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Encapsulation of soil bacteria in hydrogel carriers
Orišková, Sofia ; Smilek, Jiří (referee) ; Sedláček, Petr (advisor)
The goal of this bachelor thesis was both to review existing literature regarding the topic of inoculation of soil bacteria and test a relevant encapsulation method and optimize it. The evaluation process involved the study of various encapsulation techniques that involve hydrogel carriers suitable for agronomic purposes. Encapsulation allows controlled release of soil bacteria, and protects and stabilizes it, while ensuring longer shelf life. For the practical testing, Cupriavidus necator H16 was chosen as a nitrogen fixing bacteria for the inoculation. Through an ionic gelation method, it was encapsulated into alginate carriers, forming matrix microcapsules. Sodium alginate reacts with the cross-linking agent calcium chloride to form the capsules. The impact on the quality of the product was tested through several variables. What was revealed was that molecular weight of alginate was proven to have a significant impact. Alginate with higher molecular weight was shown to be suitable for the given system. The most desirable environment was distilled water or a TRIS-HCl buffer. However, the TRIS-HCl was unsuitable in cases of retrieving a dry product by lyophilization. Eventually, the viability of encapsulated cells was examined, and it was proven that encapsulated bacteria endure the process of encapsulation in the above-mentioned environment and they were gradually released from the carrier.
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Encapsulation of soil bacteria in hydrogel carriers
Orišková, Sofia ; Smilek, Jiří (referee) ; Sedláček, Petr (advisor)
The goal of this bachelor thesis was both to review existing literature regarding the topic of inoculation of soil bacteria and test a relevant encapsulation method and optimize it. The evaluation process involved the study of various encapsulation techniques that involve hydrogel carriers suitable for agronomic purposes. Encapsulation allows controlled release of soil bacteria, and protects and stabilizes it, while ensuring longer shelf life. For the practical testing, Cupriavidus necator H16 was chosen as a nitrogen fixing bacteria for the inoculation. Through an ionic gelation method, it was encapsulated into alginate carriers, forming matrix microcapsules. Sodium alginate reacts with the cross-linking agent calcium chloride to form the capsules. The impact on the quality of the product was tested through several variables. What was revealed was that molecular weight of alginate was proven to have a significant impact. Alginate with higher molecular weight was shown to be suitable for the given system. The most desirable environment was distilled water or a TRIS-HCl buffer. However, the TRIS-HCl was unsuitable in cases of retrieving a dry product by lyophilization. Eventually, the viability of encapsulated cells was examined, and it was proven that encapsulated bacteria endure the process of encapsulation in the above-mentioned environment and they were gradually released from the carrier.
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