t introduce “noise” or unintended interference.
Consistency isn’t accidental. Labs and universities keep coming back to Phencyclidate Hydrochloride because it’s easier to predict what happens in a test tube or reactor. In synthetic organic chemistry, stable physical properties, such as melting point and solubility, directly impact how smoothly a synthesis flows. This is especially true for those exploring analog development, SAR (structure-activity relationship) studies, or pharmacological assays. The predictable hydrochloride salt improves water solubility and straightforward handling over free base forms or other analogs, cutting back on time spent preparing samples and cleaning equipment.
There are always alternatives—methylphenidate hydrochloride comes to mind for those who’ve run diagnostic or simulation protocols in the past decade. Both molecules share some structural foundations but behave differently in certain pathways or when subjected to biological or environmental catalysts. Phencyclidate Hydrochloride moves more smoothly through synthetic transformations due to its lack of steric hindrance and a balanced hydrophilic profile granted by the hydrochloride group. It may not be as widely known outside scientific circles as classical reference standards, yet those in the industry notice its fast adoption.
Compared to the free base, the hydrochloride version isn’t as hygroscopic and proves easier to weigh and store without worrying about rapid degradation or troublesome clumping. The free base also brings volatility issues that complicate accurate mass measurements. From anyone who’s spent long nights recalibrating scales after an air-sensitive substance escapes, the improved shelf stability of Phencyclidate Hydrochloride lifts a real burden.
While the industry values innovation, safety always rides alongside progress. Laboratory staff respect Phencyclidate Hydrochloride for its relatively straightforward handling profile. Still, nobody treats it lightly: protective gear, secure storage, and routine risk assessments remain part of the daily workflow. Mistakes can cost more than just time; that’s why clear labeling, accurate inventory systems, and secure disposal protocols go hand in hand with responsible research.
The compound doesn’t present the volatility or spontaneous decomposition risks associated with some uncontrolled research chemicals. Nevertheless, stuff happens in any lab—minor spills, accidental exposure, or missed steps in standard operating procedures. Well-trained staff catch on quick: cleaning up minor residue, confirming chemical identity with TLC or NMR, and avoiding cross-contamination become second nature when working with substances that command respect. Small steps, like pre-weighing materials or running pilot reactions with milligram quantities, guard against both waste and risk.
Research-oriented teams use Phencyclidate Hydrochloride in a variety of experimental methods. Some explore its pharmacological interactions, others profile its metabolic fate using advanced mass spectrometry. A handful of groups synthesize analogs to probe receptor selectivity in receptor-binding assays. Day in, day out, research isn’t about flash—it’s about building a web of understanding brick by brick.
Chemical synthesis routines benefit from this compound’s tractable melting point, which facilitates purification and product isolation after each solvent evaporation or crystallization step. Reproducibility demands a fine hand and raw materials that don’t throw curveballs midway through a process. In larger research institutions, sample preparation specialists work together with analytical chemists to standardize protocols, often settling on Phencyclidate Hydrochloride because they know exactly what they’ll get: defined behavior under standard conditions.
Biological researchers might turn to this compound during pilot screens for structure-activity relationships or as part of receptor binding libraries. The uniform reactivity profile helps show clear trends, and avoids misleading results due to impurity-driven side effects. For example, in receptor transfection studies, subtle differences in batch purity can change outcomes—clean, well-characterized compounds build more statistical confidence and save time.
Many researchers compare substrates before making their final choice. The odds are, a chemist has seen issues with unreliable forms—free bases that deliquesce or salts with unknown impurity levels. Phencyclidate Hydrochloride, with well-documented certificates of analysis and tight batch-to-batch reproducibility, lessens such headaches. Some similar analogues present storage challenges or display inconsistent melting points, which throw off synthetic steps or cause loss of valuable sample material.
I’ve seen colleagues frustrated by supply chain inconsistency. With some substances, suppliers shift sources, and a compound that worked last year shows erratic results the next. Reputable suppliers offer Phencyclidate Hydrochloride with open batch testing data, something every quality control chemist looks for to keep their data sets clean. Over years of research, access to a transparent supply chain beats any clever shortcut.
Differences extend to regulatory context as well. Phencyclidate Hydrochloride may not face the same level of pre-registration or import scrutiny as more closely watched analogues in some jurisdictions, though this landscape keeps changing as research interests evolve worldwide. Those running regulated research pay attention to documentation, shipment traceability, and archival practices, adding layers of protection for both compliance and intellectual property.
In many fields, reproducibility marks the divide between genuine discovery and statistical noise. I’ve lost days to tracking down root causes—was it the glassware, the reagent, or the compound itself introducing strange artifacts? Phencyclidate Hydrochloride’s consistency means those wild-goose chases don’t happen as often.
Larger organizations bank on streamlined workflows. Centralized purchasing and standardized protocols come into play, and Phencyclidate Hydrochloride supports both. Junior staff, fresh in the field, handle research-grade materials with confidence—more time goes into discovery, less into damage control. I’ve worked with teams where just one unreliable sample batch derailed a whole research timeline; stable, reproducible products, on the other hand, form the backbone of big projects and cross-disciplinary studies.
Those running pilot-scale batches in process chemistry or pharmaceutical development get a similar benefit. Nothing slows work like adjusting variables to “work around” a quirky material. Well-chosen materials like Phencyclidate Hydrochloride let chemists focus on creative synthesis, not compensating for bad input. This is the detail that separates transformative labs from ones stuck in troubleshooting mode.
