整形外科学レビュー 2021-'22

出版社: 総合医学社
著者:
発行日: 2021-03-30
分野: 臨床医学:外科  >  整形外科学
ISBN: 9784883787340
電子書籍版: 2021-03-30 (第1版第1刷)
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整形外科学分野のエキスパートによって選別された、2018年8月から2020年7月までの2年間に国内外で発表された最新の文献レビューです。広く整形外科関連の最近のトピックスを把握でき、整形外科医だけでなく、専門医を目指す方、非専門医にも役立つ1冊です。 

目次

  • I章 脊 椎
     1.頸・胸椎
      1-1.急性期脊髄損傷に対する治療方法
      1-2.脊柱靱帯骨化症に対する診断と治療
      1-3.頸椎症性脊髄症に対する手術法
      1-4.後頭骨・上位頸椎疾患の治療
      1-5.DISHを伴った脊椎骨折の治療
     2.腰 椎
      2-1.腰部脊柱管狭窄症に対する手術治療
      2-2.腰椎椎間板ヘルニア治療の現状
      2-3.腰痛に対する集学的治療
      2-4.骨粗鬆症性椎体骨折に対する治療
      2-5.腰椎椎間板の変性予防と再生治療
     3.脊柱変形
      3-1.早期発症側弯症に対する手術治療
      3-2.思春期特発性側弯症の原因・診断・治療
      3-3.成人脊柱変形に対する手術治療

    II章 上 肢
     4.肩・肘
      4-1.腱板断裂
      4-2.上腕骨近位端骨折
      4-3.上腕骨外側上顆炎
      4-4.上腕骨遠位端骨折
     5.手
      5-1.手指変形性関節症(母指CM関節症含む)
      5-2.橈骨遠位端骨折
      5-3.キーンベック病
      5-4.手指屈筋腱損傷
     6.末梢神経
      6-1.腕神経叢損傷
      6-2.上肢における絞扼性神経障害

    III章 下 肢
     7.股関節
      7-1.特発性大腿骨頭壊死
      7-2.変形性股関節症
      7-3.大腿骨近位部骨折
      7-4.股関節唇損傷
     8.膝関節
      8-1.変形性膝関節症
      8-2.前十字靱帯損傷
      8-3.半月板損傷
      8-4.反復性膝蓋骨脱臼
     9.足関節・足
      9-1.変形性足関節症
      9-2.後脛骨筋腱機能不全症
      9-3.外反母趾
      9-4.距骨骨軟骨損傷

    IV章 骨軟部
     10.骨腫瘍
      10-1.良性骨腫瘍・骨巨細胞腫の診断・治療指針
      10-2.原発性悪性骨腫瘍の治療指針
      10-3.骨転移の診断・治療指針
     11.軟部腫瘍
      11-1.良性軟部腫瘍・デスモイド型線維腫症の診断・治療指針
      11-2.悪性軟部腫瘍の診断・治療指針

    V章 基 礎
     1.骨代謝研究
     2.軟骨代謝・OA研究
     3.整形外科疾患に関連したゲノム研究
     4.筋代謝研究
     5.脊髄損傷に対する再生医療

この書籍の参考文献

参考文献のリンクは、リンク先の都合等により正しく表示されない場合がありますので、あらかじめご了承下さい。

本参考文献は電子書籍掲載内容を元にしております。

I章 脊椎

P.2 掲載の参考文献
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2) Ter Wengel PV, De Witt Hamer PC, Pauptit JC et al : Early surgical decompression improves neurological outcome after complete traumatic cervical spinal cord injury : a meta-analysis. J Neurotrauma 36 : 835-844, 2019
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3) Bruke JF, Yue JK, Ngwenya LB et al : Ultra-early (< 12 hours) surgery correlates with higher rate of American Spinal Injury Association impairment scale conversion after cervical spinal cord injury. Neurosurgery 85 : 199-203, 2019
 
4) Du JP, Fan Y, Zhang JN et al : Early versus delayed decompression for traumatic cervical spinal cord injury : application of the AOSpine subaxial cervical spinal injury classification system to guide surgical timing. Eur Spine J 28 : 1855-1863, 2019
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P.3 掲載の参考文献
5) Haldrup M, Schwartz OS, Kasch H et al : Early decompressive surgery in patients with traumatic spinal cord injury improves neurological outcome. Acta Neurochir (Wien) 161 : 2223-2228, 2019
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6) Wutte C, Becker J, Klein B et al : Early decompression (< 8 hours) improves functional bladder outcome and mobility after traumatic thoracic spinal cord injury. World Neurosurg 134 : e847-e854, 2020
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7) Wutte C, Klein B, Becker J et al : Earlier decompression (< 8 hours) results in better neurological recovery and functional outcome after traumatic thoracolumbar spinal cord injury. J Neurotrauma 36 : 2020-2027, 2019
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8) Ter Wengel PV, Martin E, De Witt Hamer PC et al : Impact of early (< 24 h) surgical decompression in neurological recovery in thoracic spinal cord injury : a meta-analysis. J Neurotrauma 36 : 2609-2617, 2019
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9) Fehlings MG, Tetreault LA, Wilson JR et al : A clinical practice guideline for the management of patients with acute spinal cord injury and central cord syndrome : recommendation on the timing (24 <= hours versus > 24 hours) of decompressive surgery. Global Spine J 7 : 195S-202S, 2017
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10) Zheng C, Yu Q, Shan X et al : Early surgical decompression ameliorates dysfunction of spinal motor neuron in patients with acute traumatic central cord syndrome : an ambispective cohort analysis. Spine (Phila Pa 1976) 45 : E829-E838, 2020
 
11) Du L, Zhao S, Zhu Z et al : Effect of surgical intervention on neurologic recovery in patients with central cord syndrome. J Neurolo Surg A Cent Eur Neurosurg 81 : 318-323, 2020
 
12) Fehlings MG, Wilson JR, Tetreault LA et al : A clinical practice guideline for the management of patients with acute spinal cord injury : recommendation on the use of methylprednisolone sodium succinate. Global Spine J 7 : 203S-211S, 2017
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13) Arnold PM, Anderson PA, Chi JH et al : Congress of Neurological Surgeons systematic review and evidence-based guideline on the evaluation and treatment of patients with thoracolumbar spine trauma : pharmacological treatment. Neurosurgery 84 : E36-E38, 2019
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P.4 掲載の参考文献
14) Miekisiak G, Latka D, Jarmuzek P et al : Steroids in acute spinal cord injury : all but gone within 5 years. World Neurosurg 122 : e467-e471, 2019
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15) Liu Z, Yang Y, He L et al : High-dose methylprednisolone for acute traumatic spinal cord injury : a meta-analysis. Neurology 93 : e841-e850, 2019
 
16) Fehlings MG, Tetreault LA, Aarabi B et al : A clinical practice guideline for the management of patients with acute spinal cord injury : recommendations on the type and timing of anticoagulant thromboprophylaxis. Global Spine J 7 (3 Suppl) : 212S-220S, 2017
 
17) Raksin PB, Harrop JS, Anderson PA et al : Congress of Neurological Surgeons systematic review and evidence-based guideline on the evaluation and treatment of patientswith thoracolumbar spine trauma : prophylaxis and treatment of thoromboembolic events. Neurosurgery 84 : E39-E42, 2019
 
