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21	The Development of an In Vivo Spinal Fusion Monitor Using Microelectromechanical(MEMS) Technology to Create Implantable Microsensors Ferrara, Lisa Anne January 2008 (has links) No description available. Biomedical Research spinal fusion MEMS microsensors bone caprine
22	The use of low intensity pulsed ultrasound and mesenchymal stem cells in enhancing spinal fusion: --an in vitro and in vivo study. January 2009 (has links) Hui, Fan Fong. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2009. / Includes bibliographical references (leaves 153-181). / Abstract also in Chinese. / Acknowledgements --- p.ii / Abstract --- p.iii / Abbreviations --- p.vii / Table of Contents --- p.ix / List of Tables --- p.xv / List of Tables --- p.xv / List of Figures --- p.xvi / Major Conference Presentations --- p.xix / Publications in Preparation --- p.xxii / Chapter Chapter 1 --- Study Background --- p.1 / Chapter 1. --- Introduction --- p.2 / Chapter 1.1. --- Spinal Deformities --- p.2 / Chapter 1.1.1. --- Treatment --- p.2 / Chapter 1.2. --- Spinal fusion --- p.4 / Chapter 1.2.1. --- Gold Standard of Spinal Fusion --- p.4 / Chapter 1.2.2. --- Decortication in Spinal Fusion --- p.4 / Chapter 1.2.3. --- Autograft in Spinal Fusion --- p.4 / Chapter 1.2.4. --- Local Factors Influencing Spinal Fusion --- p.5 / Chapter 1.2.5. --- Ultimate Goals of Spinal Fusion --- p.7 / Chapter 1.2.6. --- Limitations of Spinal fusion --- p.7 / Chapter 1.3. --- Alternatives of Different Components for Enhancing Spinal Fusion / Chapter 1.3.1. --- Bone Graft Substitute --- p.9 / Chapter 1.3.2. --- Bioactive Factors --- p.15 / Chapter 1.4. --- Limitations of the Alternative Methods in Spinal Fusion Enhancement --- p.19 / Chapter 1.4.1. --- BMPs --- p.19 / Chapter 1.4.2. --- Gene Therapy --- p.20 / Chapter 1.4.3. --- Biophysical Stimulation --- p.20 / Chapter 1.5. --- Recent Methods in Enhancing Spinal Fusion --- p.21 / Chapter 1.5.1. --- Low Intensity Pulsed Ultrasound --- p.21 / Chapter 1.5.2. --- Mesenchymal Stem Cells in Spinal Fusion --- p.24 / Chapter 1.6. --- Conclusion --- p.26 / Chapter Chapter 2 --- "Hypothesis, Objectives and Plan of Study" --- p.29 / Chapter 2. --- "Hypothesis, Objectives and Plan of Study" --- p.30 / Chapter 2.1 --- Study Hypothesis --- p.31 / Chapter 2.2 --- Study Objectives --- p.31 / Chapter 2.3 --- Plan of Study --- p.32 / Chapter 2.3.1 --- For First Objective --- p.32 / Chapter 2.3.2 --- For Second Objective --- p.32 / Chapter 2.3.3 --- For Third Objective --- p.33 / Chapter Chapter 3 --- In vitro Study of Effect of Low Intensity Pulsed Ultrasound on Mesenchymal Stem Cells --- p.34 / Chapter 3.1. --- Introduction --- p.35 / Chapter 3.2. --- Materials and Methods --- p.36 / Chapter 3.2.1. --- Experimental Animal --- p.36 / Chapter 3.2.2. --- Materials and Reagents --- p.36 / Chapter 3.2.2.1. --- Dulbecco，s Modified Eagle Medium (DMEM) --- p.36 / Chapter 3.2.2.2. --- Phosphate Buffered Saline (PBS) --- p.37 / Chapter 3.2.2.3. --- Osteogenic Medium (OS) --- p.37 / Chapter 3.2.2.4. --- Alkaline Phosphatase (ALP) Buffer --- p.37 / Chapter 3.2.2.5. --- ALP Substrate Buffer --- p.38 / Chapter 3.2.2.6. --- MTT Stock Solution --- p.38 / Chapter 3.2.2.7. --- MTT Working Solution --- p.38 / Chapter 3.2.2.8. --- Lysis buffer --- p.38 / Chapter 3.2.2.9. --- Alkaline Phosphatase (ALP) Working Reagents --- p.39 / Chapter 3.2.3. --- Isolation of Bone Marrow Derived Mesenchymal Stem Cells (BM derived MSCs) --- p.39 / Chapter 3.2.4. --- In vitro Low Intensity Pulsed Ultrasound Treatment --- p.40 / Chapter 3.2.4.1. --- In vitro LIPUS Devices --- p.40 / Chapter 3.2.4.2. --- Treatment Procedure and Experimantal Groupings --- p.40 / Chapter 3.2.5. --- Effect of LIPUS on Cell Viability and Osteogenesis in bone marrow derived-MSCs --- p.41 / Chapter 3.2.5.1. --- Cell Viability Assay --- p.41 / Chapter 3.2.5.2. --- Alkaline Phosphatase (ALP) Enzyme Activity --- p.42 / Chapter 3.2.5.3. --- Cell Morphology and Alkaline Phosphatase Cytochemistry --- p.42 / Chapter 3.2.6. --- Statistical