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Continuous Nanoprecipitation of Polycaprolactone in Additively Manufactured Micromixers

Simeon Göttert, Irina Salomatov, Stephan W. Eder, Bernhard C. Seyfang, Diana C. Sotelo, Johann F. Osma, Clemens K. Weiss

2022Polymers10 citationsDOIOpen Access PDF

Abstract

The polymeric ouzo effect is an energy-efficient and robust method to create nanoparticles with biologically degradable polymers. Usually, a discontinuous or semi-continuous process is employed due to its low technical effort and the fact that the amount of dispersions needed in a laboratory is relatively small. However, the number of particles produced in this method is not enough to make this process economically feasible. Therefore, it is necessary to improve the productivity of the process and create a controllable and robust continuous process with the potential to control parameters, such as the particle size or surface properties. In this study, nanoparticles were formulated from polycaprolactone (PCL) in a continuous process using additively manufactured micromixers. The main goal was to be able to exert control on the particle parameters in terms of size and zeta potential. The results showed that particle size could be adjusted in the range of 130 to 465 nm by using different flow rates of the organic and aqueous phase and varying concentrations of PCL dissolved in the organic phase. Particle surface charge was successfully shifted from a slightly negative potential of -14.1 mV to a negative, positive, or neutral value applying the appropriate surfactant. In summary, a continuous process of nanoprecipitation not only improves the cost of the method, but furthermore increases the control over the particle's parameters.

Topics & Concepts

Zeta potentialMaterials sciencePolycaprolactoneParticle sizeNanoparticleParticle (ecology)Chemical engineeringPhase (matter)PolymerSurface chargeAqueous solutionAqueous two-phase systemPulmonary surfactantNanotechnologyProcess engineeringComposite materialChemistryOrganic chemistryPhysical chemistryGeologyOceanographyEngineering3D Printing in Biomedical ResearchInnovative Microfluidic and Catalytic Techniques InnovationElectrohydrodynamics and Fluid Dynamics