Tarwa, KevinNanoparticle delivery systems composed of food polymers are a sustainable and eco-friendly approach to protect functional ingredients and promote healthier food options. In this research, a hordein-pectin nanoparticle complex (HP-NPC) was fabricated using an anti-solvent precipitation and electrostatic deposition (pH 4) method for the encapsulation of hydrophobic bioactive compounds to enhance their functionalities. First, hordein was extracted from whole barley grains to obtain a dried powder to synthesize hordein nanoparticles (HNP). Then pectin with a degree of esterification (DE) around 71% was applied as a coating material. The average particle size of the freshly prepared nanoparticle complex was relatively small (~246 ± 11 nm), and Fourier transform infrared spectroscopy (FTIR) indicated that cationic hordein interacted with anionic pectin mainly though newly formed hydrogen bonds and electrostatic interaction as indicated by their opposite surface charges. Scanning electron microscopy (SEM) revealed that the morphology of the nanoparticle complex was spherical with a smooth surface. The pectin coating was shown to have a protective effect against pH (3.0-9.0), heat (80 °C for 0-120 mins), and salt (0-100 µM) which are all factors known to degrade proteins. Second, lutein, a hydrophobic bioactive xanthophyll was encapsulated into HP-NPC to develop a lutein-hordein/pectin nanoparticle complex (L-HP-NPC). Since lutein has low water solubility and low bioavailability in the gastrointestinal tract (GIT), the effect of the encapsulation system on the functional properties of lutein was investigated. The loading capacity (LC%) and encapsulation efficiency (EE%) was around 15.5 and 82%, respectively. In vitro digestion resulted in a higher bioaccessibility of lutein for encapsulated HP-NPC (~22.3%), which is defined as the percentage of lutein accessible for absorption in the simulated intestinal fluid (SIF) compared to lutein encapsulated into HNP (~9%). The ability of pectin to produce gels in acidic media was shown to have a significant effect against gastric enzymes that can degrade both hordein and lutein. Also, lyophilization (an important step in food processing) had no significant effect on the stability of L-HP-NPC. This encapsulation system could potentially be used as a functional ingredient in the food industry to develop healthy and nutritious foods for consumers. Third, carvacrol, a phenolic monoterpene known for its antimicrobial properties was encapsulated into HP-NPC to develop a carvacrol-hordein/pectin nanoparticle complex (CA-HP-NPC). Special focus was on the solubility of encapsulate carvacrol due to its known low solubility in aqueous solutions. The antimicrobial effectiveness of the encapsulated nanoparticle complex was tested against non-pathogenic gram-positive L. innocua and gram-negative E. coli K12. CA-HP-NPC was still able to maintain a relatively small particle size (~207 ± 8 nm) after being dispersed into water post-lyophilization. Carvacrol was shown to be effective against the two bacteria, however, CA-HP-NPC did not show antimicrobial effectiveness. Although carvacrol was successfully encapsulated into the nanoparticle complex, further studies on their release properties need to be investigated to further understand their functional properties for food applications.enThesisFood scienceAgricultureBioactiveEncapsulationFood nanotechnologyNanoparticlePolysaccharideProtein