Comparative Analysis of Osteoblastic Responses to Titanium and Alumina-Toughened Zirconia Implants: An In Vitro Study.

INTRODUCTION: Osteoblastic responses play a crucial role in the success of oral implants. Enhanced proliferation of osteoblast cells is associated with reduced cell mortality and an increase in bone regeneration. This study aims to evaluate the osteoblastic responses following oral implantation. MATERIALS AND METHODS: Osteoblast stem cells were harvested and subsequently cultivated using cell culture techniques. The osteoblastic phenotype of the extracted cells was confirmed by examining the extracellular matrix. Cell morphogenesis on functionalized biomaterial surfaces was assessed through indirect immunofluorescence staining. The cellular response was investigated in the presence of two types of implant materials: titanium (Ti) and alumina-toughened zirconia (ATZ). Cell viability and apoptosis were quantitatively assessed using MTT assays and flow cytometry, respectively. RESULTS: The survival of osteoblastic lineage cells was moderately reduced post-implantation. Viability in the Ti implant group remained at approximately 86%, while in the ATZ group, it was observed at 75%, which is considered acceptable. Moreover, there was a significant disparity in cell survival between the two implant groups (p < 0.05). Analysis of apoptosis levels at various concentrations revealed that the rate of apoptosis was 3.6% in the control group and 18.5% in the ATZ group, indicating that apoptosis or programmed cell death in the ATZ-treated group had increased nearly four-fold (p < 0.05). CONCLUSIONS: The findings of this study indicate a reduction in osteoblastic cell line survival following implant treatment, with titanium implants exhibiting superior performance in terms of cell survival. However, it was also noted that the incidence of apoptosis in osteoblast cells was significantly higher in the presence of zirconium-based implants.

Scaffold Application for Bone Regeneration with Stem Cells in Dentistry: Literature Review.

Bone tissue injuries within oral and dental contexts often present considerable challenges because traditional treatments may not be able to fully restore lost or damaged bone tissue. Novel approaches involving stem cells and targeted 3D scaffolds have been investigated in the search for workable solutions. The use of scaffolds in stem cell-assisted bone regeneration is a crucial component of tissue engineering techniques designed to overcome the drawbacks of traditional bone grafts. This study provides a detailed review of scaffold applications for bone regeneration with stem cells in dentistry. This review focuses on scaffolds and stem cells while covering a broad range of studies explaining bone regeneration in dentistry through the presentation of studies conducted in this field. The role of different stem cells in regenerative medicine is covered in great detail in the reviewed literature. These studies have addressed a wide range of subjects, including the effects of platelet concentrates during dental surgery or specific combinations, such as human dental pulp stem cells with scaffolds for animal model bone regeneration, to promote bone regeneration in animal models. Noting developments, research works consider methods to improve vascularization and explore the use of 3D-printed scaffolds, secretome applications, mesenchymal stem cells, and biomaterials for oral bone tissue regeneration. This thorough assessment outlines possible developments within these crucial regenerative dentistry cycles and provides insights and suggestions for additional study. Furthermore, alternative creative methods for regenerating bone tissue include biophysical stimuli, mechanical stimulation, magnetic field therapy, laser therapy, nutritional supplements and diet, gene therapy, and biomimetic materials. These innovative approaches offer promising avenues for future research and development in the field of bone tissue regeneration in dentistry.

Application of Scaffold-Based Drug Delivery in Oral Cancer Treatment: A Novel Approach.

