Academic literature on the topic 'Thoracolumbar fracture'
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Journal articles on the topic "Thoracolumbar fracture"
Katoh, Hiroyuki, Eijiro Okada, Toshitaka Yoshii, Tsuyoshi Yamada, Kei Watanabe, Keiichi Katsumi, Akihiko Hiyama, et al. "A Comparison of Cervical and Thoracolumbar Fractures Associated with Diffuse Idiopathic Skeletal Hyperostosis—A Nationwide Multicenter Study." Journal of Clinical Medicine 9, no. 1 (January 12, 2020): 208. http://dx.doi.org/10.3390/jcm9010208.
Full textHUBNER, ANDRÉ RAFAEL, MATEUS MEIRA GARCIA, RODRIGO ALVES VIEIRA MAIA, DANIEL GASPARIN, CHARLES LEONARDO ISRAEL, and LEANDRO DE FREITAS SPINELLI. "MECHANICAL BEHAVIOR OF THORACOLUMBAR CORONAL SPLIT FRACTURES: FINITE ELEMENT ANALYSIS." Coluna/Columna 19, no. 3 (July 2020): 205–8. http://dx.doi.org/10.1590/s1808-185120201903223027.
Full textPapadopoulos, Stephen M. "Thoracolumbar Spine Fracture." Neurosurgery 36, no. 1 (January 1995): 209–10. http://dx.doi.org/10.1227/00006123-199501000-00035.
Full textPanjabi, Manohar M., Tec h, Thomas R. Oxland, Ruey-Mo Lin, and Timothy W. McGowen. "Thoracolumbar Burst Fracture." Spine 19, no. 5 (March 1994): 578–85. http://dx.doi.org/10.1097/00007632-199403000-00014.
Full textAstolfi, Matthew M., Paul Millhouse, Hamadi Murphy, Greg Schroeder, and Alexander R. Vaccaro. "Thoracolumbar Fracture Classifications." Contemporary Spine Surgery 19, no. 1 (January 2018): 1–7. http://dx.doi.org/10.1097/01.css.0000527970.36945.2c.
Full textPapadopoulos, Stephen M. "Thoracolumbar Spine Fracture." Neurosurgery 36, no. 1 (January 1995): 209???210. http://dx.doi.org/10.1097/00006123-199501000-00035.
Full textBlumenkopf, Bennett. "Thoracolumbar Burst Fracture." Journal of SPINAL DISORDERS 4, no. 2 (June 1991): 242–43. http://dx.doi.org/10.1097/00002517-199106000-00017.
Full textAlam, Waqar, Faaiz Ali Shah, Ashfaq Ahmed, Qazi Muhammad Amin, Ijaz Ahmed, and Amer Aziz. "UNSTABLE FRACTURE OF THORACOLUMBAR SPINE;." Professional Medical Journal 24, no. 01 (January 18, 2017): 200–204. http://dx.doi.org/10.29309/tpmj/2017.24.01.476.
Full textLikhachev, S. V., V. V. Zaretskov, V. B. Arsenievich, V. V. Ostrovskij, A. E. Shulga, and A. V. Zaretskov. "Outcomes with fracture-level transpedicular screws used for thoracolumbar junction fractures." Genij Ortopedii 26, no. 4 (December 2020): 548–54. http://dx.doi.org/10.18019/1028-4427-2020-26-4-548-554.
Full textSJ, Vihar, Naveen DS, and Agrawal NK. "Comparative study of long segment versus short segment posterior fixation of thoracolumbar fractures with pedicle screws." Journal of Medical and Scientific Research 9, no. 2 (April 19, 2021): 77–84. http://dx.doi.org/10.17727/jmsr.2021/9-12.
Full textDissertations / Theses on the topic "Thoracolumbar fracture"
KATO, FUMIHIKO, NAOKI ISHIGURO, MASAAKI MACHINO, KEIGO ITO, YASUTSUGU YUKAWA, and HIROAKI NAKASHIMA. "COMBINED POSTERIOR-ANTERIOR SURGERY FOR OSTEOPOROTIC DELAYED VERTEBRAL FRACTURE WITH NEUROLOGIC DEFICIT." Nagoya University School of Medicine, 2014. http://hdl.handle.net/2237/20549.
