Flexible platforms for natural orifice transluminal and endoluminal surgery

Nisha Patel; Carlo Seneci; Guang-Zhong Yang; Ara Darzi; Julian Teare

doi:10.1055/s-0034-1377171

Endoscopy International Open, Inhaltsverzeichnis

Endosc Int Open 2014; 02(02): E117-E123
DOI: 10.1055/s-0034-1377171

Review

Flexible platforms for natural orifice transluminal and endoluminal surgery

Nisha Patel

¹St. Mary’s Hospital, Imperial – Gastroenterology, London, United Kingdom

²Hamlyn Centre – Robotics and Engineering, London, United Kingdom

,

Carlo Seneci

²Hamlyn Centre – Robotics and Engineering, London, United Kingdom

,

Guang-Zhong Yang

²Hamlyn Centre – Robotics and Engineering, London, United Kingdom

,

Ara Darzi

¹St. Mary’s Hospital, Imperial – Gastroenterology, London, United Kingdom

²Hamlyn Centre – Robotics and Engineering, London, United Kingdom

,

Julian Teare

¹St. Mary’s Hospital, Imperial – Gastroenterology, London, United Kingdom

²Hamlyn Centre – Robotics and Engineering, London, United Kingdom

› Institutsangaben

Abstract

The flexible endoscope is playing an increasingly pivotal role in minimally invasive transluminal and endoluminal surgery. Whilst the flexible nature of the platform is desirable in order to navigate through the abdominal cavity or through a lumen, there are a number of issues with using the platform for this purpose.

The challenges associated with using flexible endoscopes such as a lack of triangulation of instruments and force transmission, which is often inadequate for endoscopic surgery are discussed in this review.

As a result of these difficulties, a number of mechanically and robotically driven devices based upon the flexible endoscope are emerging. The design of these devices and potential problems are also reviewed. Finally, future robotic systems which are still in the development and validation stage are briefly discussed.

The field of gastroenterology is diverging. The narrowing divide between minimally invasive and endoluminal surgery has led to a surge of innovative and novel devices which may in the future enable precise, seamless and scar less surgery.

Volltext

Referenzen

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