© v.v. rerikh et al., 2017
surgical treatment of thoracic and lumbar spine fractures using transpedicular vertebroplasty and fixation
V.V. Rerikh1,2, M.U. Baidarbekov1,3, M.A. Sadovoy1,2, N.D. Batpenov3, I.A. Kirilova1
1Novosibirsk Research Institute of Traumatology and Orthopaedics n.a. Ya.L. Tsivyan 2Novosibirsk State Medical University, Novosibirsk, Russia 3Scientific Research Institute of Traumatology and Orthopaedics, Astana, Republic of Kazakhstan
Objective. To analyze treatment results in patients with fractures of thoracic and lumbar vertebal bodies after transpedicular vertebroplasty and fixation through minimally invasive percutaneous and open approaches. Material and Methods. A total of 154 patients with uncomplicated type A2, A3 fractures of the thoracic and lumbar vertebral bodies were operated on. All patients were examined with X-ray densitometry, spondylog-raphy, and CT. Group 1 included 53 patients who underwent vertebroplasty with deproteinized bone graft and percutaneous transpedicular fixation. Patients of Group 2 (n = 41), Group 3 (n = 43) and Group 4 (n = 17) underwent open transpedicular fixation and vertebroplasty with deproteinized bone graft (Group 2) and titanium nikilide granules (Groups 3 and 4). Results. Intraoperative blood loss during open vertebroplasty combined with short-segment transpedicular fixation exceeded that during percutaneous vertebroplasty. Parameters of kyphotic deformity, the wedge index and the loss of correction did not differ significantly except for Group 4. Significant improvement in ODI and VAS scores was noted after percutaneous vertebroplasty as compared with control groups. Conclusion. Transpedicular verteboplasty and transpedicular fixation, both open and percutaneous, performed for the treatment of type A2 and A3 spinal fractures provide reliable stabilization of the injured spinal segments, allow vertebral body height restoration to a greater extent and correction of the kyphotic deformity.
Key Words: spinal fractures, transpedicular fixation, percutaneous vertebroplasty, open transpedicular vertebroplasty.
Please cite this paper as: Rerikh VV, Baidarbekov MU, Sadovoy MA, Batpenov ND, Kirilova IA. Surgical treatment of thoracic and lumbar spine fractures using transpedicular vertebroplasty and fixation. Hir. Pozvonoc. 2017; 14(3):54—61. In Russian. DOI: http://dx.doi.org/10.14531/ss20173.54-61.
Open anterior and posterior approaches are the gold standard in the surgical treatment of spinal injuries. However, despite restoring the supporting ability of the spine, these techniques have also several drawbacks: long operating room times, complicated procedure, and the potential risks of vascular and neural injury [10, 13, 30, 37]. Standard approaches to the posterior vertebral compartments are effectively used for curve correction and stabilization of injured segments [18]. The efficacy of the posterior internal fixation is a result of the long fixation length. Nevertheless, the long length arrests the function of non-injured spinal segments, impairs perfusion and innervation of paravertebral muscles, often leading to their fibrosis, thereby resulting in postoperative persistent pain syndrome
and longer rehabilitation times [12, 15, 18].
Minimally invasive techniques, including transcutaneous vertebroplasty of the fractured vertebra and transpedicular fixation (TPF) have been used in the last decade for the treatment of patients with the thoracic and lumbar spine injuries [23, 38, 39]. An analysis comparing the efficacy of transcutaneous and open short-segment fixation with transpedicu-lar vertebroplasty is not available and this circumstance motivated us to this study.
The purpose of this paper is to analyze the treatment outcomes in patients with fractures of thoracic and lumbar vertebral bodies after transpedicular ver-tebroplasty and fixation through minimally invasive transcutaneous and open approaches.
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Material and Methods
A total of 154 patients aged 38-64 years were operated on in the Clinic of Spinal Pathology, Novosibirsk RITO and at the Department of Traumatology No. 1, RITO, Astana (Kazakhstan) in 2013-2015. The patients had uncomplicated solitary fractures of the T11-L2 vertebral bodies classified as types A2 and A3 according to Magerl et al. [28], at least 7 scores on the Load Sharing Classification (LSC) proposed by McCormack [31], and did not have osteoporosis.