18) Piran S, Schulman S : Thoromboprophylaxis in patients with acute spinal cord injury : a narrative review. Semin Thoromb Hemost 45 : 150-156, 2019
 
19) Kitamura K, Nagoshi N, Tsuji O et al : Application of hepatocyte growth factor for acute spinal cord injury : the road from basic studies to human treatment. Int J Mol Sci 20 : 1054, 2019
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20) Koda M, Hanaoka H, Fujii Y et al : Randomized trial of granulocyte colony-stimulating factor for spinal cord injury. Brain, in press
 
21) Srinivas S, Wali AR, Pham MH : Efficacy of riluzole in the treatment of spinal cord injury : a systematic review of the literature. Neurosurg Focus 46 : E6, 2019
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22) Minnema AJ, Mehta A, Boling WW et al : SCING-spinal cord injury neuroprotection with glyburide : a pilot, open-label, multicenter, prospective evaluation of oral glyburide in patients with acute traumatic spinal cord injury in the USA. BMJ open 9 : e031329, 2019
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23) Cofano F, Boido M, Monticelli M et al : Mesenchymal stem cell for spinal cord injury : current options, limitations, and future of cell therapy. Int J Mol Sci 20 : 2698, 2019
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24) Levi AD, Anderson KD, Okonkwo DO et al : Clinical outcome from a multi-center study of human neural stem cell transplantation in chronic cervical spinal cord injury. J Neurotrauma 36 : 891-902, 2019
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25) Tsuji O, Sugai K, Yamaguchi R et al : Concise review : Laying groundwork for a first-in-human study of an induced pluripotent stem cell-based intervention for spinal cord injury. Stem Cells 37 : 6-13, 2019
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26) Cyranoski D : Japan's approval of stem-cell treatment for spinalcord injury concerns scientists. Nature 565 : 544-545, 2019
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27) Shackleton C, Evans R, Shamley D et al : Effectiveness of overground robotic locomotor training in moving walking performance, cardiovascular demands, secondary complications and user-satisfaction in indivisuals with spinal cord injuries : a systematic review. J Rehabil Med 51 : 723-733, 2019
 
28) McIntosh K, Charbonneau R, Bensaada U et al : The safety and feasibility of exoskeletal-assisted walking in acute rehabilitation after spinal cord injury. Arch Phys Med Rehabil 101 : 113-120, 2020
 
29) Rejc E, Angeli CA : Spinal cord epidural stimulation for lower limb motor function recovery in individuals with motor complete spinal cord injury. Phys Med Rehabil Clin N Am 30 : 337-354, 2019
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30) Calvert JS, Grahn PJ, Zhao KD et al : Emergence of epidural electrical stimulation to facilitate sensorimotor network functionality after spinal cord injury. Neuromodulation 22 : 244-252, 2019
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31) Sayenko DG, Rath M, Ferguson AR et al : Self-assisted standing enabled by non-invasive spinal stimulation after spinal cord injury. J Neurotrauma 36 : 1435-1450, 2019
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P.5 掲載の参考文献
1) 日本整形外科学会/日本脊椎脊髄病学会監, 日本整形外科学会診療ガイドライン委員会/脊柱靱帯骨化症診療ガイドライン策定委員会編 : 脊柱靱帯骨化症診療ガイドライン 2019. 南江堂, 2019
 
P.6 掲載の参考文献
2) Fujimori T, Watabe T, Iwamoto Y et al : Prevalence, concomitance, and distribution of ossification of the spinal ligaments : results of whole spine ct scans in 1500 Japanese patients.Spine (Phila Pa 1976) 41 : 1668-1676, 2016
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3) Liang H, Liu G, Lu S et al : Epidemiology of ossification of the spinal ligaments and associated factors in the Chinese population : a cross-sectional study of 2000 consecutive individuals. BMC Musculoskelet Disord 20 : 253, 2019
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4) Hirai T, Yoshii T, Iwanami A et al : Prevalence and distribution of ossified lesions in the whole spine of patients with cervical ossification of the posterior longitudinal ligament a multicenter study (JOSL CT study). PLoS One 11 : e0160117, 2016
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5) Nishimura S, Nagoshi N, Iwanami A et al : Prevalence and distribution of diffuse idiopathic skeletal hyperostosis on whole-spine computed tomography in patients with cervical ossification of the posterior longitudinal ligament : a multicenter study. Clin Spine Surg 31 : E460-E465, 2018
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6) Mori K, Yoshii T, Hirai T et al : Prevalence and distribution of ossification of the supra/interspinous ligaments in symptomatic patients with cervical ossification of the posterior longitudinal ligament of the spine : a CT-based multicenter cross-sectional study. BMC Musculoskelet Disord 17 : 492, 2016
 
7) Yoshii T, Hirai T, Iwanami A et al : Coexistence of ossification of the nuchal ligament is associated with severity of ossification in the whole spine in patients with cervical ossification of the posterior longitudinal ligament -a multi-center CT study. J Orthop Sci 24 : 35-41, 2019
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8) Mori K, Yoshii T, Hirai T et al : The characteristics of the patients with radiologically severe cervical ossification of the posterior longitudinal ligament of the spine : A CT-based multicenter cross-sectional study. J Orthop Sci 25 : 746-750, 2020
 
9) Hirai T, Yoshii T, Nagoshi N et al : Distribution of ossified spinal lesions in patients with severe ossification of the posterior longitudinal ligament and prediction of ossification at each segment based on the cervical OP index classification : a multicenter study (JOSL CT study). BMC Musculoskelet Disord 19 : 107, 2018
 
P.7 掲載の参考文献
10) Hirai T, Yoshii T, Ushio S et al : Clinical characteristics in patients with ossification of the posterior longitudinal ligament : a prospective multi-institutional cross-sectional study. Sci Rep 10 : 5532, 2020
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11) Nakajima M, Kou I, Ohashi H et al : Identification and functional characterization of RSPO2 as a susceptibility gene for ossification of the posterior longitudinal ligament of the spine. Am J Hum Genet 99 : 202-207, 2016
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12) Nakajima H, Watanabe S, Honjoh K et al : Expression analysis of susceptibility genes for ossification of the posterior longitudinal ligament of the cervical spine in human OPLL-related Tissues and a spinal hyperostotic mouse (ttw/ttw). Spine (Phila Pa 1976) 45 : E1460-E1468, 2020
 
13) Yuan X, Guo Y, Chen D et al : Long noncoding RNA MALAT1 functions as miR-1 sponge to regulate Connexin 43-mediated ossification of the posterior longitudinal ligament. Bone 127 : 305-314, 2019
 
14) Xu C, Zhang H, Gu W et al : The microRNA-10a/ID3/RUNX2 axis modulates the development of ossification of posterior longitudinal ligament. Sci Rep 8 : 9225, 2018
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15) Xu C, Zhang H, Zhou W et al : MicroRNA-10a, -210, and -563 as circulating biomarkers for ossification of the posterior longitudinal ligament. Spine J 19 : 735-743, 2019
 
16) Liu N, Zhang Z, Li L et al : MicroRNA-181 regulates the development of ossification of posterior longitudinal ligament via epigenetic modulation by targeting PBX1. Theranostics 10 : 7492-7509, 2020
 
