This study, for the first time, tries to provide a simultaneous experimental and computational fluid dynamic (CFD) simulation investigation for production of uniform, reproducible, and stable polylactic-co-glycolic acid (PLGA) nanoparticles. CFD simulation was carried out to observe fluid flow behavior and micromixing in microfluidic system and improve our understanding about the governing fluid profile. The major objective of such effort was to provide a carrier for controlled and sustained release profile of different drugs. Different experimental parameters were optimized to obtain PLGA nanoparticles with proper size  and minimized polydispersity index. The particle size, polydispersity, morphology, and stability of nanoparticles were compared. Microfluidic system provided a platform to control over the characteristics of nanoparticles. Using microfluidic system, the obtained particles were more uniform and harmonious in size,  more stable, monodisperse and spherical, while particles produced by batch method were non-spherical and polydisperse. The best size and polydispersity index in the microfluidic method was obtained using 2% PLGA and 0.0625% (w/v) polyvinyl alcohol (PVA) solutions, and the flow rate ratio of 10:0.6 for PVA and PLGA solutions. CFD simulation demonstrated the high mixing intensity of about 0.99 at optimum condition in the microfluidic system, which is the possible reason for advantageous performance of  this system. Altogether, the results of microfluidic-assisted method were found to be more reproducible, predictable, and controllable than batch method for producing a nanoformulation for delivery of drugs. 

Nagavarma BVN, Yadav HK, Ayaz A, Vasudha LS, Shivakumar HG. Different techniques for preparation of polymeric nanoparticles- a review. Asian J Pharm Clin Res. 2012;5(Suppl3):16-23.

Varshosaz J, Taymouri S, Hamishehkar H, Vatankhah R, Yaghubi S. Development of dry powder inhaler containing tadalafil-loaded PLGA nanoparticles. Res Pharm Sci. 2017;12(3):222-232.

Tripathi A, Gupta R, Saraf SA. PLGA nanoparticles of anti tubercular drug: drug loading and release studies of a water in-soluble drug. Int J Pharmtech Res. 2010;2(3):2116-2123.

Dizaj SM, Vazifehasl Z, Salatin S, Adibkia K, Javadzadeh Y. Nanosizing of drugs: effect on dissolution rate. Res Pharm Sci.2015;10(2):95-108.

Emami J, ShetabBoushehri MA, Varshosaz J, Eisaei A. Preparation and characterization of a sustained release buccoadhesive system for delivery of terbutaline sulfate. Res Pharm Sci. 2013;8(4):219-231.

Anton N, Bally F, Serra CA, Ali A, Arntz Y,Mely Y, et al. A new microfluidic setup for precise control of the polymer nanoprecipitation process and lipophilic drug encapsulation. Soft Matter. 2012;8(41):10628-10635.

Taghipour B, Yakhchali M, Haririan I, Tamaddon AM, Samani SM. The effects of technical and compositional variables on the size and release profile of bovine serum albumin from PLGA based particulate systems. Res Pharml Sci. 2014;9(6):407-420.

Salatin S, Barar J, Barzegar-Jalali M, Adibkia K, Kiafar F, Jelvehgari M. Development of a nanoprecipitation method for the entrapment of a very water soluble drug into Eudragit RL nanoparticles. Res Pharm Sci. 2017;12(1):1-14.

Bally F, Garg DK, Serra CA, Hoarau Y, Anton N, Brochon C, et al. Improved size-tunable preparation of polymeric nanoparticles by microfluidic nanoprecipitation. Polymer. 2012;53(22):5045-5051.

Zhao H, Wang JX, Wang QA, Chen JF, Yun J. Controlled liquid antisolvent precipitation of hydrophobic pharmaceutical nanoparticles in a microchannel reactor. Indust Eng Chem Res. 2007;46(24):8229-8235.

Zhao CX. Multiphase flow microfluidics for the production of single or multiple emulsions for drug delivery. Adv Drug Deliv Rev. 2013;65(11-12):1420-1446.

