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Nanotransporters for theranostics
Dostálová, Simona ; Adam,, Vojtěch (referee) ; Kizek, René (advisor)
Master thesis deals with the use of bacteriophage as a theranostic drug nanocarrier. The term theranostics is used in recent years for systems that allow connecting of diagnostics, targeted drug delivery and monitoring of patient’s response to administered treatment in a single modality. These systems are very suitable especially with heterogeneous diseases, such as cancer. Nowadays, the treatment of cancer has often severe side effects to the patient’s body, which lowers his capability to fight the disease. Theoretical part of this work is focused on the properties of viral capsids, proteins and inorganic materials as drug nanocarriers. In practical part of this work, different methods for cultivation of bacteriophage are compared, both in liquid and solid medium and with different concentrations of the maltose, trough whose receptors bacteriophage is able to enter the host cell. Optimal was cultivation with 0.2% maltose in solid medium. Practical part is focused mainly on the use of bacteriophage as a nanocarrier for cytotoxic drug doxorubicin. Bacteriophage was able to encapsulate all applied concentrations of doxorubicin (0; 12.5; 25; 50; 100 and 200 g/ml), which was proved using fluorescent detection. Different times of encapsulation (2; 4; 8 and 12 hours) were studied. Optimal time was 2 hours. Encapsulation properties of bacteriophage were compared to apoferritin. Bacteriophage was able to encapsulate 4× higher concentrations of doxorubicin and its release during rinsing with water was 10× lower compared to apoferritin. This work concludes that bacteriophage is a very suitable platform for targeted drug delivery in theranostics.
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Modifikace ferritinových nanoklecí cílícími modalitami
Kurcová, Jana
In last two decades, application of protein nanoparticles has emerged as an excellent candidate in a field of biomedical research, especially as a tool for targeted drug delivery. Nanocarriers can ensure specific drug delivery into the damaged cells without the risk of premature release of the drug hence damage to normal cells. It is possible to modify the surface of nanocarriers with targeting modalities and use active targeting to improve cell specificity and internalization of nanocarriers. Therefore, this thesis is focused on specific surface modifications of nanocarriers with respect to active targeted drug delivery. Herein, a new method of covalent binding of the hexameric HWR (HWRGWV) peptide to the surface of fluorescently labeled apoferritin cages (APO-Cy7) using a zero-length crosslinker N,N’ dicyclohexylcarbodiimide (DCC), is presented. HWR peptide can specifically bind Fc region of antibodies enabling its application for site directed conjugation with various targeting antibodies. The optimal ratio of HWR to APO for maximum reaction effect was 1.26 mg HWR to 1 mg APO-Cy7. Furthermore, the stability of as-prepared fluorescent nanocarrier was confirmed after the binding with peptide. Fluorescence of nanocarrier increased in the emission maximum (λ = 773 nm) from 1943 ± 209 a.u. to 2594 ± 62 a.u. due to the transfer of electrons from the tryptophan residues of the peptide to Cy7. The size of the nanocarrier was 12.71 ± 0.49 nm with a surface ζ-potential of -14.37 ± 3.15 mV. The correct binding orientation of the peptide was confirmed using polyclonal IgG antibodies. After incubation and following purification, the presence of antibodies was proven spectrophotometrically, via SDS-PAGE and by changing the size of the nanocarrier. Thus, the presented work demonstrates a versatile platform suitable for a surface modification with targeting antibodies for utilization in active anticancer nanomedicine.
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Preparation of mitotic inhibitors in the form of nanotransporters
Meskařová, Veronika ; Indra, Radek (advisor) ; Hýsková, Veronika (referee)
Cancer is one of the most widespread diseases that every third person will encounter it. It is a disease arising from the sudden growth and rapid division of own cells. Despite progress in treatment, an effectiveness is not sufficient, and cancer is the second most common cause of death. In addition, the treatment is associated with several side effects. Currently nanomedicine uses nanomaterials for transport drugs in cancer treatment. It is possible to deliver the drug to the target site, but also to reduce the systemic toxicity of the drug by binding the drug to a suitable nanotransporter. This diploma thesis deals with seeking the appropriate mass ratio of antitumor drugs, colchicine and docetaxel, and the nanotransporter apoferritin. The aim was to find suitable in vitro conditions for high drugs encapsulation into the nanotransporter. Drugs encapsulation took place under active and passive conditions. Active encapsulation was under way on opening and closing nanotransporter by changing pH environment in test tube. Drugs were dissolved in DMSO or water with addition of HCl to charge the drug molecules and improve the binding of the drug into nanotransporter. As part of passive encapsulation, drugs were incubated in surroundings of urea or bivalent metal ions. Overall, it can be concluded that...
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Nanoparticle forms of anticancer drugs and the mechanisms influencing their efficiency
Urbanová, Tereza ; Stiborová, Marie (advisor) ; Hýsková, Veronika (referee)
Currently, cancer is one of the major diseases of civilization. The disadvantage of conventional chemotherapy, which began in the 1940s, is its non-specific effect, so the cytostatics are toxic to healthy cells. However, if the cytostatic is inserted into a nanotransporter, it increases its specific efficacy and reduces the negative side effects. One of the possible nanotransporters is protein called apoferritin (a protein component of ferritin, an iron-carrying protein) that contains light and heavy subunits differing in their function in iron uptake. In this bachelor thesis, the ability of apoferritin to encapsulate two cytostatics (ellipticine and doxorubicin), depending on its origin and the proportion of light and heavy apoferritin subunits, was studied.
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Nanotransporters for theranostics
Dostálová, Simona ; Adam,, Vojtěch (referee) ; Kizek, René (advisor)
Master thesis deals with the use of bacteriophage as a theranostic drug nanocarrier. The term theranostics is used in recent years for systems that allow connecting of diagnostics, targeted drug delivery and monitoring of patient’s response to administered treatment in a single modality. These systems are very suitable especially with heterogeneous diseases, such as cancer. Nowadays, the treatment of cancer has often severe side effects to the patient’s body, which lowers his capability to fight the disease. Theoretical part of this work is focused on the properties of viral capsids, proteins and inorganic materials as drug nanocarriers. In practical part of this work, different methods for cultivation of bacteriophage are compared, both in liquid and solid medium and with different concentrations of the maltose, trough whose receptors bacteriophage is able to enter the host cell. Optimal was cultivation with 0.2% maltose in solid medium. Practical part is focused mainly on the use of bacteriophage as a nanocarrier for cytotoxic drug doxorubicin. Bacteriophage was able to encapsulate all applied concentrations of doxorubicin (0; 12.5; 25; 50; 100 and 200 g/ml), which was proved using fluorescent detection. Different times of encapsulation (2; 4; 8 and 12 hours) were studied. Optimal time was 2 hours. Encapsulation properties of bacteriophage were compared to apoferritin. Bacteriophage was able to encapsulate 4× higher concentrations of doxorubicin and its release during rinsing with water was 10× lower compared to apoferritin. This work concludes that bacteriophage is a very suitable platform for targeted drug delivery in theranostics.
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