Microparticle Formation Kinetics in Spray Drying

喷雾干燥中的微粒形成动力学

• 批准号: RGPIN-2016-04111
• 负责人: Vehring, Reinhard
• 金额: $ 2.77万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=667678
• 关键词: Microparticle; Formation; Kinetics; Spray; Drying

Particle Engineering provides the analytical and theoretical basis for the design of advanced microparticles. These small particles have applications in many fields, e.g. in the chemical and food industries. One application in particular has grown steadily over the last decade, the design of inhalable microparticles for drug delivery to the nose or lung. Several therapeutics based on these particles have entered the market or are in late stage pharmaceutical development. Particle engineering methodology has been implemented in the industrial development process. Advanced microparticles typically have diameters in the range of 0.5 – 50 µm and are structured, i.e. they have functional substructures often in the nanometer scale, which impact important product attributes such as physical and chemical stability, encapsulation, or powder flowability and dispersibility, i.e., the property of a powder that describes how easy it is to disperse it into individual particles.******The most developed manufacturing technique for structured microparticles is spray drying. Much progress has been achieved in understanding relevant sub-processes and the effect of process parameters on product attributes. Theoretical models for process control and diffusion controlled solid particle formation have been developed and implemented. Yet the kinetics of precipitation events during the solidification of drying microdroplets remain poorly understood. This lack of basic understanding has resulted in a partially empirical approach in the industrial development process. This approach is time and resource consuming and has the tendency to increase early development risk, timelines, and budget. This provides the motivation to study particle formation kinetics in depth, develop models for key processes such as nucleation and crystallization, apply the results to the design of novel process equipment, and ultimately to enable the design of a new class of particle based products.******Particle formation events will be studied in the well controlled model environment of a chain of identically sized droplets generated by an inkjet-type droplet generator. The droplets will be injected into a controlled laminar gas flow. While drying their diameter can be measured optically and the final particles can be sampled for ultramicroscopic analysis. Molecular spectroscopy, specifically in situ low frequency shift Raman spectroscopy, will be used to identify and quantify solid phases and the amount of order in the drying particles. A numerical code that can describe drying processes with variable evaporation rate, surface activity, and precipitation processes will be developed and used to interpret the experimental results and for the development of predictive models. Larger powder quantities of microparticles will be produced under controlled drying kinetics using a novel spray dryer. **

粒子工程为先进微粒的设计提供了分析和理论基础。这些小颗粒在许多领域都有应用，例如在化学和食品工业中。在过去的十年中，有一种应用得到了稳定的发展，那就是设计可吸入的微粒，用于将药物输送到鼻子或肺部。基于这些颗粒的几种治疗方法已经进入市场或处于后期药物开发阶段。粒子工程方法已经在工业发展过程中得到了应用。高级微颗粒的直径通常在0.5 - 50µm范围内，并且是结构化的，即它们通常具有纳米尺度的功能子结构，这影响重要的产品属性，如物理和化学稳定性，封装性或粉末流动性和分散性，即粉末的特性，描述了将其分散成单个颗粒的难易程度。******最发达的结构微粒制造技术是喷雾干燥。在理解相关子过程和工艺参数对产品属性的影响方面取得了很大进展。过程控制和扩散控制固体颗粒形成的理论模型已经开发和实现。然而，在干燥微滴凝固过程中沉淀事件的动力学仍然知之甚少。由于缺乏基本的了解，导致在工业发展过程中采用部分经验主义的方法。这种方法耗费时间和资源，并且有增加早期开发风险、时间线和预算的趋势。这为深入研究颗粒形成动力学提供了动力，为关键过程（如成核和结晶）开发模型，将结果应用于新型工艺设备的设计，并最终实现新型颗粒基产品的设计。******粒子形成事件将在由喷墨式液滴发生器产生的大小相同的液滴链的良好控制模型环境中进行研究。液滴将被注入受控的层流气体中。当干燥时，它们的直径可以用光学测量，最终的颗粒可以取样进行超微分析。分子光谱，特别是原位低频移拉曼光谱，将用于识别和量化固体相和干燥颗粒中的有序量。将开发一种能够描述具有可变蒸发速率、表面活性和降水过程的干燥过程的数值代码，并用于解释实验结果和开发预测模型。在控制干燥动力学下，使用新型喷雾干燥机将产生更大的粉末量的微粒。**