about
Use of roentgenography and magnetic resonance imaging to predict meniscal geometry determined with a three-dimensional coordinate digitizing systemIdentification of cross-sectional parameters of lateral meniscal allografts that predict tibial contact pressure in human cadaveric knees.A high-accuracy three-dimensional coordinate digitizing system for reconstructing the geometry of diarthrodial joints.Longitudinal shapes of the tibia and femur are unrelated and variable.Scientific justification and technique for anterior cruciate ligament reconstruction using autogenous and allogeneic soft-tissue grafts.Do patient-specific guides improve coronal alignment in total knee arthroplasty?Does Malrotation of the Tibial and Femoral Components Compromise Function in Kinematically Aligned Total Knee Arthroplasty?The role of arthroscopy in treating osteoarthritis of the knee in the older patient.Comparison of viscoelastic, structural, and material properties of double-looped anterior cruciate ligament grafts made from bovine digital extensor and human hamstring tendons.In vivo calibration of a femoral fixation device transducer for measuring anterior cruciate ligament graft tension: a study in an ovine model.An in vitro osteotomy method to expose the medial compartment of the human knee.Does varus alignment adversely affect implant survival and function six years after kinematically aligned total knee arthroplasty?Contributions of femoral fixation methods to the stiffness of anterior cruciate ligament replacements at implantation.An implantable transducer for measuring tension in an anterior cruciate ligament graft.Reply to letter to the editor: the ACL in the arthritic knee: how often is it present and can preoperative tests predict its presence?Are undesirable contact kinematics minimized after kinematically aligned total knee arthroplasty? An intersurgeon analysis of consecutive patients.Method for quantifying patient expectations and early recovery after total knee arthroplasty.Anterior laxity, slippage, and recovery of function in the first year after tibialis allograft anterior cruciate ligament reconstruction.Roentgen stereophotogrammetric analysis methods for determining ten causes of lengthening of a soft-tissue anterior cruciate ligament graft construct.Telemetry system for monitoring anterior cruciate ligament graft forces in vivo.Anterior tibial translation during a maximum quadriceps contraction: is it clinically significant?Roofplasty requirements in vitro for different tibial hole placements in anterior cruciate ligament reconstruction.What are the bias, imprecision, and limits of agreement for finding the flexion-extension plane of the knee with five tibial reference lines?Does graft construct lengthening at the fixations cause an increase in anterior laxity following anterior cruciate ligament reconstruction in vivo?How cyclic loading affects the migration of radio-opaque markers attached to tendon grafts using a new method: a study using roentgen stereophotogrammetric analysis (RSA).Serial magnetic resonance imaging of hamstring anterior cruciate ligament autografts during the first year of implantation. A preliminary study.Native Knee Laxities at 0°, 45°, and 90° of Flexion and Their Relationship to the Goal of the Gap-Balancing Alignment Method of Total Knee Arthroplasty.Virtual axis finder: a new method to determine the two kinematic axes of rotation for the tibio-femoral joint.Migration of radio-opaque markers injected into tendon grafts: a study using roentgen stereophotogrammetric analysis (RSA).In vivo tensile behavior of a four-bundle hamstring graft as a replacement for the anterior cruciate ligament.Contact pressure and tension in anterior cruciate ligament grafts subjected to roof impingement during passive extension.Arthroscopic roofplasty: a method for correcting an extension deficit caused by roof impingement of an anterior cruciate ligament graft.A method for quantifying the anterior load-displacement behavior of the human knee in both the low and high stiffness regions.Does Kinematic Alignment and Flexion of a Femoral Component Designed for Mechanical Alignment Reduce the Proximal and Lateral Reach of the Trochlea?Can markers injected into a single-loop anterior cruciate ligament graft define the axes of the tibial and femoral tunnels? A cadaveric study using roentgen stereophotogrammetric analysis.Accurate alignment and high function after kinematically aligned TKA performed with generic instruments.How Frequently Do Four Methods for Mechanically Aligning a Total Knee Arthroplasty Cause Collateral Ligament Imbalance and Change Alignment from Normal in White Patients? AAOS Exhibit Selection.Knee extension and its relationship to the slope of the intercondylar roof. Implications for positioning the tibial tunnel in anterior cruciate ligament reconstructions.A new technique for transmission of signals from implantable transducers.A rationale for predicting anterior cruciate graft impingement by the intercondylar roof. A magnetic resonance imaging study.
