The intricate process of drug discovery and development relies heavily on a diverse arsenal of chemical building blocks and intermediates. Among these, 10-Acetyl-3,7-dihydroxyphenoxazine (ADHP), identified by its CAS number 119171-73-2, has emerged as a valuable player in the synthesis of complex pharmaceutical compounds. Its unique structural features and reactivity make it an attractive intermediate for medicinal chemists.

The Chemical Structure and Reactivity of ADHP

ADHP is a derivative of phenoxazine, a tricyclic heterocyclic compound containing nitrogen and oxygen atoms within its core structure. The presence of acetyl (-COCH3) and hydroxyl (-OH) functional groups imparts specific reactivity to the molecule:

  • The hydroxyl groups offer sites for etherification, esterification, or conjugation reactions.
  • The acetyl group can be involved in condensation reactions or further functionalization.
  • The phenoxazine ring system itself can undergo electrophilic substitution or oxidation/reduction reactions, depending on the conditions.

This combination of features allows medicinal chemists to creatively incorporate ADHP into larger molecular frameworks, tailoring them to achieve desired pharmacological properties.

Applications in Pharmaceutical Synthesis

ADHP's utility as a pharmaceutical intermediate stems from its ability to be transformed into various complex organic molecules. While specific proprietary syntheses are often confidential, its structural motifs suggest potential applications in areas such as:

  • Development of Bioactive Compounds: The phenoxazine scaffold is present in some biologically active molecules, and ADHP can serve as a starting point for synthesizing novel compounds with potential therapeutic activities.
  • Creation of Fluorescent Probes for Drug Discovery: Although ADHP itself is a probe for H2O2, its derivatives might be synthesized to create fluorescent tags or probes for specific biological targets within drug discovery pipelines.
  • Synthesis of Specialty Chemicals: Beyond direct pharmaceutical applications, ADHP can be an intermediate in the synthesis of other high-value specialty chemicals used in research or niche industrial applications.

Sourcing ADHP for Synthesis: Quality and Reliability

For effective pharmaceutical synthesis, the quality and consistency of intermediates like ADHP are paramount. Researchers and manufacturers looking to buy ADHP must prioritize suppliers who can guarantee:

  • High Purity: A minimum purity of 97% is generally required to ensure clean reactions and avoid issues in downstream processes.
  • Batch-to-Batch Consistency: Reliable performance in synthesis depends on consistent quality from one batch of ADHP to the next.
  • Scalability: As projects progress from research to larger-scale production, the supplier must be able to scale up their manufacturing of ADHP accordingly.
  • Competitive Pricing: Cost-effectiveness is crucial in pharmaceutical development, making it important to source ADHP from competitive manufacturers, often found in regions like China.

Finding ADHP Manufacturers and Suppliers

When searching for ADHP, using its CAS number (119171-73-2) is the most precise method to ensure you are finding the correct chemical. Online B2B platforms, chemical directories, and specialized supplier websites are excellent resources. Look for suppliers that:

  • Clearly list ADHP as a pharmaceutical intermediate or fine chemical.
  • Provide detailed specifications, including purity levels and physical properties.
  • Offer technical documentation such as Certificates of Analysis (CoA).
  • Are transparent about their manufacturing capabilities and pricing for various quantities.

Engaging with suppliers, requesting quotes, and potentially obtaining samples for evaluation are essential steps in selecting the right ADHP manufacturer for your synthesis needs.

Conclusion

10-Acetyl-3,7-dihydroxyphenoxazine (ADHP) is more than just a laboratory reagent; it's a versatile pharmaceutical intermediate that enables the creation of complex and potentially life-saving drugs. By understanding its synthetic potential and prioritizing quality sourcing, researchers and manufacturers can effectively leverage ADHP in their pursuit of novel therapeutics.