Full textDavis, Johan H. "Thoracolumbar injuries : short segment posterior instrumentation as standalone treatment - thoracolumbar fractures." Thesis, Stellenbosch : University of Stellenbosch, 2010. http://hdl.handle.net/10019.1/5351.
Full textObjective: This research paper reports on the radiographic outcome of unstable thoracolumbar injuries with short segment posterior instrumentation as standalone treatment; in order to review rate of instrumentation failure and identify possible contributing factors. Background: Short segment posterior instrumentation is the treatment method of choice for unstable thoracolumbar injuries in the Acute Spinal Cord Injury Unit (Groote Schuur Hospital). It is considered adequate treatment in fracture cases with an intact posterior longitudinal ligament, and Gaines score below 7 (Parker JW 2000); as well as fracture dislocations, and seatbelt-type injuries (without loss of bone column - bearing integrity). The available body of literature often states instrumentation failure rates of up to 50% (Alanay A 2001, Tezeren G 2005). The same high level of catastrophic hardware failure is not evident in the unit researched. Methods: Sixty-five consecutive patients undergoing the aforementioned surgery were studied. Patients were divided into two main cohorts, namely the “Fracture group” (n=40) consisting of unstable burst fractures and unstable compression fractures; and the “Dislocation group” (n=25) consisting of fracture dislocations and seatbelt-type injuries. The groups reflect similar goals in surgical treatment for the grouped injuries, with reduction in loss of sagittal profile and maintenance thereof being the main aim in the fracture group, appropriately treated with Schantz pin constructs; and maintenance in position only, the goal in the dislocation group, managed with pedicle screw constructs. Data was reviewed in terms of complications, correction of deformity, and subsequent loss of correction with associated instrumentation failure. Secondly, factors influencing the aforementioned were sought, and stratified in terms of relevance. Results: Average follow up was 278 days for the fracture group and 177 days for the dislocation group (all patients included were deemed to have achieved radiological fusion – if fusion technique was employed). There was an average correction in kyphotic deformity of 10.25 degrees. Subsequent loss in sagittal profile averaged 2 degrees (injured level) and 5 degrees (thoracolumbar region) in the combined fracture and dislocation group. The only factor showing a superior trend in loss of reduction achieved was the absence of bone graft (when non-fusion technique was employed). Instrumentation complications occurred in two cases (bent connection rods in a Schantz pin construct with exaggerated loss in regional sagittal profile, and bent Schantz pins). These complications represent a 3.07% hardware failure in total. None of the failures were considered catastrophic. Conclusion: Short segment posterior instrumentation is a safe and effective option in the treatment of unstable thoracolumbar fractures as a standalone measure.
Figueiredo, Adriana Valente de. "Estudo biomecânico ex vivo em coluna tóraco-lombar de cães com técnicas de estabilização utilizando Placa Bloqueada, Clamp Rod Internal Fixation, Pino com Cimento Ósseo e Técnica Segmentar Modificada." Universidade de São Paulo, 2013. http://www.teses.usp.br/teses/disponiveis/10/10137/tde-20082014-145759/.
Full textSpinal fractures and luxations resulting from trauma consist frequent disorder in clinical veterinary practice, being thoracolumbar spine the region that is the most commonly affected in canines, thus in many cases surgical treatment is necessary. There are several proposed techniques of implants to perform spinal stabilization; however, few studies of the thoracolumbar spine were carried out to evaluate the biomechanical properties of each technic. Therefore, the objective of the present study is to analyze biomechanical effects comparing the strength and the stiffness promoted by five different technics of stabilization in the thoracolumbar spine (pin with bone cement, modified segmental stabilization, locking plate and clamp rod internal fixation) under compression and bending forces. In the study, thirty four thoracolumbar dog spines were used, dividing the specimens in five groups. In order to perform the biomechanical tests, it was used a Kratos testing machine (model KE3000MP) and loading cell of 100 Kg. Each body of proof was submitted to three biomechanical tests, the control, in the segment intact, after disarticulation of the T13/L1 and after the realization of one of the proposed technics. Data were exported to statistical analyses to the Statistical Package for the Social Sciences (SPSS) version 18.0. The results led to the conclusion that despite there was no statistically significant difference between the techniques, the Locking Plate was the technique that promoted greater rigidity and stability in the injured vertebrae, followed by the Clamp Rod Internal Fixation bicortical, Modified Segmental Instrumentation and Pins with Bone Cement. Statistically, the locking plate and the Clamp Rod Internal Fixation with bicortical pins showed more stiffness and stability in T13/L1 when compared to the Clamp Rod Internal Fixation monocortical, which did not achieved the adequate rigidity for the stabilization of the vertebrae.
