| Summary: | The formation of microparticles (<i>MPs</i>) of biocompatible and biodegradable hydrogels such as polyethylene glycol diacrylate (PEGDA) utilizing microfluidic devices is an attractive option for entrapment and encapsulation of active principles and microorganisms. Our research group has presented in previous studies a formulation to produce these hydrogels with adequate physical and mechanical characteristics for their use in the formation of <i>MPs</i>. In this work, hydrogel <i>MPs</i> are formed based on PEGDA using a microfluidic device with a T-junction design, and the <i>MPs</i> become hydrogel through a system of photopolymerization. The diameters of the <i>MPs</i> are evaluated as a function of the hydrodynamic condition flow rates of the continuous (Qc) and disperse (Qd) phases, measured by optical microscopy, and characterized through scanning electron microscopy. As a result, the following behavior is found: the diameter is inversely proportional to the increase in flow in the continuous phase (Qc), and it has a significant statistical effect that is greater than that in the flow of the disperse phase (Qd). While the diameter of the <i>MPs</i> is proportional to Qd, it does not have a significant statistical effect on the intervals of flow studied. Additionally, the <i>MPs’</i> polydispersity index (PDI) was measured for each experimental hydrodynamic condition, and all values were smaller than 0.05, indicating high homogeneity in the <i>MPs</i>. The microparticles have the potential to entrap pharmaceuticals and microorganisms, with possible pharmacological and bioremediation applications.
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