Weight Bearing Cone Beam Computed Tomography (WBCT) in the Foot and Ankle
A Scientific, Technical and Clinical Guide
Weight Bearing Cone Beam Computed Tomography (WBCT) in the Foot and Ankle
A Scientific, Technical and Clinical Guide
This scientific, technical and clinical guide to Weight Bearing Cone Beam Computed Tomography (WBCT), written by the board of the International WBCT Society, presents all of the relevant content to date on the development, implementation, interpretation and clinical application of WBCT for the foot and ankle.
Part One describes the history of the development of, and need for, WBCT as an imaging option and a scientific overview of the procedure. Part Two is an exhaustive scientific background, comprised of 16 landmark studies, describing its advantages for selected foot and ankle injuries and deformities (both congenital and acquired). With this science as context, Part Three includes chapters on the technical aspects and necessary background for WBCT, introduces the different devices, and provides insight into the actual measurement possibilities, including the initial software solutions for automatic measurements. Current clinical applications via case material are illustrated in atlas-like fashion in the next chapter, and a final chapter on future developments explores further applications of WBCT, such as dynamic scans and measurements or hologram-like visualization.
The first book publication of its kind on this exciting and developing imaging modality, Weight Bearing Cone Beam Computed Tomography (WBCT) in the Foot and Ankle will be an excellent resource for orthopedic and foot and ankle surgeons, radiologists, and allied medical professionals working in this clinical area.
Part II: Scientific Background of Weight Bearing Cone Beam Computed Tomography.- Weight Bearing CT Allows for More Accurate Bone Position (Angle) Measurement than Radiographs or CT
Combination of Weight Bearing CT (WBCT) with Pedography Shows No Statistical Correlation of Bone Position with Force/Pressure Distribution
Combination of Weight Bearing CT (WBCT) with Pedography Shows Relationship between Anatomy Based Foot Center (FC) and Force/Pressure Based Center of Gravity (COG)
A New Concept of 3D Biometrics for Hindfoot Alignment Using Weight Bearing CT
3D Biometrics for Hindfoot Alignment Using Weight Bearing Computed Tomography: A Prospective Assessment of 249 Feet
Relationship between Chronic Lateral Ankle Instability and HindfootVarus Using Weight Bearing Cone Beam Computed Tomography: A Retrospective Study
Normal Hindfoot Alignment Assessed by Weight Bearing CT: Presence of a Constitutional Valgus?- Reliability and Correlation Analysis of Computed Methods to Convert Conventional 2D Radiological Hindfoot Measurements to 3D Equivalents Using Weight Bearing CT
The Hind- and Midfoot Alignment Analyzed after a Medializing Calcaneal Osteotomy Using a 3D Weight Bearing CT
Is Load Application Necessary When Using Computed Tomography Scans to Diagnose Syndesmotic Injuries? A Cadaver Study
Use of Weight Bearing Computed Tomography in Subtalar Joint Instability: A Cadaver Study
Is Torque Application Necessary When Using Computed Tomography Scans to Diagnose Syndesmotic Injuries? A Cadaver Study
Flexible Adult Acquired Flatfoot Deformity: Comparison Between Weight Bearing and Non-Weight Bearing Measurements Using Cone Beam Computed Tomography
Hindfoot Alignment of Adult Acquired Flatfoot Deformity: A Comparison of Clinical Assessment and Weight Bearing Cone Beam CT Examinations
Influence of Investigator Experience on Reliability of Adult Acquired Flatfoot Deformity Measurements Using Weight Bearing Computed Tomography
Results of More Than 11,000 Scans with Weight Bearing CT: Impact on Costs, Radiation Exposure and Procedure Time
Part III: Technical Guide to Weight Bearing Cone Beam Computed Tomography.- Technology of Weight Bearing Cone Beam Computed Tomography
Weight Bearing Computed Tomography Devices
Measurements in Weight Bearing Computed Tomography
Clinical Examples of Weight Bearing Computed Tomography
Future Developments in Weight Bearing Computed Tomography.
