Periosteum: biology, regulation, and response to osteoporosis therapies.
about
Teriparatide for osteoporosis: importance of the full courseConcise review: the periosteum: tapping into a reservoir of clinically useful progenitor cellsPotential mechanisms of a periosteum patch as an effective and favourable approach to enhance tendon-bone healing in the human bodyCurrent insights on the regenerative potential of the periosteum: molecular, cellular, and endogenous engineering approachesAnchoring structure of the calvarial periosteum revealed by focused ion beam/scanning electron microscope tomography.Surgical membranes as directional delivery devices to generate tissue: testing in an ovine critical sized defect modelBmp2 in osteoblasts of periosteum and trabecular bone links bone formation to vascularization and mesenchymal stem cells.Biomimetic strategies for fracture repair: Engineering the cell microenvironment for directed tissue formation.A phenotypically restricted set of primary afferent nerve fibers innervate the bone versus skin: therapeutic opportunity for treating skeletal pain.Are we taking full advantage of the growing number of pharmacological treatment options for osteoporosis?Periosteal PTHrP regulates cortical bone modeling during linear growth in mice.Does bone resorption stimulate periosteal expansion? A cross-sectional analysis of β-C-telopeptides of type I collagen (CTX), genetic markers of the RANKL pathway, and periosteal circumference as measured by pQCT.Activation of the Hh pathway in periosteum-derived mesenchymal stem cells induces bone formation in vivo: implication for postnatal bone repair.Estrogens and Androgens in Skeletal Physiology and Pathophysiology.Cell replication in craniofacial periosteum: appositional vs. resorptive sites.The effect of aging on the density of the sensory nerve fiber innervation of bone and acute skeletal pain.Imaging and quantifying solute transport across periosteum: implications for muscle-bone crosstalk.Bone vs. fat: embryonic origin of progenitors determines response to androgen in adipocytes and osteoblasts.Frontiers in the bioarchaeology of stress and disease: cross-disciplinary perspectives from pathophysiology, human biology, and epidemiology.Dimensional change of the healed periosteum on surgically created defects.Anti-DKK1 antibody promotes bone fracture healing through activation of β-catenin signaling.PTH receptor signaling in osteocytes governs periosteal bone formation and intracortical remodeling.Emulating native periosteum cell population and subsequent paracrine factor production to promote tissue engineered periosteum-mediated allograft healingHuman periosteum is a source of cells for orthopaedic tissue engineering: a pilot studySystemic transplantation of human adipose-derived stem cells stimulates bone repair by promoting osteoblast and osteoclast function.Novel Lesions of Bones and Joints Associated with Chikungunya Virus Infection in Two Mouse Models of Disease: New Insights into Disease Pathogenesis.A computational assessment of the independent contribution of changes in canine trabecular bone volume fraction and microarchitecture to increased bone strength with suppression of bone turnover.Electrospun hydroxyapatite-containing chitosan nanofibers crosslinked with genipin for bone tissue engineeringA single administration of combination therapy inhibits breast tumour progression in bone and modifies both osteoblasts and osteoclasts.Osteogenic Potential of Mouse Periosteum-Derived Cells Sorted for CD90 In Vitro and In VivoPTHrP regulates the modeling of cortical bone surfaces at fibrous insertion sites during growth.32 wk old C3H/HeJ mice actively respond to mechanical loading.Craniofacial tissue engineering by stem cells.Elucidating multiscale periosteal mechanobiology: a key to unlocking the smart properties and regenerative capacity of the periosteum?In vivo delivery of fluoresceinated dextrans to the murine growth plate: imaging of three vascular routes by multiphoton microscopyMultiscale mechanobiology of de novo bone generation, remodeling and adaptation of autograft in a common ovine femur model.Role of muscle-derived growth factors in bone formationIntermittent PTH stimulates periosteal bone formation by actions on post-mitotic preosteoblastsCOX-2 from the injury milieu is critical for the initiation of periosteal progenitor cell mediated bone healingTamoxifen-inducible CreER-mediated gene targeting in periosteum via bone-graft transplantation.
P2860
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P2860
Periosteum: biology, regulation, and response to osteoporosis therapies.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Periosteum: biology, regulation, and response to osteoporosis therapies.
@ast
Periosteum: biology, regulation, and response to osteoporosis therapies.
@en
type
label
Periosteum: biology, regulation, and response to osteoporosis therapies.
@ast
Periosteum: biology, regulation, and response to osteoporosis therapies.
@en
prefLabel
Periosteum: biology, regulation, and response to osteoporosis therapies.
@ast
Periosteum: biology, regulation, and response to osteoporosis therapies.
@en
P1433
P1476
Periosteum: biology, regulation, and response to osteoporosis therapies
@en
P2093
David B Burr
P304
P356
10.1016/J.BONE.2004.07.014
P577
2004-11-01T00:00:00Z