Purpose <p>Conventional nanoparticle manufacturing techniques remain costly, labor-intensive, and difficult to scale, while also being subject to batch-to-batch variability. These limitations hinder their clinical translation, particularly in first-in-human trials. Emerging transformative technologies such as microfluidics and three-dimensional (3D) printing offer opportunities to develop agile, continuous, and scalable manufacturing processes. This study aims to demonstrate the feasibility of continuous microfluidic production of nanoparticles using customizable 3D-printed chips, integrated with atomization technologies, to generate solid nano-enabled controlled release therapies.</p> Methods <p>3D-printed microfluidic chips were designed using computational fluid dynamics (CFD) to optimize flow characteristics. Nifedipine (NFD)–loaded nanoparticles were continuously manufactured with Eudragit L-100 and subsequently embedded into pullulan microparticles by spray-drying, yielding nano-in-microparticles (NIM). Particle size, encapsulation efficiency, solid-state properties,&#xa0;permeability, and release kinetics were assessed in&#xa0;ex vivo&#xa0;Franz cell studies across porcine intestinal membranes.</p> Results <p>Continuous microfluidic processing produced NFD-loaded nanoparticles with 95% encapsulation efficiency. Spray-drying yielded spherical pullulan-based NIMs of ~ 10 µm, which, upon rehydration, released NFD nanoparticles of ~ 100 nm. The nanoparticles retained their amorphous state and displayed a three-fold increase in intestinal permeability compared to free drug, accompanied by a three-fold reduction in lag time. Release studies demonstrated reduced burst release and a sustained zero-order release profile over 24 h, favorable for blood pressure maintenance therapy.</p> Conclusions <p>The integration of 3D-printed microfluidic chip design with continuous manufacturing and spray-drying enables scalable production of solid nano-enabled therapies. The NFD-loaded NIMs demonstrated enhanced permeability and controlled release, supporting the potential of this platform for the clinical translation of nanomedicines.</p> Graphical Abstract <p></p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Continuous Microfluidic Manufacture of Nano-in-Microparticles Combining 3D-Printed Micromixers and Spray Drying

  • Aytug Kara,
  • Baris Ongoren,
  • Brayan J. Anaya,
  • Aikaterini Lalatsa,
  • Dolores R. Serrano

摘要

Purpose

Conventional nanoparticle manufacturing techniques remain costly, labor-intensive, and difficult to scale, while also being subject to batch-to-batch variability. These limitations hinder their clinical translation, particularly in first-in-human trials. Emerging transformative technologies such as microfluidics and three-dimensional (3D) printing offer opportunities to develop agile, continuous, and scalable manufacturing processes. This study aims to demonstrate the feasibility of continuous microfluidic production of nanoparticles using customizable 3D-printed chips, integrated with atomization technologies, to generate solid nano-enabled controlled release therapies.

Methods

3D-printed microfluidic chips were designed using computational fluid dynamics (CFD) to optimize flow characteristics. Nifedipine (NFD)–loaded nanoparticles were continuously manufactured with Eudragit L-100 and subsequently embedded into pullulan microparticles by spray-drying, yielding nano-in-microparticles (NIM). Particle size, encapsulation efficiency, solid-state properties, permeability, and release kinetics were assessed in ex vivo Franz cell studies across porcine intestinal membranes.

Results

Continuous microfluidic processing produced NFD-loaded nanoparticles with 95% encapsulation efficiency. Spray-drying yielded spherical pullulan-based NIMs of ~ 10 µm, which, upon rehydration, released NFD nanoparticles of ~ 100 nm. The nanoparticles retained their amorphous state and displayed a three-fold increase in intestinal permeability compared to free drug, accompanied by a three-fold reduction in lag time. Release studies demonstrated reduced burst release and a sustained zero-order release profile over 24 h, favorable for blood pressure maintenance therapy.

Conclusions

The integration of 3D-printed microfluidic chip design with continuous manufacturing and spray-drying enables scalable production of solid nano-enabled therapies. The NFD-loaded NIMs demonstrated enhanced permeability and controlled release, supporting the potential of this platform for the clinical translation of nanomedicines.

Graphical Abstract