Wang, Wei-Kai, and 王微凱. "Finite Element Analysis of Fixation Methods of Thoracolumbar Burst Fracture." Thesis, 2005. http://ndltd.ncl.edu.tw/handle/14467620788284823361.
Full text國立陽明大學
復健科技輔具研究所
93
Pedicle screw fixation has been a standard procedure to treat thoracolumbar burst fracture. The aim of surgery is to achieve a post-operation spinal stabilization and enhance bony fusion. There are good clinical results followed up with pedicle fixation, but some complications as pedicle screw loosening or body collapse were found clinically. Additionally, the major studies in pedicle screw fixation were employed using cadaver and animal models. Few literatures are associated with finite element methods. The goal of this study is to establish a three-dimensional finite element model of the thoracolumbar (TL) spine T11-L3 and analyze the surgical methods of two-, three- and four segments fixation. In this study, we expect to find the most proper fixation method to manage thoracolumbar burst fracture. In this study, a 3-D finite element model of TL spine was established that based on the CT images from a 26 y/o male. The software Image J 1.31V (Wayne Rasband National Institutes of Health, USA) was used to determine the geometry of the TL spine and built by the finite element software ANSYS8.1 (Swanson Analysis System Inc., Houston, TX, USA). The model included cancellous bone, cortical bone, posterior element, disc, endplate, and spinal ligament. The material properties were adopted from previous literatures. After verifying the TL spine model, an L1 corpectomy model was performed to simulate serious burst fracture. The pedicle screws were implanted to the model and to analyze the influence of the different fixation methods. The four models included two segment fixation (TSF), Up-three segment fixation (UTSF), Below-three segment fixation (BTSF) and four segment fixation (FSF). In normal bone density model, the TSF model increased the range of motion (ROM) with respect to all other fixed model under the different loading conditions. On the flexion motion, the TSF model was 105% greater than other model (UTSF: 93%; BTSF: 95%; FSF: 79%). On the lateral bending motion, the TSF model was 20% also greater than other model (UTSF: 9%; BTSF: 9%; FSF: 0.8%). The TSF model was 10% a little greater than other model (UTSF: 4%; BTSF: 4%; FSF: 0.5%) under the extension motion. On the torsion motion, the TSF model was 56% greater than other model (UTSF: 47%; BTSF: 50%; FSF: 44%). The osteoporosis model was the same tendency to toward the normal bone density model. On the flexion motion, the TSF model was 109% greater than other model (UTSF: 100%; BTSF: 100%; FSF: 89%). On the lateral bending motion, the TSF model was 38% also greater than other model (UTSF: 16%; BTSF: 18%; FSF: 2%). The TSF model was 13% a little greater than other model (UTSF: 4%; BTSF: 6%; FSF: 1%) under the extension motion. On the torsion motion, the TSF model was 64% greater than other model (UTSF: 58%; BTSF: 61%; FSF: 50%). Furthermore, the percentage of anterior body compression (%ABC) with “TSF”, “UTSF”, “BTSF” and “FSF” was 68.8%, 70.6%, 70.6% and 72.5% in the normal bone density model. %ABC with “TSF”, “UTSF”, “BTSF” and “FSF” was 66.6%, 70.3%, 70.3% and 72.5% in the osteoporosis model. According to the results, the ROM of UTSF, BTSF and FSF were smaller than TSF under various loading condition. The mean was that the methods of long segment fixation provided the better stability for the spinal structure than the short segment fixation. Especially, on the flexion motion, the ROM of TSF were over the intact model in the different bone density models that seems the TSF method was imperfect to manage the thoracolumbar burst fracture. Because of the additional fixation systems were provide the stronger stiffness than TSF method. The additional stiffness provided the unstable spine more stability. Although the ROM of FSF were the smallest, but the %ABC were no significant differences during the long segment fixation that to prevent the collapse were to be similar. The study also to change bone mineral density to simulate the osteoporosis. When decreasing the BMD to 0.08 g/cm3 to simulate the osteoporosis. The ROM of four models were all increased to compare with the normal bone model. The long segment fixation methods were better than TSF method to manage the thoracolumbar burst fracture, FSF method especially. The TSF method for burst fracture was difficult to prevent body collapse.
