Abstract
Orthodontic tooth movement (OTM) is a biologically orchestrated process involving the dynamic interplay of mechanical force, inflammatory signaling, and bone remodeling. Osteocytes, the most abundant cells within the bone matrix, serve as mechanosensitive regulators that transduce mechanical cues into biochemical signals in response to orthodontic force. This review delineates the multifaceted role of osteocytes in facilitating bone resorption required for OTM. The role of osteocytes is examined in inflammation, mechanical adaptation, and cell death. Additionally, we discuss the evidence on how aging alters osteocyte function, with senescence-associated changes disrupting mechanosensory networks and attenuating bone remodeling. Finally, the possibility that osteocytes themselves undergo morphological adaptation during force application is explored. This structural plasticity may impact individual variability in orthodontic outcomes. Advancing our understanding of osteocyte signaling in OTM holds significant promise for optimizing treatment outcomes across diverse patient populations.