5-Chloro-2-Thiophenecarboxylic Acid: A Key Intermediate for Rivaroxaban Synthesis and Organic Chemistry Applications
Discover the pivotal role of 5-Chloro-2-thiophenecarboxylic acid in modern pharmaceuticals and advanced organic synthesis.
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5-Chloro-2-thiophenecarboxylic acid
This compound is a critical intermediate in the synthesis of Rivaroxaban, a widely used anticoagulant essential for treating and preventing thromboembolic disorders. Its unique chemical structure makes it a versatile building block in various organic synthesis pathways.
- As a key building block in organic chemistry, explore the 5-chloro-2-thiophenecarboxylic acid synthesis for novel compounds. Its structure facilitates the creation of complex molecules.
- The significance of this compound lies in its role as a Rivaroxaban intermediate, a crucial step in producing anticoagulant drugs. This contributes to the treatment of cardiovascular issues.
- Understanding pharmaceutical intermediate chemical properties is vital for reliable drug manufacturing. This compound's high purity ensures efficacy.
- Investigate the diverse organic synthesis applications of thiophene derivatives. This compound's chlorine and carboxylic acid functionalities offer many reaction possibilities.
Key Advantages
High Purity and Stability
With an assay purity of ≥97.0% and a low loss on drying (≤0.5%), this chemical intermediate ensures consistent quality for demanding applications. Its physical properties make it stable for industrial handling.
Critical Role in Rivaroxaban Production
As a pivotal pharmaceutical intermediate chemical, it is indispensable in the multi-step synthesis of Rivaroxaban, a life-saving anticoagulant, demonstrating its direct impact on public health.
Versatile Organic Synthesis Building Block
The thiophene structure with specific functional groups makes it a versatile tool for organic chemists, enabling the exploration of new chemical entities and advanced material science projects.
Key Applications
Pharmaceutical Synthesis
Primarily used as a key intermediate in the production of Rivaroxaban, a vital anticoagulant medication. This application underpins its importance in the healthcare sector.
Organic Chemistry Research
Serves as a valuable building block for synthetic organic chemists exploring new molecular structures and reaction pathways.
Material Science
Potential applications in material science due to its unique heterocyclic structure and reactive functional groups, opening avenues for new material development.
Drug Discovery
Its derivatives can be explored for the development of novel bioactive molecules, contributing to future pharmaceutical innovations.