Cho-HsuanTsai and 蔡卓軒. "Finite Element Analysis of Biomechanics on Thoracolumbar Burst Fracture after Posterior Spinal Fixation." Thesis, 2011. http://ndltd.ncl.edu.tw/handle/66487355719024160670.
Full textYu-HengHuang and 黃友恒. "Finite Element Analysis of Biomechanics for Osteoporotic Thoracolumbar Vertebral Fracture after Decompression and Internal Fixation." Thesis, 2013. http://ndltd.ncl.edu.tw/handle/60716311344713702810.
Full text國立成功大學
土木工程學系碩博士班
101
Facing the rapid aging of the population in the world, osteoporosis becomes an important issue for the bone health of elders. It’s more frequent that the vertebral fracture happened to the osteoporosis patients because of colliding or falling down. When the vertebral fracture happened, the bone fragments sometimes compress the nervous system or spinal cord. If the conservative treatment is failed, it needs to decompress the neural compression by surgery. Because the vertebra has been destroyed, if we perform the decompression surgery, the stability of the spine will be worse. Therefore, it must combine internal fixation to maintain the stability of the spine, and different surgical methods have the corresponding biomechanical performances. The research about the fracture of osteoporotic thoracolumbar vertebrae after decompression and internal fixation is not widely studied. The purpose of this study is to explore the biomechanical behaviors of the decompression surgery in combination with various kinds of spinal surgeries for patients with osteoporotic thoracolumbar vertebral fractures and to analyze the postoperative stability. We adopt Anterior vertebral body replacement surgery with posterior instrumentation, Posterior laminectomy with short or long-segment posterior instrumentation with or without PMMA (Polymethylmethacrylate )vertebroplasty as the design of this study. We analyze the biomechanical behavior and explore the stability of the spine in the different surgical models to provide a valuable reference on surgery. This study used the computed tomography and the finite element package software to create the model of the spine, and selected segments from T10 to L3. We supposed that L1 vertebra has a fracture and changed the material strength of middle half of L1 vertebral body by decreasing the elastic moduli to 10% of that of original cortical and cancellous bones to simulate the osteoporotic fracture condition. In addition we implanted the pedicle screws or vertebral body cage into the spinal models. To observe the stress distribution, stability, and relative rotation angles of the spine under extension, flexion, lateral bending and axial rotation.
Yu-XuanWang and 王喻璿. "Finite Element Analysis of Biomechanics for Osteoporotic Thoracolumbar Vertebral Fracture after Vertebroplasty or Posterior Spinal Fixation." Thesis, 2012. http://ndltd.ncl.edu.tw/handle/64078533627927387503.
Full text國立成功大學
土木工程學系碩博士班
100
The elderly generally have symptoms of osteoporosis, compression fractures caused by osteoporosis is a growing trend with Taiwan to become an aging society. In the present study, less attention to the study of osteoporosis patients received surgical treatment for thoracolumbar fractures for osteoporosis patients receiving surgery, including Vertebroplasty or Posterior Spinal Fixation, various operation would have the spine have different mechanical performance. In order to understand the Biomechanics for Osteoporotic Thoracolumbar Vertebral Fracture after surgery, we use finite element software Patran, ABAQUS to analyze and consider different control variables such as different materials for bone cement(PMMA ,CPC), the location where bone cement inject, the effect of implanting pedicle screws or not. Use these to analyze the effects in Biomechanics. CT scans used in this study to establish the spine module, in the lumbar part of Section 1 (L1), take the position of the middle half, weakening the material parameters of cancellous bone and cortical bone for the tenth to simulate the case of fracture of the lumbar section I. Also, we established pedicle screw system with screw thread, and we use FEM software Patran to insert pedicle screw into T12 and L2 segments. Finally, stress in the pedicle screws , stress in the segments near L1 fracture, spinal stabilities and ROM under four motions(Flexion, Extension, Lateral Bending and Rotation) were compared.
Khan, Shahzad Ali. "Minimally invasive posterior spinal fusion in unstable thoracolumbar." Thesis, 2017. http://hdl.handle.net/10539/23179.
