Micro-fluidic jet spray dried Pickering emulsion powders with high encapsulation efficiency: mechanistic insights into structural evolution during emulsion formation, drying and storage

Powdered Pickering emulsions show great potential for advanced oil encapsulation, but key gaps persist in understanding their structural evolution during spray drying. This study utilized a micro-fluidic jet spray dryer to produce cellulose nanocrystal (CNC)-based Pickering emulsion (CbPE) powders encapsulating medium-chain triglycerides (MCT), with maltodextrin (MD) as the wall matrix. Low-field nuclear magnetic resonance revealed the emulsion stabilization mechanism. The effects of oil content, matrix concentration, total solid content, and drying temperature on microcapsule morphology, size, molecular structure, and thermal stability were systematically investigated using SEM, FT-IR, and DSC. A novel extraction method was developed to differentiate between oil truly encapsulated by CNCs and free oil entrapped by MD, elucidating the phase evolution of emulsion droplets during drying. Under optimized conditions (CNC:MCT mass ratio of 1:6, CbPE:MD ratio of 7:3, total solid content of 10 % w/w, and inlet temperature of 180 °C), the powder achieved a remarkable total encapsulation efficiency of 97 % and maintained stability for six months under refrigeration with negligible oil leakage. This work provides fundamental insights into the formation, drying, and storage of Pickering emulsion powders, advancing their potential for functional oil delivery systems.