医学影像技术在骨质疏松症中的研究进展

doi:10.20047/j.issn1673-7210.2022.32.09

摘要
图/表
参考文献(30)
相关文章 (15)

全文: PDF (484 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要骨质疏松症是一种高发的代谢性骨病，每年有数百万人因此发生脆性骨折，而其中大多数是可以预防的，故早期诊断并准确评估骨质疏松症成为研究热点。随着医学影像技术的快速发展，其已逐渐成为骨质疏松症诊断及评估的核心方法，而临床上常用的X线、双能X线吸收测定、超声、计算机断层扫描和磁共振成像在骨质疏松症的诊断和评估等方面发挥了至关重要的作用。本文将针对目前临床上常用的医学影像技术在骨质疏松症中的研究新进展作一简要概述，以期为骨质疏松症的诊断和评估提供理论依据，扩展对骨质疏松症发生发展的认识。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	李露琴1 孙中洋2

关键词 ：骨质疏松症, 医学影像技术, X线, 双能X线吸收测定, 超声, 计算机断层扫描, 磁共振成像

Abstract：Osteoporosis is a metabolic bone disease with high incidence. Millions of people suffer from fragility fractures every year, most of which can be prevented. Therefore, early diagnosis and accurate evaluation of osteoporosis have become a research hotspot. With the rapid development of medical imaging technology, it has gradually become the core method of diagnosis and evaluation of osteoporosis. Medical imaging technology commonly used in clinic, such as X-ray, dual energy X-ray absorptiometry, ultrasound, computed tomography, and magnetic resonance imaging have played a vital role in the diagnosis and evaluation of osteoporosis. This paper will briefly summarize the new progress of medical imaging technology used in the study of osteoporosis, in order to provide theoretical basis for the diagnosis and evaluation of osteoporosis and expand the understanding of the occurrence and development of osteoporosis.

Key words： Osteoporosis Medical imaging technology X-ray Dual energy X-ray absorptiometry Ultrasound Computed tomography Magnetic resonance imaging

基金资助:国家自然科学基金资助项目（81600694）；
军委后勤科研项目（CKJ18J019、CKJ20J024、CKJ21J033）。

通讯作者: 孙中洋（1988.9-），男，博士，副教授，硕士生导师；研究方向：骨质疏松的发病机制及诊疗。

引用本文:

李露琴1 孙中洋2. 医学影像技术在骨质疏松症中的研究进展[J]. 中国医药导报, 2022, 19(32): 39-42.
LI Luqin1 SUN Zhongyang2. Research progress of medical imaging technology in osteoporosis. 中国医药导报, 2022, 19(32): 39-42.

链接本文:

https://www.yiyaodaobao.com.cn/CN/10.20047/j.issn1673-7210.2022.32.09 或 https://www.yiyaodaobao.com.cn/CN/Y2022/V19/I32/39

