
Announcement
Select search scope: search across all journals or within the current journal


Dental implants have been clinically used for almost five decades with high success rates.
The development of new dental implants is an accelerating field aiming to improve biocompatibility and durability of implants and to overcome complications associated with them. This highlights the importance of developing robust and reproducible models to study dental implants. There is increasing interest to switch from animal and two-dimensional
Synthetic hydroxyapatite (HA) is a widely studied bioceramic for bone tissue engineering (BTE) due to its similarity to the mineral component of bone. As bone mineral contains various ionic substitutions that play a crucial role in bone metabolism, the bioactivity of HA can be improved by adding small amounts of physiologically relevant ions into its crystal structure, with silicate-substituted HA (Si-HA) showing particularly promising results. Nevertheless, it remains unclear how distinct material characteristics influence the bioactivity due to the intertwined nature of surface properties.
A coculture methodology was optimized and applied for
Overall, 1.25 wt% Si-HA exhibited most nanoscale variations in surface potential. In terms of bioactivity, 1.25 wt% Si-HA samples induced the highest osteoblast attachment and vessel formation. Additionally,
Hydroxyapatite (HA), a synthetic bioceramic with structural similarities to bone mineral, has garnered significant attention in bone tissue engineering (BTE). However, optimizing its bioactivity remains a challenge due to the intricate interplay between physical and electrochemical surface properties. Our work pioneers the exploration of Si-HA’s bioactivity using an
Fibroblast growth factor 23 (FGF23) plays a crucial role in managing renal phosphate and the synthesis of 1,25(OH)2-vitamin D3, which is essential for bone homeostasis. Developing robust
This research introduces a high-throughput method for generating preosteoblastic spheroids that significantly enhance fibroblast growth factor 23 (FGF23) production via the parathyroid hormone signaling pathway. The findings offer a robust