Full textBackground Unstable Thoracolumbar spinal fractures are conventionally treated by open reduction and internal fixation. This involves extensive mobilization of paraspinal muscles, which in turn leads to long-term disability in the form of chronic backache. One of the reasons fractures are stabilized is to prevent kyphotic deformity. Posterior lumbar stabilization done through a minimally invasive technique can achieve the same result as the open technique at the expense of less mobilization of the paraspinal muscles. Aim of the study The aim of the study was to assess the effectiveness of minimally invasive posterior spinal fixation in unstable Thoraco-lumbar fractures in our setting at Charlotte Maxeke Academic Hospital. Objectives To assess the effectiveness of Minimally Invasive Spine Surgery over a short term of minimum of 12 months regarding: Maintaining the correction of fracture kyphosis, Re-operations and Any serious Adverse Events Methodology This was a prospective interventional pilot study. Fractures were classified according to the AO comprehensive system. AO Comprehensive classification fractures A3, B1, B2, C1 and C2 were considered suitable for this technique. Pre-operative, immediate post-operative and one year follow up Cobb’s angles of fracture kyphosis were measured on plain lateral x-rays. Any Serious Adverse Events (SAE) that may have required re-operations were recorded over the minimum of 12 months follow up. Results Twenty patients met the inclusion criteria for this study. Post-operative follow up ranged between 12 and 22 months. There were 14 males and 6 females. The age ranged between 16 years to 54 years with mean of 33.9 years. L1 was the most commonly fractured vertebra. Eleven out of 20 patients sustained fracture of L1, 6 patients had fracture of L2 whereas 3 patients sustained fracture of T12. The AO classification types included one B1, five B2, seven C1 and seven C2 fractures. The pre-operative Cobb’s angle ranged from 7 degrees to 38 degrees with mean of 21.2 degrees. The immediate post-operative Cobb’s angle ranged between zero degrees to 16 degrees with mean of 8.3 degrees. The last follow up Cobb’s angle ranged between zero degrees to 21 degrees with a mean of 10.7 degrees. The loss of correction of fracture kyphosis ranged between zero degrees to 6 degrees with a mean of 2.4 degrees. The post-operative Cobb’s angle was maintained. There was no deterioration of pre-operative neurological status. There was no serious adverse event requiring a re-operation. Conclusion Minimally Invasive Posterior Spinal stabilization for thoracolumbar fractures had an acceptable outcome in our hands in appropriately selected cases. The average loss of correction of 2.4 degrees was in keeping with that found in open technique as well as MIS at other centers. While the number is less, this procedure can be recommended for well selected patients where skills are available.
MT2017
Goulet, Julien. "Prédicteurs de l'issue neurologique : adapter la conduite chirurgicale chez les blessés médullaires thoraco-lombaires." Thesis, 2020. http://hdl.handle.net/1866/25187.
Full textTraumatic spinal cord injury (TSCI) is a debilitating condition that leads to many adverse consequences on a personal, physical and social standpoint for the injured victim. Medical and surgical care evolved along with the progression of understanding regarding what factors lead to better neurological recovery and overall quality of life in paralyzed patients. With respect to surgical care, modifiable factors significantly related to neurological recovery in thoracolumbar TSCI are not well known. In this regard, the optimal timing threshold for surgical spinal decompression and stabilization has not been demonstrated objectively. Moreover, there are no radiological parameter on the pre-operative computed tomography scan (CT scan) that have been shown to predict long term neurological outcome. The main goal of the presented work is to provide precise identification of such factors, and therefore evaluate the impact of the spine fracture specific morphological features on the effect of early surgical care. The first part involves the assessment of the optimal surgical timing threshold for neurological recovery. A retrospective clinical study was conducted to evaluate several neurological outcome measures in a prospective cohort of 35 thoracolumbar TSCI patients. Thresholds were obtained from the elaboration of prediction models with the use of Classification And Regression Tree (CART) statistical analysis. The first article demonstrated that for optimal recovery of the neurological level of injury, a timing threshold of a maximum of 21 hours should ideally be respected between the traumatic event and the beginning of the surgical intervention. The second part encompasses the study of the morphology of the fractured vertebrae in thoracolumbar burst fractures. Many radiological descriptors are used to describe these severe spine compression injuries but few have been evaluated with regards to neurological recovery. A second retrospective clinical study was conducted and associated a thorough examination of the preoperative CT scan reconstructions to the assessment of long term neurological outcome. Three morphologic parameters were found to be linked to poor prognostic of neurological recovery: complete lamina fracture, comminution of the posteriorly retropulsed fragment and vertebral body postero-inferior corner translation of 4 mm or more. Such features, all three describing the disrupted anatomy of the spinal canal, could be potential indicators of the amount of energy locally dissipated to the neural elements. These parameters were found to be more important to predict neurological outcome than the initial neurologic examination and global trauma energy indicators. The third part integrates the notions derived from the two presented studies and aims to assess for the influence of the presence of specific fracture parameters on the effect of early surgery regarding neurological outcome. Additional analyses did not show that the advantage of early surgery, defined in the first article, was influenced by the presence of any of the relevant fracture features demonstrated in the second article. Therefore, this work emphasizes on the importance of early surgery for better neurological recovery and serves to guide the surgeon in planning the timing of the intervention. Defining the concept of early surgery is key in implementing future retrospective or prospective research protocols. It also highlights the importance of new morphological features of the most common type of thoracolumbar fracture. It sets standards for further research involving preoperative CT scan parameters and their potential relationship with surgical approach, neurological and non-neurological outcomes.