[1] F?觟ger-Samwald U，Dovjak P，Azizi-Semrad U，et al. Osteoporosis：Pathophysiology and therapeutic options [J]. EXCLI J，2020，19：1017-1037.
[2] Langdahl BL. Overview of treatment approaches to osteoporosis [J]. Br J Pharmacol，2021，178（9）：1891-1906.
[3] Johnston CB，Dagar M. Osteoporosis in older adults [J]. Med Clin North Am，2020，104（5）：873-884.
[4] Tse JJ，Smith ACJ，Kuczynski MT，et al. Advancements in osteoporosis imaging，screening，and study of disease etiology [J]. Curr Osteoporos Rep，2021，19（5）：532-541.
[5] Anam AK，Insogna K. Update on osteoporosis screening and management [J]. Med Clin North Am，2021，105（6）：1117- 1134.
[6] Cheng C，Wentworth K，Shoback DM. New frontiers in osteoporosis therapy [J]. Annu Rev Med，2020，71：277-288.
[7] Singh M，Nagrath AR，Maini PS. Changes in trabecular pattern of the upper end of the femur as an index of osteoporosis [J]. J Bone Joint Surg Am，1970，52（3）：457-467.
[8] Jhamaria NL，Lal KB，Udawat M，et al. The trabecular pattern of the calcaneum as an index of osteoporosis [J]. J Bone Joint Surg Br，1983，65（2）：195-198.
[9] Messina C，Albano D，Gitto S，et al. Body composition with dual energy X-ray absorptiometry：from basics to new tools [J]. Quant Imaging Med Surg，2020，10（8）：1687-1698.
[10] Wang L，Ran L，Zha X，et al. Adjustment of DXA BMD measurements for anthropometric factors and its impact on the diagnosis of osteoporosis [J]. Arch Osteoporos，2020，15（1）：155.
[11] Kennel KA，Sfeir JG，Drake MT. Optimizing DXA to assess skeletal health：key concepts for clinicians [J]. J Clin Endocrinol Metab，2020，105（12）：632.
[12] Sebro R，Ashok SS. A statistical approach regarding the diagnosis of osteoporosis and osteopenia from DXA：are we underdiagnosing osteoporosis [J]. JBMR Plus，2021，5（2）：e10444.
[13] Vestergaard P. Discrepancies in bone mineral density and fracture risk in patients with type 1 and type 2 diabetes- a meta-analysis [J]. Osteoporos Int，2007，18（4）：427-444.
[14] Fitzgerald GE，Anachebe T，McCarroll KG，et al. Calcaneal quantitative ultrasound has a role in out ruling low bone mineral density in axial spondyloarthropathy [J]. Clin Rheumatol，2020，39（6）：1971-1979.
[15] Nguyen HG，Lieu KB，Ho-Le TP，et al. Discordance between quantitative ultrasound and dual-energy X-ray absorptiometry in bone mineral density：The Vietnam Osteoporosis Study [J]. Osteoporos Sarcopenia，2021，7（1）：6- 10.
[16] Akil S，Al-Mohammed H，Al-Batati N，et al. Quantitative ultrasound assessment of the effect of parity on bone mineral density in females [J]. BMC Womens Health，2021，21（1）：380.
[17] Krieg MA，Barkmann R，Gonnelli S，et al. Quantitative ultrasound in the management of osteoporosis：the 2007 ISCD Official Positions [J]. J Clin Densitom，2008，11（1）：163-187.
[18] Keaveny TM，Clarke BL，Cosman F，et al. Biomechanical Computed Tomography analysis（BCT）for clinical assessment of osteoporosis [J]. Osteoporos Int，2020，31（6）：1025- 1048.
[19] Brunnquell CL，Winsor C，Aaltonen HL，et al. Sources of error in bone mineral density estimates from quantitative CT [J]. Eur J Radiol，2021，144：110001.
[20] L?觟ffler MT，Jacob A，Scharr A，et al. Automatic opportunistic osteoporosis screening in routine CT：improved prediction of patients with prevalent vertebral fractures compared to DXA [J]. Eur Radiol，2021，31（8）：6069-6077.
[21] Ohs N，Collins CJ，Atkins PR. Validation of HR-pQCT against micro-CT for morphometric and biomechanical analyses：A review [J]. Bone Rep，2020，13：100711.
[22] Cheung WH，Hung VW，Cheuk KY，et al. Best performance parameters of HR-pQCT to predict fragility fracture：systematic review and meta-analysis [J]. J Bone Miner Res，2021，36（12）：2381-2398.
[23] Stein EM，Silva BC，Boutroy S，et al. Primary hyperparathyroidism is associated with abnormal cortical and trabecular microstructure and reduced bone stiffness in postmenopausal women [J]. J Bone Miner Res，2013，28（5）：1029-1040.
[24] Patsch JM，Burghardt AJ，Yap SP，et al. Increased cortical porosity in type 2 diabetic postmenopausal women with fragility fractures [J]. J Bone Miner Res，2013，28（2）：313- 324.
[25] Figueiredo CP，Perez MO，Sales LP，et al. HR-pQCT in vivo imaging of periarticular bone changes in chronic inflammatory diseases：Data from acquisition to impact on treatment indications [J]. Mod Rheumatol，2021，31（2）：294- 302.
[26] Caroca S，Villagran D，Chabert S. Four functional magnetic resonance imaging techniques for skeletal muscle exploration，a systematic review [J]. Eur J Radiol，2021，144：109995.
[27] Li X，Schwartz AV. MRI Assessment of bone marrow composition in osteoporosis [J]. Curr Osteoporos Rep，2020，18（1）：57-66.
[28] Singhal V，Bredella MA. Marrow adipose tissue imaging in humans [J]. Bone，2019，118：69-76.
[29] Tratwal J，Labella R，Bravenboer N，et al. Reporting guidelines，review of methodological standards，and challenges toward harmonization in bone marrow adiposity research. Report of the methodologies working group of the international bone marrow adiposity society [J]. Front Endocrinol，2020，11：65.
[30] Jarraya M，Bredella MA. Clinical imaging of marrow adiposity [J]. Best Pract Res Clin Endocrinol Metab，2021， 35（4）：101511.