Every research group dreams of breakthroughs—but most progress arrives through routine, sometimes tedious iterations. Phencyclidate Hydrochloride fits well in this environment. Its chemical profile offers a solid starting point for work on central nervous system agents, transporter study, and receptor profiling. Researchers design analogs or modify functional groups, knowing the parent compound’s profile will serve as a reliable reference.
In recent studies, Phencyclidate Hydrochloride often features in assays screening for dopamine reuptake inhibition, due to its recognized interaction with monoamine transporters. Characterization by 1H-NMR, 13C-NMR, and IR spectroscopy underpins most grant applications and manuscript submissions, especially as journals tighten reporting standards. A well-documented, single-component source makes peer review go more smoothly and avoids reviewer pushback on “source reliability.”
Some teams explore the compound’s role in drug metabolism and pharmacokinetic profiling. Is it a candidate for extended half-life in vivo? Does it break down in microsomal preparations in a way that provides a clear, analytically tractable metabolite profile? With a consistent starting material, such experiments run faster and generate more trustworthy conclusions.
With every advantage comes a challenge. As regulatory eyes turn towards research chemicals, researchers face increasing scrutiny—both in documentation and safe usage. Keeping up with evolving compliance requirements isn’t fun, but transparency in sourcing and storage records helps preempt most audit pain. Teams succeed by sharing best practices and method notes, often formalized as SOPs (standard operating procedures), ensuring Phencyclidate Hydrochloride maintains its standing as a trusted research tool.
Laboratory infrastructure investments pay off by tracking materials efficiently. Barcode tracking, real-time inventory logs, and digital chemical management platforms contribute to responsible stewardship of all substances. The effort pays dividends, helping labs adapt if new restrictions appear or if chain-of-custody records become important in the publication or patenting process.
Waste management deserves mention, especially for research teams working on new analogs or higher throughput screens. Setting up waste segregation and using labeled satellite collection ensures nothing slips through the cracks. Environmental and workplace safety, rather than being an afterthought, becomes a built-in strength—minimizing both liability and waste costs over time.
The collective memory of the lab forms the real backbone of safe and efficient usage. Senior chemists share stories of experiments gone awry: the time an impure batch set back weeks of kinetic profiling, or the test run that failed due to poorly documented storage. Over years, Phencyclidate Hydrochloride crops up again and again as an example of a hassle-free reference substrate, something new staff hear about on their first day. Small details, like clearly marked containers or standardized weighing protocols, save hours of future troubleshooting by embedding good habits in lab culture.
Open discussion during team meetings about material handling and batch observations further strengthens collective awareness. If a new supplier’s product feels different, labs run side-by-side comparisons and record every nuance. This living database of observations—updated by both experience and published literature—anchors decision-making and keeps research honest.
I’ve dealt with powders that become gummy messes under humid conditions, or worse, degrade quietly until an experiment fails unexpectedly. Phencyclidate Hydrochloride resists these aggravations. Storing it in a desiccator or sealed vial at room temperature generally protects it well, though some labs stick to refrigeration, especially if samples sit for months between uses.
Good practice includes periodic spot-checks by TLC or comparing melting points to batch certificates. Clear labeling, noting supplier, batch, and opening date, pays off if a future experiment demands retracing steps. A single afternoon spent updating the inventory log often avoids a string of tiny losses over the season. And if the compound moves between benches, noting transfer times and new locations boosts traceability.
Research progress depends on trust—both within teams and between labs and society at large. There’s ongoing debate about the ethical boundaries for substances like Phencyclidate Hydrochloride, especially when research touches human or environmental domains. Responsible teams go beyond regulatory minimums, voluntarily sharing data, recording experimental details, and participating in peer review. Grant panels, journal editors, and collaborative networks all look for this transparency.
Training programs for interns and early-stage researchers include more than technical skills. Young scientists, learning from seasoned staff, connect the dots between choices made in the storeroom and the credibility of their published findings. I’ve seen firsthand how questions from regulatory bodies or journal reviewers become easier to answer when source materials are unimpeachable. Open documentation and clear reporting remove doubt and foster a healthy scientific culture.
Many universities use Phencyclidate Hydrochloride in advanced synthesis or analysis labs, due in no small part to its predictable profile. Students quickly learn that results depend on both their hands and the reliability of their reagents. Discovering the difference a pure, well-characterized material makes becomes a teachable moment—one that sticks far longer than hours spent watching reaction mixtures for color changes.
Educators often plan their curriculum around substances that behave reliably under a variety of conditions. This allows for deeper dives into mechanism elucidation, chromatographic troubleshooting, or advanced spectral analysis. Instead of vague results or ambiguous chromatograms, students see crisp outcomes, setting a stronger foundation for future scientific work.
Supply chains bear increased scrutiny these days, with labs fact-checking source integrity and lab-to-bench-test reproducibility. Suppliers maintaining high quality assurance win repeat business and long-term partnerships. Labs often establish yearly reviews of all frequently used chemicals, including Phencyclidate Hydrochloride, to flag any shifts in purity, particle size, or unexpected behavioral quirks.
The trend toward automation has led some teams to establish batch sample archives, so each experiment can be traced backwards with physical proof. These archives add a layer of reliability as research grows more collaborative and geographically distributed. Future projects that lean on shared databases and pooled resources trust time-tested compounds, like Phencyclidate Hydrochloride, to keep their findings credible.
Phencyclidate Hydrochloride stands as a quiet workhorse in labs that take accuracy and progress seriously. Reliable, straightforward compounds underpin findings that others can build on, and lessen the burden of checking every uncontrollable variable. Subtle differences between raw materials change research history more often than splashy new techniques. A compound that remains dependable, with transparent sourcing and clear documentation, ends up saving more than frustration—it protects both scientific integrity and investment.