Yang, Wen-Ta, and 楊文達. "A Biomechanical Study of the Unilateral Intermediate Screw in the Short Segment Pedicular Fixation for Unstable Thoracolumbar Burst Fractures." Thesis, 2007. http://ndltd.ncl.edu.tw/handle/51243922136037553661.
Full text國立陽明大學
醫學工程研究所
95
Two goals must be achieved during the surgical treatment of thoracolumbar burst fractures. One is decompression of the spinal canal to make a good condition for neural recovery, and the other is re-establishment of the mechanical stability of the injured spine. By doing so, patients with thoracolumbar burst fractures will be mobilized earlier, and the risk of post-traumatic kyphosis can be decreased. Because of easier approach, fewer motion segments sacrificed, shorter surgical time spent, and less blood loss, posterior short segment fixation with pedicle screw systems has been used widely to manage unstable thoracolumbar burst fractures. However, post-traumatic kyphosis caused by loss of reduction and implant failures is not uncommon. To solve these problems, instrumentation with additional bilateral pedicle screws, or intermediate screws, at the level of the fractured vertebra had been studied and shown to increase the stiffness of the short segment construct. However, this 6-screw construct may interfere a possible anterior decompression after the posterior instrumentation. Posterior short segment instrumentation with a single pedicle screw, or a lordirizing screw, at the fractured vertebra has been shown to yield similar clinical outcomes with the intermediate screws. By preserving one pedicle of the fractured vertebra, an anterior decompression, if necessary, can be carried out with less interference after the posterior instrumentation with this 5-screw construct. Though the clinical outcomes are compatible between the 5-screw and 6-screw constructs, the biomechanical behavior of the 5-screw one is still not known. The purpose of this study is to clarify whether the lordorizing screw can significantly increase the stiffness of the conventional short segment construct. Fresh frozen porcine lumbar spines with a 5-vertebrae segment (L1-L5) were prepared for this study. The burst fracture was simulated by corpectomy of L3. Each specimen was tested as an intact spine, as a fractured spine fixed by a 4-screw construct, as a fractured spine fixed by a 5-screw construct and as a fractured spine fixed by a 6-screw construct. Biomechanical tests with flexion, extension, lateral bending, torsion and compression were carried out for each specimen. The results showed that the slopes of the load displacement curves of the 5-screw and 6-screw constructs increased significantly in right lateral bending (4-screw vs. 5-scrwe p=0.023; 4-screw vs. 6-scrwe p=0.014) and less significant in flexion (4-screw vs. 5-scrwe p=0.065; 4-screw vs. 6-scrwe p=0.067) when they were compared with the 4-screw construct. No significant difference was found between the slopes of the 5-screw and 6-screw constructs. This study showed that the stability on flexion and right lateral bending was similar between the 5-screw and 6-screw constructs, and both were better than the 4-screw construct.
Books on the topic "Thoracolumbar fracture"
Fabris, Daniele A. The surgical correction of spinal deformities: Instrumentation strategies for scoliosis, thoracolumbar fractures, degenerative lumbosacral spine. Padova: CLEUP University Press, 1998.