P50
Q28144590-CC93463A-E565-4FEA-9E9C-D0B2153ADB3DQ31116261-EA6AE2C1-C1E2-4A51-9B3F-D2D81DEF328AQ32013531-7D7C9CF6-2515-480B-B7B8-D2BB85F83E6AQ33715591-856678FE-4C10-480F-A42D-7D9BE7572018Q35123074-FAA4629F-EA4F-4FA1-9CE0-B2DC7687369EQ35723162-7DCEC07C-08E2-43A1-8390-764FEC068BF0Q38651470-61D59181-B01E-4A84-8316-F15594568E72Q39279945-8017694D-3F73-4A3D-A50B-710D30C069BAQ39566470-ACCB76FA-4543-4F7D-B4AC-4CD007ACB87EQ39579913-47716427-12B1-4841-92DD-BD51E8FAC838Q40874177-72C46B15-A368-4303-9382-95D9D74431A0Q41370111-ECA28820-4880-4570-B0C5-1408A42317DBQ41669581-57B9A007-1531-4772-8981-CAC510EA7C20Q41680199-06C9B321-42C2-48C3-8A83-D389C27E73FEQ43156611-5F026A17-E10D-42BD-81A3-FB83D531007DQ43666578-80231E81-FE7C-472F-856A-55223BA9F3B9Q43751347-4F013571-B8CF-4495-83CF-916692CFAD22Q43815714-85D39B49-DB95-4962-A28C-6564EA39B9F3Q44356718-5F3A717D-F564-4696-BFDB-EFF21F81CE10Q44748287-9401824C-A750-4304-9D1D-034A6F7B61EAQ44838743-7E8D4DD8-0B03-4732-A6DD-85692A0B65C4Q45151125-D2D61161-5570-4315-8962-D43CF455A191Q45982330-198403AD-EF71-4726-9483-AC0EF469CAA9Q45983250-567BC572-9ECF-425A-BC27-0A79C7A36A37Q45987011-6B1AD072-3F2D-46F4-AE03-EC4597F30512Q46021377-4C73EC48-5753-45EF-82EF-60752C21B2FAQ46043491-5A138700-260D-411F-925A-0EB80B73B260Q46048440-CCC00733-D8F7-418D-9C81-8AE0AA8D8D17Q46048857-2F3D17EC-7875-4C12-B3D5-2666B1C452DAQ46049162-A8F0C5D9-63D7-406C-995C-C6870E3A29EDQ46057212-32A44E3D-067E-4596-AAC8-EB8DB5B14D9CQ46073411-1B51EF6B-D2AC-44B7-B117-BDF3EE775D1AQ46092427-ED292DA5-B9B5-4F6B-A1E7-03D81D092D71Q46101358-F27A94C7-FBBB-40D3-8064-22EBF7577C54Q46118405-1B326843-6B66-4D04-B5E8-4EA70682D824Q46121493-26A66440-7F44-4169-A58D-FF94F5015583Q46125165-3ECD0281-6394-4D35-A50D-6FA15671A392Q46220694-01D89CDC-D722-472F-B8B6-FA332DF7A5E7Q46309359-ECF919EA-B291-4066-903C-5E0F0704034AQ46319053-49C4BA45-FE12-4D85-8D36-3AF073CF3297
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Stephen Howell
@ast
Stephen Howell
@en
Stephen Howell
@es
Stephen Howell
@nl
Stephen Howell
@sl
type
label
Stephen Howell
@ast
Stephen Howell
@en
Stephen Howell
@es
Stephen Howell
@nl
Stephen Howell
@sl
altLabel
Stephen M. Howell MD
@en
prefLabel
Stephen Howell
@ast
Stephen Howell
@en
Stephen Howell
@es
Stephen Howell
@nl
Stephen Howell
@sl
P1053
R-6875-2016
P106
P21
P31
P3829
P496
0000-0001-8184-0324