Xu, Zheqi2016-04-262018-03-0520162016-04-26http://hdl.handle.net/1828/7190This thesis includes three studies on related aspects of structure and function control for drug delivery block copolymer nanoparticles manufactured in segmented gas-liquid microfluidic reactors. First, the self-assembly of a series of photoresponsive poly(o-nitrobenzyl acrylate)-b-polydimethylacrylamide copolymers is conducted in the gas-liquid segmented microfluidic reactor at various flow rates. The resulting morphologies are found to be flow-variable and distinct from nanoparticles prepared off-chip by dropwise water addition. Photocleaving of the nanoparticles formed at different flow rates reveal flow-variable photodissociation kinetics. Next, we conduct a direct comparison between a commercially-available single-phase microfluidic mixer and the two-phase, gas-liquid segmented microfluidic reactor used in our group, with respect to nanoparticle formation from a typical block copolymer identified for drug delivery applications, polycaprolactone-b-poly(ethylene oxide). The two-phase chip yields morphologies and core crystallinities that vary with flow rate; however, the same parameters are found to be flow-independent using the single-phase mixer. This study provides the first direct evidence that flow-variable structure control is a unique feature of the two-phase chip design. Finally, we investigate structure and function control for paclitaxel (PAX)-loaded nanoparticles prepared from a series of poly(6-methyl caprolactone-co-ε-caprolactone)-block-poly(ethylene oxide) copolymers with variable 6-methyl caprolactone (MCL) content. For all MCL-containing copolymers, off-chip preparations form nanoparticles with no measurable crystallinity, although PAX loading levels are higher and release rates are slower compared to the copolymer without MCL. Both off-chip and on-chip preparations yield amorphous spheres of similar size from MCL-containing copolymers, although on-chip nanoparticles showed slower release rates, attributed to more homogeneous PAX distribution due to faster mixing.enAvailable to the World Wide WebMicrofluidicsDrug DeliveryBlock CopolymerNanoparticlesThesisZ. Xu, B. Yan, J. Riordon, Y. Zhao, D. Sinton and M. G. Moffitt Microfluidic Synthesis of Photoresponsive Spool-Like Block Copolymer Nanoparticles: Flow-Directed Formation and Light-Triggered Dissociation. Chemistry of Materials 2015, 27, 8094.