Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection
Permanent URI for this collectionhttps://hdl.handle.net/11147/7148
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Article Citation - WoS: 1The Impact of Oxygen and Antimicrobial Tea Tree Oil Carrying Biomaterial on Cell Viability Under Hypoxic Conditions(Wiley, 2025) Tepeli, Dilek; Soyer, Ferda; Kehr, Nermin Seda; Soyer, Ferda; Akin, Ozlem; Kehr, Nermin Seda; 01. Izmir Institute of Technology; 04. Faculty of Science; 04.03. Department of Molecular Biology and Genetics; 04.01. Department of ChemistryTraditional wound treatment involves protecting the wound with dressing and administering antibiotics to prevent tissue infection due to bacteria. However, these methods are inadequate due to the side effects of antibiotics on healthy cells and microbial resistance to antibiotics. Therefore, new strategies involving the application of natural resources such as essential oils as antimicrobial agents in combination with biomaterials as wound dressings have been tested in the treatment of wounds. Furthermore, oxygen (O2)-releasing biomaterials have attracted great interest due to the important role of O2 in wound healing processes. However, the co-application of O2 and essential oil as antimicrobial and cell-promoting agents has not been studied. In this context, we report a novel biomaterial capable of co-delivering O2 and natural antimicrobial tea tree oil (TTO) for 15 and 5 days, respectively. The biomaterial consists of an alginate scaffold (Alg-PMOF-O) containing O2-carrying nanomaterial, laponite and TTO. In vitro bacterial experiments have shown that O2 release from Alg-PMOF-O is an additional parameter acting as an antibacterial agent to inhibit bacterial growth but is not sufficient alone to inhibit bacteria. 5 mu L of TTO in Alg-PMOF-O is necessary to suppress both E. coli and S. aureus over a 1-day incubation period. The effect of TTO and O2 alone or in combination on cell viability is examined using WST-1 and PrestoBlue assays. According to the WST-1 and PrestoBlue tests, the combined application of TTO and O2 does not show any toxic effect on fibroblast cells under normoxic conditions during the 5-day incubation period. Under hypoxic conditions, the WST-1 test shows no toxic effect after only 1 day of incubation, while the PrestoBlue test shows no toxicity under hypoxia during both 1 and 5 days of incubation. On the other hand, the combined application of TTO and O2 indicates toxic effects on cancer Malme-3M cells during both normoxic and hypoxic conditions over 1 and 5 days of incubation. This effect is confirmed by both the WST-1 and PrestoBlue tests. The overall results demonstrate that Alg-PMOF-O exhibits antibacterial activity while having a lower toxic effect on fibroblasts under hypoxic conditions, and therefore has potential for use as wound dressing.Article The Effect of Co-Delivery of Oxygen and Antibacterial Drug Gentamicin From Alginate-Based Nanocomposite Hydrogels on Bacterial Apoptosis and Cell Viability(Wiley-v C H verlag Gmbh, 2025) Tepeli, Dilek; Kehr, Nermin Seda; Tepeli, Dilek; Demirci, Eylem Kurulgan; Pehlivanoglu, Pelin; Kehr, Nermin Seda; 04.01. Department of Chemistry; 01. Izmir Institute of Technology; 04. Faculty of ScienceThere is a need to develop multifunctional biomaterials that can deliver oxygen and antibacterial drugs together for effective wound healing applications. Here, we report a novel biomaterial capable of co-delivering O2 and the antibacterial drug Gentamicin (GEN) for a period of 7 and 15 days, respectively. This biomaterial is fabricated by the synthesis of perfluorocarbon-based periodic mesoporous organosilica (PMOF) and the loading of its pores with GEN (GENPMOF). The synthesized GENPMOF is incorporated in alginate hydrogel to obtain Alg-GENPMOF with O2 and GEN co-delivery ability. Our results show that PMOF and GENPMOF have concentration-dependent toxicity on both Gram-negative E. coli and Gram-positive S. aureus bacteria. The most effective concentration of PMOF and GENPMOF (0.5 mg/mL) show little toxic effect for fibroblast cells. On the other hand, Alg-PMOF and Alg-GENPMOF prepared using this concentration require a long incubation time with E. coli to induce apoptosis. However, an incubation period of 1 day is sufficient to inhibit the growth of S. Aureus. Furthermore, Alg-PMOF and Alg-GENPMOF increase fibroblast cell viability under both normoxic and hypoxic conditions while slightly decreasing cancerous Malme-3M cell viability within 5 days of incubation.Article Citation - WoS: 7Citation - Scopus: 6Polymeric Biomaterials for Periodontal Tissue Engineering and Periodontitis(Royal Soc Chemistry, 2024) Kehr, Nermin Seda; Demir, Yagmur Damla; Vural, Sevra; Kehr, Nermin Seda; 01. Izmir Institute of Technology; 04. Faculty of Science; 04.01. Department of ChemistryThe periodontium is one of the most complex tissues in the body because its structure is formed by a hierarchical combination of soft and hard tissues. Due