The patients were divided into four groups based on the surgical approach and the type of bone grafting material (Table 1). Group I included 53 patients operated on using transcutaneous TPF and grafting of deproteinized cancellous bone (DCB) [4]. Surgical intervention was performed according to the developed
method using devices for the delivery of osteoplastic material [5, 7].
Group II included 41 (26.6 %) patients who underwent open transpedicular grafting and TPF. The DCB was used for vertebroplasty.
Group III included 43 (39.0 %) patients operated on using open transpedicular vertebroplasty and TPF. Granules of titanium nickelide (NiTi) were used as grafting material.
Group IV included 17 patients with fractures estimated as greater than 8 by the LSC, who underwent open transpedicular grafting and TPF. NiTi granules were used for vertebroplasty.
The difference between open trans-pedicular vertebroplasty with TPF and transcutaneous vertebroplasty with TPF was as follows: the first procedure involved the postural correction of kyphosis through positioning of the patient on an operating table in an extension position followed by screw insertion, vertebroplasty, and an extra local extension created after construct implantation. The transcutaneous procedure incorporated an extension positioning of the patient on an operating table for postural correction and unilateral screw insertion; local extension using instrumentation and vertebroplasty using DCB were then performed [4].
The bone mineral density (BMD) was assessed using the Duo Diagnost Sonost-2000 dual energy roentgen densitometer. All patients underwent multi-slice helical CT, frontal and lateral standard spondylography of the fractured spinal segments as well as lateral spon-dylography when the patient lied in the maximum extension position. The
intensity of the deformity of the injured spinal segment was graded from kypho-sis measures and the vertebral wedge indexon routine radiographs. Kyphosis was assessed from the cranial endplate of the overlying vertebra to the caudal endplate of the underlying intact vertebra [32]. The wedge index was estimated using the ratio of the anterior height of the injured vertebrae to the height of anterior portions of adjacent vertebrae [19]. The amount of kyphosis correction and the height restoration of the fractured vertebra were estimated from lateral radiograms recorded in the supine extension position on a cushion. Intraoperative blood loss was assessed by intraoperative material weighing (napkins, balls) on electronic scales and the volume of blood during vacuum aspiration. The amount of administered grafting material necessary for the complete correction of the fractured vertebral body was estimated using the formula: Vpl = nR2 (hi - h2), where Vpl - the volume of osteoplastic material, mm3; R -the vertebral body radius in the frontal plane, mm; h1 -vertebral body height prior to compression (the mean height of adjacent vertebrae, mm), h2 -vertebral body height after compression, mm [1]. The weight of administered DCB was 5.76 ± 1.09 g and the weight of NiTi granules was greater by 1.35 g than that of DCB based on the specific weight of NiTi granules. The Oswestry index [9] was used to evaluate the long-term function after vertebro-plasty and VAS scale [27] - to assess pain intensity. ODI scoring: 0 to 20 %- minimal disability, 20 to 40 % - moderate disability, 40 to 60 % - severe disability, 60 to 80 %-incapacitating pain, and 80 to
100 % - these patients are either bed-bound or have an exaggeration of their symptoms.
Statistical measures: the mean and standard deviation were used for quantitative data. Magnitude frequencies and percentages are given for qualitative data. The quantitative data were tested for normality using the Shapiro-Wilk test. Since almost all data had non-normal distribution, nonparametric Mann-Whitney test was used for the comparisons of independent samples. A p-value of < 0.05 was considered statistically significant. Statistical estimations were performed using the IBM SPSS 19 software [2, 3].
Results
The treatment outcomes were traced immediately after surgery, in the short-term period up to 4 months, and in the long-term period - 6 to 24 months. The average intraoperative blood loss was 145.80 ± 90.35 ml in group I, 193.70 ± 110.60 ml - in II, 162.80 ± 57.20 ml -in III, i.e., the volume of blood loss was statistically equal in groups I and III, while in group II it significantly exceeded that of the main group.
The LSC indices were 7.0 ± 0.8 in group I, 7.0 ± 0.9- in II, and 7.0 ± 0.9-in III, which were statistically comparable (p < 0.05). However, it is emphasized that LSC scores reached 8-9 in 17 patients in group IV.
Preoperative kyphotic deformity was 10.30° ± 2.86° in group I, 10.40° ± 3.89°-in II, and 10.70° ± 4.04° - in III, which means that preoperative data were comparable equal between the groups and did not differ significantly (p < 0.05).
