[1]《眼部超声可视化生物规范测量指南(0)》专家组,中国医药教育协会眼科影像与智能医疗分会及智能医学专委会,国际转化医学会眼科学专委会,等.眼部超声可视化生物规范测量指南(2024)[J].眼科新进展,2024,44(6):421-427.[doi:10.13389/j.cnki.rao.2024.0082]
 Expert Workgroup of Standard Operating Guidelines for Ocular Ultrasound Examination and Measurement (0),Ophthalmic Imaging and Intelligent Medicine Branch Chinese Medicine Education Association,Ophthalmology Committee of International Association of Translational Medicine,et al.Standard operating guidelines for ocular ultrasound examination and measurement (2024)[J].Recent Advances in Ophthalmology,2024,44(6):421-427.[doi:10.13389/j.cnki.rao.2024.0082]
点击复制

眼部超声可视化生物规范测量指南(2024)/HTML
分享到:

《眼科新进展》[ISSN:1003-5141/CN:41-1105/R]

卷:
44卷
期数:
2024年6期
页码:
421-427
栏目:
述评
出版日期:
2024-06-03

文章信息/Info

Title:
Standard operating guidelines for ocular ultrasound examination and measurement (2024)
作者:
《眼部超声可视化生物规范测量指南(2024)》专家组中国医药教育协会眼科影像与智能医疗分会及智能医学专委会国际转化医学会眼科学专委会中国眼科影像研究专家组
Author(s):
Expert Workgroup of Standard Operating Guidelines for Ocular Ultrasound Examination and Measurement (2024)Ophthalmic Imaging and Intelligent Medicine Branch Chinese Medicine Education AssociationOphthalmology Committee of International Association of Translational MedicineChinese Ophthalmic Imaging Study Groups
关键词:
眼部超声A型超声 B型超声超声生物显微镜彩色多普勒血流成像
Keywords:
ocular ultrasound amplitude-mode ultrasound brightness-mode ultrasound ultrasound biomicroscopy color Doppler flow imaging
分类号:
R770.4
DOI:
10.13389/j.cnki.rao.2024.0082
文献标志码:
A
摘要:
超声检查和测量的准确性对眼部疾病的诊断有着重要意义。常用的眼超声检查主要包括A型超声、B型超声、超声生物显微镜(UBM)和彩色多普勒血流成像等方法。A型超声主要用于测量不同回声强度的组织之间的距离。B型超声可以显示眼的二维结构并对目标点进行定量测量。UBM是一种超高频的二维成像方法,可清晰显示眼前段的结构特点并测量相关参数,对房角形态改变的定量分析,眼内镜植入手术前、后的眼前段形态变化均可提供帮助。彩色多普勒血流成像在二维超声的基础上应用多普勒效应可定量测量移动物质的相关参数,反映眼局部的血流变化情况。为规范不同超声检查方法在眼部检查中的测量操作,特制定本指南。本指南主要针对不同类型眼部超声仪器测量的规范化操作及其在眼部疾病中的临床应用来进行阐述,从而为相关眼部疾病的诊断和治疗提供一定的指导意见。
Abstract:
The accuracy of ultrasound examination and measurement is of great significance to diagnosing ocular diseases. The commonly used ocular ultrasonography includes amplitude (A)-mode ultrasound, brightness (B)-mode ultrasound, ultrasound biomicroscopy (UBM), and color Doppler flow imaging (CDFI). A-mode ultrasound is mainly used to measure the distance between tissues with different echo intensities. B-mode ultrasound can visualize the two-dimensional structure of the eye and make quantitative measurements of the target point. UBM is an ultra-high-frequency two-dimensional imaging method, which can clearly display the structural characteristics of the anterior segment and measure the relevant parameters. It can also help quantitatively analyze the morphological changes of the angle and the anterior segment before and after implantable collamer lens surgery. CDFI can quantitatively measure the parameters of blood vessels by applying the Doppler effect on the basis of two-dimensional ultrasound, reflecting the changes of blood flow in the eye. To standardize the operations of different ultrasound examination methods, this guideline is formulated. This guideline mainly focuses on the standardized operation of ocular ultrasound instruments and their clinical application in ocular diseases, so as to provide guidance for the diagnosis and treatment of related ocular diseases.

参考文献/References:

