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Öğe A bi-layer electrospun polyurethane/silicone membrane scaffold: drug delivery and cytotoxicity studies(Indian Acad Sciences, 2023) Mohsenzadeh, Elham; Demir, Didem; Ceylan, Seda; Khenoussi, Nabyl; Schacher, Laurence; Adolphe, Dominique; Bolgen, NimetIn this study, a bi-layer scaffold combining polyurethane nanofibrous and silicone membrane layers was produced. Chemical, morphological and physical properties of the scaffolds were determined by Fourier-transform infrared spectroscopy, scanning electron microscope (SEM) and Brunauer-Emmett-Teller analyses, respectively. The surface properties were examined with the contact angle test. To evaluate the encapsulation and release behaviour of the scaffolds Rhodamine B and Nile red were used as model drugs. Further, the cytotoxicity and cell proliferation investigations were carried out using mouse embryonic fibroblasts cell lines. 3-(4,5-dimethylthiazoyl-2-yl)-2,5-diphenyltetrazolium bromide assay and SEM were used to investigate the cell viability and cell-scaffold interactions, respectively. The results of the study were evaluated in order to develop a bimodal drug release system that has the potential to be used in tissue engineering applications.Öğe A new application of avocado oil to enrich the biological activities of polycaprolactone membranes for tissue engineering(Wiley, 2024) Yurtsever, Merve Capkin; Aydogan, Selin; Iyigundogdu, Zeynep; Comertpay, Alican; Demir, Didem; Ceylan, SedaThe metabolites synthesized by plants to protect themselves serves as natural antimicrobial agents used in biomaterials. In this study, avocado oil (AO), was incorporated as a plant source and natural antimicrobial agent into polycaprolactone (PCL) membranes. The effects of varying AO ratios (25, 50, and 100 wt%.-PCL@25AO, PCL@50AO, PCL@100AO) on PCL membrane morphology, chemical structure, wettability, antimicrobial activity, and cell viabilities were investigated. It was demonstrated that the AO acts as a pore-forming agent in solvent-casted membranes. Young's modulus of the membranes varied between 602.68 and 31.92 MPa and more flexible membranes were obtained with increasing AO content. Inhibition zones of AO were recorded between 7.86 and 13.97 mm against clinically relevant microbial strains including bacteria, yeast, and fungi. Antimicrobial activity of AO was retained in PCL membranes at all ratios. Resazurin assay indicated that PCL@25AO membranes were cytocompatible with mouse fibroblast cells (L929 cell line) on day 6 showing 72.4% cell viability with respect to neat PCL membranes. Viability results were supported by scanning electron microscopy images and DAPI staining. The overall results of this study highlight the potential of PCL@25AO membranes as a biomaterial with antimicrobial properties, cytocompatibility, and mechanical strength suitable for various biomedical applications. imageÖğe Antimicrobial activity enhancement of PVA/chitosan films with the additive of CZTS quantum dots(Springer Link, 2023) Ceylan, Seda; Küçükosman, Rıdvan; Yurt, Fatma; Özel, Derya; Öztürk, İsmail; Demir, Didem; Ocakoğlu, KasımThe wound environment is a breeding ground for pathogens, and traditional wound dressing materials lack antibacterial properties. In this work, we aimed to develop PVA/chitosan (P/C)-based wound dressing scaffolds with anti-infective properties using Cu2ZnSnS4 quantum dots (CZTS QDs) to prevent infections in the wound. CZTS quantum dots were prepared by a simple hydrothermal process and characterized using appropriate techniques such as TEM, XRD, FTIR spectrum, and UV-Vis absorption spectroscopy. CZTS QDs were subsequently loaded at different concentrations onto PVA/chitosan membranes (0, 1.6, 2.5 and 3.3% w/w, based on the total polymer quantity). The chemical structure, contact angle and mechanical properties of the membranes were analyzed, and their antimicrobial activities and cell viability were also investigated. The cytocompatibility of the membranes and cell morphology was investigated using a 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay and SEM. Based on studies on the interactions between membranes and cells, it was determined that incorporation of CZTS QDs into the membrane did not cause toxicity. To the best of our knowledge, this is the first report on loading CZTS QDs into membranes for tissue engineering applications, and the overall findings suggest that CZTS QDs-integrated membranes might have potentially appealing uses as antimicrobial films for wound healing.