Dynamic Lumbar Spine Stabilization

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This books presents the state-of-the-art of lumbar dynamic spine stabilization, a set of surgical techniques designed to overcome the limits of fusion surgery, such as mortality and morbidity, especially in elderly people and chronic instability.
The opening chapters explore the philosophy and rationale of dynamic stabilization and present its evolution over the past two decades. It also analyzes the differences with other non-fusion systems such as disc prostheses, interspinous devices, facet replacement, and other soft or semi-rigid stabilization systems.
Readers discover the biomechanics, indications, technical pearls and pitfalls, as well as the clinical results and complications of this technical innovation. They further learn its application in special deformities, e.g. idiopathic scoliosis in adolescents which have not reached the bone growth age, as well as its increased success rate in lumbar disc herniation surgery. Insights into its application at the initial stage of degeneration, preparing the ground for regeneration, complement the book.
Written by an international panel of experts, this timely and up-to-date guide offers an excellent source of knowledge and a valuable aid to clinical practice for orthopedic surgeons and neurosurgeons alike.
 
 

List of contents

Chapter 1. Dynamic Stabilization and Philosophy.- Chapter 2. Functional Anatomy & Load Dynamics of the Lumbar Spine.- Chapter 3. Degenerative Spine Biomechanics.- Chapter 4. Lumbar Segmental Instability.- Chapter 5. Adult Deformity Classifications and Dynamic Stabilization.- Chapter 6. Spinal Fusion Surgery Advantages and Disadvantages.- Chapter 7. Total Disc Replacement and Posterior Dynamic Stabilization in the Treatment of Degenerative Disc Disease.- Chapter 8. ANESTHESIA IN LUMBAR DYNAMIC STABILIZATION SURGERIES.- Chapter 9. POSTERIOR DYNAMIC SYSTEMS as FACET REPLACEMENT SYSTEM.- Chapter 10. Biomechanics of Posterior Dynamic Pedicular Stabilization Systems.- Chapter 11. Stabilization with Polyaxial dynamic screw and Hinged screw.- Chapter 12. Combination of Dynamic Rods and Screws.- Chapter 13. INDICATIONS OF DYNAMIC STABILIZATION WITHOUT FUSION.- Chapter 14. THE ORTHRUS PEDICULAR DYNAMIC STABILIZATION SYSTEM.- Chapter 15. DYNAMIC ROD.- Chapter 16. Biomechanical analysis of different dynamic rods used with rigid screws .- Chapter 17. Long segment pedicular stabilization in multilevel steno-instability using hybrid fixation.- Chapter 18. Dynamic stabilization in scoliosis deformity.- Chapter 19. Pedicular Dynamic Stabilization in Kyphotic Deformities.- Chapter 20. Complications of Dynesys system.- Chapter 21. TWO-STAGE SURGERY FOR DYNAMIC STABILIZATION OF THE SPINE.- Chapter 22. Vertebra Body Tethering.- Chapter 23. RE-EVALUATION OF TREATMENT IN LUMBAR DISC SURGERY.- Chapter 24. Reevaluation of the treatment of chronic degenerative spine disease.- Chapter 25. Rehabilitation after  lumbar transpedicular dynamic stabilization surgery .- Chapter 26. Emerging Biological Treatments for Intervertebral Disc Degeneration Disease: A Regenerative Medicine Perspective.

About the author

Ali Fahir Özer
graduated from Atatürk University School of Medicine in 1976. He did his neurosurgery residency between 1977 and 1982 at Hacettepe University School of Medicine. He obtained his Associate Professor degree in 1988 and full-professorship in 1994. He served as the head of neurosurgery department in Kocaeli University between 1994 and 1995. He has been working at the neurosurgery department of the American Hospital since 1995 and is currently a faculty at Koc University School of Medicine, Department of Neurosurgery. Since 2018, he is Adjunct Professor in Bioengineering and Orthopaedic Surgery Colleges of Engineering and Medicine, University of Toledo (OH, USA).


Professor Özer is member of
Eurospine
and
North American Spine Society
. He also is member of the advisory board and reviewer of sevarel journals, e. g.
The Spine Journal, World Neurosurgery, BMC Musculoskelatal Journal, Journal of Turkish Neurosurgery, Case Reports in Orthopedics
etc. He has authored or co‐authored over 230 articles and 46 book chapters, and he also editor of 9 books.


Prof. Özer’s research mainly focuses on biomechanics  and dynamic stabilization of spine. He had patented
Orthrus Dynamic Spinal System
,
Safinaz Dynamic Screw
and
Cervical Disc Prosthesis
.

Mario Di Silvestre
attended the Scoliosis Center of the Pisa University Orthopedic Clinic (Pisa, Italy) during his Orthopedics and Traumatology residency, directed by Prof. Pier Giorgio Marchetti. After his specialization, in 1984 he moved to the Scoliosis Center at the Rizzoli Orthopedic Institute in Bologna (taly), becoming more actively involved in spine surgery under the guidance of Prof. Leonardo Gui and Prof. Romolo Savini. He was then hired back to the Rizzoli Institute in 1989, first as an orthopedics and traumatology medical assistant, then as an orthopedics and traumatology hospital assistant, and finally as a medical director of the Spine Surgery Department. Since 2017, he is responsible of the Spine Surgery at the Santa Corona Hospital in Pietra Ligure (Savona, Italy). He has many publications published in international journals and many papers presented at international meetings.

Vijay K. Goel
 is professor of Orthopaedic Bioengineering and Co-Director of the Engineering Center for Orthopaedic Research Excellence (E-CORE), Department  of Bioengineering and Orthopaedic Surgery, University of Toledo, Toledo (OH, USA). He has been active as professor of bioengineering over four decades, and is a globally recognized biomechanical researcher and mentor of a large number of scientis and clinicians.  He is a prolific contributor to device development as an industrial advisor/entrepreneur, and a dedicated society-benefactor in developing treatments of orthopedic ailments

Deniz Erbulut
, PhD, received his PhD in Mechanical Engineering from the University of Melbourne in 2010. After faculty appointments in the USA and Turkey, he joined HBI as a senior research fellow in 2020. He gained about 10 years of research experience in biomechanics for understanding clinically relevant issues in medicine. Using a combination of experimental and computational tools, he performs research in in-vivo/in vitro joint mechanics, human motion, musculoskeletal modelling, computational biomechanics and spinal/orthopaedic implant development and testing. Dr. Erbulut holds three orthopaedic implant patents for the USA and most European countries. He has been a principal investigator for several projects, teaching graduate and undergraduate level courses in the biomedical and mechanical engineering departments at various universities, and supervised several master and PhD students as a principal advisor.