Nanoarchitectonics of Fullerene Based Enzyme Mimics for Osteogenic Induction of Stem Cells

Bioinspired Multi-Layer Biopolymer-Based Dental Implant Coating for Enhanced Osseointegration

The major drawbacks of metal-based implants are weak osseointegration and post-operational infections. These limitations restrict the long-term use of implants that may cause severe tissue damage and replacement of the implant. Recent strategies to enhance the osseointegration process require an elaborate fabrication process and suffer from post-operative complications. To address the current challenges taking inspiration from the extracellular matrix (ECM), the current study is designed to establish enhanced osseointegration with lowered risk of infection. Natural biopolymer pectin, peptide amphiphiles, and enzyme-mimicking fullerene moieties are governed to present an ECM-like environment around the implant surfaces. This multifunctional approach promotes osseointegration via inducing biomineralization and osteoblast differentiation. Application of the biopolymer-based composite to the metal surfaces significantly enhances cellular attachment, supports the mineral deposition, and upregulates osteoblast-specific gene expression. In addition to the osteoinductive properties of the constructed layers, the inherent antimicrobial properties of multilayer coating are also used to prevent infection possibility. The reported biopolymer-artificial enzyme composite demonstrates antimicrobial activity against Escherichia coli and Bacillus subtilis as a multifunctional surface coating.

Pectin hydrogels crosslinked via peptide nanofibers for designing cell-instructive dynamic microenvironment

As has been reported many times before, the two-dimensional (2D) cell culture techniques used today are far from modeling native tissue environments. Therefore, tremendous amounts of effort were devoted to developing three-dimensional (3D) cell cultures with high tissue resemblance. Whereas, these techniques suffer from elaborate preparation processes, batch-to-batch variations, unnatural components, chemical modifications, side products, static culture conditions, or complex reactor systems. To overcome these limitations, we report an undocumented one-step strategy to create a tissue-like 3D cell culture method by mimicking the extracellular matrix (ECM) microenvironment with rapid, non-covalent cross-linking of biopolymer-peptide complex and recently designed non-static cell culturing modules. In the current method, we prepared a very facile and tailorable ECM-like network by using easily attainable building blocks without the need for chemical modifications and possible undesirable/noncontrollable responses resulting from these unnatural modifications. Cells encapsulated in this new biopolymer mesh were located in the swimming culture module to mimic not only the microenvironment but also the non-static physical environment of the ECM. The feasibility of this method was analyzed on a bio-regeneration model; SaOS-2 cells cultured in the current 3D system induced improved osteogenic regeneration. The ECM resemblance of the method was also exhibited by histological sections of the cells incubated in the recent gel formulation. Furthermore, different cell types derived from various tissues could be cultured in our recent ECM model, which could be very practicable for personalized test models for future applications as a replacement for animal studies.