Diminazene API Manufacturers
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Looking for Diminazene API 536-71-0?
- Description:
- Here you will find a list of producers, manufacturers and traders of Diminazene. You can sort by certificates such as GMP, FDA, CEP, Written Confirmation and more. Send inquiries for free and get in direct contact with the supplier of your choice.
- API | Excipient name:
- Diminazene
- Synonyms:
- Diminazene aceturate , Diminazine , Diminazine aceturate
- Cas Number:
- 536-71-0
- DrugBank number:
- DB03608
- Unique Ingredient Identifier:
- Y5G36EEA5Z
About Diminazene
Do you want to know more about Diminazene? You can find a small explanation about it here. Diminazene, also known as Diminazine, 4'-(Diazoamino)benzamidine, 4'-(1-triazene-1-diyl)bis-benzenecarboximidamide, diminazine aceturate, or Diminazene aceturate, is a trypanocidal agent. Major brands of Diminazene are Berenil, Pirocide, Ganasag, and Azidin. This substance is a solid.
This compound belongs to the phenylhydrazines. These are compounds containing a phenylhydrazide moiety, which consists of a hydrazide substituent attached to a phenyl group. Known drug targets of diminazene include HTH-type transcriptional regulator QacR, trypsin-1, amiloride-sensitive amine oxidase [copper-containing], and mitochondrial peroxiredoxin-5.
Ask the supplier for a certificate of analysis to find out more about the quality of Diminazene.
Diminazene is a type of Antiprotozoics
Antiprotozoics are a vital subcategory of pharmaceutical Active Pharmaceutical Ingredients (APIs) used to combat protozoan infections. Protozoa are single-celled microorganisms that can cause severe diseases in humans, such as malaria, leishmaniasis, and toxoplasmosis. Antiprotozoic APIs play a crucial role in the development of effective medications to treat these infections.
These APIs work by targeting specific metabolic pathways or enzymes within the protozoan organisms, effectively inhibiting their growth and reproduction. By interrupting essential processes, antiprotozoics can eliminate the protozoa from the body or suppress their activity, allowing the immune system to effectively combat the infection.
Pharmaceutical companies invest significant efforts in research and development to discover and synthesize new antiprotozoic APIs. The goal is to develop highly potent and selective compounds that can effectively eradicate protozoa while minimizing side effects on the human body. This involves rigorous testing and screening of various chemical compounds to identify potential drug candidates with optimal therapeutic properties.
Antiprotozoic APIs are then used as the active ingredients in the formulation of pharmaceutical drugs, such as tablets, capsules, or injectables. These drugs are prescribed by healthcare professionals to patients suffering from protozoan infections. The selection of the appropriate antiprotozoic API depends on the specific protozoan strain and the characteristics of the infection.
In summary, antiprotozoic APIs are essential pharmaceutical ingredients that play a vital role in treating protozoan infections. Their development involves rigorous research and testing to identify potent compounds that can effectively target and eliminate protozoa, leading to improved health outcomes for patients.
Diminazene (Antiprotozoics), classified under Antiparasitics
Antiparasitics are a category of pharmaceutical Active Pharmaceutical Ingredients (APIs) that are used to combat parasitic infections in humans and animals. These APIs play a crucial role in the field of medicine and veterinary care by targeting and eliminating various parasites, such as protozoa, helminths, and ectoparasites.
The use of antiparasitics is essential in preventing and treating parasitic diseases, which can cause significant health issues and even be life-threatening. These APIs work by interfering with the parasite's vital biological processes, such as reproduction, metabolism, and survival mechanisms.
Pharmaceutical companies develop and manufacture a wide range of antiparasitic APIs to cater to different parasitic infections. Some common examples of antiparasitics include anthelmintics (used against intestinal worms), antimalarials (used to treat malaria), and ectoparasiticides (used to control external parasites like ticks and fleas).
The development of antiparasitic APIs requires rigorous research, including the identification of suitable targets within the parasite's biology and the formulation of effective chemical compounds. Safety and efficacy are paramount in the manufacturing of antiparasitics, ensuring that they effectively combat the targeted parasites while minimizing adverse effects on the host.
Overall, antiparasitics are vital tools in the fight against parasitic infections, benefiting both human and animal health. Through ongoing research and development, the pharmaceutical industry continues to innovate and improve antiparasitic APIs, contributing to the advancement of healthcare and the well-being of individuals and their animal companions.