17) Lee JB, Kim IS, Kwon JY et al : Difference of dynamic morphometric changes between in patients with ossification of posterior longitudinal ligament and patients with cervical spondylosis : assessment by cervical dynamic magnetic resonance imaging. World Neurosurg 123 : e566-e573, 2019
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18) Kawaguchi Y, Kitajima I, Nakano M et al : Increase of the serum FGF-23 in ossification of the posterior longitudinal ligament. Global Spine J 9 : 492-498, 2019
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19) Kawaguchi Y, Nakano M, Yasuda T et al : Serum biomarkers in patients with ossification of the posterior longitudinal ligament (OPLL) : inflammation in OPLL. PLoS One 12 : e0174881, 2017
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20) Lee DH, Cho JH, Lee CS et al : A novel anterior decompression technique (vertebral body sliding osteotomy) for ossification of posterior longitudinal ligament of the cervical spine. Spine J 18 : 1099-1105, 2018
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P.8 掲載の参考文献
21) Lee DH, Lee CS, Hwang CJ et al : Improvement in cervical lordosis and sagittal alignment after vertebral body sliding osteotomy in patients with cervical spondylotic myelopathy and kyphosis. J Neurosurg Spine, 2020 [Epub ahead of print]
 
22) Sun J, Shi J, Xu X et al : Anterior controllable antidisplacement and fusion surgery for the treatment of multilevel severe ossification of the posterior longitudinal ligament with myelopathy : preliminary clinical results of a novel technique. Eur Spine J 27 : 1469-1478, 2018
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23) Yang H, Guo Y, Shi J et al : Surgical results and complications of anterior controllable antedisplacement fusion as a revision surgery after initial posterior surgery for cervical myelopathy due to ossification of the posterior longitudinal ligament. J Clin Neurosci 56 : 21-27, 2018
 
24) Lee DH, Park S, Hong CG : A novel anterior decompression technique for kyphosis line (K-line) ossification of posterior longitudinal ligament (OPLL) : vertebral body sliding osteotomy. J Spine Surg 6 : 196-204, 2020
 
25) Yang H, Sun J, Shi J et al : Anterior controllable antedisplacement fusion as a choice for 28 patients of cervical ossification of the posterior longitudinal ligament with dura ossification : the risk of cerebrospinal fluid leakage compared with anterior cervical corpectomy and fusion. Eur Spine J 28 : 370-379, 2019
 
26) Chen Y, Sun J, Yuan X et al : Comparison of anterior controllable antedisplacement and fusion with posterior laminoplasty in the treatment of multilevel cervical ossification of the posterior longitudinal ligament : a prospective, randomized, and control study with at least 1-year follow up. Spine (Phila Pa 1976) 45 : 1091-1101, 2020
 
27) Sun J, Xu X, Wang Y et al : How to avoid postoperative remaining ossification mass in anterior controllable antedisplacement and fusion surgery. World Neurosurg X 3 : 100034, 2019
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28) Kong QJ, Sun XF, Wang Y et al : Risk assessment of vertebral artery injury in anterior controllable antedisplacement and fusion (ACAF) surgery : a cadaveric and radiologic study. Eur Spine J 28 : 2417-2424, 2019
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P.9 掲載の参考文献
29) Yoshii T, Egawa S, Hirai T et al : A systematic review and meta-analysis comparing anterior decompression with fusion and posterior laminoplasty for cervical ossification of the posterior longitudinal ligament. J Orthop Sci 25 : 58-65, 2020
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30) Furuya T, Maki S, Miyamoto T et al : Mid-term surgical outcome of posterior decompression with instrumented fusion in patients with K-line (-) type cervical ossification of the posterior longitudinal ligament with a 5-year minimum follow-up. Clin Spine Surg 33 : 333-338, 2020
 
31) Kimura A, Shiraishi Y, Sugawara R et al : Impact of K-line (-) in the neck-flexion position on patient-reported outcomes after cervical laminoplasty for patients with ossification of the posterior longitudinal ligament. Clin Spine Surg 32 : 382-386, 2019
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32) Nori S, Aoyama R, Ninomiya K et al : Kline (-) in the neck-flexed position affects surgical outcomes in patients with ossification of the posterior longitudinal ligament after muscle-preserving selective laminectomy. J Orthop Sci 25 : 770-775, 2020
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33) Kimura A, Takeshita K, Shiraishi Y et al : Effectiveness of surgical treatment for degenerative cervical myelopathy in preventing falls and fall-related neurological deterioration : a prospective multiinstitutional study. Spine (Phila Pa 1976) 45 : E631-E638, 2020
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34) Kimura A, Takeshita K, Inoue H et al : The 5-question Geriatric Locomotive Function Scale predicts postoperative fall risk in patients undergoing surgery for degenerative cervical myelopathy. J Orthop Sci : S0949-2658 (20) 30274-8, 2020 [Epub ahead of print]
 
35) Morishita S, Yoshii T, Okawa A et al : Perioperative complications of anterior decompression with fusion versus laminoplasty for the treatment of cervical ossification of the posterior longitudinal ligament : propensity score matching analysis using a nation-wide inpatient database. Spine J 19 : 610-616, 2019
 
36) Yoshii T, Morishita S, Inose H et al : Comparison of perioperative complications in anterior decompression with fusion and posterior decompression with fusion for cervical ossification of the posterior longitudinal ligament : propensity score matching analysis using a nation-wide inpatient database. Spine (Phila Pa 1976) 45 : E1006-E1012, 2020
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P.10 掲載の参考文献
37) Imagama S, Ando K, Takeuchi K et al : Perioperative complications after surgery for thoracic ossification of posterior longitudinal ligament : a nationwide multicenter prospective study. Spine (Phila Pa 1976) 43 : E1389-E1397, 2018
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38) Uei H, Tokuhashi Y, Oshima M et al : Efficacy of posterior decompression and fixation based on ossification-kyphosis angle criteria for multilevel ossification of the posterior longitudinal ligament in the thoracic spine. J Neurosurg Spine 29 : 150-156, 2018
 
39) Imagama S, Ando K, Ito Z et al : Risk factors for ineffectiveness of posterior decompression and dekyphotic corrective fusion with instrumentation for beak-type thoracic ossification of the posterior longitudinal ligament : a single institute study. Neurosurgery 80 : 800-808, 2017
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40) Kato S, Murakami H, Demura S et al : Indication for anterior spinal cord decompression via a posterolateral approach for the treatment of ossification of the posterior longitudinal ligament in the thoracic spine : a prospective cohort study. Eur Spine J 29 : 113-121, 2020
 
41) Kobayashi K, Imagama S, Yoshida G et al : Efficacy of intraoperative intervention following tc-mep alert during posterior decompression and fusion surgery for thoracic OPLL : a prospective multicenter study of the monitoring committee of the Japanese society for spine surgery and related research. Spine (Phila Pa 1976), 2020 [Epub ahead of print]
 
42) Kadone H, Kubota S, Abe T et al : Muscular activity modulation during postoperative walking with Hybrid Assistive Limb (HAL) in a patient with thoracic myelopathy due to ossification of posterior longitudinal ligament : a case report. Front Neurol 11 : 102, 2020
 
43) Ando K, Imagama S, Kaito T et al : Outcomes of surgery for thoracic myelopathy owing to thoracic ossification of the ligamentum flavum in a nationwide multicenter prospectively collected study in 223 patients : is instrumented fusion necessary? Spine (Phila Pa 1976) 45 : E170-E178, 2020
 