This comprehensive review consolidates insights from two sources to emphasize the transformative impact of scaffold-based drug delivery systems in revolutionizing oral cancer therapy. By focusing on their core abilities to facilitate targeted and localized drug administration, these systems enhance therapeutic outcomes significantly. Scaffolds, notably those coated with anti-cancer agents such as cisplatin and paclitaxel, have proven effective in inhibiting oral cancer cell proliferation, establishing a promising avenue for site-specific drug delivery. The application of synthetic scaffolds, including Poly Ethylene Glycol (PEG) and poly(lactic-co-glycolic acid) (PLGA), and natural materials, like collagen or silk, in 3D systems has been pivotal for controlled release of therapeutic agents, executing diverse anti-cancer strategies. A key advancement in this field is the advent of smart scaffolds designed for sequential cancer therapy, which strive to refine drug delivery systems, minimizing surgical interventions, accentuating the significance of 3D scaffolds in oral cancer management. These systems, encompassing local drug-coated scaffolds and other scaffold-based platforms, hold the potential to transform oral cancer treatment through precise interventions, yielding improved patient outcomes. Local drug delivery via scaffolds can mitigate systemic side effects typically associated with chemotherapy, such as nausea, alopecia, infections, and gastrointestinal issues. Post-drug release, scaffolds foster a conducive environment for non-cancerous cell growth, adhering and proliferation, demonstrating restorative potential. Strategies for controlled and targeted drug delivery in oral cancer therapy span injectable self-assembling peptide hydrogels, nanocarriers, and dual drug-loaded nanofibrous scaffolds. These systems ensure prolonged release, synergistic effects, and tunable targeting, enhancing drug delivery efficiency while reducing systemic exposure. Smart scaffolds, capable of sequential drug release, transitioning to cell-friendly surfaces, and enabling combinatorial therapy, hold the promise to revolutionize treatment by delivering precise interventions and optimized outcomes. In essence, scaffold-based drug delivery systems, through their varied forms and functionalities, are reshaping oral cancer therapy. They target drug delivery efficiency, diminish side effects, and present avenues for personalization. Challenges like fabrication intricacy, biocompatibility, and scalability call for additional research. Nonetheless, the perspective on scaffold-based systems in oral cancer treatment is optimistic, as ongoing advancements aim to surmount current limitations and fully leverage their potential in cancer therapy.

A Narrative Review on the Promising Potential of Graphene in Vaccine Design: Evaluating the Benefits and Drawbacks of Carbon Nanoplates in Nanovaccine Production.

Graphene, a two-dimensional material consisting of a single layer of carbon atoms arranged in a honeycomb lattice, has shown great potential in various fields, including biomedicine. When it comes to vaccine development, graphene can offer several advantages due to its unique properties. Potential applications of graphene in vaccine development include improved vaccine delivery, adjuvant properties, improved vaccine stability, improved immune response, and biosensing capabilities. Although graphene offers many potential benefits in vaccine development, there are also some drawbacks and challenges associated with its use. Although graphene shows promising potential for vaccine development, overcoming the challenges and limitations associated with its use is critical to realizing its full potential in the field of immunization. Further research and development efforts are needed to overcome these drawbacks and take advantage of graphene for improved vaccine formulations. In this review, we focus on the advantages and disadvantages of graphene for vaccine development.

Success in Tooth Bud Regeneration: A Short Communication.

INTRODUCTION: Tooth caries and loss are frequent clinical diseases in dentistry. Tissue engineering is a new therapeutic choice for the complete biological regeneration of pulpal and dental tissues in regenerative dentistry. The aim of this study was to establish a protocol for in situ regeneration of a dental bud in the extracted socket. METHODS: The current study examined tooth bud regeneration with dental pulp stem cells induced by a dentin derivative signal in a rabbit's jaw. RESULT: A tooth bud was regenerated; the morphology and structure of it were typical, and it was post-Bell stage. CONCLUSIONS: In our study, a real tooth bud was formed in the post-Bell stage with complete morphologic and biological features. However, the application of this method for tooth regeneration in humans necessitates further research.

Characteristics and Cytotoxic Effects of Nano-Liposomal Paclitaxel on Gastric Cancer Cells.

OBJECTIVE: Addressing both the initial treatment response and subsequent paclitaxel resistance is a pivotal concern. Nano drug delivery, an emerging approach, presents a cutting-edge alternative to conventional chemotherapy. METHODS: This investigation synthesized PEGylated nanoparticles (NPs) via the Reverse Phase Evaporation technique for liposomal NPs. Characteristics such as zeta potential, size, drug release and polydispersity index (PDI) were subjected to evaluation. Subsequently, cytotoxicity assays were conducted on gastric cancer cells (AGS) following 24 and 48-hour incubation periods. RESULTS: In this study, the liposomal NPs had a zeta potential of -22 mV and a particle size of 285 nm. The Entrapment efficiency was determined as 41% that occurred physically. Additionally, the liposomal NPs demonstrated a high drug retention rate (39% remained after 72 hours), and they exhibited significantly increased cytotoxicity compared to the free drug, confirming their effectiveness as a suitable carrier for paclitaxel during both incubation periods (P<0.05). CONCLUSION: These findings collectively advocate the potential of liposomal NPs as promising contenders for effective nano-drug application in propelling chemotherapy forward.