Find full textFabris, Daniele A. The surgical correction of spinal deformities: Instrumentation strategies for scoliosis, thoracolumbar fractures, degenerative lumbosacral spine. Padova: CLEUP, 1998.
Find full textSell, Philip. Thoracolumbar, lumbar, and sacral fractures. Oxford University Press, 2011. http://dx.doi.org/10.1093/med/9780199550647.003.012043.
Full textYizhar, Floman, Farcy Jean-Pierre C, and Argenson Claude, eds. Thoracolumbar spine fractures. New York: Raven Press, 1993.
Find full textManagement of thoracolumbar fractures. Rosemont, IL: American Academy of Orthopaedic Surgeons, 2004.
Find full textA, Reitman Charles, ed. Management of thoracolumbar fractures. Rosemont, IL: American Academy of Orthopaedic Surgeons, 2004.
Find full textShannon, Stauffer E., and An Howard S, eds. Thoracolumbar spine fractures without neurological deficit. Rosemont, IL: American Academy of Orthopaedic Surgeons, 1993.
Find full textCharles A., M.D. Reitman. Management of Thoracolumbar Fractures (Monograph Series (American Academy of Orthopaedic Surgeons)). Amer Acad of Orthopaedic Surgeons, 2004.
Find full textFinfer, Simon, and Oliver Flower. Assessment and immediate management of spinal cord injury. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199600830.003.0344.
Full textBook chapters on the topic "Thoracolumbar fracture"
Babu, Jacob. "Thoracolumbar Fracture." In Essential Orthopedic Review, 233–34. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-78387-1_104.
Full textDunsmuir, Robert A. "Thoracolumbar Fractures." In Fracture Reduction and Fixation Techniques, 15–30. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-24608-2_2.
Full textMakhni, Melvin C., Eric C. Makhni, Eric F. Swart, and Charles S. Day. "Thoracolumbar Fracture-Dislocation." In Orthopedic Emergencies, 87–89. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-31524-9_24.
Full textNeal, Kevin M. "Thoracolumbar Flexion-Distraction Injuries: Chance Fracture-Dislocations." In Pediatric Orthopedic Trauma Case Atlas, 1–4. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-28226-8_74-1.
Full textOner, F. C. "Posterior Decompression Technique for Thoracolumbar Burst Fracture." In Spine Trauma, 283–89. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-03694-1_24.
Full textNeal, Kevin M. "Thoracolumbar Flexion-Distraction Injuries: Chance Fracture-Dislocations." In Pediatric Orthopedic Trauma Case Atlas, 465–68. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-319-29980-8_74.
Full textDiPaola, Christian P., and Brian K. Kwon. "Posterior Instrumentation for Thoracolumbar and Lumbar Fracture Dislocation." In Spine Trauma, 271–82. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-03694-1_23.
Full textPneumaticos, Spiros G., George K. Triantafyllopoulos, and Nick G. Lasanianos. "Thoracolumbar Fractures." In Trauma and Orthopaedic Classifications, 223–25. London: Springer London, 2014. http://dx.doi.org/10.1007/978-1-4471-6572-9_49.
Full textAgarwal, A. "Thoracolumbar Fractures." In Current Orthopedic diagnosis & treatment, 182–83. London: Current Medicine Group, 2000. http://dx.doi.org/10.1007/978-1-4613-1107-2_91.
Full textMakhni, Melvin C., Eric C. Makhni, Eric F. Swart, and Charles S. Day. "Thoracolumbar Fractures." In Orthopedic Emergencies, 65–69. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-31524-9_19.
Full textConference papers on the topic "Thoracolumbar fracture"
Wahba, George M., Nitin N. Bhatia, and Thay Q. Lee. "Biomechanical Evaluation of Short-Segment Posterior Instrumentation With Crosslinks in an Unstable Human Burst Fracture Model." In ASME 2009 4th Frontiers in Biomedical Devices Conference. ASMEDC, 2009. http://dx.doi.org/10.1115/biomed2009-83066.
Full textAlizadeh, Mina, Mohammed Rafiq Abdul Kadir, and Saturnino Saldanha. "Biomechanical effects of short construct spine posterior fixation, in thoracolumbar region with L1 burst fracture." In 2010 IEEE EMBS Conference on Biomedical Engineering and Sciences (IECBES). IEEE, 2010. http://dx.doi.org/10.1109/iecbes.2010.5742280.
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