Table 1 Characterization of study groups
Group Age, years Fracture type, n (%) Escore, SD
Ä2 Ä3
|I (n = 53) 55.6 ± 9.2 30 (56.6) 23 (43.4) 1.91 ± 0.50
II (n = 41) 60.0 ± 8.8 23 (56.0) 18 (43.9) 2.28 ± 0.60
III (n = 43) 46.6 ± 13.6* 30 (50.0) 30 (50.0) 1.84 ± 0.70
IV (n = 17) 48.1 ± 9.4 7 (41.0) 10 (59.0) 1.83 ± 0.80
^significant differences compared to group I ^ > 0.05).
Kyphotic deformity was approximately 13.20° ± 3.04° in group IV, which indicates that this parameter exceeds that of other groups and is related to sample selection criteria. The postoperative magnitudes of kyphotic deformity significantly decreased in all groups: in I - to 0.50° ± 0.91°, in II - to 1.40° ± 2.12°, in III - to 1.60° ± 2.0°, and in IV - to 1.90° ± 2.25°. Pairwise comparison of magnitudes from all groups with group I revealed significantly exceeded postoperative correction of kyphotic deformity in group I compared to other groups (p < 0.05; Table 2).
Preoperatively, the wedge index was 133.0 ±19.0 % in group I, 136.6 ± 22.2 % - in II, 146.7 ± 23.2 % - in III, and 151.6 ± 6.1 % - in IV, indicating that the data of groups I and II were equal and the data of group I were significantly lower compared to groups III and IV (p < 0.05). The postoperative wedge index significantly decreased in all groups: I - to 105.5 ± 5.5 %, II - to 105.5 ± 8.2%, III - to 110.8 ± 9.9%, and IV - to 109.6 ± 7.2 %. Pair-wise comparison of the wedge indices revealed that the vertebral body height was equal in groups I and II, but the wedge indices were higher in groups III and IV than in group I (p < 0.05).
Therefore, it was revealed that along with the postoperative decline in the deformity magnitudes of the fractured spinal segment in all groups, significant improvements in the correction of kyphosis in group I compared to other groups (p < 0.05) and in the wedge index in group I compared to groups III and IV (p < 0.05) were achieved.
In the short-term postoperative period, the slight aggravation of kyphotic
deformity in groups II, III, IV was not reliable. However, pairwise comparison of this indicator in group I with that in other groups detected that kyphotic deformity reliably worsened in all other groups. In the long-term period, kypho-sis increased in all groups, but there were no significant differences in the curve progression in pairwise comparison (p > 0.05; Table 2).
In the short-term postoperative period, the wedge indices tended to grow in all groups. Pairwise comparison did not reveal any significant differences between groups I and II. However,when wedge indices of groups I, III, and IV were compared, the wedge indices of group I were significantly lower than those in groups III and IV (p < 0.05). In the long-term postoperative period,vertebral wedging increased in all groups; there were no significant differences in the progression of the wedge index in pairwise comparison (p > 0.05). It is noted that the major loss of kyphosis correction in the short-term and long-term periods was observed in group IV (p < 0.05; Table 3).
Preoperative BMD indices in the groups were within the range of osteo-penia due to that this range was an inclusion criterion in study groups (T-score up to -2.4 SD). The mean preoperative value of BMD in group I was -1.9 SD and in the long-term period -2.2 SD; in group II preoperative T-score was -2.2 SD, and in the long-term period -2.3 SD; in groups III and IV preoperative T-score was -1.8 SD and in the long-term period -2.4 SD (Table 4). Thus, despite a significant exceeding of BMD indices in group II compared with group I, T-scores in
all groups were the same and did not decrease below the threshold of osteo-penia in the long term period.
There were no significant differences between group I and other groups when VAS scores were compared in the short-term postoperative period (p > 0.05). Similar results were obtained when the Oswestry index was compared (p > 0.05; Table 5).
A comparison of VAS scores in the long-term periods revealed a significant alleviation of pain syndrome: to 1.90 ± 1.58 scores - in group I, to 2.80 ± 1.27 scores - in II, to 3.00 ± 1.07 scores -in III and IV (p < 0.05). Based on the Oswestry index,the worst outcomes were observed in group IV (p < 0.001). Thus, in addition to the alleviation of pain syndrome in the short-term period in all groups, the alleviation of pain syndrome remained in the long-term postoperative period only when using minimally invasive techniques indicating the efficacy of the method.
