Precision, repeatability, and accuracy are of paramount importance in these tactile medical examinations to ensure favourable patient outcomes.A range of automatic and semi-automatic devices have been proposed to aid with optimising this task, particularly for difficult to detect and hard to reach situations such as during minimally invasive surgery.
The team created their manipulator using 3D printing and other computerised numerical control techniques and employed a combination of laboratory experiments and simulated experiments on a fake (silicone) breast and its digital twin, both modelled on a volunteer at the simulation and modelling in medicine and surgery research group at Imperial College London.The simulations allowed the team to perform thousands of palpitations and test lots of hypothetical scenarios such as calculating the difference in efficiency when using two, three, or four sensors at the same time.
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In the lab, they were able to carry out the experiments on the silicone breast to demonstrate the simulations were accurate and to experimentally discover the forces for the real equipment. The ultimate goal is that the device and sensors will have the capability to detect lumps more accurately and deeper than it is possible only from applying human touch.It could also be combined with other existing techniques, such as ultrasound examination.”We have shown that our robotic system has the dexterity necessary to carry out a clinical breast examination – we hope that in the future this could be a real help in diagnosing cancers early,” Jenkinson said.
Source: IANS