Part One describes the history of the development of, and need for, WBCT as an imaging option and a scientific overview of the procedure. Part Two is an exhaustive scientific background, comprised of 16 landmark studies, describing its advantages for selected foot and ankle injuries and deformities (both congenital and acquired). With this science as context, Part Three includes chapters on the technical aspects and necessary background for WBCT, introduces the different devices, and provides insight into the actual measurement possibilities, including the initial software solutions for automatic measurements. Current clinical applications via case material are illustrated in atlas-like fashion in the next chapter, and a final chapter on future developments explores further applications of WBCT, such as dynamic scans and measurements or hologram-like visualization.
The first book publication of its kind on this exciting and developing imaging modality, Weight Bearing Cone Beam Computed Tomography (WBCT) in the Foot and Ankle will be an excellent resource for orthopedic and foot and ankle surgeons, radiologists, and allied medical professionals working in this clinical area.
Part I: History and Scientific Overview of Weight Bearing Cone Beam Computed Tomography.- Background of Weight Bearing Cone Beam Computed Tomography
Scientific Overview of Weight Bearing Cone Beam Computed TomographyPart II: Scientific Background of Weight Bearing Cone Beam Computed Tomography.- Weight Bearing CT Allows for More Accurate Bone Position (Angle) Measurement than Radiographs or CT
Combination of Weight Bearing CT (WBCT) with Pedography Shows No Statistical Correlation of Bone Position with Force/Pressure Distribution
Combination of Weight Bearing CT (WBCT) with Pedography Shows Relationship between Anatomy Based Foot Center (FC) and Force/Pressure Based Center of Gravity (COG)
A New Concept of 3D Biometrics for Hindfoot Alignment Using Weight Bearing CT
3D Biometrics for Hindfoot Alignment Using Weight Bearing Computed Tomography: A Prospective Assessment of 249 Feet
Relationship between Chronic Lateral Ankle Instability and HindfootVarus Using Weight Bearing Cone Beam Computed Tomography: A Retrospective Study
Normal Hindfoot Alignment Assessed by Weight Bearing CT: Presence of a Constitutional Valgus?- Reliability and Correlation Analysis of Computed Methods to Convert Conventional 2D Radiological Hindfoot Measurements to 3D Equivalents Using Weight Bearing CT
The Hind- and Midfoot Alignment Analyzed after a Medializing Calcaneal Osteotomy Using a 3D Weight Bearing CT
Is Load Application Necessary When Using Computed Tomography Scans to Diagnose Syndesmotic Injuries? A Cadaver Study
Use of Weight Bearing Computed Tomography in Subtalar Joint Instability: A Cadaver Study
Is Torque Application Necessary When Using Computed Tomography Scans to Diagnose Syndesmotic Injuries? A Cadaver Study
Flexible Adult Acquired Flatfoot Deformity: Comparison Between Weight Bearing and Non-Weight Bearing Measurements Using Cone Beam Computed Tomography
Hindfoot Alignment of Adult Acquired Flatfoot Deformity: A Comparison of Clinical Assessment and Weight Bearing Cone Beam CT Examinations
Influence of Investigator Experience on Reliability of Adult Acquired Flatfoot Deformity Measurements Using Weight Bearing Computed Tomography
Results of More Than 11,000 Scans with Weight Bearing CT: Impact on Costs, Radiation Exposure and Procedure Time
Part III: Technical Guide to Weight Bearing Cone Beam Computed Tomography.- Technology of Weight Bearing Cone Beam Computed Tomography
Weight Bearing Computed Tomography Devices
Measurements in Weight Bearing Computed Tomography
Clinical Examples of Weight Bearing Computed Tomography
Future Developments in Weight Bearing Computed Tomography.
Richter, Martinus
Lintz, Francois
de Cesar Netto, Cesar
Barg, Alexej
Burssens, Arne
Ellis, Scott
ISBN | 978-3-030-31948-9 |
---|---|
Artikelnummer | 9783030319489 |
Medientyp | Buch |
Auflage | 1st ed. 2020 |
Copyrightjahr | 2019 |
Verlag | Springer, Berlin |
Umfang | XIV, 313 Seiten |
Abbildungen | XIV, 313 p. 113 illus., 96 illus. in color. |
Sprache | Englisch |