Öğe Assessment of chitosan:gum tragacanth cryogels for tissue engineering applications(Wiley, 2022) Demir, Didem; Ugurlu, Muge Asik; Ceylan, Seda; Sakim, Burcu; Genc, Rukan; Bolgen, NimetGum tragacanth is one of the most widely used natural gums in food, medicine, cosmetics and personal care products, and its use as polysaccharide-based scaffolds in tissue engineering applications has attracted great attention in recent years. The fabrication of pure gum tragacanth as a scaffold poses many challenges because of the high viscosity, poor mechanical properties and repulsive interaction between the polyanions. To overcome these, facilitate the formation of scaffolds and improve their final properties, chitosan and gum tragacanth were used together as natural, biocompatible and biodegradable polysaccharides. The scaffolds based on chitosan and gum tragacanth were successfully fabricated through cryotropic gelation and were characterized using different chemical, morphological, mechanical and biocompatibility analyses. All cryogel scaffolds exhibited a porous structure with an average diameter of 96.56-30.21 mu m, exhibiting high liquid absorption capacity, appropriate mechanical stability and controlled degradation behavior. According to the biocompatibility results, mouse embryonic fibroblast cells adhered well to the scaffolds and achieved high viability. The results are also discussed in the light of their potential usefulness as a scaffold for tissue engineering applications. (c) 2022 Society of Industrial Chemistry.Öğe Biologically active sodium pentaborate pentahydrate and Hypericum perforatum oil loaded polyvinyl alcohol: chitosan membranes(Elsevier, 2024) Oztas, Necla; Kara, Eray; Demir, Didem; Yetkin, Derya; Ceylan, Seda; Iyiguendogdu, ZeynepIn this study, sodium pentaborate pentahydrate (NaB) and Hypericum perforatum (HP) oil were incorporated into polyvinyl alcohol (PVA) and chitosan (CH) polymer blend to obtain membranes by solution casting method. In order to see the synergistic effects of NaB and HP oil on the biological and physical properties of the membranes NaB and HP oil were incorporated into membrane matrix in different ratios. Fourier-transform infrared spectroscopy (FTIR) results showed that no significant bond formation between the bioactive components and the PVA:CH matrix. According to mechanical test results, Young's Modulus and elongation at break decreased from 426 MPa to 346 MPa and 52.23 % to 15.11 % for neat PVA:CH membranes and NaB and HP oil incorporated PVA:CH (PVA:CH@35NaB:HP) membranes, respectively. Antimicrobial activity tests have shown the membranes were over 99 % effective against Escherichia coli, Staphylococcus aureus, and Candida albicans, underlining their potential for infection control. Cytocompatibility assay performed with Human Dermal Fibroblast (HDFa) cells highlight the biocompatibility of the membranes, revealing 74.84 % cell viability after 72 h. The properties of NaB and HP oil doped PVA:CH based membranes obtained from these experiments reveal the promise of a versatile membrane for applications in wound healing, tissue engineering and other biomedical fields.Öğe Chitosan based injectable cryospheres as a potential biopolymeric carrier for drug delivery systems: Characterization, biocompatibility and drug release(Elsevier, 2024) Demir, Didem; Ceylan, Seda; Bolgen, NimetThree-dimensional scaffolds with the right design to support cell metabolism and the right physico-chemical, mechanical, and biological qualities have become more interesting for tissue engineering because of the complexity and diversity of the tissues involved. Moreover, three-dimensional scaffolds with tuneable drug delivery capabilities have drawn more attention in the field of soft tissue engineering. In this research, chitosanbased microspheres (called cryospheres) were fabricated in spherical shapes micron-sized with highly interconnected porous structures as a result of combining emulsification and cryogelation methods. The characterization of cryospheres was evaluated using morphological, physicochemical, and biological analyses. According to the results of the in vitro and in vivo biocompatibility investigation, the microspheres had no toxic effects on cell survival, and they even enhanced cell viability at the implantation site when compared to the control group. After the cryospheres were characterized, research was done on drug loading, drug release, and release processes using two distinct dyes (Nile Red: NR and Rhodamine-B: RB) in simulated body fluids (simulated intestinal, stomach, and tear fluids). The results showed that the maximum drug loading capacities for RB and NR were 89.32 +/- 1.57 % and 61.51 +/- 0.70 %, respectively. This study contributed to the development of minimally invasive biomaterials that have the potential to provide both drug release and tissue formation/regeneration at damaged implantation sites by carrying not only drugs but also active substances such as hormones/growth factors that will trigger new tissue formation.Öğe Composite Cryogels for Drug Delivery Applications: A Preliminary Study with Dye as a Model Drug(2023) Demir, Didem; Ceylan, Seda; Bolgen, NimetCryogels are suitable candidates to be used as drug release systems due to their interconnected pore structures, high surface areas, high liquid absorption capacities, and elasticity. With this purpose, we aimed to produce a cryogel structure to be used in drug release applications with the approach of tissue engineering. As biodegradable and biocompatible polymers chitosan and gelation were selected. The cryogels were fabricated using the combination of these polymers in the presence of glutaraldehyde under cryogenic conditions. The produced optimum gel scaffold was first characterized using FTIR, SEM, porosity, swelling ability, and degradation analyses. Successfully crosslinked gels exhibited an interconnected pore structure with an average pore diameter of 52.95 µm. As a result of the examination of the time-dependent weight change, it was also revealed that the cryogels have a liquid absorption capacity of about 500 times their dry weight and are biodegradable. The mainly characterized cryogel sample was evaluated for potential drug loading and release applications using methyl orange (MO) as a model drug. Gels, which swell in a short time, absorb the dye quickly and the cumulative release of the dye indicates that the gels are suitable for extended-release systems.