About this Research Topic
Within the realm of dentistry, unraveling the intricate connections between bone metabolism, biomechanics, and epigenetics holds significant promise. This Research Topic aims to delve into the molecular nuances that govern bone health within the context of dentistry. Utilizing state-of-the-art bioinformatics methodologies, this collection seeks to uncover the epigenetic landscape governing bone cells under diverse biomechanical conditions, with an emphasis on both DNA and RNA methylation dynamics.
The central aim of this Research Topic is to untangle the intricate relationship between bone metabolism, biomechanics, and dental health. By delving into the epigenetic modifications that shape gene expression within bone cells and dental tissues, this collection endeavors to illuminate the origins and progression of dental and bone diseases. The article collection aspires to leverage advanced bioinformatics analyses and extensive datasets to reveal novel insights into the mechanisms of bone remodeling and dental tissue development. Additionally, this research endeavors to decode the roles of both DNA and RNA methylation in these processes, paving the way for innovative diagnostic and therapeutic strategies that can transform dental care and bone-related treatments.
This Research Topic invites authors to unravel the intricate web of interactions between bone biology, dental health, and multifaceted epigenetic regulation. Contributors are encouraged to explore a broad spectrum of themes, ranging from the roles of DNA and RNA methylation in gene expression to deciphering the impact of mechanical forces on the epigenetic landscape of bone cells. Researchers are urged to employ cutting-edge bioinformatics techniques to dissect the signaling pathways orchestrating bone metabolism and dental tissue formation.
By weaving together the dimensions of biomechanics, epigenetics, and dentistry, this Research Topic strives to provide transformative insights that elevate personalized dental care and preventive strategies, ultimately fostering comprehensive oral health and overall well-being.
The central aim of this Research Topic is to untangle the intricate relationship between bone metabolism, biomechanics, and dental health. By delving into the epigenetic modifications that shape gene expression within bone cells and dental tissues, this collection endeavors to illuminate the origins and progression of dental and bone diseases. The article collection aspires to leverage advanced bioinformatics analyses and extensive datasets to reveal novel insights into the mechanisms of bone remodeling and dental tissue development. Additionally, this research endeavors to decode the roles of both DNA and RNA methylation in these processes, paving the way for innovative diagnostic and therapeutic strategies that can transform dental care and bone-related treatments.
This Research Topic invites authors to unravel the intricate web of interactions between bone biology, dental health, and multifaceted epigenetic regulation. Contributors are encouraged to explore a broad spectrum of themes, ranging from the roles of DNA and RNA methylation in gene expression to deciphering the impact of mechanical forces on the epigenetic landscape of bone cells. Researchers are urged to employ cutting-edge bioinformatics techniques to dissect the signaling pathways orchestrating bone metabolism and dental tissue formation.
By weaving together the dimensions of biomechanics, epigenetics, and dentistry, this Research Topic strives to provide transformative insights that elevate personalized dental care and preventive strategies, ultimately fostering comprehensive oral health and overall well-being.
Keywords: Epigenetics, Bone metabolism, Biomechanics, RNA-seq, scRNA-seq, m6A, Orthodontics, Periodontology
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
