The Actuation Mechanism of 3D Printed Flexure-Based Robotic Microtweezers

Patient specific porous implants for the reconstruction of craniofacial defects have gained importance due to their better performance over their generic counterparts. The recent introduction of electron beam melting (EBM) for the processing of titanium has led to a one step fabrication of porous custom titanium implants with controlled porosity to meet the requirements of the anatomy and functions at the region of implantation. This paper discusses an image based micro-structural analysis and the mechanical characterization of porous Ti6Al4V structures fabricated using the EBM rapid manufacturing process. SEM studies have indicated the complete melting of the powder material with no evidence of poor inter-layer bonding. Micro-CT scan analysis of the samples indicate well formed titanium struts and fully interconnected pores with porosities varying from 49.75%-70.32%. Compression tests of the samples showed effective stiffness values ranging from 0.57(+/-0.05)-2.92(+/-0.17)GPa and compressive strength values of 7.28(+/-0.93)-163.02(+/-11.98)MPa. For nearly the same porosity values of 49.75% and 50.75%, with a variation in only the strut thickness in the sample sets, the compressive stiffness and strength decreased significantly from 2.92 GPa to 0.57 GPa (80.5% reduction) and 163.02 MPa to 7.28 MPa (93.54 % reduction) respectively. The grain density of the fabricated Ti6Al4V structures was found to be 4.423 g/cm(3) equivalent to that of dense Ti6Al4V parts fabricated using conventional methods. In conclusion, from a mechanical strength viewpoint, we have found that the porous structures produced by the electron beam melting process present a promising rapid manufacturing process for the direct fabrication of customized titanium implants for enabling personalized medicine. (c) 2009 Elsevier Ltd. All rights reserved.

It has been nearly 20 years since the first appearance of robotics in the operating room. In that time, much progress has been made in integrating robotic technologies with surgical instrumentation, as evidenced by the many thousands of successful robot-assisted cases. However, to build on past success and to fully leverage the potential of surgical robotics in the future, it is essential to maximize a shared understanding and communication among surgeons, engineers, entrepreneurs, and healthcare administrators. This article provides an introduction to medical robotic technologies, develops a possible taxonomy, reviews the evolution of a surgical robot, and discusses future prospects for innovation. Robotic surgery has demonstrated some clear benefits. It remains to be seen where these benefits will outweigh the associated costs over the long term. In the future, surgical robots should be smaller, less expensive, easier to operate, and should seamlessly integrate emerging technologies from a number of different fields. Such advances will enable continued progress in surgical instrumentation and, ultimately, surgical care.

Recently, robotic technology in the surgical area has gained wide popularity. However, in the filed of head and neck surgery, the applications of robotic instruments are problematic owing to spatial and technical limitations. The authors performed robot-assisted endoscopic thyroid operations in consecutive thyroid tumor patients using the newly introduced da Vinci S surgical system. Herein the authors describe the technique used and its utility for the operative management of thyroid tumors. From October 2007 to November 2008, 338 patients underwent robot-assisted endoscopic thyroid operations using a gasless, transaxillary approach. All procedures were successfully completed without conversion to an open procedure. Patient's clinicopathologic characteristics, operation types, operation times, the learning curve, and postoperative hospital stays and complications were evaluated. The mean patient age was 40 years (range, 16-69) and the male to female ratio was 1:16.8. Two hundred and thirty-four patients underwent less than total and 104 underwent bilateral total thyroidectomy. Ipsilateral central compartment node dissection was conducted in all malignant cases. Mean operation time was 144.0 minutes (range, 69-347) and mean postoperative hospital stay was 3.3 days (range, 2-7). No serious postoperative complication occurred; there were 3 cases of recurrent laryngeal nerve injury and 1 of Horner's syndrome. Our technique of robotic thyroid surgery using a gasless, transaxillary approach is feasible and safe in selected patients with a benign or malignant thyroid tumor.