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Surgical Endoscopy
Published in: Surgical Endoscopy 10/2021

Open Access 01-10-2021 | New Technology

A novel Veress needle mechanism that reduces overshooting after puncturing the abdominal wall

Authors: Roelf R. Postema, David Cefai, Bart van Straten, Rein Miedema, Latifa Lesmana Hardjo, Jenny Dankelman, Felix Nickel, Tim Horeman-Franse

Published in: Surgical Endoscopy | Issue 10/2021

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Abstract

Background

Complications that occur in laparoscopic surgery are often associated with the initial entry into the peritoneal cavity. The literature reported incidences of Veress needle (VN) injuries of e.g. 0.31% and 0.23%. In a 2010 national survey of laparoscopic entry techniques in the Canadian General Surgical practice, 57.3% of respondents had either experienced or witnessed a serious laparoscopic entry complication like bowel perforation and vascular injury. As those complications are potentially life threatening and should be avoided at all costs, improving safety of this initial action is paramount.

Methods

Based on a bare minimum design approach with focus on function expansion of existing components, a new Safety mechanism was developed for the VN that decreases the risks of VN overshooting. The mechanism works by preventing the puncturing acceleration of the tip of the VN by decoupling the surgeon’s hand from the VN immediately after entering the abdomen.

Results

Based on a set of requirements, a first prototype of the VN+ with force decoupling safety mechanism is presented and evaluated on an ex vivo porcine abdominal wall tissue model in a custom setup. The experiments conducted by two novices and one experienced surgeon indicated a significant difference between the attempts with a standard, conventional working VN (41.4 mm [37.5–45 mm]) and VN+ with decoupling mechanism (20.8 mm [17.5–22.5 mm]) of p < 0.001.

Conclusion

A new decoupling safety mechanism was integrated successfully in a standard VN resulting in a VN+ . The results from the pilot study indicate that this new VN+ reduces overshooting with a minimum of 50% in a standardised ex vivo setting on fresh porcine abdominal wall specimens.
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Metadata
Title
A novel Veress needle mechanism that reduces overshooting after puncturing the abdominal wall
Authors
Roelf R. Postema
David Cefai
Bart van Straten
Rein Miedema
Latifa Lesmana Hardjo
Jenny Dankelman
Felix Nickel
Tim Horeman-Franse
Publication date
01-10-2021
Publisher
Springer US
Published in
Surgical Endoscopy / Issue 10/2021
Print ISSN: 0930-2794
Electronic ISSN: 1432-2218
DOI
https://doi.org/10.1007/s00464-021-08603-x

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