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Looking for Rocaglamide API 84573-16-0?

Description:
Here you will find a list of producers, manufacturers and distributors of Rocaglamide. You can filter on 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:
Rocaglamide 
Synonyms:
 
Cas Number:
84573-16-0 
DrugBank number:
DB15495 
Unique Ingredient Identifier:
FRG4N852F7

General Description:

Rocaglamide, identified by CAS number 84573-16-0, is a notable compound with significant therapeutic applications. Rocaglamide, also referred to as rocaglamide-A, is the eponymous member of a class of anti-cancer phytochemicals known as rocaglamides. Rocaglamides are secondary metabolites of the plant genus _Aglaia_, and extracts of the plant have traditionally been used as a form of insect repellant due to its natural insecticidal properties. Reports of _Aglaia_ anti-tumor activity date back as far as 1973, and rocaglamide-A was first isolated in 1982 from the species _A. elliptifolia_. Rocaglamide and a number of its derivatives (e.g. ) are currently being studied for use as chemotherapeutic agents in the treatment of various leukemias, lymphomas, and carcinomas, as well as adjuvant therapy in the treatment of certain chemotherapy-resistant cancers.

Mechanism of Action:

Rocaglamide functions by: Rocaglamide’s anti-tumor activity is driven primarily via inhibition of protein synthesis in tumor cells. Inhibition of protein synthesis is accomplished via inhibition of prohibitin 1 (PHB1) and prohibitin 2 (PHB2) - these proteins are necessary in the proliferation of cancer cells and are implicated in the Ras-mediated CRaf-MEK-ERK signaling pathway responsible for phosphorylating eIF4E, a key factor in the initiation of protein synthesis. The rocaglamide derivative silvestrol has also been observed to act directly on eIF4A, another translation initiation factor of the eIF4F complex ultimately responsible for initiation of protein synthesis. Inhibition of protein synthesis has a number of downstream effects. Many of the proteins that are down-regulated in response to protein synthesis inhibition in tumor cells are short-lived proteins responsible for regulation of the cell cycle, such as Cdc25A. Cdc25A is an oncogene that can become overexpressed in certain cancers and lead to unchecked cell growth. In addition to inhibiting its synthesis via the mechanism described above, rocaglamide promotes degradation of Cdc25A via activation of the ATM/ATR-Chk1/Chk2 checkpoint pathway. This pathway is normally activated in response to DNA damage and serves to reduce the expression of proteins responsible for cell cycle progression, thereby inhibiting proliferation of damaged (i.e. tumour) cells. Rocaglamide’s inhibition of protein synthesis also appears to prevent the actions of the transcription factor heat shock factor 1 (HSF1), leading to an increased expression of thioredoxin-interacting protein (TXNIP) which is negatively regulated by HSF1. TXNIP is a negative regulator of cell glucose uptake, and its increased expression blocks glucose uptake and consequently impairs the proliferation of malignant cells. Rocaglamide also appears to induce apoptosis in tumor cells via activation of the pro-apoptotic proteins p38 and JNK and inhibition of the anti-apoptotic Mcl-1 protein. Similarly, it has been studied as an adjuvant in TRAIL-resistant cancers due to its ability to inhibit the synthesis of c-FLIP and IAP/XIAP - these anti-apoptotic proteins can become elevated in certain cancers, preventing the induction of apoptosis and resulting in resistance to TRAIL-based therapies. This mechanism highlights the drug's role in inhibiting or promoting specific biological pathways, contributing to its therapeutic effects.

Classification:

Rocaglamide belongs to the class of organic compounds known as flavaglines. These are heterocyclic compounds with a structure characterized by a cyclopenta[b]benzofuran skeleton, classified under the direct parent group Flavaglines. This compound is a part of the Organic compounds, falling under the Organoheterocyclic compounds superclass, and categorized within the Benzofurans class, specifically within the Flavaglines subclass.

Categories:

Rocaglamide is categorized under the following therapeutic classes: Heterocyclic Compounds, Fused-Ring. These classifications highlight the drug's diverse therapeutic applications and its importance in treating various conditions.

Rocaglamide is a type of Anticancer drugs


Anticancer drugs belong to the pharmaceutical API (Active Pharmaceutical Ingredient) category designed specifically to combat cancer cells. These powerful medications play a crucial role in cancer treatment and are developed to target and destroy cancerous cells, preventing their growth and spread.

Anticancer drugs are classified based on their mode of action and can include various types such as chemotherapy drugs, targeted therapy drugs, immunotherapy drugs, and hormonal therapy drugs. Chemotherapy drugs work by interfering with the cell division process, thereby inhibiting the growth of cancer cells. Targeted therapy drugs, on the other hand, are designed to attack specific molecules or genes involved in cancer growth, minimizing damage to healthy cells. Immunotherapy drugs stimulate the body's immune system to recognize and destroy cancer cells. Hormonal therapy drugs are used in cancers that are hormone-dependent, such as breast or prostate cancer, to block the hormones that fuel cancer cell growth.

These APIs are typically synthesized through complex chemical processes in state-of-the-art manufacturing facilities. Stringent quality control measures ensure the purity, potency, and safety of these drugs. Anticancer APIs undergo rigorous testing and adhere to stringent regulatory guidelines before being approved for clinical use.

Due to their critical role in cancer treatment, anticancer drugs are in high demand worldwide. Researchers and pharmaceutical companies continually strive to develop new and more effective APIs in this category to enhance treatment outcomes and minimize side effects. The ongoing advancements in the field of anticancer drug development offer hope for improved cancer therapies and better patient outcomes.