Noradrenaline tartrate stands out among chemical compounds for its role as a vital catecholamine with both therapeutic and research significance. This compound shows up across medicine and chemistry for its ability to mimic the function of noradrenaline naturally present in the human body. Noradrenaline, also known as norepinephrine, drives key responses of the nervous system—regulating blood pressure, heart rate, and other critical functions. Structurally, noradrenaline tartrate appears as a white or slightly off-white crystalline solid. Large amounts feature as dense flakes, powder, or crystalline pearls, each form dictated by both transport and intended use. Storage often comes down to ensuring moisture remains far away, keeping decomposition at bay and guaranteeing safe handling in both hospital and laboratory environments.
The substance carries the molecular formula C8H11NO3·C4H6O6, pinpointing a functional catechol core and a tartrate anion bound together. This structure allows for high solubility in water, producing an aqueous solution with relatively neutral pH and consistent performance in a range of preparation methods. Compared by density, noradrenaline tartrate measures about 1.24 g/cm³, an aspect that matters for accurate dosing and mixing in solution form. The chemical merges catecholamine reactivity with tartaric acid stability. Its crystalline nature gives it edge in purification and identification—labs rely on the clear, sparkling grains or powder for both assay and formulation.
Pharmaceutical and industrial recipes demand noradrenaline tartrate in highly pure states—impurities throw off both therapeutic value and chemical reactions. Most commercial quantities arrive in containers sealed against light, humidity, and oxygen, all to keep the raw material as stable as possible. The flakes or pearls dissolve readily in water, releasing a colorless solution known for both quick action and enduring effectiveness. The product shows low volatility, which makes accidental inhalation less likely during weighing or transfer, but the powder must be treated with care due to its fine, dust-like nature. Unsafe handling, through spills or contact with skin and eyes, opens the door to chemical burns and toxic exposure. Wearing gloves, goggles, and lab coats stops unnecessary exposure and preserves both comfort and safety during every step.
Noradrenaline tartrate falls under HS Code 2922199090, assigned according to international trade standards for organic compounds with pharmaceutical use. This designation helps customs offices, shippers, and buyers identify, classify, and process the material without confusion or delay. The HS Code tightly links to the compound’s intended use for research and medicine—getting country clearances, verifying shipment lists, and tracking inventories in hospitals relies on this universally recognized number. This transparency also helps prevent shipment errors and keeps hazardous materials from falling into unqualified hands.
Even with its broad utility, noradrenaline tartrate earns a spot among both pharmacologically active and hazardous chemicals. Exposure can cause cardiovascular disturbances, skin irritation, or allergic reactions. Strict safety data sheets exist for a reason—reading those instructions before touching or dissolving the powder pays off, both for personal health and in case of spills or emergency. Storage containers need airtight seals and cool, dry shelves, ideally in locked cabinets away from food, drink, and open flames. As a hazardous supplier, responsible companies must reduce traces in wastewater and dispose of unused or expired product in line with environmental policies. Workers handling raw materials need periodic training, regular health monitoring, and fast access to first-aid measures, underscoring a pattern of care that should stretch from supplier to end-user.
Production and use of noradrenaline tartrate continue to drive new questions. Purity demands keep climbing, while emerging needs push for tighter quality controls and greener synthesis routes. Traditional manufacturing leaves some waste; green chemistry offers cleaner alternatives, cutting risk for both humans and the environment. Hospitals and research labs play a part, supporting responsible disposal and recycling wherever possible. Suppliers must also invest in worker protection programs, hazard communication, and ongoing audits to keep up with regulatory changes and stakeholder expectations. As I have seen in lab environments, proactive education builds confidence, reduces mistakes, and at the end of the day, strengthens the chain between raw material and patient or research outcome.
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