to its complex architecture, the treatment and regeneration of damaged periodontal tissue caused by diseases is still a challenge in biomedicine. The most common disease of the periodontium is periodontitis, which occurs when the periodontium becomes infected and inflamed as a bacterial biofilm forms in the mouth. Recently, various biocompatible biomaterials made of natural and synthetic polymers have been developed for periodontal tissue regeneration or treatment due to their superior properties such as controlled drug and bioactive molecule delivery, mimicking the 3D network of tissue, biocompatibility, antibacterial and mechanical properties. In particular, biomaterials designed for drug delivery, such as hydrogels, scaffolds, films, membranes, micro/nanoparticles and fibers, and additively manufactured biomaterials have undergone in vitro and in vivo testing to confirm their potential clinical utility in periodontal regeneration and periodontitis treatment. This review explores recent advances in the use of biomaterials for the prevention and/or treatment of periodontal regeneration and periodontitis. Specifically, it emphasizes advancements in drug/biomolecule delivery and the use of additively manufactured biomaterials for addressing periodontal issues.Article Citation - WoS: 2Citation - Scopus: 4Injectable Nanocomposite Hydrogels With Co-Delivery of Oxygen and Anticancer Drugs for Higher Cell Viability of Healthy Cells Than Cancer Cells Under Normoxic and Hypoxic Conditions(Iop Publishing Ltd, 2025) Kehr, Nermin Seda; Kehr, Nermin Seda; 04.01. Department of Chemistry; 04. Faculty of Science; 01. Izmir Institute of TechnologyInjectable nanocomposite hydrogels (NC hydrogels) have the potential to be used for minimally invasive local drug delivery. In particular, pH-sensitive injectable NC hydrogels can be used in cancer treatment to deliver high doses of anticancer drugs to the target site in cancer tissue without damaging healthy tissue. Recent studies have shown that in addition to stimuli-responsive delivery of anticancer drugs to cancer cells, oxygen delivery to the hypoxic environment of cancer tissue can lead to advanced effects, as hypoxia and an acidic pH are common characteristics of cancer tissue. However, few studies have investigated the effects of simultaneous administration of oxygen (O2) and pH-dependent anticancer drugs via injectable NC hydrogels on the viability of healthy and cancer cells under normoxic and hypoxic conditions. In this context, we describe the synthesis of injectable NC hydrogels composed of pH-responsive nanomaterials carrying oxygen and anticancer drugs. Our system provides sustained O2 release and pH-responsive sustained release of anticancer drugs for 15 and 30 d, respectively. Moreover, O2 delivery and/or simultaneous delivery of O2 and anticancer drug resulted in higher cell survival of healthy fibroblast cells than malignant Colo-818 cells under hypoxic conditions (1% O2) after 7 d of incubation.Review Citation - WoS: 13Citation - Scopus: 13Oxygen Delivery Biomaterials in Wound Healing Applications(WILEY-V C H VERLAG GMBH, 2023) Bayraktar, Sema; Kehr, Nermin Seda; Üstün, Cansu; Kehr, Nermin Seda; 04.01. Department of Chemistry; 04. Faculty of Science; 01. Izmir Institute of TechnologyOxygen (O2) delivery biomaterials have attracted great interest in the treatment of chronic wounds due to their potential applications in local and continuous O2 generation and delivery, improving cell viability until vascularization occurs, promoting structural growth of new blood vessels, simulating collagen synthesis, killing bacteria and reducing hypoxia-induced tissue damage. Therefore, different types of O2 delivery biomaterials including thin polymer films, fibers, hydrogels, or nanocomposite hydrogels have been developed to provide controlled, sufficient and long-lasting O2 to prevent hypoxia and maintain cell viability until the engineered tissue is vascularized by the host system. These biomaterials are made by various approaches, such as encapsulating O2 releasing molecules into hydrogels, polymer microspheres and 3D printed hydrogel scaffolds and adsorbing O2 carrying reagents into polymer films of fibers. In this article, different O2 generating sources such as solid inorganic peroxides, liquid peroxides, and photosynthetic microalgae, and O2 carrying perfluorocarbons and hemoglobin are presented and the applications of O2 delivery biomaterials in promoting wound healing are discussed. Furthermore, challenges encountered and future perspectives are highlighted. Oxygen delivery (O2) biomaterials have attracted great interest in the treatment of chronic wounds due to their ability to continuously deliver oxygen and support cell viability. Therefore, various O2 generating sources such as solid inorganic peroxides, liquid peroxides and photosynthetic microalgae, and O2-carrying perfluorocarbons and hemoglobin are incorporated into different biomaterial networks for wound healing applications.image