Department of Mechanical Engineering, King's College London, London, United Kingdom.
J Endourol. 2010 Jul;24(7):1155-9. doi: 10.1089/end.2010.0131.
We describe a comparative study between an enhanced air-cushion tactile sensor and a wheeled indentation probe. These laparoscopic tools are designed to rapidly locate soft-tissue abnormalities during minimally invasive surgery (MIS).
The air-cushion tactile sensor consists of an optically based sensor with a 7.8 mm sphere "floating" on a cushion of air at the tip of a shaft. The wheeled indentation probe is a 10 mm wide and 5 mm in diameter wheel mounted to a force/torque sensor. A continuous rolling indentation technique is used to pass the sensors over the soft-tissue surfaces. The variations in stiffness of the viscoelastic materials that are detected during the rolling indentations are illustrated by stiffness maps that can be used for tissue diagnosis. The probes were tested by having to detect four embedded nodules in a silicone phantom. Each probe was attached to a robotic manipulator and rolled over the silicone phantom in parallel paths. The readings of each probe collected during the process of rolling indentation were used to achieve the final results.
The results show that both sensors reliably detected the areas of variable stiffness by accurately identifying the location of each nodule. These are illustrated in the form of two three-dimensional spatiomechanical maps.
These probes have the potential to be used in MIS because they could provide surgeons with information on the mechanical properties of soft tissue, consequently enhancing the reduction in haptic feedback.
我们描述了一种增强型气枕式触觉传感器与轮式压痕探头的对比研究。这些腹腔镜工具旨在微创外科手术 (MIS) 期间快速定位软组织异常。
气枕式触觉传感器由一个基于光学的传感器组成,传感器的顶端有一个 7.8 毫米的球体“漂浮”在气垫上。轮式压痕探头是一个 10 毫米宽、5 毫米直径的轮子,安装在力/扭矩传感器上。连续滚动压痕技术用于使传感器在软组织表面上滚动。在滚动压痕过程中检测到的粘弹性材料的刚度变化通过刚度图来表示,可用于组织诊断。通过在硅酮模型中检测四个嵌入式结节来测试探头。每个探头都连接到机器人操纵器上,并在平行路径上在硅酮模型上滚动。在滚动压痕过程中收集的每个探头的读数用于获得最终结果。
结果表明,两种传感器都通过准确识别每个结节的位置可靠地检测到可变刚度区域。这些结果以两个三维空间力学图的形式呈现。
这些探头有可能用于 MIS,因为它们可以为外科医生提供关于软组织力学特性的信息,从而减少触觉反馈的减少。