Intact
and stable bone reconstruction is ideal for the treatment
of periodontal bone destruction but remains challenging. In research,
biomaterials are used to encapsulate stem cells or bioactive factors
for periodontal bone regeneration, but, to the best of our knowledge,
using a supramolecular hydrogel to encapsulate bioactive factors for
their sustained release in bone defect areas to promote periodontal
bone regeneration has not been reported. Herein, we used a well-studied
hydrogelator, NapFFY, to coassemble with SDF-1 and BMP-2
to prepare a supramolecular hydrogel, SDF-1/BMP-2/NapFFY. In vitro and in vivo results
indicated that these two bioactive factors were ideally, synchronously,
and continuously released from the hydrogel to effectively promote
the regeneration and reconstruction of periodontal bone tissues. Specifically,
after the bone defect areas were treated with our SDF-1/BMP-2/NapFFY hydrogel for 8 weeks using maxillary critical-sized periodontal
bone defect model rats, a superior bone regeneration rate of 56.7%
bone volume fraction was achieved in these rats. We anticipate that
our SDF-1/BMP-2/NapFFY hydrogel could replace bone transplantation
in the clinic for the repair of periodontal bone defects and periodontally
accelerated osteogenic orthodontics in the near future.
Age related defect of the osteogenic differentiation of mesenchymal stem cells (MSCs) plays a key role in osteoporosis. Mechanical loading is one of the most important physical stimuli for osteoblast differentiation. Here, we compared the osteogenic potential of MSCs from young and adult rats under three rounds of 2 h of cyclic stretch of 2.5% elongation at 1 Hz on 3 consecutive days. Cyclic stretch induced a significant osteogenic differentiation of MSCs from young rats, while a compromised osteogenesis in MSCs from the adult rats. Accordingly, there were much more reactive oxygen species (ROS) production in adult MSCs under cyclic stretch compared to young MSCs. Moreover, ROS scavenger N-acetylcysteine rescued the osteogenic differentiation of adult MSCs under cyclic stretch. Gene expression analysis revealed that superoxide dismutase 1 (SOD1) was significantly downregulated in those MSCs from adult rats. In summary, our data suggest that reduced SOD1 may result in excessive ROS production in adult MSCs under cyclic stretch, and thus manipulation of the MSCs from the adult donors with antioxidant would improve their osteogenic ability.
Osteoporosis is a common disease that affects patient quality of life, especially among the elderly population. Although inflammation contributes significantly to osteoporosis, the underlying mechanism is unclear. In this study, we found that tumor necrosis factor (TNF)-α, an inflammatory environment mimic, inhibits osteogenesis of bone mesenchymal stem cells (BMSCs), induces miR-146a and decreases Smad4. Moreover, overexpression of miR-146a inhibited the osteogenic ability of BMSCs, whereas blocking miR-146a partially rescued the osteogenesis deficiency under TNF-α treatment. Molecularly, miR-146a decreased Smad4 expression at the protein level by binding to an element located in the Smad4 3′-untranslated region, and restoration of Smad4 reversed the inhibitory effects of miR-146a on osteogenesis. Together, our results showed that the inflammatory environment mimic TNF-α inhibits osteogenesis via upregulation of miR-146a and subsequent downregulation of Smad4, thus suggesting that therapeutic manipulation of miR-146a maybe a potential strategy to improve osteogenesis in the context of osteoporosis.
Objective. To prepare, characterize, and analyze the release behavior of bleomycin-loaded magnetite nanoparticles (BLM-MNPs) coated with polyacrylic acid (PAA) as a new drug delivery system that can be specifically distributed in the tumor site. Methods. BLM-MNPs coated with PAA were prepared using a solvothermal approach. The particles were characterized using scanning electron microscope (SEM), vibrating sample magnetometer (VSM), and Fourier transform infrared spectroscopy (FTIR). The loading and release behaviors of BLM-MNPs were examined by a mathematical formula and in vitro release profile at pH 7.5. Results. The sphere Fe3O4 nanoparticles with the size of approximately 30 nm exhibit a saturation magnetization of 87 emu/g. The noncoordinated carboxylate groups of PAA confer on the good dispersibility in the aqueous solution and lead to a good loading efficiency of BLM reaching 50% or higher. Approximately 98% of immobilized BLM could be released within 24 h, of which 22.4% was released in the first hour and then the remaining was released slowly and quantitatively in the next 23 hours. Conclusion. BLM-MNPs were prepared and characterized successfully. The particles show high saturation magnetization, high drug loading capacity, and favorable release property, which could contribute to the specific delivery and controllable release of BLM, and the BLM-MNPs could be a potential candidate for the development of treating solid tumors.
Along with a deeper understanding of odontogenesis, the epigenetic mechanism involved in has become increasingly important. Therefore, it's necessary to further study the functions of epigenetic regulation in tooth development and regeneration, which may make tooth regeneration a reality in the future.
Mesenchymal stem cells (MSCs) are ideal candidates for different cellular therapies due to their simple isolation, extensive expansion potential, and low immunogenicity. For various therapeutic approaches, such as bone and cartilage repair, MSCs are expected to replace the damaged tissues by direct differentiation. However, age-related changes in MSCs lead to the loss of differentiation potential, loss of proliferation potential and increase in senescent cell numbers, which involve a steady loss of bone mass and frequently result in osteoporosis. In this review, we will introduce the characteristic and age-related changes of MSCs. In addition, we will also summarize the potential rescue mechanisms of age-related bone loss involved in differentiation regulation and proliferation regulation, including transcription factors, signal pathways, epigenetic regulation, and oxidative stress regulation.
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