Öğe Development of antimicrobial nanocomposite scaffolds via loading CZTSe quantum dots for wound dressing applications(Iop Publishing Ltd, 2022) Ceylan, Seda; Sert, Buse; Yurt, Fatma; Tuncel, Ayca; Ozturk, Ismail; Demir, Didem; Ocakoglu, KasimThe antimicrobial properties of scaffolds designed for use in wound healing are accepted as an important factor in the healing process to accelerate the wound healing process without causing inflammation. For this purpose, chitosan-polyvinyl alcohol composite membranes loaded with Cu2ZnSnSe4 quantum dots (CZTSe QDs) as an antibacterial and cytocompatible biomaterial to regulate the wound healing process were produced. CZTSe QDs particles were synthesized under hydrothermal conditions. Polymer-based nanocomposites with different concentrations of the synthesized nanoparticles were produced by the solvent casting method. After detailed physicochemical and morphological characterizations of CZTSe QDs and composite membranes, antibacterial activities and cell viability were extensively investigated against gram-positive and gram-negative bacterial and yeast strains, and L929 mouse fibroblast cells lines, respectively. The results show that the preparation of composite scaffolds at a QDs concentration of 3.3% by weight has the best antimicrobial activity. Composite scaffold membranes, which can be obtained as a result of an easy production process, are thought to have great potential applications in tissue engineering as wound dressing material due to their high mechanical properties, wettability, strong antibacterial properties and non-toxicity.Öğe Electrospun Composite Nanofibers Based on Poly (epsilon-Caprolactone) and Styrax Liquidus (Liquidambar orientalis Miller) as a Wound Dressing: Preparation, Characterization, Biological and Cytocompatibility Results(Springer, 2022) Demir, Didem; Ozdemir, Sadin; Ceylan, Seda; Yalcin, M. Serkan; Sakim, Burcu; Bolgen, NimetIn this study, styrax liquidus (sweet gum balsam) extracted from Liquidambar orientalis Mill. incorporated PCL fibrous scaffolds were prepared using the electrospinning method. The effects of the styrax liquidus content on the prepared scaffolds were investigated using different physico-chemical and morphological analyses. Then, the styrax-loaded nanofibers were examined for their antioxidant activity, anti-biofilm, metal chelating, antimicrobial and DNA cleavage properties. The results obtained from these studies showed that the nanofibers exhibited effective biological activity depending on the weight ratio of the styrax liquidus. In light of the data obtained from the characterization and biological studies, a sample with high ratio of balsam was built for determining the cytocompatibility analysis in vitro. The cytotoxicity studies of the selected membrane were conducted using mouse embryonic fibroblast cells. The fibrous scaffolds lead to increase the cell number as a result of high viability. According to the results, we propose a novel biocompatible electrospun hybrid scaffold with antioxidant and antimicrobial properties that can be used as wound healing material for potential tissue engineering applications.Öğe Imparting of Nearly Superparamagnetic Properties to Cryogel Scaffolds With Mesoporous MNPs for Magneto-Sensitive Tissue Engineering Strategies(Wiley, 2024) Demir, Didem; Ulusal, Fatma; Ulusal, Hasan; Ceylan, Seda; Dagli, Sibel; Ozdemir, Nalan; Tarakcioglu, MehmetThis work reports the assembly of mesoporous iron oxide nanoparticles (meso-MNPs) with cryogel scaffolds composed of chitosan and gelatin. Meso-MNPs with a particle size ranging from 2 and 50 nm, a surface area of 140.52 m2 g-1, and a pore volume of 0.27 cm3 g-1 were synthesized on a porous SiO2 template in the presence of PEG 6000 followed by leaching of SiO2. Different ratios of meso-MNPs were successfully incorporated into chitosan:gelatin cryogels up to an amount equivalent to the entire amount of polymer. The morphological structure and physicochemical properties of the cryogels were directly affected by the amount of MNPs. VSM curves showed that all composite cryogels could be magnetized by applying a magnetic field. In the context of the safety of magnetic cryogel scaffolds for use in biomedicine, it is important to note that all values are below the exposure limit for static magnetic fields, and according to cytotoxicity data, scaffolds containing meso-MNPs showed nontoxicity with cell viability ranging from 150% to 275%. In addition, microbial