Development and First Patient Trial of a Surgical Robot for Complex Trajectory Milling

Korb, Werner; Engel, Dirk; Boesecke, R.; Eggers, Georg; Kotrikova, B.; Marmulla, Rüdiger; Raczkowsky, Jörg; Wörn, Heinz; Mühling, Joachim; Haßfeld, Stefan

doi:10.3109/10929080309146060

Cited by 32 publications

(21 citation statements)

References 11 publications

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“…The robot system bRobaCKaQ has performed the first milling of a complex trajectory on a patient's scull worldwide in April 2003 [1]. Yet, the dura mater cannot be detected, the heat produced by the milling can lead to necroses and the impressed forces may move the patient and invalidate its registration.…”

Section: Introductionmentioning

confidence: 99%

Bringing laser for osteotomy into the operation theatre

Peters

Knoop

Korb

et al. 2005

International Congress Series

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Section: Introductionmentioning

confidence: 99%

Bringing laser for osteotomy into the operation theatre

Peters

Knoop

Korb

et al. 2005

International Congress Series

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“…The use of robot systems for drilling tasks on the skull has been shown to be a valuable surgical technique for the insertion of cochlea implants [5,6] and for the development of a system for craniotomy [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Robot- and computer-assisted craniotomy (CRANIO): From active systems to synergistic man—machine interaction

Cunha-Cruz

Follmann

Popović

et al. 2009

Proc Inst Mech Eng H

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Computer and robot assistance in craniotomy/craniectomy procedures is intended to increase precision and efficiency of the removal of calvarial tumours, enabling the preoperative design and manufacturing of the corresponding implant. In the framework of the CRANIO project, an active robotic system was developed to automate the milling processes based on a predefined resection planning. This approach allows for a very efficient milling process, but lacks feedback of the intra-operative process to the surgeon. To better integrate the surgeon into the process, a new teleoperated synergistic architecture was designed. This enables the surgeon to realize changes during the procedure and use their human cognitive capabilities. The preoperative planning information is used as guidance for the user interacting with the system through a master-slave architecture. In this article, the CRANIO system is presented together with this new synergistic approach. Experiments have been performed to evaluate the accuracy of the system in active and synergistic modes for the bone milling procedure. The laboratory studies showed the general feasibility of the new concept for the selected medical procedure and determined the accuracy of the system. Although the integration of the surgeon partially reduces the efficiency of the milling process compared with a purely active (automatic) milling, it provides more feedback and flexibility to the user during the intra-operative procedure.

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“…The systems display instrument movement within a 3D-CT data set using a graphical instrument representation. Although navigation systems have been used to guide medical robots they have been mostly used for interventions on rigid anatomical areas (orthopedics, maxillofacial and neurology) (17)(18)(19). Improvements in robot control have shown a variety of benefits.…”

Section: Introductionmentioning

confidence: 99%