Analysis --- p.43 / Chapter 3.3. --- Results --- p.43 / Chapter 3.3.1. --- Morphology --- p.43 / Chapter 3.3.2. --- Total Number of Viable Cells --- p.44 / Chapter 3.3.3. --- ALP Activity Absorbance --- p.44 / Chapter 3.3.4. --- ALP staining --- p.45 / Chapter 3.3.5. --- Qualitative Analysis --- p.45 / Chapter 3.3.6. --- Quantitative Analysis --- p.46 / Chapter 3.4. --- Discussion --- p.46 / Chapter 3.4.1. --- LIPUS have No Enhancing Effect on Proliferation of MSCs in Basal Medium Nor Osteogenic Medium --- p.47 / Chapter 3.4.2. --- LIPUS Stimulate Proliferation of MSCs in Early Period --- p.49 / Chapter 3.4.3. --- LIPUS Further Enhanced Osteogenesis of MSCs in Osteogenic Medium --- p.49 / Chapter 3.4.4. --- 10 mins LIPUS treatment for 7 days can positively enhance osteogenic differentiation --- p.50 / Chapter 3.4.5. --- Optimum Conditions of LIPUS was Cell Type Dependent --- p.51 / Chapter 3.4.6. --- LIPUS Promoted Osteogenesis in MSCs through Accelerated Mineralization --- p.52 / Chapter Chapter 4 --- Enhancement of Posterior Spinal Fusion The Effect of Tissue-Engineered MSC and Calcium Phosphate Ceramic composite treated with LIPUS in Vivo --- p.68 / Chapter 4.1. --- Introduction --- p.69 / Chapter 4.1.1. --- TCP Biomaterials --- p.70 / Chapter 4.2. --- Materials and Methods --- p.71 / Chapter 4.2.1. --- Materials and Reagents --- p.71 / Chapter 4.2.2. --- Preparation of MSC Derived Osteogenic Cells-tricalcium Phosphate Ceramics Composite --- p.73 / Chapter 4.2.3. --- Posterior Spinal Fusion Surgery --- p.74 / Chapter 4.2.4. --- In vivo LIPUS treatment --- p.75 / Chapter 4.2.5. --- Assessment of Fusion Mass --- p.76 / Chapter 4.2.6. --- Histology --- p.77 / Chapter 4.2.7. --- Statistical Analysis --- p.79 / Chapter 4.3. --- Results --- p.79 / Chapter 4.3.1. --- Fusion by Manual Palpation --- p.79 / Chapter 4.3.2. --- pQCT Analysis --- p.80 / Chapter 4.3.3. --- Histological Analysis --- p.81 / Chapter 4.4. --- Discussion --- p.85 / Chapter 4.4.1. --- Summary of the Findings from Different Assessment Methods --- p.85 / Chapter 4.4.2. --- Addition of MSCs to TCP ceramic in Spinal Fusion --- p.87 / Chapter 4.4.3. --- The Needs of Differentiated MSC in Spinal Fusion --- p.89 / Chapter 4.4.4. --- bFGF Masked the Effect of OS in MSC --- p.91 / Chapter 4.4.5. --- LIPUS Enhanced Bone Formation --- p.95 / Chapter 4.4.6. --- LIPUS Enhanced Bone Formation through Mineralization --- p.96 / Chapter 4.4.7. --- LIPUS Enhanced Spinal Fusion through Bone Remodeling-induced Fusion Mass --- p.97 / Chapter 4.4.8. --- LIPUS Enhanced Bone Formation through Endochondral Ossification --- p.99 / Chapter Chapter 5 --- In Vivo Monitoring of Spinal Fusion in Animal Model with High-resolution Peripheral Quantitative Computed Tomography-A New Pilot Study --- p.122 / Chapter 5.1. --- Introduction --- p.123 / Chapter 5.2. --- Materials and Methods --- p.124 / Chapter 5.2.1. --- Animal Groupings --- p.124 / Chapter 5.2.2. --- Preparation of MSC Derived Osteogenic Cells-tricalcium Phosphate Ceramics Composite --- p.124 / Chapter 5.2.3. --- Posterior Spinal Fusion Operation Procedures --- p.125 / Chapter 5.2.4. --- LIPUS treatment --- p.125 / Chapter 5.2.5. --- High-resolution Peripheral Quantitative Computed Tomography …- --- p.125 / Chapter 5.2.6. --- Analysis with HR-pQCT --- p.126 / Chapter 5.3. --- Result --- p.128 / Chapter 5.3.1. --- Qualitative Observations from HR-pQCT Images --- p.128 / Chapter 5.3.2. --- Quantitative Analysis --- p.129 / Chapter 5.4. --- Discussion --- p.130 / Chapter Chapter 6 --- "Overall Summary, Discussion and Conclusion" --- p.140 / Chapter 6.1. --- Overall Summary and Discussion --- p.141 / Chapter 6.2. --- Limitations and Further Studies --- p.145 / Chapter 6.3. --- Conclusions --- p.147 / Chapter 6.4. --- Summary Flowchart of the whole thesis --- p.148 / References --- p.153 Spinal fusion Ultrasonic waves--Therapeutic use Mesenchymal stem cells Spinal Fusion--methods Ultrasonic Therapy Mesenchymal Stromal Cells