analysis with gram-negative and gram-positive bacteria showed that the scaffolds exhibited activity against these bacteria. imageÖğe Optimized Peppermint Essential Oil Microcapsules Loaded into Gelatin-Based Cryogels with Enhanced Antimicrobial Activity(Mdpi, 2023) Demir, Didem; Goksen, Gulden; Ceylan, Seda; Trif, Monica; Rusu, Alexandru VasileIn this study, chitosan (Chi) was used to microencapsulate peppermint essential oil (PEO). A novel gelatin-based cryogel loaded with PEO microcapsules was further developed and characterized for potential applications. Four different cryogel systems were designed, and the morphological, molecular, physical and antibacterial properties were investigated. Additionally, the antimicrobial properties of PEO, alone and microcapsulated, incorporated into the cryogel network were evaluated. The observed gel structure of cryogels exhibited a highly porous morphology in the microcapsules. The highest values of the equilibrium swelling ratio were acquired for the GelCryo-ChiCap and GelCryo-PEO@ChiCap samples. The contact angle GelCryo-PEO@ChiCap sample was lower than the control (GelCryo) due to the water repelling of the essential oil. It has been found that the incorporation of encapsulated PEO into the cryogels would be more advantageous compared to its direct addition. Moreover, GelCryo-PEO@ChiCap cryogels showed the strongest antibacterial activities, especially against Staphylococcus aureus (Gram-positive bacteria) and Escherichia coli (Gram-negative bacteria). The system that was developed showed promising results, indicating an improved antibacterial efficacy and enhanced structural properties due to the presence of microcapsules. These findings suggest that the system may be an appropriate candidate for various applications, including, but not limited to, drug release, tissue engineering, and food packaging. Finally, this system demonstrates a strategy to stabilize the releasing of the volatile compounds for creating successful results.Öğe Polysaccharides from shell waste of shellfish and their applications in the cosmeceutical industry: A review(Elsevier, 2024) Nirmal, Nilesh; Demir, Didem; Ceylan, Seda; Ahmad, Sameer; Goksen, Gulden; Koirala, Pankaj; Bono, GioacchinoShell waste from shellfish processing contains valuable natural polysaccharides, including sulfated polysaccharides, acidic polysaccharides, glycosaminoglycans, chitin and their derivatives. These shellfish wastederived polysaccharides have numerous functional and biological properties that can be applied in various industries, including the cosmeceutical industry. In keeping with global sustainability and green industry trends, the cosmeceuticals industry is transitioning from petrochemical-based ingredients to natural substitutes. In this context, shell waste-derived polysaccharides and their derivatives can play a major role as natural substitutes for petroleum-based components in various cosmeceutical skincare, hair care, oral care and body care products. This review focuses on the presence of polysaccharides and their derivatives in shell waste and discusses their various cosmeceutical applications in skin care, hair care, sun care, oral care and body care products. This indicates that shell waste utilization will help create a circular economy in which extracted polysaccharides are used to produce green cosmeceutical products.Öğe Polyvinyl alcohol: Starch based membrane scaffolds for tissue transparency requirements: Fabrication, characterization and cytotoxicity studies(Elsevier B.V., 2024) Ceylan, Seda; Demir, DidemIn this study, the characterization and cytocompatibility of polyvinyl alcohol:starch (PVA:ST) based membrane tissue scaffolds developed for tissue transparency requirements in tissue engineering applications were evaluated in the presence of sodium dodecyl sulphate (SDS). In this context, two different amounts of SDS were added to the polymer structure of transparent membrane scaffolds to roughen the surfaces of PVA:ST membranes and to promote cell adhesion. In the light of this aim, three different types of membranes were created: A constant PVA:ST ratio of 9:1 (wt:wt) was used as a control and varying amounts of SDS (2 and 4 wt% of the total polymer amount) were added to the polymer solutions. Membrane tissue scaffolds were formed by freeze-drying method. Scaffold properties such as morphology, transparency, water absorption, chemical structure and cytocompatibility were investigated. In terms of physicochemical properties, it was observed that with the addition of SDS, the membranes had a rougher surface while retaining water retention and transparency. In cytotoxicity studies, the membranes were found to be non-cytotoxic and promoted cell proliferation as assessed by MTT assay. Furthermore, the PVA:ST membrane scaffold with 4% SDS added was able to promote the attachment, migration and proliferation of Mouse Embryonic Fibroblasts (MEFs) more than the control group. Overall, the results indicate that SDS-added PVA:ST scaffold membranes are suitable for human corneal stromal regeneration, wound dressing material and neural tissue engineering applications. © 2024 The Authors
