The delivery of peptides via non-invasive administration routes remains a challenge to be addressed. In this regard, chitosan nanoparticles (CS NPs) have shown promise. However, their current batch preparation methods (ionotropic gelation, polyelectrolyte complexing, emulsification solvent diffusion or micro emulsification) have proven difficult to scale up. Here, we established a microfluidic-assisted ionotropic gelation method for the manufacturing of CS NPs, ionically crosslinked with sodium tripolyphosphate (TPP), and loaded with a model peptide, Argireline. The microfluidic process was optimized through a design of experiments approach. CS concentration and pH have the greatest effect on particle size, while CS and TPP concentrations and pH on PDI. The optimum formulation was successfully loaded with the peptide (90 % EE) and characterized by a size of 186.0 ± 1.0 nm and a PDI of 0.440 ± 0.002. Subsequently, Argireline-loaded CS-TPP NPs suspension was converted into a gel for a potential topical application, considering the non-toxic, biocompatible, and biodegradable properties of the components used in the formulation. The NPs gel demonstrated appropriate mechanical properties for Argireline transdermal delivery, along with improved control over its release and enhanced skin permeation for up to 48 h, compared to NPs suspension and free drug solution. Hence, this study demonstrated that the microfluidic-assisted ionotropic gelation method could be an easy-scalable platform for the manufacturing of peptide-loaded CS-TPP NPs which could be potentially applied for the transdermal delivery of biologics.

Non-invasive peptides delivery using chitosan nanoparticles assembled via scalable microfluidic technology

Maurizii, Giorgia;Moroni, Sofia;Tiboni, Mattia;Aluigi, Annalisa;Casettari, Luca
2024

Abstract

The delivery of peptides via non-invasive administration routes remains a challenge to be addressed. In this regard, chitosan nanoparticles (CS NPs) have shown promise. However, their current batch preparation methods (ionotropic gelation, polyelectrolyte complexing, emulsification solvent diffusion or micro emulsification) have proven difficult to scale up. Here, we established a microfluidic-assisted ionotropic gelation method for the manufacturing of CS NPs, ionically crosslinked with sodium tripolyphosphate (TPP), and loaded with a model peptide, Argireline. The microfluidic process was optimized through a design of experiments approach. CS concentration and pH have the greatest effect on particle size, while CS and TPP concentrations and pH on PDI. The optimum formulation was successfully loaded with the peptide (90 % EE) and characterized by a size of 186.0 ± 1.0 nm and a PDI of 0.440 ± 0.002. Subsequently, Argireline-loaded CS-TPP NPs suspension was converted into a gel for a potential topical application, considering the non-toxic, biocompatible, and biodegradable properties of the components used in the formulation. The NPs gel demonstrated appropriate mechanical properties for Argireline transdermal delivery, along with improved control over its release and enhanced skin permeation for up to 48 h, compared to NPs suspension and free drug solution. Hence, this study demonstrated that the microfluidic-assisted ionotropic gelation method could be an easy-scalable platform for the manufacturing of peptide-loaded CS-TPP NPs which could be potentially applied for the transdermal delivery of biologics.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11576/2728631
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