Only one patient from group I experienced a complication in form of infectious infiltration of hematoma in postoperative wound, which was relieved by vacuum drainage up to complete healing. In group II, six patients required secondary surgical wound cleaning via resection of the necrotic margins with placement of secondary sutures.
Discussion
The foreign literature includes numerous references on the use of transcutaneous vertebroplasty and TPF in the treatment
Table 2 Deformity magnitudes of the fractured spinal segment in the short-term and the long-term postoperative periods in the study groups
Group Kyphosis, degree The wedc e index, %
the short-term postoperative period the long-term postoperative period the short-term postoperative period the long-term postoperative period
|I (n = 53) 0.5 ± 0.9 2.1 ± 2.3 107.3 ± 7.6 110.8 ± 12.9
II (n = 41) 1.4 ± 2.1* 3.8 ±4.3** 109.1 ± 11.8** 112.2 ± 15.6**
III (n = 43) 2.0 ± 2.6* 3.4 ± 4.2** 110.3 ± 10.3* 111.7 ± 10.7**
IV (n = 17) 3.0 ± 2.7* 3.6 ± 3.2** 111.6 ± 11.6* 112.6 ± 12.8**
^significant differences 0.05), **insignificant differences ^ > 0.05).
Table 3
The mean magnitudes of correction loss in groups studied
Group Loss of correction, degrees
the short-term period the long-term period
|I (n = 53) 1.0 ± 1.6 2.0 ± 2.2
II (n = 41) 2.0 ± 3.3* 2.0 ± 3.5**
III (n = 43) 1.0 ± 1.1** 1.0 ± 2.0**
IV (n = 17) 3.2 ± 1.5* 3.5 ± 1.7*
^significant differences ^ < 0.05), **insignificant differences ^ > 0.05).
Table 4
Densitometry indices of the spine according to ^score in study groups
Group ^score, SD
preoperative the long-term period
|i -1.91 ± 0.50 -2.22 ± 0.40
II -2.28 ± 0.60* -2.33 ± 0.40**
III -1.84 ± 0.70** -2.48 ± 1.20**
IV -1.83 ± 0.60** -2.30 ± 0.40**
^significant differences ^ < 0.05), **insignificant differences ^ > 0.05).
of the thoracic and lumbar spinal fractures [23, 38, 40].
Minimally invasive technique, an alternative to traditional approaches, can substantially reduce the traumatization degree of a surgical intervention, intraoperative blood loss, operating times, and the risk of infectious complications, permits stabilization and elimination of kyphotic deformity [6, 8, 11, 33, 34, 36]. In addition, cost minimization in the treatment of patients with spinal fractures is also an important issue [29].
Thoracic and lumbar vertebral fractures with at least 6 scores on the LSC require surgical correction of deformity and stabilization. Meanwhile, a high risk of failure is present when using only
short-segment fixation. For this reason, it is recommended to restore the supporting ability of the spine using anterior fusion [31]. It is possible to raise the strength of the fractured vertebral body and enhance its resistance to compression loads by administering granular implants or bone grafts into the fractured segment. Moreover, the higher implant strength is associated with the higher resistance to compression and better preservation of the restored shape and vertical size of the fractured vertebral body [1]. Fractures of the cortical bone plate, including of the posterior vertebral elements, always appear in Magerl type A3 vertebral body lesions and
are associated with weaker resistance to compression [1].
Our study included patients with vertebral body fractures scoring 6 to 8 points on McCormack classification in groups I—III and more than 8 points - in group IV.
