Octopus arm inspires future surgical tool
13 May 2015
A robotic arm that can bend, stretch and squeeze through cluttered environments has been created by a group of researchers from Italy.
Inspired by the eight arms of an octopus, the device has been specifically designed for surgical operations to enable surgeons to easily access remote, confined regions of the body and, once there, manipulate soft organs without damaging them.
It is believed the device could reduce the number of instruments – and therefore entry incisions – necessary in surgical operations, with part of the arm being used to manipulate organs while another part of the arm operates.
The device, which has been presented today, Thursday 14 May, in IOP Publishing’s journal Bioinspiration and Biomimetics, holds a key advantage over traditional surgical tools by way of its ability to quickly transform from a bending, flexible instrument into a stiff and rigid one.
Lead author of the study Dr Tommaso Ranzani said: “The human body represents a highly challenging and non-structured environment, where the capabilities of the octopus can provide several advantages with respect to traditional surgical tools.
“Generally, the octopus has no rigid structures and can thus adapt the shape of its body to its environment. Taking advantage of the lack of rigid skeletal support, the eight highly flexible and long arms can twist, change their length, or bend in any direction at any point along the arm.”
To achieve this effect in the robotic arm, the researchers, from the Sant'Anna School of Advanced Studies in Italy, constructed a device that was made from two interconnecting identical modules.
Each module could be made to move by the inflation of three cylindrical chambers that were equally spaced inside the module. By alternating and combining the inflation of the three chambers, the module could be made to bend and stretch in various directions.
The stiffness of the two modules could also be controlled by exploiting a ‘granular jamming phenomenon’ in which a flexible membrane inside the module is filled with a granular media. When a vacuum is applied to the membrane, its density increases and the whole membrane becomes rigid.
In their study, the researchers performed a number of characterization tests on the robotic device, showing that it could bend to angles of up to 255° and stretch to up to 62% of its initial length. The stiffening mechanism was able to provide stiffness increases from 60% up to 200%.
The ability of the robotic arm to manipulate organs while surgical tasks are performed was successfully demonstrated in simulated scenarios where organs were represented by water-filled balloons.
“Traditional surgical tasks often require the use of multiple specialized instruments such as graspers, retractors, vision systems and dissectors to carry out a single procedure,” Dr Ranzani continued.
“We believe our device is the first step to creating an instrument that is able to perform all of these tasks, as well as reach remote areas of the body and safely support organs around the target site.”
From Thursday 14 May, this paper can be downloaded from http://iopscience.iop.org/1748-3190/10/3/035008.