P.11 掲載の参考文献
1) Rao H, Huang Y, Lan Z et al : Does preoperative T1 slope and cervical lordosis mismatching affect surgical outcomes after laminoplasty in patients with cervical spondylotic myelopathy? World Neurosurg 130 : e687-e693, 2019
 
2) Chen HY, Yang MH, Lin YP et al : Impact of cervical sagittal parameters and spinal cord morphology in cervical spondylotic myelopathy status post spinous process-splitting laminoplasty. Eur Spine J 29 : 1052-1060, 2020
PubMed
P.12 掲載の参考文献
3) Tamai K, Suzuki A, Yabu A et al : Clinical impact of cervical imbalance on surgical outcomes of laminoplasty : a propensity score-matching analysis. Clin Spine Surg 33 : E1-E7, 2020
PubMed
4) Kobayashi Y, Matsumaru S, Kuramoto T et al : Plate fixation of expansive opendoor laminoplasty decreases the incidence of postoperative C5 palsy. Clin Spine Surg 32 : E177-E182, 2019
PubMed
5) Chen C, Yang C, Yang S et al : Clinical and radiographic outcomes of modified unilateral open-door laminoplasty with posterior muscle-ligament complex preservation for cervical spondylotic myelopathy. Spine (Phila Pa 1976) 44 : 1697-1704, 2019
 
6) Nakajima K, Nakamoto H, Kato S et al : A multicenter observational study on the postoperative outcomes of C3 laminectomy in cervical double-door laminoplasty. Clin Spine Surg, 2020 [Epub ahead of print]
 
P.13 掲載の参考文献
7) Lopez WY, Goh BC, Upadhyaya S et al : Laminoplasty-an underutilized procedure for cervical spondylotic myelopathy. Spine J, 2020 [Epub ahead of print]
 
8) Mesregah MK, Buchanan IA, Formanek B et al : Intra- and post-complications of cervical laminoplasty for the treatment of cervical myelopathy : an analysis of a nationwide database. Spine (Phila Pa 1976) 45 : E1302-E1311, 2020
PubMed
9) He X, Zhang JN, Liu TJ et al : Is laminectomy and fusion the better choice than laminoplasty for multilevel cervical myelopathy with signal changes on magnetic resonance imaging? A comparison of two posterior surgeries. BMC Musculoskelet Disord 21 : 423, 2020
PubMed
10) Ibaseta A, Rahman R, Andrade NS et al : Crossing the cervicothoracic junction in cervical arthrodesis results in lower rates of adjacent segment disease without affecting operative risks or patient-reported outcomes. Clin Spine Surg 32 : 377-381, 2019
PubMed
11) Chan AK, Badiee RK, Rivera J et al : Crossing the cervicothoracic junction during posterior cervical fusion for myelopathy is associated with superior radiographic parameters but similar clinical outcomes. Neurosurgery 87 : 1016-1024, 2020
PubMed
P.14 掲載の参考文献
12) Huang KT, Harary M, Abd-El-Barr MM et al : Crossing the cervicothoracic junction in posterior cervical decompression and fusion : a cohort analysis. World Neurosurg 131 : e514-e520, 2019
PubMed
13) Pehlivanoglu T, Wuertz-Kozak K, Heider F et al : Clinical and radiographic outcome of patients with cervical spondylotic myelopathy undergoing total disc replacement. Spine (Phila Pa 1976) 44 : 1403-1411, 2019
PubMed
14) Banno F, Zreik J, Alvi MA et al : Anterior cervical corpectomy and fusion versus anterior cervical discectomy and fusion for treatment of multilevel cervical spondylotic myelopathy : insights from a national registry. World Neurosurg 132 : e852-e861, 2019
 
15) Sun B, Shi C, Wu H et al : Application of zero-profile spacer in the treatment of three-level cervical spondylotic myelopathy : 5-year follow-up results. Spine (Phila Pa 1976) 45 : 504-511, 2020
PubMed
P.15 掲載の参考文献
16) Lee DH, Lee CS, Hwang CJ et al : Improvement in cervical lordosis and sagittal alignment after vertebral body sliding osteotomy in patients with cervical spondylotic myelopathy and kyphosis. J Neurosurg Spine 33 : 273-424, 2020 [Epub ahead of print]
 
17) Oshima Y, Kato S, Doi T et al : Comparison of microendoscopic selective laminectomy versus conventional laminoplasty in patients with degenerative cervcical myelopathy : a minimum 2-year follow-up study. BMC Musculoskelet Disord 20 : 471, 2019
PubMed
18) Lin Y, Rao S, Li Y et al : Posterior percutaneous full-endoscopic cervical laminectomy and decompression for cervical stenosis with myelopathy : a technical note. World Neurosurg 124 : 350-357, 2019 [Epub ahead of print]
 
19) Liu X, Zhu Y : Endoscopic bilateral decompression for cervical stenosis caused by calcification of ligamentum flavum through unilateral approach : technical note. Clin Spine Surg, 2020 [Epub ahead of print]
 
P.16 掲載の参考文献
20) Carr DA, Abecassis IJ, Hofstetter CP : Full endoscopic unilateral laminotomy for bilateral decompression of the cervical spine : surgical technique and early experience. J Spine Surg 6 : 447-456, 2020
PubMed
21) Kato S, Nouri A, Wu D et al : Comparison of anterior and posterior surgery for degenerative cervical myelopathy : an MRI-based propensity-score-matched analysis using data from the prospective multicenter AOSpine CSM North America and international studies. J Bone Joint Surg Am 99 : 1013-1021, 2017
PubMed
22) Morishita S, Yoshii T, Okawa A et al : Comparison of perioperative complications between anterior decompression with fusion and laminoplasty for cervical spondylotic myelopathy : propensity scorematching analysis using Japanese diagnosis procedure combination database. Clin Spine Surg 33 : E101-E107, 2020
PubMed
P.17 掲載の参考文献
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13) Henriksson HB, Papadimitriou N, Hingert D et al : The traceability of mesenchymal stromal cells after injection into degenerated discs in patients with low back pain. Stem Cells Dev 28 : 1203-1211, 2019
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14) Wolff M, Shillington JM, Rathbone C et al : Injections of concentrated bone marrow aspirate as treatment for discogenic pain : a retrospective analysis. BMC Musculoskelet Disord 21 : 135, 2020
 
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15) Jain D, Goyal T, Verma N et al : Intradiscal platelet-rich plasma injection for discogenic low back pain and correlation with platelet concentration : a prospective clinical trial. Pain Med, 2020 [Epub ahead of print]
 
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2) Beauchamp EC, Anderson RCE, Vitale MG : Modern surgical management of early onset and adolescent idiopathic scoliosis. Neurosurgery 84 : 291-304, 2019
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3) Helenius IJ, Sponseller PD, McClung A et al : Surgical and health-related quality-of-life outcomes of growing rod "Graduates" with severe versus moderate early-onset scoliosis. Spine (Phila Pa 1976) 44 : 698-706, 2018
 
4) Agarwal A, Goswami A, Vijayaraghavan GP et al : Quantitaive characterisics of consective lengthening episodes in early-onset scoliosis (EOS) patients with dual growth rods. Spine (Phila Pa 1976) 44 : 397-403, 2018
 