Surgical treatment for vertebral fractures with anterior fusion and different cages has been always associated with the loss of correction in the long-term radiographic findings; Pesenti et al. [35] therefore used a combination of anterior and posterior fixation. The authors evaluated the clinical and radiologic outcomes for patients operated by percutaneous (transcutaneous) TPF and anterior fusion using telescopic vertebral body prosthesis for fractures at the thoracic and lumbar spine without neurological deficit and observed the loss of correction up to 1° in the long-term follow-up. Jo et al. [16] used anterior spinal fusion with cage and TPF for unstable fractures with LSC score more than 7; no loss of correction was noted in the long-term follow-up. During posterior short-segment fixation after vertebroplasty, transpedicular screw was inserted in the fractured vertebra as a required step allowing equal load redistribution over the fixation system. Lin et al.[26] and Liao et al. [24] also implanted additional screws in the fractured vertebra during transpedicular fixation after vertebroplasty resulting in a low percent of deformity progression at the injured vertebral segment. Along with successful outcome of such operations, short-segment instrumentation can potentially prevent degeneration of adjacent segments [42]. The outcomes of our proposed minimally invasive method for the treatment of types A2 and A3
Table 5
The mean VAS scores and the Oswestry indices in study groups
Group VAS, scores Oswestry index, %
the short-term period the long-term period the short-term period the long-term period
|i 2.70 ± 1.49 1.90 ± 1.58 22.00 ± 6.32 19.90 ± 3.89
II 2.90 ± 1.28** 2.80 ± 1.27* 22.70 ± 6.22** 23.80 ± 5.04*
III 2.80 ± 1.36** 3.00 ± 1.07* 23.60 ± 6.41** 24.20 ± 4.81*
IV 3.10 ±1.07* 3.10 ± 1.10* 32.60 ± 6.41* 30.60 ± 7.41*
*significant differences ^ < 0.05), **insignificant differences ^ > 0.05).
57
vertebral fractures with LSC score up to 8 were not inferior to vertebroplasty and fixation through an open approach. Along with the significant postoperative improvement of the kyphotic deformity magnitudes in all groups, kyphotic curve correction, when compared, was improved significantly better in group I. In the long-term period, kyphotic deformity magnitudes increased in all groups; however, there were no significant differences between the groups in pairwise comparison.
The reduced wedge indices after operation went up slightly in the short-term period, but the increase was significantly less in group I compared to groups III and IV. In the long-term postoperative period, these indicators continued to decline in all groups, and pairwise comparison did not reveal significant differences that also agrees with the data by Liao et al. [25] and Li et al. [22].
The magnitude of the loss of achieved deformity correction at the level of fracture in the short-term follow-up in group I in pairwise comparison was significantly lower than in groups II and IV. The loss of correction increased in the long-term period in all groups and the magnitudes were significantly lower only in the group IV compared to group I in a pairwise comparison.
The comparison of the outcomes with the results after TPF alone in the long-term period has revealed that TPF alone resulted in screw breakage, progression of the initial kyphotic deformity, loss of correction, absence of consolidation, neurological signs, and worsening of pain syndrome which required repeated surgical intervention on the anterior spine [14, 17, 30, 41].
Despite the significant exceeding of BMD indices in group II compared with group I, the magnitudes of all groups were similar in the long-term period and did not fall below the osteopenia threshold. Similar results were obtained by Li et al. [21] in the long-term period who also noted correction loss of up to 2-5°.
This study demonstrates that along with the alleviation of pain syndrome in the short-term period in all groups, only minimally invasive techniques are associated with milder pain syndrome in the long-term postoperative period that indicates the efficacy of this method.
When the Oswestry index scores were compared, the magnitudes of only group I were significantly lower versus the rest groups in the long-term period (p < 0.001), which also supports the efficacy of minimally invasive method in the improvement of functional adaptation of a patient. The outcomes match to the results by Li et al. [23] and Lee et al. [20]
who compared the efficacy of conventional and transcutaneous short-segment TPF with vertebroplasty.
We observed that the intraoperative blood loss averaged 145.80 ± 90.35 ml in group I, which did not differ significantly from that of group III - 162.80 ± 57.20 ml, while this indicator in group II significantly exceeded that of the main group - up to 193.70 ± 110.60 ml thereby evidencing to the low traumatization of our proposed method. This agrees with data by Wang et al. [39].
Conclusion
Transcutaneous vertebroplasty and TPF in the treatment of types A2 and A3 fractures with LDS score up to 8 provides solid stabilization of fractured spinal segments over the entire period of vertebral body consolidation, vertebral body height restoration to a greater extent, and correction of kyphotic deformity. Our developed method reduces the traumatization degree of surgery, alleviates pain syndrome, and facilitates the functional adaptation of patients in the long-term postoperative periods.
