Phd Degree / Doktora

Permanent URI for this collectionhttps://hdl.handle.net/11147/2869

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Author: search.filters.author.Erdal Bağrıyanık, Şerife EsraSubject: search.filters.subject.Cancer cells

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  • Doctoral Thesis
    Multi-organ-on-a-chip for cancer drug testing
    (Izmir Institute of Technology, 2022) Mohammed, Abdurehman Eshete; Pesen Okvur, Devrim; Erdal Bağrıyanık, Şerife Esra
    Cancer is one of the devastating and fatal severe diseases worldwide that kills millions of people every year. Globally cancer is the second leading cause of death after cardiovascular disease and was responsible for 10 million deaths in 2020. Breast cancer is one of the predominant cancers in females and is the cause of more than half a million females death each year. The primary cause of cancer patients' death is cancer metastasis. Triple-negative BREAST cancer (TNBC) is mainly treated by chemotherapy. In the current drug discovery and development processes, the efficacy and toxicity of chemotherapies identify using 2D and animal testing but not simulating the in vivo microenvironment. This research designed multiorgan-on-a-chip with liver and breast cell line compartments, and drug PKPD modeling was done by Monolix software. In this research, a unique multiorgan-on-a-chip (MOC) was designed and fabricated, generated experimental PK and PD data using the new MOC device, and modeled and simulated PK and PD using the experimental data. To conclude, we developed a new multiorgan-on-a-chip (MOC) platform used for PKPD modeling and PKPD simulations that would be helpful in the preclinical research to evaluate the effectiveness and toxicity of drugs. In the future, using calceinAM, a fluorescent cell viability dye, generating PD data for each cell type and determining side effects of doxorubicin in each cell line is essential. Adding more organs to the MOC, such as heart tissue, to study the cytotoxicity of doxorubicin in different organs gives more efficient data for PKPD modeling.
  • Doctoral Thesis
    Invetigation of Mechanical Vibration Effects on Breast Cancer Cells
    (Izmir Institute of Technology, 2018) Olçum Uzan, Melis; Özçivici, Engin; Erdal Bağrıyanık, Şerife Esra
    In this doctoral dissertation, low magnitude mechanical signals (LMMS, <1g in magnitude) were used to test the stress shielding model hypothesized on breast cancer cells. The hypothesis was that the breast cancer cells will be sensitive to mechanical vibrations and will respond to these vibrations. It was similarly used to test the adipogenic differentiation of Lamin A/C knockdown (by siRNA) bone marrow-derived mesenchymal stem cells. It is known that Lamin A/C plays a role in the nucleus and intracellular organization in these cells and affects gene expression by chromatin regulation. The hypothesis was that if these cells are deprived of the organization for the nucleus, they will be sensitive to mechanical vibrations, but that the mechanical vibrations cannot restore the effect of lamin A/C on gene regulation. We investigated the effects of high-frequency low-density mechanical signals (LMMS) on cell proliferation, apoptosis, cell cycle, protein expression, differentiation, cytoskeleton and phenotypic change processes. According to findings, LMMS caused cell cycle arrest in the aggressive type of breast cancer cells and slowed proliferation. Non-aggressive breast cancer has not responded to LMMS. In mammary epithelial cells, LMMS has not shown an effect that triggers proliferation. In the mesenchymal stem cell model, Lamin A/C knockdown accelerated adipogenic differentiation. Although LMMS in these cells decreased the rate of adipogenic differentiation, it was not sufficient to restore the baseline.