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5) Xu L, Qiu Y, Chen Z et al : A re-evaluation of the effcts of dual growing rods on apical vertebral rotation in patients with early-onset scoliosis and a minimum of two lengthening procedures : a CT-based study. J Neurosurg Pediatr 22 : 306-312, 2018
 
6) Helenius IJ, Saarinen AJ, White KK et al : Results of growth-friedly management of early-onset scoliosis in children with and without skeletal dysplasia. A matched comparison. Bone Joint J 101-B : 1563-1569, 2019
 
7) Lonstein JE : Long-term outcome of early fusions for congenital scoliosis. Spine Deform 6 : 552-559, 2018
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8) Carbone M, Vittoria F, Sal AD : Treatment of early-onset scoliosis with growing rods in patients with neurofibromatosis-1. J Pediatr Orthop B 28 : 278-287, 2019
 
9) Jeszensky D, Kaiser B, Meuli M et al : Surgical growth guidance with non-fused anchoring segments in early-onset scoliosis. Eur Spone J 28 : 1301-1313, 2019
 
10) Cottrill E, Margalit A, Brucker C et al : Comparison of sacral-alar-iliac and iliac-only methods of pelvic fixation in early-onset scoliosis at 5.8 years' mean follow-up. Spine Deform 7 : 364-370, 2019
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12) Bouthors C, Izatt MT, Adam CJ et al : Minimizing spine autofusion with the use of semiconstrained growing rods for early onset scoliosis in children. J Pediatr Orthop 38 : e562-e571, 2018
 
13) Iyer S, Duah HO, Wulff I et al : The use of halo gravity traction in the treatment of severe early onset spinal deformity. Spine (Phila Pa 1976) 44 : E841-E845, 2019
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14) El-Hawary R, Morash K, Kadhim M et al : VEPTR treatment of early onset scoliosis in children without rib abnormalities : long-term results of a prospective, multicenter study. J Pediatr Orthop 40 : e406-e412, 2020
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16) Nossov SB, Curatolo E, Campbell RM et al : VEPTR : are we reducing respiratory assistance requirements? J Pedaitr Orthop 39 : 28-32, 2019
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17) Murphy RF, Pacult MA, Barfield WR et al : Experience with definitive instrumented final fusion after posterior-based distraction lengthening in patients with early-onset spinal deformity : single center results. J Pediatr Orthop B 28 : 10-16, 2019
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18) Thaker C, Kieser DC, Mardare M et al : Systematic review of the complications associated with magnetically controlled growing rods for the treatment of early onset scoliosis. Eur Spine J 27 : 2062-2071, 2018
 
19) Akbarnia BA, Mundis GM : Magnetically controlled growing rods in early onset. Orthopade 48 : 477-485, 2019
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20) Harshavardhana NS, Noordeen MHH, Dormans JP : Cost analysis of magnet-driven growing rods for early-onset scoliosis at 5 years. Spine (Phila Pa 1976) 44 : 60-67, 2018
 
21) Mardare M, Kieser DC, Ahmad A et al : Targeted distraction. Spinal growth in children with early-onset scoliosis treated a tail-gaiting technique for magnetically controlled growing rods. Spine (Phila Pa 1976) 43 : E1225-E1231, 2018
 
22) Wilkinson JT, Songy CE, Bumpass DB et al : Curve modulation and apex migraton using Shilla growth guidance rods for early-onset scoliosis at 5-year follow up. J Pediatr Orthop 39 : 400-405, 2019
 
23) Verma K, Slattery C, Duah H et al : Comprehensive assessment of outcomes from patients with severe early-onset scoliosis treated with a vertebral column resection : results from SRS global outreach site (FOCOS) in Ghana. J Pediatr Orthop 38 : e393-e398, 2018
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24) Glotzbecker MP, St Hilaire TA, Pawelek JB et al : Best practice guidelines for surgical site infection prevention with surgical treatment for early onset scoliosis. J Pediatr Orthop 39 : e602-e607, 2019
 
25) Minkara AA, Matsumoto H, Glotzbecker M et al : A multicenter study of the epidemiology of deep surgical site infections in children with nonidiopathic early-onset scoliosis including associated pathogens. Spine Deform 7 : 647-651, 2019
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26) Baky FJ, Milbrandt TA, Flick R et al : Cumulative anesthesia exposure in patients treated for early-onset scoliosis. Spine Deform 6 : 781-786, 2018
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2) Watanabe K, Aoki Y, Matsumoto M : An application of artificial intelligence to diagnostic imaging of spine disease : estimating spinal alignment from moire images. Neurospine 16 : 697-702, 2019
 
3) Sudo H, Kokabu T, Abe Y et al : Automated noninvasive detection of idiopathic scoliosis in children and adolescents : a principle validation study. Sci Rep 8 : 17714, 2018
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4) Yang J, Zhang K, Fan H et al : Development and validation of deep learning algorithms for scoliosis screening using back images. Commun Biol 2 : 390, 2019
 
5) Watanabe K, Ohashi M, Hirano T et al : Health-related quality of life in nonoperated patients with adolescent idiopathic scoliosis in the middle years : a mean 25-year follow-up study. Spine (Phila Pa 1976) 45 : E83- E89, 2020
 
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6) Kirzner N, Hilliard L, Martin C et al : Bone graft in posterior spine fusion for adolescent idiopathic scoliosis : a meta-analysis. ANZ J Surg 88 : 1247-1252, 2018
 
7) Ovadia D, Drexler M, Kramer M et al : Closed wound subfascial suction drainage in posterior fusion surgery for adolescent idiopathic scoliosis : a prospective randomized control study. Spine (Phila Pa 1976) 44 : 377-383, 2019
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8) Chan A, Parent E, Wong J et al : Does image guidance decrease pedicle screw-related complications in surgical treatment of adolescent idiopathic scoliosis : a systematic review update and meta-analysis. Eur Spine J 29 : 694-716, 2020
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9) Goobie SM, Zurakowski D, Glotzbecker MP et al : Tranexamic acid is efficacious at decreasing the rate of blood loss in adolescent scoliosis surgery : a randomized placebo-controlled trial. J Bone Joint Surg Am 100 : 2024-2032, 2018
 
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10) Aghdasi B, Bachmann KR, Clark D et al : Patient-reported outcomes following surgical intervention for adolescent idiopathic scoliosis : a systematic review and meta-Analysis. Clin Spine Surg 33 : 24-34, 2020
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1) Daniels AH, Reid DBC, Tran SN et al : Evolution in surgical approach, complications, and outcomes in an adult spinal deformity surgery multicenter study group patient population. Spine Deform 7 : 481-488, 2019
 
