Process Research and Development, Merck & Co. Inc., 126 East Lincoln Avenue, Rahway, New Jersey 07065, United States.
Drug Product Development, Bristol-Myers Squibb, 1 Squibb Drive, New Brunswick New Jersey 08903, United States.
Mol Pharm. 2020 Jul 6;17(7):2232-2244. doi: 10.1021/acs.molpharmaceut.0c00198. Epub 2020 Jun 10.
Optimized physical properties (e.g., bulk, surface/interfacial, and mechanical properties) of active pharmaceutical ingredients (APIs) are key to the successful integration of drug substance and drug product manufacturing, robust drug product manufacturing operations, and ultimately to attaining consistent drug product critical quality attributes. However, an appreciable number of APIs have physical properties that cannot be managed via routes such as form selection, adjustments to the crystallization process parameters, or milling. Approaches to control physical properties in innovative ways offer the possibility of providing additional and unique opportunities to control API physical properties for both batch and continuous drug product manufacturing, ultimately resulting in simplified and more robust pharmaceutical manufacturing processes. Specifically, diverse opportunities to significantly enhance API physical properties are created if allowances are made for generating co-processed APIs by introducing nonactive components (e.g., excipients, additives, carriers) during drug substance manufacturing. The addition of a nonactive coformer during drug substance manufacturing is currently an accepted approach for cocrystals, and it would be beneficial if a similar allowance could be made for other nonactive components with the ability to modify the physical properties of the API. In many cases, co-processed APIs could enable continuous direct compression for small molecules, and longer term, this approach could be leveraged to simplify continuous end-to-end drug substance to drug product manufacturing processes for both small and large molecules. As with any novel technology, the regulatory expectations for co-processed APIs are not yet clearly defined, and this creates challenges for commercial implementation of these technologies by the pharmaceutical industry. The intent of this paper is to highlight the opportunities and growing interest in realizing the benefits of co-processed APIs, exemplified by a body of academic research and industrial examples. This work will highlight reasons why co-processed APIs would best be considered as drug substances from a regulatory perspective and emphasize the areas where regulatory strategies need to be established to allow for commercialization of innovative approaches in this area.
优化原料药(API)的物理性质(例如,体积、表面/界面和机械性能)是成功整合药物物质和药物产品制造、稳健的药物产品制造操作以及最终实现一致的药物产品关键质量属性的关键。然而,相当数量的 API 具有无法通过选择剂型、调整结晶过程参数或研磨等途径来管理的物理性质。以创新方式控制物理性质的方法为控制批处理和连续药物产品制造中的 API 物理性质提供了额外的独特机会,最终简化和增强药物制造过程。具体来说,如果允许在药物物质制造过程中引入非活性成分(例如赋形剂、添加剂、载体)来生成共加工 API,那么就有机会显著增强 API 的物理性质。在药物物质制造过程中添加非活性共晶形成剂目前是共晶的一种公认方法,如果可以对具有改变 API 物理性质能力的其他非活性成分做出类似的允许,将会是有益的。在许多情况下,共加工 API 可以实现小分子的连续直接压缩,从长远来看,这种方法可以用于简化小分子和大分子的从药物物质到药物产品制造过程的连续端到端的简化。与任何新技术一样,对于共加工 API 的监管期望尚未明确界定,这给制药行业实施这些技术带来了挑战。本文的目的是强调实现共加工 API 优势的机会和日益增长的兴趣,这由学术研究和工业实例来证明。这项工作将强调从监管角度来看,为什么共加工 API 最好被视为药物物质,并强调需要制定监管策略的领域,以允许在这一领域采用创新方法进行商业化。