23	The development of a posterior dynamic stabilisation implant indicated for thoraco-lumbar disc degeneration / Christopher Daniel (Chris) Parker Parker, Christopher Daniel January 2013 (has links) Posterior lumbar spinal dynamic stabilisation devices are intended to relieve the pain of spinal segments while prolonging the lifespan of adjacent intervertebral discs. This study focuses on the design of such a device, one that has the correct stiffness to stabilise the spinal segment by the correct amount. An initial literature survey covers contemporary topics related to the lumbar spine. Included topics are lumbar anatomy and kinematics, pathology of degenerative disc disease and treatment thereof, other spinal disorders such as spondylolisthesis and spinal stenosis, as well as the complications associated with lumbar dynamic stabilisation. The influence of factors such as fatigue and wear, as well as the properties of appropriate biomaterials are considered when determining the basis of the device design and development. Stabilising the spinal segment begins with correct material selection and design. Various designs and biomaterials are evaluated for their stiffness values and other user requirements. The simplest design, a U-shaped spring composed of carbon fibre-reinforced poly-ether-ether-ketone (CFR-PEEK) and anchored by polyaxial titanium pedicle screws, satisfies the most critical user requirements. Acceptable stiffness is achieved, fatigue life of the material is excellent and the device is very imaging-friendly. Due to financial constraints, however, a simpler concept that is cheaper and easier to rapid prototype was chosen. This concept involves a construct primarily manufactured from the titanium alloy Ti6Al4V extra-low interstitial (ELI) and cobalt-chrome-molybdenum (CCM) alloys. The first rapid prototype was manufactured using an additive manufacturing process (3D-printing). The development of the device was performed in three main stages: design, verification and validation. The main goal of the design was to achieve an acceptable stiffness to limit the spinal segmental range of motion (ROM) by a determined amount. The device stiffness was verified through simple calculations. The first prototype’s stiffness was validated in force-displacement tests. Further validation, beyond the scope of this study, will include fatigue tests to validate the fatigue life of the production-ready device. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2014 Dynamic stabilisation Spinal fusion Finite element analysis Lumbar vertebrae Degenerative disc disease Joint instability
24	The development of a posterior dynamic stabilisation implant indicated for thoraco-lumbar disc degeneration / Christopher Daniel (Chris) Parker Parker, Christopher Daniel January 2013 (has links) Posterior lumbar spinal dynamic stabilisation devices are intended to relieve the pain of spinal segments while prolonging the lifespan of adjacent intervertebral discs. This study focuses on the design of such a device, one that has the correct stiffness to stabilise the spinal segment by the correct amount. An initial literature survey covers contemporary topics related to the lumbar spine. Included topics are lumbar anatomy and kinematics, pathology of degenerative disc disease and treatment thereof, other spinal disorders such as spondylolisthesis and spinal stenosis, as well as the complications associated with lumbar dynamic stabilisation. The influence of factors such as fatigue and wear, as well as the properties of appropriate biomaterials are considered when determining the basis of the device design and development. Stabilising the spinal segment begins with correct material selection and design. Various designs and biomaterials are evaluated for their stiffness values and other user requirements. The simplest design, a U-shaped spring composed of carbon fibre-reinforced poly-ether-ether-ketone (CFR-PEEK) and anchored by polyaxial titanium pedicle screws, satisfies the most critical user requirements. Acceptable stiffness is achieved, fatigue life of the material is excellent and the device is very imaging-friendly. Due