2) Schwab F, Ungar B, Blondel B et al : Scoliosis Research Society-Schwab adult spinal deformity classification : a validation study. Spine (Phila Pa 1976) 37 : 1077-1082, 2012
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3) Protopsaltis TS, Soroceanu A, Tishelman JC et al : Should sagittal spinal alignment targets for adult spinal deformity correction depend on pelvic incidence and age? Spine (Phila Pa 1976) 45 : 250-257, 2020
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4) Yamato Y, Hasegawa T, Togawa D et al : Rigorous correction of sagittal vertical axis is correlated with better ODI outcomes after extensive corrective fusion in elderly or extremely elderly patients with spinal deformity. Spine Deform 7 : 610-618, 2019
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5) Lee KY, Lee JH, Kang KC et al : Minimally invasive multilevel lateral lumbar interbody fusion with posterior column osteotomy compared with pedicle subtraction osteotomy for adult spinal deformity. Spine J 20 : 925-933, 2020
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6) Saigal R, Akbarnia BA, Eastlack RK et al : Anterior column realignment : analysis of neurological risk and radiographic outcomes. Neurosurgery 87 : E347-E354, 2020
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7) Mummaneni PV, Park P, Shaffrey CI et al : The MISDEF2 algorithm : an updated algorithm for patient selection in minimally invasive deformity surgery. J Neurosurg Spine 32 : 221-228, 2020
 
8) Xu Z, Li F, Chen G et al : Reassessment system and staged surgical strategy with minimally invasive techniques for treatment of severe adult spinal deformities. World Neurosurg 126 : e860-e868, 2019
 
9) Matsumura A, Namikawa T, Kato M et al : Factors related to postoperative coronal imbalance in adult lumbar scoliosis. J Neurosurg Spine, 2020 [Epub ahead of print]
 
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10) Tanaka N, Ebata S, Oda K et al : Predictors and clinical importance of postoperative coronal malalignment after surgery to correct adult spinal deformity. Clin Spine Surg 33 : E337-E341, 2020
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11) Obeid I, Berjano P, Lamartina C et al : Classification of coronal imbalance in adult scoliosis and spine deformity : a treatment-oriented guideline. Eur Spine J 28 : 94-113, 2019
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12) Yoshida G, Hasegawa T, Yamato Y et al : Predicting perioperative complications in adult spinal deformity surgery using a simple sliding scale. Spine (Phila Pa 1976) 43 : 562-570, 2017
 
13) Phan K, Kim JS, Xu J et al : Nutritional insufficiency as a predictor for adverse outcomes in adult spinal deformity surgery. Global Spine J 8 : 164-171, 2018
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14) Oe S, Yamato Y, Hasegawa T et al : Association between a prognostic nutritional index less than 50 and the risk of medical complications after adult spinal deformity surgery. J Neurosurg Spine 33 : 219-224, 2020
 
15) Yagi M, Michikawa T, Hosogane N et al : The 5-item modified frailty index is predictive of severe adverse events in patients undergoing surgery for adult spinal deformity. Spine (Phila Pa 1976) 44 : E1083-E1091, 2019
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16) Pierce KE, Passias PG, Alas H et al : Does patient frailty status influence recovery following spinal fusion for adult spinal deformity? : an analysis of patients with 3-year follow-up. Spine (Phila Pa 1976) 45 : E397-E405, 2020
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17) Yagi M, Michikawa T, Hosogane N et al : Treatment for frailty does not improve complication rates in corrective surgery for adult spinal deformity. Spine (Phila Pa 1976) 44 : 723-731, 2019
 
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18) Pellise F, Serra-Burriel M, Smith JS et al : Development and validation of risk stratification models for adult spinal deformity surgery. J Neurosurg Spine 31 : 587-99, 2019
 
19) Lee NJ, Lenke LG, Cerpa M et al : The 90-day reoperations and readmissions in complex adult spinal deformity surgery. Global Spine J, 2020 [Epub ahead of print]
 
20) Martini C, Langella F, Mazzucchelli L et al : Revision strategies for failed adult spinal deformity surgery. Eur Spine J 29 : 116-125, 2020
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21) Yilgor C, Sogunmez N, Boissiere L et al : Global Alignment and Proportion (GAP) score : development and validation of a new method of analyzing spinopelvic alignment to predict mechanical complications after adult spinal deformity surgery. J Bone Joint Surg Am 99 : 1661-1672, 2017
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22) Jacobs E, van Royen BJ, van Kuijk SMJ et al : Prediction of mechanical complications in adult spinal deformity surgery-the GAP score versus the Schwab classification. Spine J 19 : 781-788, 2019
 
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23) Kawabata A, Yoshii T, Sakai K et al : Identification of predictive factors for mechanical complications after adult spinal deformity surgery : a multi-institutional retrospective study. Spine (Phila Pa 1976) 45 : 1185-1192, 2020
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24) Sebaaly A, Gehrchen M, Silvestre C et al : Mechanical complications in adult spinal deformity and the effect of restoring the spinal shapes according to the Roussouly classification : a multicentric study. Eur Spine J 29 : 904-913, 2020
 
25) Roussouly P, Gollogly S, Berthonnaud E et al : Classification of the normal variation in the sagittal alignment of the human lumbar spine and pelvis in the standing position. Spine (Phila Pa 1976) 30 : 346-353, 2005
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26) Kim JS, Phan K, Cheung ZB et al : Surgical, radiographic, and patient-related risk factors for proximal junctional kyphosis : a meta-analysis. Global Spine J 9 : 32-40, 2019
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27) Iyer S, Lovecchio F, Elysee JC et al : Posterior ligamentous reinforcement of the upper instrumented vertebrae+1 does not decrease proximal junctional kyphosis in adult spinal deformity. Global Spine J 10 : 692-699, 2020
 
28) Line BG, Bess S, Lafage R et al : Effective prevention of proximal junctional failure in adult spinal deformity surgery requires a combination of surgical implant prophylaxis and avoidance of sagittal alignment overcorrection. Spine (Phila Pa 1976) 45 : 258-267, 2020
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29) Lertudomphonwanit T, Kelly MP, Bridwell KH et al : Rod fracture in adult spinal deformity surgery fused to the sacrum : prevalence, risk factors, and impact on health-related quality of life in 526 patients. Spine J 18 : 1612-1624, 2018
 
30) Guevara-Villazon F, Boissiere L, Hayashi K et al : Multiple-rod constructs in adult spinal deformity surgery for pelvic-fixated long instrumentations : an integral matched cohort analysis. Eur Spine J 29 : 886-895, 2020
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31) Jung JM, Hyun SJ, Kim KJ et al : Rod fracture after multiple-rod constructs for adult spinal deformity. J Neurosurg Spine 32 : 407-414, 2020
 
32) Jacobs K, Dewilde T, Vandoren C et al : Variability in hospital costs of adult spinal deformity care. Spine (Phila Pa 1976) 45 : 1221-1228, 2020
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33) Carreon LY, Glassman SD, Lurie J et al : Cost-effectiveness of operative versus non-operative treatment of adult symptomatic lumbar scoliosis an intent-to-treat analysis at 5-year follow-up. Spine (Phila Pa 1976) 44 : 1499-1506, 2019
 
34) Glassman SD, Carreon LY, Shaffrey CI et al : Cost-effectiveness of adult lumbar scoliosis surgery : an as-treated analysis from the adult symptomatic scoliosis surgery trial with 5-year follow-up. Spine Deform, (accepted) 2020 [Epub ahead of print]
 
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35) Yagi M, Ames CP, Keefe M et al : A cost-effectiveness comparisons of adult spinal deformity surgery in the United States and Japan. Eur Spine J 27 : 678-684, 2018
 