This study is not a sponsored project. The authors declare that they have no conflict of interest.
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_hirurgia pozvonochnika 2017;14(3):54-61_
v.v. rerikh et al. treatment of thoracic and lumbar spine fractures using transpedicular vertebroplasty and fixation
References
1. Avetisyan AR. Thoracic and lumbar veretebroplasty with porous bioceramic granules (experimental study): MD/PhD Thesis. Novosibirsk, 2015. In Russian.
2. Buyul A, Cefel P. SPSS: The Art of Information Processing. Moscow, 2005. In Russian.
3. Giants S. Medico-Biological Statistics. Moscow, 1999. In Russian.
4. Kirilova IA. Anatomical and functional properties of bone as a basis for creating osteoplastic materials for traumatology and orthopaedics (anatomical and experimental study): DMSc Thesis. Novosibirsk, 2011. In Russian.
5. Rerikh VV, Baidarbekov MU, Anikin KA. Device for administering bone-plastic material. Patent RU 2579305. Appl. 23.03.2015; publ. 10.04.2016. Bull. 10. In Russian.
6. Rerikh VV, Sadovoy MA, Rakhmatillaev SN. Application of Osteoplasty for Complex treatment of the thoracic and lumbar vertebrae fractures Hir. Pozvonoc. 2009;(2):25-34. In Russian. DOI: http://dx.doi.org/10.14531/ss2009.2.25-34.
7. Sadovoy MA, Rerikh VV, Baidarbekov MU. Method for transcutaneous repair of vertebral body. Patent RU 2573101. Appl. 29.08.2014; publ. 20.01.2016. Bull. 2. In Russian.
8. Barbagallo GM, Yoder E, Dettori JR, Albanese V. Percutaneous minimally invasive versus open spine surgery in the treatment of fractures of the thoracolumbar junction: a comparative effectiveness review. Evid Based Spine Care J. 2012;3:43-49. DOI: 10.1055/s-0032-1327809.
9. Fairbank JC, Pynsent PB. The Oswestry Disability Index. Spine. 2000;25:2940-2952.
10. Fantini GA, Pawar AY. Access related complications during anterior exposure of the lumbar spine. World J Orthop. 2013;4:19-23. DOI: 10.5312/wjo.v4.i1.19.
11. Fischer S, Vogl TJ, Kresing M, Marzi I, Zangos S, Mack MG, Eichler K. Minimally invasive screw fixation of fractures in the thoracic spine: CT-controlled pre-surgical guidewire implantation in routine clinical practice. Clin Radiol. 2016;71:997-1004. DOI: 10.1016/j.crad.2016.06.112.
12. Giorgi H, Blondel B, Adetchessi T, Dufour H, Tropiano P, Fuentes S. Early percutaneous fixation of spinal thoracolumbar fractures in polytrauma patients. Orthop Traumatol Surg Res. 2014;100:449-454. DOI: 10.1016/j.otsr.2014.03.026.
13. Hamdan AD, Malek JY, Schermerhorn ML, Aulivola B, Blattman SB, Pomposelli FB Jr. Vascular injury during anterior exposure of the spine. J Vasc Surg. 2008;48:650-654. DOI: 10.1016/j.jvs.2008.04.028.
14. Hua YJ, Wang RY, Guo ZH, Shu CH, Li CH. [Clinical studies of pedicle screw-rod fixation of thoracolumbar burst fractures through posterior unilateral approach after vertebrae corpectomy fusion]. Zhongguo Gu Shang. 2016;29:27-32. In Chinese.
15. Huang QS, Chi YL, Wang XY, Mao FM, Lin Y, Ni WF, Xu HZ. [Comparative percutaneous with open pedicle screw fixation in the treatment of thoracolumbar burst fractures without neurological deficit]. Zhonghua Wai Ke Za Zhi. 2008;46:112-114. In Chinese.
16. Jo DJ, Kim KT, Kim SM, Lee SH, Cho MG, Seo EM. Single-stage posterior subtotal corpectomy and circumferential reconstruction for the treatment of unstable thoracolumbar burst fractures. J Korean Neurosurg Soc. 2016;59:122-128. DOI: 10.3340/jkns.2016.59.2.122.
