Bela Musits

An image-directed robotic system for precise orthopaedic surgery

The authors have developed an image-directed robotic system to augment the performance of human surgeons in precise bone machining procedures in orthopaedic surgery, initially targeted at cementless total hip replacement surgery. The total system consists of an interactive CT-based presurgical planning component and a surgical system consisting of a robot, redundant motion monitoring, and man-machine interface components. In vitro experiments conducted with this system have demonstrated an order-of-magnitude improvement in implant fit and placement accuracy, compared to standard manual preparation techniques. The first generation system described in this paper was used in a successful veterinary clinical trial on 26 dogs needing hip replacement surgery. It was the basis for subsequent development of a second-generation system that is now in human clinical trials. >

Development of a surgical robot for cementless total hip arthroplasty.

The long-term success of cementless total hip arthroplasty (THA) may depend on bone ingrowth into the porous-fixation surfaces of the implant. The ingrowth process is facilitated when the surgeon achieves a satisfactory fit for the prosthesis. Clinically or roentgenographically visible failure and persistent thigh pain after cementless THA remain significant problems, both of which may be alleviated by more precise preparation of the femoral canal and selection of an appropriately sized prosthesis. The objective of this study was to obtain an exact fit for the prosthesis through the use of an image-directed surgical robot for femoral canal preparation.

A surgical robot for total hip replacement surgery

The authors describe a robotic surgical system that has been designed to create femoral cavities that are precisely shaped and positioned for implantation of uncemented prostheses. This robotics system creates cavities with a dimensional accuracy more than 50 times greater than broached cavities, exceeds the tolerances to which implants are manufactured, and does not produce gaps that prevent bone ingrowth. A canine study was undertaken to evaluate the prosthesis fit and placement achieved by employing a surgical robot to prepare the femur. This study compared the results achieved on 15 dogs undergoing total hip replacement with manual broaching techniques and 25 dogs undergoing robotically assisted surgery. Among the 25 dogs, which ranged in age from 2/sup 1///sub 2/ to 11 years, there were no deaths, no infections, and no intraoperative complications. Human applications of this technique are also considered.<<ETX>>

An integrated system for cementless hip replacement

Describes robotics and medical imaging technology in the enhancement of precision surgery. The authors consider: cementless total hip replacement application; system overview; ORTHODOC preoperative planning workstation; ROBODOC surgical assistant; safety features; surgical protocol. >

Development of a surgical robot for cementless total hip replacement

The combination of robotics and medical imaging may soon provide orthopaedic surgeons with a tool that significantly increases the precision of cementless total hip replacement operations and directly links preoperative planning with surgical execution. Twenty-six successful robot-assisted operations have been performed on dogs and the first clinical trials on human patients have recently taken place.

Architecture of a surgical robot

The ROBODOC Surgical Assistant System has been developed to increase the accuracy and efficacy of surgical procedures. The first application is total hip replacement surgery, where the function of the robot is to machine a cavity in the patients femure for a prosthetic implant. The authors describe the hardware and software architecture of the operating room component of the system. The design satisfies the unique requirements of the surgical environment and the general requirements of a complex robotic system.<<ETX>>

Robotic total hip replacement surgery in dogs

Approximately half of over 120000 total hip replacement operations performed annually in the United States use cementless implants. The standard method for preparing the femoral cavity for such implants improves the use of mallet-driven handheld broach whose shape matches that of the desired implant. In vitro experiments have supported the possibility that more accurate (and efficacious) results can be achieved by using a robot to machine the cavity. The authors are developing a second-generation system suitable for use in an operating room, targeted at clinical trials on dogs needing hip implants. A description is given of the background, objectives, architecture, and surgical procedure for this system. Also provided are brief descriptions of key results from earlier experiments and planned future work.<<ETX>>

Sensors for robotic assembly

Special-purpose sensors and hybrid mechanical systems have been developed to assemble advanced electronic circuits. State-of-the-art robot systems that are used for electronic assembly and accuracy requirements for the developing surface mount technology are reviewed, showing the need for improved robot positioning capability. Examples of laboratory experiments that demonstrated successful precision assembly or testing using an ordinary robot, a micropositioner, and an optical sensing system are given. These involve fiber-optic sensing, machine-vision endpoint sensing, and hybrid tactic-vision endpoint sensing.<<ETX>>