Effect of Hydroxyapatite porous characteristics on healing outcomes in rabbit posterolateral spinal fusion model
about
Factors influencing arthrodesis rates in a rabbit posterolateral spine model with iliac crest autograftUltrastructural study by backscattered electron imaging and elemental microanalysis of biomaterial-to-bone interface and mineral degradation of bovine xenografts in maxillary sinus floor elevation.An update on bone substitutes for spinal fusionCeramic and non-ceramic hydroxyapatite as a bone graft material: a brief review.Evaluation by bone scintigraphy of osteogenic activity of commercial bioceramics (porous beta-TCP and HAp particles) subcutaneously implanted in rats.Postoperative lumbar spinal stenosis after intertransverse fusion with granules of hydroxyapatite: a case report.Histological Evaluation of Hydroxyapatite Granules with and without Platelet-Rich Plasma versus an Autologous Bone Graft: Comparative study of biomaterials used for spinal fusion in a New Zealand white rabbit model.Evaluation of an injectable silk fibroin enhanced calcium phosphate cement loaded with human recombinant bone morphogenetic protein-2 in ovine lumbar interbody fusion.Experimental posterolateral spinal fusion with beta tricalcium phosphate ceramic and bone marrow aspirate composite graft.Posterolateral arthrodesis in lumbar spine surgery using autologous platelet-rich plasma and cancellous bone substitute: an osteoinductive and osteoconductive effect.Physicochemical characterization of biomaterials commonly used in dentistry as bone substitutes--comparison with human bone.Low-melt Bioactive Glass-reinforced 3D Printing Akermanite Porous Cages with Highly Improved Mechanical Properties for Lumbar Spinal Fusion.Bone Healing in Extraction Sockets Covered With Collagen Membrane Alone or Associated With Porcine-Derived Bone Graft: a Comparative Histological and Histomorphometric Analysis.A preclinical large animal study on a novel intervertebral fusion cage covered with high porosity titanium sheets with a triple pore structure used for spinal fusion.
P2860
Q26996015-3692DD1B-5078-444B-9C7C-F727633C0EACQ34196861-422464EC-3161-4AFB-9814-CFE0C66745ADQ37413018-E9E9427F-578C-4623-B7EE-6F191B51F534Q38271888-1B87CE8C-5925-420A-8484-3DD396DF5CCCQ39804390-F06BBF51-1E17-4B93-B2FD-597F7113FB39Q41587449-89C78862-7820-4190-9674-4EAD9F70A376Q41840603-F67631A4-A742-4001-AEBC-65A0224B7E2FQ42018010-FA2C9AA7-31E8-4841-AAA6-670B30A4A8C7Q42043548-B3276C1B-1F1D-4F8E-9D13-74465348733DQ42750362-C25F9059-36C4-407C-961A-8E3016D41460Q43244527-9066364E-BB8A-4961-88F7-1A75B625A844Q46401148-6070E704-3D48-48D9-9653-142DB19ACCEBQ50052785-9586BC79-02B3-4290-800E-98EC783FD5B1Q53485526-75B117BD-714F-4669-958F-9E0FBCC03DEE
P2860
Effect of Hydroxyapatite porous characteristics on healing outcomes in rabbit posterolateral spinal fusion model
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh
2007年學術文章
@zh-hant
name
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@ast
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@en
type
label
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@ast
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@en
prefLabel
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@ast
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@en
P2093
P2860
P1476
Effect of Hydroxyapatite porou ...... erolateral spinal fusion model
@en
P2093
Akio Minami
Kazuharu Irie
Ken Kadoya
Kuniyoshi Abumi
Makoto Motomiya
Manabu Ito
Masahiko Takahata
P2860
P2888
P304
P356
10.1007/S00586-007-0501-0
P577
2007-09-22T00:00:00Z