Interpreting ultrasound images for accurate epidural needle insertion

Authors: Vaughan, N. and Dubey, V.N.

Journal: Journal of Medical Devices

Volume: 11

Issue: 3

Publisher: American Society of Mechanical Engineers (ASME)

ISSN: 1932-619X

This work presents development and testing of image processing algorithms for the automatic detection of landmarks within ultrasound images. The aim was to automate ultrasound analysis, for use during the process of epidural needle insertion. For epidural insertion, ultrasound is increasingly used to guide the needle into the epidural space. Ultrasound can improve the safety of epidural and was recommended by the 2008 NICE guidelines (National Institute for Health and Care Excellence). Without using ultrasound, there is no way for the anaesthetist to observe the location of the needle within the ligaments requiring the use of their personal judgment which may lead to injury. If the needle stops short of the epidural space, the anaesthetic is ineffective. If the needle proceeds too deep, it can cause injuries ranging from headache, to permanent nerve damage or death. Ultrasound of the spine is particularly difficult, because the complex bony structures surrounding the spine limit the ultrasound beam acoustic windows. Additionally, the important structures for epidural that need to be observed are located deeper than other conventional procedures such as peripheral nerve block. This is why a low frequency, curved probe (2-5 MHz) is used, which penetrates deeper but decreases in resolution. The benefits of automating ultrasound are to enable real-time ultrasound analysis on the live video, mitigate human error, and ensure repeatability by avoiding variation in perception by different users.

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Authors: Vaughan, N. and Dubey, V.N.

Journal: Frontiers in Biomedical Devices, BIOMED - 2017 Design of Medical Devices Conference, DMD 2017

ISBN: 9780791840672

DOI: 10.1115/DMD2017-3494

The data on this page was last updated at 05:09 on February 24, 2020.