II章 上肢

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2) Gil JA, Gunaseelan V, DeFroda SF et al : Risk of prolonged opioid use among opioid-naive patients after common shoulder arthroscopy procedures. Am J Sports Med 47 : 1043-1050, 2019
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3) Toma O, Persoons B, Pogatzki-Zahn E et al : PROSPECT Working Group collaborators. PROSPECT guideline for rotator cuff repair surgery : systematic review and procedure-specific postoperative pain management recommendations. Anaesthesia 74 : 1320-1331, 2019
 
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5) Kwong CA, Ono Y, Carroll MJ et al : Full-thickness rotator cuff tears : what is the rate of tear progression? A systematic review. Arthroscopy 35 : 228-234, 2019
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6) Keener JD, Aleem AW, Chamberlain AM et al : Factors associated with choice for surgery in newly symptomatic degenerative rotator cuff tears : a prospective cohort evaluation. J Shoulder Elbow Surg 29 : 12-19, 2020
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7) Docter S, Khan M, Ekhtiari S et al : The relationship between the critical shoulder angle and the incidence of chronic, full-thickness rotator cuff tears and outcomes after rotator cuff repair : a systematic review. Arthroscopy 35 : 3135-3143.e4, 2019
 
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8) Tang Y, Hou J, Li Q et al : The effectiveness of using the critical shoulder angle and acromion index for predicting rotator cuff tears : accurate diagnosis based on standard and nonstandard anteroposterior radiographs. Arthroscopy 35 : 2553-2361, 2019
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9) Suter T, Gerber Popp A, Zhang Y et al : The influence of radiographic viewing perspective and demographics on the critical shoulder angle. J Shoulder Elbow Surg 24 : e149-e158, 2015
 
10) Bakti N, Antonios T, Phadke A et al : Early versus delayed mobilization following rotator cuff repair. J Clin Orthop Trauma 10 : 257-260, 2019
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11) Tirefort J, Schwitzguebel AJ, Collin P et al : Postoperative mobilization after superior rotator cuff repair : sling versus no sling : a randomized prospective study. J Bone Joint Surg Am 101 : 494-503, 2019
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12) Neviaser AS : No sling after rotator cuff repair : balancing short-term benefit with long-term health of shoulder : commentary on an article by Jerome Tirefort, MD, et al. : "Postoperative mobilization after superior rotator cuff repair : sling versus no sling. a randomized prospective study". J Bone Joint Surg Am 101 : e24, 2019
 
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13) Yamakado K : A prospective randomized trial comparing suture bridge and medially based single-row rotator cuff repair in medium-sized supraspinatus tears. Arthroscopy 35 : 2803-2813, 2019
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14) Muench LN, Kia C, Williams AA et al : High clinical failure rate after latissimus dorsi transfer for revision massive rotator cuff tears. Arthroscopy 36 : 88-94, 2020
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15) Neviaser RJ : Regarding "High clinical failure rate after latissimus dorsi transfer for revision massive rotator cuff tears". Arthroscopy 36 : 2350, 2020
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16) Schumaier A, Kovacevic D, Schmidt C et al : Defining massive rotator cuff tears : a Delphi consensus study. J Shoulder Elbow Surg 29 : 674-680, 2020
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17) Catapano M, de Sa D, Ekhtiari S et al : Arthroscopic superior capsular reconstruction for massive, irreparable rotator cuff tears : a systematic review of modern literature. Arthroscopy 35 : 1243-1253, 2019
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18) Mihata T : Editorial commentary : superior capsule reconstruction : grafts for superior capsular reconstruction must be thick and stiff. Arthroscopy 35 : 2535-2536, 2019
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19) リバース型人工肩関節全置換術適正使用基準. https://www.joa.or.jp/member/topics/2020/files/20200507.pdf
 
20) Werthel JD, Walch G, Vegehan E et al : Lateralization in reverse shoulder arthroplasty : a descriptive analysis of different implants in current practice. Int Orthop 43 : 2349-2360, 2019
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21) American Academy of Orthopaedic Surgeons (AAOS) : Optimizing the management of rotator cuff problems. http://www.orthoguidelines.org/topic?id=1007
 
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1) Bergdahl C, Wennergren D, Ekelund J et al : Mortality after a proximal humeral fracture. Bone Joint J 102-B : 1484-1490, 2020
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2) Adam J, Basil Ammori M, Isah I et al : Mortality after inpatient stay for proximal humeral fractures. J Shoulder Elbow Surg 29 : e22-e28, 2020
PubMed
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3) McLean AS, Price N, Graves S et al : Nationwide trends in management of proximal humeral fractures : an analysis of 77,966 cases from 2008 to 2017. J Shoulder Elbow Surg 28 : 2072-2078, 2019
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4) Rangan A, Handoll H, Brealey S et al : Surgical vs nonsurgical treatment of adults with displaced fractures of the proximal humerus : the PROFHER randomized clinical trial. JAMA 313 : 1037-1047, 2015
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5) Aguado HJ, Arino B, Moreno-Mateo F et al : Does an early mobilization and immediate home-based self-therapy exercise program displace proximal humeral fractures in conservative treatment? Observational study. J Shoulder Elbow Surg 27 : 2021-2029, 2018
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6) Frank FA, Niehaus R, Borbas P et al : Risk factors for secondary displacement in conservatively treated proximal humeral fractures. Bone Joint J 102-B : 881-889, 2020
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7) Malcherczyk D, Klasan A, Ebbinghaus A et al : Factors affecting blood loss and blood transfusion in patients with proximal humeral fractures. J Shoulder Elbow Surg 28 : e165-e174, 2019
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8) Cuff DJ, Simon P, Gorman RA 2nd : Randomized prospective evaluation of the use of tranexamic acid and effects on blood loss for proximal humeral fracture surgery. J Shoulder Elbow Surg 29 : 1627-1632, 2020
PubMed
9) Rouleau DM, Balg F, Benoit B et al : Deltopectoral vs. deltoid split approach for proximal HUmerus fracture fixation with locking plate : a prospective RAndomized study (HURA). J Shoulder Elbow Surg 29 : 2190-2199, 2020
 
10) Robinson CM, Stirling PHC, Goudie EB et al : Complications and Long-term outcomes of open reduction and plate fixation of proximal humeral fractures. J Bone Joint Surg Am 101 : 2129-2139, 2019
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11) Lee SH, Han SS, Yoo BM et al : Outcomes of locking plate fixation with fibular allograft augmentation for proximal humeral fractures in osteoporotic patients : comparison with locking plate fixation alone. Bone Joint J 101-B : 260-265, 2019
PubMed
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12) Boileau P, d'Ollonne T, Bessiere C et al : Displaced humeral surgical neck fractures : classification and results of third-generation percutaneous intramedullary nailing. J Shoulder Elbow Surg 28 : 276-287, 2019
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13) Sears BW, Hatzidakis AM, Johnston PS : Intramedullary fixation for proximal humeral fractures. J Am Acad Orthop Surg 28 : e374-e383, 2020
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14) Shi X, Liu H, Xing R et al : Effect of intramedullary nail and locking plate in the treatment of proximal humerus fracture : an update systematic review and meta-analysis. J Orthop Surg Res 14 : 285, 2019
 
