(319d) Continuous Polymer Coating of Nanoparticles: A Novel Method | AIChE

(319d) Continuous Polymer Coating of Nanoparticles: A Novel Method

Authors 

Chen, D. - Presenter, New Jersey Institute of Technology
Sirkar, K. K., New Jersey Institute of Technology
Singh, D., New Jersey Institute of Technology
Pfeffer, R., Arizona State University



Nanoparticle-based drug delivery systems are of significant interest in controlled release of drugs, delivery of anticancer drugs and imaging agents to tumors, tuberculosis treatment and as non-viral gene delivery vehicles. To develop controlled release of the drug as well as to protect the drug from demanding environments, appropriate coatings are employed on the drug nanoparticles. Conventional methods for coating or encapsulating micron–sized and nanoparticles utilize dry or wet approaches. Dry methods include physical vapor deposition, plasma treatment, chemical vapor deposition and pyrolysis of polymeric organic materials. Wet methods cover sol-gel processes, emulsification and solvent evaporation techniques.  Supercritical fluid (SCF) processes such as Rapid Expansion of Supercritical Solutions (RESS), Supercritical Anti-Solvent (SAS), and Gas Anti-Solvent (GAS) processes employing supercritical CO2 are alternative methods for nanoparticle coating or encapsulation of ultrafine particles. These SCF-based processes have many shortcomings. Some processes require demanding operating conditions, suffer from low polymer solubility etc. Most of these techniques are also batch processes. Fluidized bed-based processes, which can be continuous, face difficulties with nanoparticles caused by van der Waals and other interparticle forces. In all such processes, scale-up is also quite demanding.  We will illustrate a technique for continuous polymer coating of nanoparticles that is easily scalable. The nanoparticles used were of silica. Polymers used for coating were Eudragit and PLGA.