Browsing by Subject "wood hemicelluloses"

In recent years, consumer interest for probiotic products has significantly grown due to their health benefits, however challenges regarding viability and controlled release of probiotic bacteria during their processing and storage still exist. Microencapsulation of probiotics by spray drying with a suitable protective material could alleviate these challenges. This research aims to assess the viability of utilizing wood hemicelluloses recovered from forest industry side-streams, specifically galactoglucomannans (GGM) and glucuronoxylans (GX), as protective agents for the probiotic strain Lacticaseibacillus rhamnosus GG (LGG) during spray drying. The study results were compared to those of maltodextrins, considering varying solid concentrations (15 and 20%) and inlet air drying temperatures (105 and 140 oC). Feed dispersion properties including viscosity, pH, particle diameter and physical stability were determined. The probiotic's viability pre- and post-spray drying was evaluated, alongside powder characterization for moisture content, water activity, particle size, morphology and structure. Results indicated that both GGM and GX effectively shield LGG from heat impact during spray drying, yielding microcapsule powders with desirable attributes such as amorphous structure and low water activity. High encapsulation efficiency (>90%) comparable to maltodextrins suggested hemicelluloses as sustainable alternatives for conventionally used wall materials. Inlet air temperature or solid concentration did not affect encapsulation efficiency of hemicelluloses. Probiotic counts met a recommended level for probiotic products, signifying potential applications in food and pharmaceuticals. Powder yield, which varied between 35 and 58%, was significantly influenced by the encapsulating material. Morphological studies demonstrated well-formed, spherical particles at a specific drying temperature. The study proposes the potential use of wood hemicelluloses for effective probiotic protection, offering new possibilities for synbiotic powder applications in diverse industries due to their prebiotic properties which have been well reported in literature. Despite promising results, long-term stability and process optimization to improve the process yield and achieve lower moisture content for the microcapsule powders require further investigation. Adjusting feed dispersion parameters and exploring varied concentrations of hemicelluloses could enhance product yield. Meanwhile, increasing outlet air temperature possibly reduces the moisture content. This research fosters sustainable development in the forest industry, presenting a novel avenue for natural functional ingredient production.