to financial constraints, however, a simpler concept that is cheaper and easier to rapid prototype was chosen. This concept involves a construct primarily manufactured from the titanium alloy Ti6Al4V extra-low interstitial (ELI) and cobalt-chrome-molybdenum (CCM) alloys. The first rapid prototype was manufactured using an additive manufacturing process (3D-printing). The development of the device was performed in three main stages: design, verification and validation. The main goal of the design was to achieve an acceptable stiffness to limit the spinal segmental range of motion (ROM) by a determined amount. The device stiffness was verified through simple calculations. The first prototype’s stiffness was validated in force-displacement tests. Further validation, beyond the scope of this study, will include fatigue tests to validate the fatigue life of the production-ready device. / MIng (Mechanical Engineering), North-West University, Potchefstroom Campus, 2014 Dynamic stabilisation Spinal fusion Finite element analysis Lumbar vertebrae Degenerative disc disease Joint instability
25	Wundheilungsraten nach Roboter-assistierter minimalinvasiver Pedikelschraubenosteosynthese im Vergleich zu konventioneller fluoroskopisch-gestützter Instrumentierung bei pyogener Spondylodiszitis. / Robot guidance for percutaneous minimally invasive placement of pedicle screws for pyogenic spondylodiscitis is associated with lower rates of wound breakdown compared to conventional fluoroscopy-guided instrumentation Alaid, Awad 30 July 2019 (has links) No description available. 610 Neurochirurgie (PPN619876271)
26	Photocrosslinked poly(anhydrides) for spinal fusion characterization and controlled release studies / Weiner, Ashley Aston. January 2007 (has links) Thesis (Ph. D. in Biomedical Engineering)--Vanderbilt University, May 2007. / Title from title screen. Includes bibliographical references.
27	Evaluation of a Body Pillow to Aid Pediatric Spinal Fusion Recovery Joffe, Naomi Eve 14 August 2009 (has links) Spinal fusion is a surgical procedure used to correct structural spinal damage or abnormalities. Recovery is painful and consists of a minimum 3-day hospital stay. Specific body positioning is necessary for healing but is difficult to maintain due to physical discomfort. The purpose of this study was to use a single-subject multiple baseline design to compare the current practice of using standard hospital pillows to a body-sized pillow for increasing comfort and decreasing pain in pediatric patients recovering from spinal fusion surgery. Four adolescents who had recently undergone spinal fusion surgery served as participants. Outcome measures included self- and nurse-report, heart rate, and requested medication. Three patients found that the BodyPillow® increased their comfort as they recovered from surgery; the fourth reported that he was less comfortable. No changes in pain were reported with the BodyPillow®. Results should help guide medical care and future research regarding pediatric spinal fusion recovery. Adolescents Positioning Spinal fusion surgery Medical pain Pediatric psychology Environmental factors Comfort Multiple-baseline design Psychology
28	A comparison of bone marrow derived and adipose derived stem cells in point of care goat non-instrumented posterolateral intertransverse spinal fusion Neidre, Daria Brigitte 22 June 2011 (has links) A Comparison of Bone Marrow Derived and Adipose Derived Stem Cells in Point of Care Goat Non-Instrumented Posterolateral Intertransverse Spinal Fusion Daria Brigitte Neidre, Ph.D. The University of Texas at Austin, May, 2010 Supervisor: Roger P. Farrar Concentrated bone marrow containing mesenchymal stem cells (BMSCs) in combination with osteoconductive scaffolds has been used in orthopaedics to replace the need for iliac crest bone grafts. Autologous BMSC volume is limited, but adipose tissue represents a large reservoir of stem cells; adipose derived stem cells (ADSCs). To test these cells, a large animal model using goats was selected due to their similarities