Litcius/Paper detail

Modeling, design, and machine learning-based framework for optimal injectability of microparticle-based drug formulations

Morteza Sarmadi, Adam M. Behrens, Kevin J. McHugh, Hannah T. M. Contreras, Zachary L. Tochka, Xueguang Lu, Róbert Langer, Ana Jaklenec

2020Science Advances68 citationsDOIOpen Access PDF

Abstract

Inefficient injection of microparticles through conventional hypodermic needles can impose serious challenges on clinical translation of biopharmaceutical drugs and microparticle-based drug formulations. This study aims to determine the important factors affecting microparticle injectability and establish a predictive framework using computational fluid dynamics, design of experiments, and machine learning. A numerical multiphysics model was developed to examine microparticle flow and needle blockage in a syringe-needle system. Using experimental data, a simple empirical mathematical model was introduced. Results from injection experiments were subsequently incorporated into an artificial neural network to establish a predictive framework for injectability. Last, simulations and experimental results contributed to the design of a syringe that maximizes injectability in vitro and in vivo. The custom injection system enabled a sixfold increase in injectability of large microparticles compared to a commercial syringe. This study highlights the importance of the proposed framework for optimal injection of microparticle-based drugs by parenteral routes.

Topics & Concepts

MicroparticleDrug deliveryComputer scienceDrugNanotechnologyMaterials scienceEngineeringMedicineChemical engineeringPharmacologyAdvanced Drug Delivery SystemsDrug Solubulity and Delivery SystemsInhalation and Respiratory Drug Delivery