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Razvoj tehnološkega postopka izdelave lipidnih nanodelcev za vnos cepiv
ID Fridrih, Bine (Author), ID Kocbek, Petra (Mentor) More about this mentor... This link opens in a new window, ID Potrč, Tanja (Comentor)

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Abstract
Trdne lipidne nanodelce so razvili z namenom izboljšanja lastnosti konvencionalnih dostavnih sistemov na osnovi lipidov. Sestavljeni so iz biokompatibilnih in biorazgradljivih snovi ter imajo številne prednosti pri dostavi učinkovin, med katere spada nadzorovano sproščanje in možnost ciljane dostave. Zaradi teh prednosti so jih znanstveniki začeli raziskovati kot potencialni dostavni sistem za dostavo antigenov in adjuvansov. Velik potencial imajo kot dostavni sistemi za peroralno dostavo cepiv, s čimer bi se lahko povečala komplianca pacientov in zmanjšala pojavnost poškodb med aplikacijo. Cilj magistrske naloge je bil optimizirati tehnološki postopek izdelave lipidnih nanodelcev za vnos adjuvansa za cepiva. V prvem delu magistrske naloge smo izdelali prazne trdne lipidne nanodelce in nanostrukturirane lipidne nosilce z metodo homogeniziranja taline lipida v vodno fazo stabilizatorjev s pomočjo ultrazvočnega homogeniziranja. Med postopkom izdelave smo spreminjali koncentracijo, vrsto in razmerje stabilizatorjev ter vsebnost tekočega lipida. Proučili smo vpliv procesnih parametrov na lastnosti nanodelcev in modificirali postopek izdelave do te mere, da smo dobili ponovljive serije trdnih lipidnih nanodelcev in nanostrukturiranih lipidnih nosilcev z ustrezno velikostjo in porazdelitvijo njihove velikosti. Delce smo nato ločili od disperznega medija s pomočjo ultracentrifugiranja. Ko smo postopek in sestavo praznih lipidnih nanodelcev optimizirali, smo v delce vgradili adjuvans za cepiva. Adjuvans smo morali zaradi postopka izdelave nanodelcev raztopiti, zato smo pred vgrajevanjem preverili še vpliv izbranih organskih topil na velikost nanodelcev in njihovo porazdelitev. V trdne lipidne nanodelce in nanostrukturirane lipidne nosilce z 10 % (m/m) tekočega lipida smo vgradili 5 % ali 2,5 % (m/m) adjuvansa z uporabo etilacetata. Pri uporabi etilacetata je med postopkom izdelave prišlo do pojava geliranja, zato smo ga zamenjali s tetrahidrofuranom. Končni izdelek so predstavljali trdni lipidni nanodelci in nanostrukturirani lipidni nosilci z 10 % (m/m) tekočega lipida in z 2,5 % (m/m) adjuvansa. Vsem vzorcem smo izmerili povprečno velikost in porazdelitev velikosti delcev s pomočjo fotonske korelacijske spektroskopije. Delcem z vgrajenim adjuvansom smo izmerili tudi zeta potencial z metodo laserske Dopplerjeve anemometrije.

Language:Slovenian
Keywords:adjuvans, cepiva, nanostrukturirani lipidni nosilci, optimizacija tehnološkega postopka, trdni lipidni nanodelci
Work type:Master's thesis/paper
Organization:FFA - Faculty of Pharmacy
Year:2024
PID:20.500.12556/RUL-155089 This link opens in a new window
Publication date in RUL:20.03.2024
Views:459
Downloads:45
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Secondary language

Language:English
Title:Development of lipid nanoparticle production procedure for vaccine delivery
Abstract:
Solid lipid nanoparticles were developed with the aim to improve propreties of conventional lipid-based delivery systems. They are composed of biocompatible and biodegredable substances and have several advantages in drug delivery, including controlled release and targeted delivery. Due to these advantages, scientists have begun to investigate them as potential delivery systems for antigens and adjuvants. They have great potential as delivery systems for oral vaccines, which could increase patient compliance and reduce injuries during administration. The aim of the master's thesis was to optimize the technological process of producing lipid nanoparticles for adjuvant delivery in vaccines. In the first part of the thesis, empty solid lipid nanoparticles and nanostructured lipid carriers were prepared using the method of lipid melt homogenization in an aqueous phase of stabilizers by ultrasonic homogenization. During manufacturing process, we varied the concentration, type, and ratio of stabilizers, as well as the content of liquid lipid. We studied the influence of process parameters on the properties of nanoparticles and modified the manufacturing process to obtain reproducible series of solid lipid nanoparticles and nanostructured lipid carriers with appropriate size and size distribution. The particles were then seperated from the dispersion medium using ultracentrifugation. Once we optimized the process and composition of empty lipid nanoparticles, we incorporated adjuvants for vaccines into the particles. Since we had to dissolve the adjuvant due to the manufacturing process of the nanoparticles, we also investigated the effects of selected organic solvents on the size and distribution of nanoparticles before incorporation of adjuvant. We incorporated 5 % and 2.5 % (w/w) adjuvant into solid lipid nanoparticles and nanostructured lipid carriers with 10 % (w/w) liquid lipid using ethyl acetate. However, gelation occured during manufacturing process when using ethyl acetate, so we replaced it with tetrahydrofuran. The final product consisted of solid lipid nanoparticles and nanostructured lipid carriers with 10 % (w/w) liquid ipid and with 2.5 % (w/w) adjuvant. We measured the average size and size distribution of the particles using photon correlation spectroscopy for all samples. We also measured the zeta potential of particles with incorporated adjuvant using laser Doppler anemometry.

Keywords:adjuvant, vaccines, nanostructured lipid carriers, optimization of technological process, solid lipid nanoparticles

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