[1] SHRIKI J.Ultrasound physics[J].Crit Care Clin,2014,30(1):1-24.
[2] TRIVEDI R H,WILSON M E.Globe axial length data in children using immersion A-scan ultrasound[J].J Cataract Refract Surg,2021,47(11):1481-1482.
[3] HUANG H,DING X,WANG D,YANG X,WANG D,HE M.Desktop auxiliary apparatus for A-scan ultrasound:repeatability and validity[J].J Cataract Refract Surg,2012,38(1):97-101.
[4] HE M,CHEN H,WANG W.Refractive errors,ocular biometry and diabetic retinopathy:a comprehensive review[J].Curr Eye Res,2021,46(2):151-158.
[6] CASS K,THOMPSON C M,TROMANS C,WOOD I C J.Evaluation of the validity and reliability of A-scan ultrasound biometry with a single use disposable cover[J].Br J Ophthalmol,2002,86(3):344-349.
[7] DE BERNARDO M,VITIELLO L,ROSA N.A-scan ultrasonography as a supportive diagnostic tool in case of acute optic neuritis[J].Mult Scler Relat Disord,2019,36:101434.
[8] SZALAI E,BERTA A,NMETH G,HASSAN Z,MDIS L Jr.Anterior chamber depth measurements obtained with Pentacam HR? imaging system and conventional A-scan ultrasound[J].Ophthalmic Surg Lasers Imaging,2011,42(3):248-253.
[9] SHAMMAS H J.A comparison of immersion and contact techniques for axial length measurement[J].J Am Intraocul Implant Soc,1984,10(4):444-447.
[10] SCHELENZ J,KAMMANN J.Comparison of contact and immersion techniques for axial length measurement and implant power calculation[J].J Cataract Refract Surg,1989,15(4):425-428.
[11] HAIGIS W,LEGE B,MILLER N,SCHNEIDER B.Comparison of immersion ultrasound biometry and partial coherence interferometry for intraocular lens calculation according to Haigis[J].Graefes Arch Clin Exp Ophthalmol,2000,238(9):765-773.
[12] PACKER M,FINE I H,HOFFMAN R S,COFFMAN P G,BROWN L K.Immersion A-scan compared with partial coherence interferometry:outcomes analysis[J].J Cataract Refract Surg,2002,28(2):239-242.
[13] GOYAL R,NORTH R V,MORGAN J E.Comparison of laser interferometry and ultrasound A-scan in the measurement of axial length[J].Acta Ophthalmol Scand,2003,81(4):331-335.
[14] CHEN Y,WANG D,CHEN L,YAN W,HE M.Association of refraction and ocular biometry in highly myopic eyes[J].Clin Exp Optom,2021,104(5):589-594.
[15] LI Y,LI H X,LIU Y C,GUO Y T,GAO J M,WU B,et al.Comparison of immersion ultrasound and low coherence reflectometry for ocular biometry in cataract patients[J].Int J Ophthalmol,2018,11(6):966-969.
[16] ABU EL EINEN K G,SHALABY M H,EL SHIWY H T.Immersion B-guided versus contact A-mode biometry for accurate measurement of axial length and intraocular lens power calculation in siliconized eyes[J].Retina,2011,31(2):262-265.
[17] SCHMIDT F A,RUPRECHT K,CONNOLLY F,MAAS M B,PAUL F,HOFFMANN J,et al.B-mode ultrasound assessment of pupillary function:feasibility,reliability and normal values[J].PLoS One,2017,12(12):e0189016.
[18] SHAMMAS H J.Intraocular lens power calculations[M].USA:SLA-CK lncorpated,2003.
[19] YANG Q H,ZHANG H T,LI X Q,CHEN B,LI Z H,HUANG Y F,et al.Accuracy of segmented measurement of axial length in ultra-high myopia filled with silicone oil using immersion B-scan ultrasonography[J].Int J Ophthalmol,2022,15(5):793-799.
[20] HARRINGTON S C,O’DWYER V.Ocular biometry,refraction and time spent outdoors during daylight in Irish schoolchildren[J].Clin Exp Optom,2020,103(2):167-176.
[21] PAVLIN C J,HARASIEWICZ K,SHERAR M D,FOSTER F S.Clinical use of ultrasound biomicroscopy[J].Ophthalmology,1991,98(3):287-295.
[22] BYRNE S,GREEN R.Ultrasound of the eye and orbit[M].2nd ed.St Louis:Mosby,2002.
[23] 邵毅,接英,刘祖国.人工智能在眼前节疾病诊断中的应用指南(2023)[J].国际眼科杂志,2023,23(9):1421-1430.
SHAO Y,JIE Y,LIU Z G.Guidelines for the application of artificial intelligence in the diagnosis of anterior segment diseases(2023)[J].Int Eye Sci,2023,23(9):1421-1430.
[24] ERICKSON S J,HENDRIX L E,MASSARO B M,HARRIS G J,LEWANDOWSKI M F,FOLEY W D,et al.Color Doppler flow imaging of the normal and abnormal orbit[J].Radiology,1989,173(2):511-516.
[25] LIEB W E,FLAHARTY P M,SERGOTT R C,MEDLOCK R D,BROWN G C,BOSLEY T,et al.Color Doppler imaging provides accurate assessment of orbital blood flow in occlusive carotid artery disease[J].Ophthalmology,1991,98(4):548-552.
[26] LIEB W E,COHEN S M,MERTON D A,SHIELDS J A,MITCHELL D G,GOLDBERG B B.Color Doppler imaging of the eye and orbit.Technique and normal vascular anatomy[J].Arch Ophthalmol,1991,109(4):527-531.
[27] LIEB W E,SHIELDS J A,COHEN S M,MERTON D A,MITCHELL D G,SHIELDS C L,et al.Color Doppler imaging in the management of intraocular tumors[J].Ophthalmology,1990,97(12):1660-1664.
[28] 杨文利.临床眼超声诊断学[M].北京:科学技术文献出版社,2019.
YANG W L.Ophthalmic ultrasonography[M].Beijing:Scientific and Technical Documents Publishing House,2019.

相似文献/References:

[1]刘晓航 陶海.泪道超声检查研究进展[J].眼科新进展,2012,32(7):000.

备注/Memo

备注/Memo:
国家自然科学基金(编号:82160195);江西省双千计划科技创新高端领军人才项目(编号:jxsq2023201036);江西省重大(重点)研发专项计划(编号:20223BBH80014);国家重点研发计划项目(编号:2018YFC0116000)
注:本指南的国际实践指南注册号为 PREPARE-2023CN213(http://www.guidelines-redistry.cn/)。
更新日期/Last Update: 2024-06-05