15) Liu JN, Agarwalla A, Gowd AK et al : Reverse shoulder arthroplasty for proximal humerus fracture : a more complex episode of care than for cuff tear arthropathy. J Shoulder Elbow Surg 28 : 2139-2146, 2019
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16) Ohl X, Bonnevialle N, Gallinet D et al : How the greater tuberosity affects clinical outcomes after reverse shoulder arthroplasty for proximal humeral fractures. J Shoulder Elbow Surg 27 : 2139-2144, 2018
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17) Jain NP, Mannan SS, Dharmarajan R et al : Tuberosity healing after reverse shoulder arthroplasty for complex proximal humeral fractures in elderly patients-does it improve outcomes? A systematic review and meta-analysis. J Shoulder Elbow Surg 28 : e78-e91, 2019
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18) Lopiz Y, Alcobia-Diaz B, Galan-Olleros M et al : Reverse shoulder arthroplasty versus nonoperative treatment for 3- or 4-part proximal humeral fractures in elderly patients : a prospective randomized controlled trial. J Shoulder Elbow Surg 28 : 2259-2271, 2019
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19) Chivot M, Lami D, Bizzozero P et al : Three- and four-part displaced proximal humeral fractures in patients older than 70 years : reverse shoulder arthroplasty or nonsurgical treatment? J Shoulder Elbow Surg 28 : 252-259, 2019
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20) Torchia MT, Austin DC, Cozzolino N et al : Acute versus delayed reverse total shoulder arthroplasty for the treatment of proximal humeral fractures in the elderly population : a systematic review and meta-analysis. J Shoulder Elbow Surg 28 : 765-773, 2019
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21) Yahuaca BI, Simon P, Christmas KN et al : Acute surgical management of proximal humerus fractures : ORIF vs. hemiarthroplasty vs. reverse shoulder arthroplasty. J Shoulder Elbow Surg. 29 : S32-S40, 2020
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22) Pizzo RA, Gianakos AL, Haring RS et al : Are arthroplasty procedures really better in the treatment of complex proximal humerus fractures? A comprehensive meta-analysis and systematic review. J Orthop Trauma, 2020 [Epub ahead of print]
 
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23) Fraser AN, Bjordal J, Wagle TM et al : Reverse shoulder arthroplasty is superior to plate fixation at 2 years for displaced proximal humeral fractures in the Elderly : a multicenter randomized controlled trial. J Bone Joint Surg Am 102 : 477-485, 2020
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24) Holschen M, Siemes MK, Witt KA et al : Five-year outcome after conversion of a hemiarthroplasty when used for the treatment of a proximal humeral fracture to a reverse total shoulder arthroplasty. Bone Joint J 100-B : 761-766, 2018
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25) Ernstbrunner L, Rahm S, Suter A et al : Salvage reverse total shoulder arthroplasty for failed operative treatment of proximal humeral fractures in patients younger than 60 years : long-term results. J Shoulder Elbow Surg 29 : 561-570, 2020
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26) Nowak LL, Hall J, McKee MD et al : A higher reoperation rate following arthroplasty for failed fixation versus primary arthroplasty for the treatment of proximal humeral fractures : a retrospective population-based study. Bone Joint J 101-B : 1272-1279, 2019
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27) Valenti P, Zampeli F, Ciais G et al : The initial treatment of complex proximal humerus fracture affects the outcome of revision with reverse shoulder arthroplasty. Int Orthop 44 : 1331-1340, 2020
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3) Pan ZJ, Xu YF, Pan L et al : Zone 2 flexor tendon repairs using a tensioned strong core suture, sparse peripheral stitches and early active motion : results in 60 fingers. J Hand Surg Eur Vol 44 : 361-366, 2019
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7) Chang MK, Acharyya S, Lim ZY et al : Clinical outcomes of zone 2 flexor tendon repairs using the modified Lim/Tsai technique. J Hand Surg Asian Pac Vol 24 : 83-88, 2019
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3) Hems T : Re : Chia DSY et al. Elbow flexion strength and contractile activity after partial ulnar nerve or intercostal nerve transfers for brachial plexus injuries. J Hand Surg Eur Vol 45 : 998-999, 2020
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5) Chuang DC : Distal nerve transfers : a perspective on the future of reconstructive microsurgery. J Reconstr Microsurg 34 : 669-671, 2018
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8) Chuang DC : Discussion : outcomes of single versus double fascicular nerve transfers for restoration of elbow flexion in patients with brachial plexus injuries : a systematic review and meta-analysis. Plast Reconstr Surg 144 : 167-169, 2019
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13) Shen YP, Li TY, Chou YC et al : Comparison of perineural platelet-rich plasma and dextrose injections for moderate carpal tunnel syndrome : a prospective randomized, single-blind, head-to-head comparative trial. J Tissue Eng Regen Med 13 : 2009-2017, 2019
 
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III章 下肢

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3) Kolasinski SL, Neogi T, Hochberg MC et al : 2019 American College of Rheumatology/Arthritis Foundation guideline for the management of osteoarthritis of the hand, hip, and knee. Arthritis Care Res (Hoboken) 72 : 149-162, 2020
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4) Bannuru RR, Osani MC, Vaysbrot EE et al : OARSI guidelines for the non-surgical management of knee, hip, and polyarticular osteoarthritis. Osteoarthritis Cartilage 27 : 1578-1589, 2019
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10) Millerand M, Berenbaum F, Jacques C : Danger signals and inflammaging in osteoarthritis. Clin Exp Rheumatol 37 : 48-56, 2019
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23) 安部聡弥, 井上正弘, 三上貴司 他 : 腰椎固定術が人工股関節全置換術後のJHEQスコアに与える影響. Hip Joint 46 : 821-825, 2020
 
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2) Temmesfeld MJ, Dolatowski FC, Borthne A et al : Cross-table lateral radiographs accurately predict displacement in valgus-impacted femoral neck fractures. JB JS Open Access 4 : e0037, 2019
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4) Hsu CE, Shih CM, Wang CC et al : Lateral femoral wall thickness. A reliable predictor of post-operative lateral wall fracture in intertrochanteric fractures. Bone Joint J 95-B : 1134-1138, 2013
 
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5) Sasabuchi Y, Matsui H, Lefor AK et al : Timing of surgery for hip fractures in the elderly : a retrospective cohort study. Injury 49 : 1848-1854, 2018
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6) Overmann AL, Richards JT, O'Hara NN et al : Outcomes of elderly patients with nondisplaced or minimally displaced femoral neck fractures treated with internal fixation : a systematic review and meta-analysis. Injury 50 : 2158-2166, 2019
 
7) Dolatowski FC, Frihagen F, Bartels S et al : Screw fixation versus hemiarthroplasty for nondisplaced femoral neck fractures in elderly patients : a multicenter randomized controlled trial. J Bone Joint Surg Am 101 : 136-144, 2019
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8) Nielsen LL, Smidt NS, Erichsen JL et al : Posterior tilt in nondisplaced femoral neck fractures increases the risk of reoperations after osteosynthesis. A systematic review and meta-analysis. Injury 51 : 2771-2778, 2020
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9) van der List JP, El Saddy S, Vos SJ et al : Role of preoperative posterior tilt on the outcomes of internal fixation of non-displaced femoral neck fractures : a systematic review and meta-analysis. Injury, 2020 [Epub ahead of print]
 
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11) 前原孝 : 転位型大腿骨頚部骨折に対するORIF ; インプラントはどこまで進化したのか? MB Orthop 33 : 14-20, 2020
 
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IV章 骨軟部

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V章 基礎

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