Enantioseparation and enantiorecognition are crucial in the pharmaceutical analysis of chiral substances, impacting safety, efficacy, and regulatory compliance. Enantioseparation refers to the process of separating enantiomers from a mixture, typically achieved through chromatography techniques like HPLC and SFC. In contrast, enantiorecognition involves the identification of enantiomers based on their interaction with a chiral selector without the need for separation. Recent advancements in these techniques have significantly improved enantioseparation efficiency and resolution. Chiral stationary phases (CSPs) have evolved, offering better selectivity, including hybrid organic-inorganic materials and miniaturization. The use of green solvents has also reduced environmental impact. Non-chromatographic methods, such as circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy, enable enantiorecognition through interactions with polarized light or chiral solvents. However, these methods face challenges, including high costs, limited solvent compatibility, and shorter operational lifespans compared with chromatographic techniques. Recent developments in solvent-tolerant hybrid CSPs aim to address these limitations. This review highlights these innovations, focusing on their relevance to the pharmaceutical industry, pollution control, and quality assurance, and emphasizes the growing importance of these techniques in the production and regulation of chiral drugs.
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