17. Kanna RM, Shetty AP, Rajasekaran S. Posterior fixation including the fractured vertebra for severe unstable thoracolumbar fractures. Spine J. 2015;15:256-264. DOI: 10.1016/j.spinee.2014.09.004.
18. Koreckij T, Park DK, Fischgrund J. Minimally invasive spine surgery in the treatment of thoracolumbar and lumbar spine trauma. Neurosurg Focus. 2014;37:E11. DOI: 10.3171/2014.5.FOCUS1494.
19. Korovessis PG, Baikousis A, Stamatakis M. Use of the Texas Scottish Rite Hospital Instrumentation in the treatment of thoracolumbar injuries. Spine. 1997;22:882-888.
20. Lee JK, Jang JW, Kim TW, Kim TS, Kim SH, Moon SJ. Percutaneous short-segment pedicle screw placement without fusion in the treatment of thoracolumbar burst
fractures: is it effective?: comparative study with open short-segment pedicle screw fixation with posterolateral fusion. Acta Neurochir (Wien). 2013;155:2305-2312. DOI: 10.1007/s00701-013-1859-x.
21. Li DP, Yang HL, Huang YH, Xu XF, Sun TC, Hu L. Transpedicular intracorporeal grafting for patients with thoracolumbar burst fractures. Saudi Med J. 2014;35:50-55.
22. Li Q, Yun C, Li S. Transpedicular bone grafting and pedicle screw fixation in injured vertebrae using a paraspinal approach for thoracolumbar fractures: a retrospective study. J Orthop Surg Res. 2016;11:115. DOI: 10.1186/s13018-016-0452-4.
23. Li Q, Liu Y, Chu Z, Chen J, Chen M. [Treatment of thoracolumbar fractures with transpedicular intervertebral bone graft and pedicle screws fixationin injured vertebrae]. Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2011;25:956-959. In Chinese.
24. Liao JC, Fan KF. Posterior short-segment fixation in thoracolumbar unstable burst fractures - Transpedicular grafting or six-screw construct? Clin Neurol Neurosurg. 2017;153:56-63. DOI: 10.1016/j.clineuro.2016.12.011.
25. Liao JC, Fan KF, Chen WJ, Chen LH, Kao HK. Transpedicular bone grafting following short-segment posterior instrumentation for acute thoracolumbar burst fracture. Orthopedics. 2009;32:493. DOI: 10.3928/01477447-20090527-11.
26. Lin YC, Fan KF, Liao JC. Two additional augmenting screws with posterior short-segment instrumentation without fusion for unstable thoracolumbar burst fracture
- Comparisons with transpedicular grafting techniques. Biomed J. 2016;39:407-413. DOI: 10.1016/j.bj.2016.11.005.
27. Macnab I. Negative disc exploration. An analysis of the cause of nerve root involvement in sixty-eight patients. J Bone Joint Surg Am. 1971;53:891-903.
28. Magerl F, Aebi M, Gertzbein SD, Harms J, Nazarian S. A comprehensive classification of thoracic and lumbar injuries. Eur Spine J. 1994;3:184-201. DOI: 10.1007/978-3-642-58824-2_4.
29. Maillard N, Buffenoir-Billet K, Hamel O, Lefranc B, Sellal O, Surer N, Bord E, Grimandi G, Clouet J. A cost-minimization analysis in minimally invasive spine surgery using a national cost scale method. Int J Surg. 2015;15:68-73. DOI: 10.1016/j. ijsu.2014.12.029.
30. Martiniani M, Vanacore F, Meco L, Specchia N. Is posterior fixation alone effective to prevent the late kyphosis after T-L fracture? Eur Spine J. 2013;22 Suppl 6:951-956. DOI: 10.1007/s00586-013-3008-x.
31. Mc Cormack T, Karaikovic E, Gaines RW. The load sharing classification of spine fractures. Spine. 1994;19:1741-1744. DOI: 10.1097/00007632-199408000-00014.
32. McLain RF, Sparling E, Benson DR. Early failure of short-segment pedicle instrumentation for thoracolumbar fractures. A preliminary report. J Bone Joint Surg Am. 1993;75:162-167.
33. Palmisani M, Gasbarrini A, Brodano GB, De Iure F, Cappuccio M, Boriani L, Amendola L, Boriani S. Minimally invasive percutaneous fixation in the treatment of thoracic and lumbar spine fractures. Spine J. 2009;18 Suppl 1:71-74. DOI: 10.1007/ s00586-009-0989-6.
