Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection

Permanent URI for this collectionhttps://hdl.handle.net/11147/7148

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Author: search.filters.author.Yilmaz-Dagdeviren, Hilal Deniz

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Now showing 1 - 4 of 4
  • Article
    Enhanced Osteoconductive Properties of Quince Seed Hydrocolloid-Based Composite Scaffolds Enriched With Bioactive Glass for Bone Tissue Engineering
    (Wiley-VCH Verlag GmbH, 2025) Yilmaz-Dagdeviren, Hilal Deniz; Zheng, Kai; Boccaccini, Aldo Roberto; Arslan Yildiz, Ahu
    Bioactive composite scaffolds enhance osteoconduction and mineralization, offering potential for bone regeneration. In this study, polysaccharide-based Quince Seed Hydrocolloid (QSH) was combined with Gelatin (Gel), mesoporous bioactive glass nanoparticles (MBGNs), and 45S5 bioactive glass (BG) to fabricate osteoconductive scaffolds. QSH/Gel/BG and QSH/Gel/MBGN composites were characterized for chemical composition, mechanical behavior, and in vitro bioactivity. FTIR and SEM-elemental mapping confirmed homogeneous bioactive glass incorporation. BET analysis revealed a >3-fold increase in surface area for MBGN-containing scaffolds compared to BG and pristine QSH/Gel samples, attributed to the nanoscale mesoporous structure of MBGNs. Swelling tests showed a hydrophilic nature in all scaffolds, with MBGN composites exhibiting the highest swelling ratio (2094 +/- 571%), nearly twice that of BG composites (1105 +/- 56%). Compression tests indicated similar elastic moduli for MBGN and BG containing scaffolds (2330 and 2140 Pa). Human osteosarcoma cell cultures (28 days) demonstrated high viability (>70%) and osteoconductive response in all composites. Alizarin Red staining and SEM mapping revealed greater mineral accumulation in MBGN-containing scaffolds (Ca/P: 2.53). Overall, both composites supported a 3D osteoconductive microenvironment, while MBGN scaffolds exhibited superior long-term cell viability and mineralization potential, emphasizing their suitability for bone tissue engineering applications.
  • Article
    Citation - WoS: 1
    From Chemistry to Clinic: Polysaccharide-Bioceramic Composites for Tissue Engineering Applications
    (Mary Ann Liebert, Inc, 2025) Yakubogullari, Nilgun; Yilmaz-Dagdeviren, Hilal Deniz; Arslan-Yildiz, Ahu
    Composite scaffolds combining polysaccharides and bioceramics represent next-generation scaffolds extensively investigated in tissue engineering (TE) and biomedical applications. Polysaccharides such as chitosan, hyaluronic acid, and pectin mimic the extracellular matrix components with their tunable physicochemical properties, enabling a favorable microenvironment for cell adhesion, proliferation, and cell-matrix interactions. On the other hand, bioceramics, including calcium phosphate, hydroxyapatite, and bioactive glasses, enhance the mechanical properties of the material and offer structural integrity and osteoconductive properties. While they have generally been preferred to be used in bone TE and dental applications, various studies have also demonstrated their potential in cartilage regeneration, wound healing, and broader biomedical applications. Recent advancements in material design and scaffold fabrication techniques, particularly 3D printing and electrospinning, have provided precise engineering of materials and fabrication of scaffolds for desirable mechanical properties and biological performance. These innovations foster the development of patient-specific scaffolds, thereby paving the way for applications in personalized medicine. This review critically summarizes alternative polysaccharides, bioceramics, and composite materials used in TE and biomedical applications. It also highlights advanced fabrication strategies and finally explores the translational potential of these biocomposites. By integrating emerging technologies, this review aims to provide alternative and sustainable materials for the development of next-generation scaffolds that meet clinical needs.Impact Statement This study introduces polysaccharide-bioceramic composites with enhanced mechanical and biological properties for tissue engineering. Beyond bone and dental repair, their applications increasingly extend to wound healing, cartilage, cardiac, and muscle regeneration with drug delivery, angiogenesis, and neurogenesis. By mimicking the native extracellular matrix, these composites support cell growth and tissue regeneration, offering a versatile platform for advanced regenerative therapies.
