Utku Devamoglu scite author profile

The bioengineerined and whole matured human brain organoids stand as highly valuable three-dimensional in vitro brain-mimetic models to recapitulate in vivo brain development, neurodevelopmental and neurodegenerative diseases. Various instructive signals affecting multiple biological processes including morphogenesis, developmental stages, cell fate transitions, cell migration, stem cell function and immune responses have been employed for generation of physiologically functional cerebral organoids. However, the current approaches for maturation require improvement for highly harvestable and functional cerebral organoids with reduced batch-to-batch variabilities. Here, we demonstrate two different engineering approaches, the rotating cell culture system (RCCS) microgravity bioreactor and a newly designed microfluidic platform (µ-platform) to improve harvestability, reproducibility and the survival of high-quality cerebral organoids and compare with those of traditional spinner and shaker systems. RCCS and µ-platform organoids have reached ideal sizes, approximately 95% harvestability, prolonged culture time with Ki-67 + /CD31 + /β-catenin+ proliferative, adhesive and endothelial-like cells and exhibited enriched cellular diversity (abundant neural/glial/ endothelial cell population), structural brain morphogenesis, further functional neuronal identities (glutamate secreting glutamatergic, GABAergic and hippocampal neurons) and synaptogenesis (presynaptic-postsynaptic interaction) during whole human brain development. Both organoids expressed CD11b + /IBA1 + microglia and MBP + /OLIG2 + oligodendrocytes at high levels as of day 60. RCCS and µ-platform organoids showing high levels of physiological fidelity a high level of physiological fidelity can serve as functional preclinical models to test new therapeutic regimens for neurological diseases and benefit from multiplexing.

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Development of an Integrated Optical Sensor for Determination of β-Hydroxybutyrate Within the Microplatform

Devamoglu

Duman

Saygili

et al. 2021

Appl Biochem Biotechnol

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A drug-responsive multicellular human spheroid model to recapitulate drug-induced pulmonary fibrosis

Saygili¹,

Devamoglu²,

Goker-Bagca³

et al. 2022

Biomed. Mater.

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Associated with a high mortality rate, pulmonary fibrosis (PF) is the end stage of several interstitial lung diseases. Although many factors are linked to PF progression, initiation of the fibrotic process remains to be studied. Current research focused on generating new strategies to gain a better understanding of the underlying disease mechanism as the animal models remain insufficient to reflect human physiology. Herein, to account complex cellular interactions within the fibrotic tissue, a multicellular spheroid (MCS) model where human bronchial epithelial cells incorporated with human lung fibroblasts was generated and treated with bleomycin (BLM) to emulate drug-induced PF. Recapitulating the epithelial-interstitial microenvironment, the findings successfully reflected the PF disease, where excessive alpha smooth muscle actin (α-SMA) and collagen type I secretion were noted along with the morphological changes in response to BLM. Moreover, increased levels of fibrotic linked COL13A1, MMP2, WNT3 and decreased expression level of CDH1 provide evidence for the model reliability on fibrosis modelling. Subsequent administration of the FDA approved nintedanib and pirfenidone anti-fibrotic drugs proved the drug-responsiveness of the model.

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An optical pH-sensor integrated microfluidic platform multilayered with bacterial cellulose and gelatin methacrylate to mimic drug-induced lung injury

Saygili

Devamoglu

Bayır

et al. 2023

Journal of Industrial and Engineering Chemistry

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Bleomycin-induced in vitro 3D spheroid model to emulate pulmonary fibrosis

Saygili

Devamoglu

Goker-Bagca

et al. 2022

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Utku Devamoglu

Spatio-temporal dynamics enhance cellular diversity, neuronal function and further maturation of human cerebral organoids

Development of an Integrated Optical Sensor for Determination of β-Hydroxybutyrate Within the Microplatform

A drug-responsive multicellular human spheroid model to recapitulate drug-induced pulmonary fibrosis

An optical pH-sensor integrated microfluidic platform multilayered with bacterial cellulose and gelatin methacrylate to mimic drug-induced lung injury

Bleomycin-induced in vitro 3D spheroid model to emulate pulmonary fibrosis

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