34. Perera A, Qureshi A, Brecknell JE. Mono-segment fixation of thoracolumbar burst fractures. Br J Neurosurg. 2015;29:358-361. DOI: 10.3109/02688697.2014.987216.
35. Pesenti S, Graillon T, Mansouri N, Rakotozanani P, Blondel B, Fuentes S. Minimal invasive circumferential management of thoracolumbar spine fractures. Biomed Res Int. 2015;2015:639542. DOI: 10.1155/2015/639542.
36. Phan K, Rao PJ, Mobbs RJ. Percutaneous versus open pedicle screw fixation for treatment of thoracolumbar fractures: Systematic review and meta-analysis of comparative studies. Clin Neurol Neurosurg. 2015;135:85-92. DOI: 10.1016/j. clineuro.2015.05.016.
59
37. Vu TT, Morishita Y, Yugue I, Hayashi T, Maeda T, Shiba K. Radiological outcome of short segment posterior instrumentation and fusion for thoracolumbar burst fractures. Asian Spine J. 2015;9:427-432. DOI: 10.4184/asj.2015.9.3.427.
38. Van Herck B, Leirs G, Van Loon J. Transpedicular bone grafting as a supplement to posterior pedicle screw instrumentation in thoracolumbar burst fractures. Acta Orthop Belg. 2009;75:815-821.
39. Wang W, Yao N, Song X, Yan Y, Wang C. External spinal skeletal fixation combination with percutaneous injury vertebra bone grafting in the treatment of thoracolumbar fractures. Spine. 2011;36:E606-E611. DOI: 10.1097/BRS.0b013e3181f 92dac.
40. Weg owski R, Godlewski P, Blacha J, Ko odziej R, Mazurkiewicz T. [Results of operative treatment thoraco-lumbar fractures by posterior lumbar interbody fusion, Daniaux reconstruction or combination of both methods]. Chir Narzadow Ruchu Ortop Pol. 2011;76:83-90. In Polish.
41. Xing JM, Peng WM, Shi CY, Xu L, Pan QH. [Analysis of reason and strategy for the failure of posterior pedicle screw short-segment internal fixation on thoracolumbar fractures]. Zhongguo Gu Shang. 2013;26:186-189. In Chinese.
42. Yin F, Sun Z, Yin Q, Liu J, Gu S, Zhang S. [A comparative study on treatment of thoracolumbar fracture with injured vertebra pedicle instrumentation and cross segment pedicle instrumentation]. Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2014;28:227-232. In Chinese.
Address correspondence to:
Rerikh Victor Viktorovich NNIITO, Frunze str., 17, Novosibirsk, 630091, Russia, [email protected]
Received 31.05.2017 Review completed 01.06.2017 Passed for printing 09.06.2017
Victor Viktorovich Rerikh, DMSc, head of the Clinic of spine and spinal cord injury, Novosibirsk Research Institute of Traumatology and Orthopaedics n. a. Ya.L. Tsivyan; [email protected]; professor of traumatology and orthopedics, Novosibirsk State Medical University, Novosibirsk, Russia, [email protected]; Murat Umirkhanovich Baidarbekov, postgraduate student in the Novosibirsk Research Institute of Traumatology and Orthopaedics n. a. Ya.L. Tsivyan, Novosibirsk, Russia; neurosurgeon of trauma department No. 1, Scientific Research Institute of Traumatology and Orthopaedics, Astana, Republic of Kazakhstan, [email protected];
Mikhail Anatolyevich Sadovoy, DMSc, Prof., Director, Novosibirsk Research Institute of Traumatology and Orthopaedics n.a. Ya.L. Tsivyan; Head of the Department of Health Care Management, Novosibirsk State Medical University, Novosibirsk, Russia, [email protected];
Nurlan Dzhumagulovich Batpenov, DMSc, Prof., Director of Scientific Research Institute of Traumatology and Orthopaedics, Astana, Republic of Kazakhstan, [email protected];
Irina Anatolyevna Kirilova, DMSc, Head of Research Department, Novosibirsk Research Institute of Traumatology and Orthopaedics n. a. Ya.L. Tsivyan, Novosibirsk, Russia, [email protected].
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