Litcius/Paper detail

Comparison of media milling and microfluidization methods for engineering of nanocrystals: a case study

Manasi Chogale, Sandip Gite, Vandana Patravale

2020Drug Development and Industrial Pharmacy21 citationsDOI

Abstract

OBJECTIVE: The article focuses on exploring and comparing two top-down methods, i.e. media milling and microfluidization for the fabrication of nanocrystals of rifampicin (RIF), a poorly water-soluble drug in terms of their potential for generation of stable and efficacious nanocrystals. SIGNIFICANCE: Nanocrystals are often the system of choice for the formulation of poorly water-soluble drugs. The characteristic benefit of nanocrystals lies in their ability to boost the bioavailability of such drugs by enhancing their saturation solubility and dissolution velocity. Nanocrystals can be prepared by either bottom-up or top-down approach. The latter is often preferred due to the feasibility of scale-up and economical nature. Hence, the emphasis is on these methods. METHODS: dissolution, solid-state characteristics, morphology, intrinsic dissolution rate, and short-term physical stability. RESULTS: Both the methods were found to be equally efficient in terms of development of stable RIF NCs, while in terms of processing time and efficacy, microfluidization was found to be advantageous. Amorphization and polymorphic conversion were evident based on the results of solid-state characterization. Furthermore, both formulations exhibited an enhanced solubility and faster dissolution velocity. CONCLUSION: Based on the characterization outcomes, it can be concluded that both the top-down technologies could be successfully applied to develop nanocrystals of poorly water-soluble drugs. However, microfluidization was found to outplay media milling in terms of processing time and drug loading.

Topics & Concepts

NanocrystalDissolutionSolubilityMaterials scienceBioavailabilityNanotechnologyChemical engineeringSaturation (graph theory)Pulmonary surfactantChemistryOrganic chemistryMathematicsPharmacologyMedicineCombinatoricsEngineeringDrug Solubulity and Delivery Systems3D Printing in Biomedical ResearchAdvanced Drug Delivery Systems