to humans in loading conditions of the spine, trabecular bone structure of the vertebrae, and their common use in testing orthopaedic therapies as a clinically relevant model. The aim of this study is to characterize cell surface markers of the isolated cells through flow cytometry, compare goat BMSCs and ADSCs using multilineage differentiation into the osteogenic and adipogenic lineages, and utilize them in a “Point-of-Care” non-instrumented posterolateral lumbar spinal fusion. Both BMSCs and ADSCs were confirmed as stem cells through lack of expression of markers CD34, CD45, CD90, and CD105, which is supported by literature. Both cell types also differentiated into both the adipogenic and osteogenic lineages. Although we had positive in vitro results, we had limited in vivo results. There were no differences between BMSCs, ADSCs and control implantation in identifiable spinal fusion at 3 or 6 months through radiographs or CT scans. Additionally, there were no differences between groups at 6 months in biomechanical testing, histology and microradiographs. Although our in vivo results were lacking in demonstrating fusion at 6 months, this study is the first of it’s kind to investigate a large animal model comparison of BMSCs and ADSCs in spinal fusion and demonstrated that “Point-of-Care” stem cells derived from either bone marrow or adipose tissue demonstrated the potential for bone formation. The in vivo results suggests that this model can be used for stem cell research in orthopaedics, but further research needs to be performed to determine their use, proper scaffold and potential osteoinductive materials needed for solid fusion results in the in vivo model. / text Adult stem cells Othopaedics Adipose derived stem cells Bone marrow derived stem cells Goat Spinal fusion
29	Consequence of paraspinal muscle after posterior lumbar spinal fusion: the histology and electromyography findingsin a rabbit model 梁漢邦, Leung, Hon-bong. January 2003 (has links) published_or_final_version / Medical Sciences / Master / Master of Medical Sciences Lumbar vertebrae - Surgery. Spinal fusion. Spine - Surgery. Muscles - Diseases. Rabbits as laboratory animals.
30	Stuburo kaklinės dalies tarpslankstelinių sąnarių išnirimų atstatymo optimizavimas / Optimization of reduction of facet dislocations of the lower cervical spine Kontautas, Egidijus 07 December 2005 (has links) 1. INTRODUCTION Injuries of the lower cervical spine can be among the most devastating injuries of the musculoskeletal system because of the increased risk of the injury to the spinal cord, and also because they so often occur to the younger members of the population (Jones A.A.M. et al., 2003; Sekhon H.S.L. et al., 2001; Ball P.A., 2001). The cervical spine is the most vulnerable spinal segment (Sekhon H.S.L. et al., 2001). The mechanism of cervical spine trauma is defined by the direction and magnitude of the forces that have been applied externally to the head and neck complex resulting in injury (Allen B.L.Jr., 1982). Common injury vectors include flexion, compression, rotation and extension (Allen B.L.Jr., 1982). The pattern of injury is related not only to the external applied force, but also to the initial position or posture of the head and neck at the time of injury (Allen B.L.Jr., 1982). One pattern of these injuries of the lower cervical spine is a facet dislocations (Allen B.L.Jr., 1982). The facet dislocation of the cervical spine result from a hyperflexion injury of the neck (Allen B.L.Jr., 1982). These injuries are characterized radiographically by anterolisthesis of one cervical vertebrae over the other and include the slide anteriorly of the inferior facet of the upper dislocated vertebra over the superior facet of the vertebra below (Allen B.L.Jr., 1982; Razack N. et al., 2000). The facet dislocations of the lower cervical spine represent from 4% to 50% of... [to full text] Medicine Spinal reduction Cervical spine Facet dislocation Spinal fusion Cervical dislocation Spinal trauma

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