Mahmut Parmaksız scite author profile

Decellularization is the process of removing the cellular components from tissues or organs. It is a promising technology for obtaining a biomaterial with a highly preserved extracellular matrix (ECM), which may also act as a biological scaffold for tissue engineering and regenerative therapies. Decellularized products are gaining clinical importance and market space due to their ease of standardized production, constant availability for grafting and mechanical or biochemical superiority against competing clinical options, yielding clinical results ahead of the ones with autografts in some applications. Current drawbacks and limitations of traditional treatments and clinical applications can be overcome by using decellularized or acellular matrices. Several companies are leading the market with versatile acellular products designed for diverse use in the reconstruction of tissues and organs. This review describes ECM-based decellularized and acellular products that are currently in use for different branches of clinic.

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Decellularization of bovine small intestinal submucosa and its use for the healing of a critical-sized full-thickness skin defect, alone and in combination with stem cells, in a small rodent model

Parmaksız

Elçin

2015

J Tissue Eng Regen Med

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In this study, we initially described an efficient decellularization protocol for bovine-derived small intestinal submucosa (bSIS), involving freeze-thaw cycles, acid/base treatment and alcohol and buffer systems. We compared the efficacy of our protocol to some previously established ones, based on DNA content and SEM and histochemical analyses. DNA content was reduced by ~89.4%, significantly higher than compared protocols. The sulphated GAG content of the remaining interconnected fibrous structure was 5.738 ± 0.207 µg/mg (55% retained). An in vitro study was performed to evaluate whether rat bone marrow mesenchymal stem cells (MSCs) could attach and survive on bSIS membranes. Our findings revealed that MSCs can preserve their viability and proliferate on bSIS for > 2 weeks in culture. We conducted in vivo applications for the treatment of an experimental rat model of critical sized (7 cm ) full-thickness skin defect. The wound models treated with either MSCs-seeded (1.5 × 10 cells/cm ) or non-seeded bSIS membranes were completely closed by week 7 without significant differences in closure time; on the other hand, the open wound control was closed at ~47% at this time point. Immunohistopathology results revealed that the group which received MSCs-seeded bSIS had less scarring at the end of the healing process and was in further stages of appendage formation in comparison with the non-seeded bSIS group. Copyright © 2015 John Wiley & Sons, Ltd.

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Time-Resolved Fluorescence Resonance Energy Transfer [TR-FRET] Assays for Biochemical Processes

Ergin¹,

Doğan²,

Parmaksız³

et al. 2016

CPB

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Time-Resolved Fluorescence Resonance Energy Transfer (TR-FRET) is a fluorescence based technique which enables the analysis of molecular interactions in biochemical processes. Principle of TR-FRET is based on time-resolved fluorescence (TRF) measurement and fluorescence resonance energy transfer (FRET) between donor and acceptor molecules. To generate FRET signal, donor and acceptor molecules must show spectral overlap and should be in close proximity to each other and display suitable dipole orientation. The specific signal is acquired from molecules of interest via interactions of donor and acceptor molecules. TR-FRET technique is widely used for studying kinase assays, cellular signaling pathways, protein-protein interactions, DNA-protein interactions, and receptor-ligand binding. There are various propriety applications of TR-FRET. Two different sample protocols are summarized in this review.

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Decellularized bovine small intestinal submucosa-PCL/hydroxyapatite-based multilayer composite scaffold for hard tissue repair

Parmaksız

Elçin

2019

Materials Science and Engineering: C

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Magneto-sensitive decellularized bone matrix with or without low frequency-pulsed electromagnetic field exposure for the healing of a critical-size bone defect

Parmaksız

Lalegül‐Ülker

Vurat

et al. 2021

Materials Science and Engineering: C

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