  • Article
    Beyond Traditional Dentistry: How Organoids and Next-Gen Hydrogels Are Redesigning Dental Tissue Regeneration
    (Elsevier, 2026) Yilmaz-Dagdeviren, Hilal Deniz; Arslan, Yavuz Emre
    Dental tissue regeneration has advanced rapidly with the development of bioengineered hydrogels and organoid technologies. In this review, multifunctional hydrogels are examined as biomimetic platforms with osteoinductive, adhesive, angiogenic, antimicrobial, and immunomodulatory properties tailored to enamel, dentin-pulp complex, periodontal ligament, and alveolar bone repair. Incorporation of bioactive molecules, including growth factors, bioceramics, antioxidants, and immune-modulating agents, has been reported to enhance tissue-specific regeneration while mitigating infection and inflammation. Stimuli-responsive designs have been utilized to enable spatiotemporally controlled delivery and degradation. Immunomodulatory hydrogels also have been shown to direct macrophage polarization, regulate T-cell infiltration, and promote matrix remodeling. Furthermore, organoid models supported by hydrogels have been employed to replicate dental tissue architecture, guide lineage-specific differentiation, and provide reproducible, physiologically relevant platforms for drug screening and developmental studies. Emerging strategies such as microfluidic organoid-on-chip systems and mechanically stimulated cultures are noted for their potential to provide more physiologically relevant models. Early clinical studies involving hydrogel-based scaffolds and stem cell constructs are discussed, indicating growing translational potential. Overall, these developments highlights that how advanced hydrogels and organoid systems can contribute to a shift from conventional restorative methods toward tissue engineering-based regenerative therapies.
  • Article
    Citation - WoS: 4
    Citation - Scopus: 3
    Unveiling Bone and Dental Regeneration Potential of Quince Seed Mucilage-Nanohydroxyapatite Scaffolds in Rabbit Mandibles
    (Wiley, 2025) Genc, Cigdem Cetin; Yilmaz-Dagdeviren, Hilal Deniz; Deniz, Yesim; Derkus, Burak; Degirmenci, Alpin; Arslan, Yavuz Emre
    Donor-side morbidity of autografting for maxillofacial region defect regeneration has directed attention to bioengineered scaffolds. Composite scaffolds that mimic the bone extracellular matrix (ECM) are the potential candidates for defect reconstruction. Herein, a plant-based regenerative hydrogel, quince seed mucilage (QSM), was enriched with the nanohydroxyapatite (nHAp) particles to construct composite scaffolds (QSM/nHAp). The emerging scaffold is able to induce cellular spheroid formation and regenerate the critical-sized bilateral mandibular defects in rabbits. The macroscopic observations, histochemical (HC) and immunohistochemical (IHC) stainings, mu-computer tomography (CT) scanning, quantitative real time-polymerase chain reaction (qRT-PCR) analyses, and scanning electron microscopy (SEM) imaging revealed that all QSM/nHAp scaffolds were swelled with host blood, filled the whole cavity, and sustained cellular infiltration without adverse reactions. The gradual biodegradation profile of the scaffolds improved bone regeneration by releasing nHAp particles from the scaffold. Strikingly, co-development of dental and bone regeneration was observed for all QSM/nHAp groups beginning after day 21. Moreover, QSM/nHAp scaffolds induced expression (> 2-fold) of bone and dental-related gene and protein expressions at the grafted area and sustained a proper platform for maxillofacial remodeling. Therefore, we strongly believe that such biocompatible plant-based constructs, compared with conventional medical devices used in maxillofacial surgery, could support and induce simultaneous bone and dental regeneration due to the intrinsic dynamics of the material.