Rahimi M, Valeh‐e‐Sheyda P, Zarghami R, Rashidi H. On the mixing characteristics of a poorly water soluble drug through microfluidic‐assisted nanoprecipitation: Experimental and numerical study. Canadian J Chem Eng. 2018;96(5):1098-1108.

Ebrahimi A, Sadrjavadi K, Hajialyani M, Shokoohinia Y, Fattahi A. Preparation and characterization of silk fibroin hydrogel as injectable implants for sustained release of Risperidone. Drug Dev Ind Pharm. 2018;44(2):199-205.

Hung LH, Lee AP. Microfluidic devices for the synthesis of nanoparticles and biomaterials. J Med Biol Eng. 2007;27(1):1-6.

Ali HS, York P, Blagden N. Preparation of hydrocortisone nanosuspension through a bottom-up nanoprecipitation technique using microfluidic reactors. Int J Pharm. 2009;375(1-2):107-113.

Aubry J, Ganachaud F, Cohen Addad JPC, Cabane B. Nanoprecipitation of polymethylmethacrylate by solvent shifting: 1. Boundaries. Langmuir. 2009;25(4):1970-1979.

Beck-Broichsitter M, Rytting E, Lebhardt T,Wang X, Kissel T. Preparation of nanoparticles by solvent displacement for drug delivery: a shift in the “ouzo region” upon drug loading. Eur J Pharm Sci. 2010;41(2):244-253.

Lince F, Marchisio DL, Barresi AA. Strategies to control the particle size distribution of poly-ε-caprolactone nanoparticles for pharmaceutical applications. J Colloid Interface Sci. 2008;322(2):505-515.

Naher S, Orpen D, Brabazon D, Poulsen CR, Morshed MM. Effect of micro-channel geometry on fluid flow and mixing. Simul Model Pract Th. 2011;19(4):1088-1095.

Patravale VB, Date AA, Kulkarni RM. Nanosuspensions: a promising drug delivery strategy. J PharmPharmacol. 2004;56(7):827-840.

Rahimi M, Akbari M, Parsamoghadam MA, Alsairafi AA. CFD study on effect of channel confluence angle on fluid flow pattern in asymmetrical shaped microchannels. Comput Chem Eng. 2015;73:172-182.

Chang Z, Serra CA, Bouquey M, Prat L, Hadziioannou G. Co-axial capillaries microfluidic device for synthesizing size-and morphology-controlled polymer core-polymer shell particles. Lab Chip. 2009;9(20):3007-3011.

Dirksen JA, Ring TA. Fundamentals of crystallization: kinetic effects on particle size distributions and morphology. Chem Eng Sci. 1991;46(10):2389-2427.

Zhang S, Yun J, Shen S, Chen Z, Yao K, Chen J, et al. Formation of solid lipid nanoparticles in a microchannel system with a cross-shaped junction. Chem Eng Sci. 2008;63(23):5600-5605.

Hyvönen S, Peltonen L, Karjalainen M, Hirvonen J. Effect of nanoprecipitation on the physicochemical properties of low molecular weight poly(L-lactic acid) nanoparticles loaded with salbutamol sulphate and beclomethasone dipropionate. Int J Pharm. 2005;295(1-2):269-281.

Zweers ML, Grijpma DW, Engbers GH, Feijen J. The preparation of monodisperse biodegradable polyester nanoparticles with a controlled size. J Biomed Mat Res B Appl Biomater. 2003;66(2): 559-566.

Allémann E, Gurny R, Doelker E. Preparation of aqueous polymeric nanodispersions by a reversible salting-out process: influence of process parameters on particle size. Int J Pharm. 1992;87(1-3):247-253.

Khan SA, Günther A, Schmidt MA, Jensen KF. Microfluidic synthesis of colloidal silica. Langmuir. 2004;20(20):8604-8611.