Flow reactor for preparation of lipid nanoparticles via temperature variations

[Display omitted] •A scalable flow reactor for the production of lipid nanoemulsions and nanosuspensions is described.•The reactor uses temperature variations for spontaneous fragmentation of coarse lipid particles.•Lipid nanoparticles with a diameter down to 20 nm were obtained.•The size of the obt...

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Bibliographic Details
Published in:Journal of industrial and engineering chemistry (Seoul, Korea) 2022, 112(0), , pp.37-45
Main Authors: Lesov, I., Glushkova, D., Cholakova, D., Georgiev, M.T., Tcholakova, S., Smoukov, S.K., Denkov, N.
Format: Article
Language:English
Subjects:
Emulsion
Flow reactor
Infrared temperature optimization
Lipid nanoemulsions
Lipid nanoparticles
화학공학
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Summary:[Display omitted] •A scalable flow reactor for the production of lipid nanoemulsions and nanosuspensions is described.•The reactor uses temperature variations for spontaneous fragmentation of coarse lipid particles.•Lipid nanoparticles with a diameter down to 20 nm were obtained.•The size of the obtained particles is similar to that obtained in a high-pressure homogenizer.•The main factors for process optimization and scaling are clarified. Lipid nanoemulsions and nanosuspensions are used as flavor carriers and bubble stabilizers in soft drinks and foods, as well as delivery vehicles for lipophilic drugs in pharmaceutics. Common techniques for their formation are the high-pressure and ultrasonic homogenizers. These techniques dissipate most of the input energy, which results in excessive heating and generation of free radicals that might modify sensitive ingredients. Low energy methods are also used in some applications, but they have specific limitations restricting their universal use. In the current study, we propose an alternative approach - a flow reactor with a variable temperature, which utilizes the lipids' polymorphic transitions to induce spontaneous fragmentation of the lipid microparticles into nanoparticles. The reactor allows us to obtain emulsions or suspensions with particle diameters tunable between 20 and 800 nm when appropriate surfactants, temperature profiles, and flow rates are applied. The fragmentation is comparable to that in a high-pressure homogenizer at ca. 500 bars or higher, without creating emulsion overheating or cavitation typical for the conventional methods. The flow reactor can be scaled up to industrial applications using simple scaling rules.
ISSN:1226-086X
1876-794X
DOI:10.1016/j.jiec.2022.03.043