Abstract
PurposeThe study aimed to evaluate a new robotic assistance system (RAS) for needle placement in combination with a multi-axis C-arm angiography system for cone-beam computed tomography (CBCT) in a phantom setting.Materials and MethodsThe RAS consisted of a tool holder, dedicated planning software, and a mobile platform with a lightweight robotic arm to enable image-guided needle placement in conjunction with CBCT imaging. A CBCT scan of the phantom was performed to calibrate the robotic arm in the scan volume and to plan the different needle trajectories. The trajectory data were sent to the robot, which then positioned the tool holder along the trajectory. A 19G needle was then manually inserted into the phantom. During the control CBCT scan, the exact needle position was evaluated and any possible deviation from the target lesion measured.ResultsIn total, 16 needle insertions targeting eight in- and out-of-plane sites were performed. Mean angular deviation from planned trajectory to actual needle trajectory was 1.12°. Mean deviation from target point and actual needle tip position was 2.74 mm, and mean deviation depth from the target lesion to the actual needle tip position was 2.14 mm. Mean time for needle placement was 361 s. Only differences in time required for needle placement between in- and out-of-plane trajectories (337 s vs. 380 s) were statistically significant (p = 0.0214).ConclusionUsing this RAS for image-guided percutaneous needle placement with CBCT was precise and efficient in the phantom setting.
Highlights
Invasive, percutaneous, needle-based interventions are being performed more and more frequently in clinical routine
Materials and Methods The robotic assistance system (RAS) consisted of a tool holder, dedicated planning software, and a mobile platform with a lightweight robotic arm to enable image-guided needle placement in conjunction with cone-beam computed tomography (CBCT) imaging
CT-guided interventions (CTGI) can lead to increased radiation exposure for the medical staff and/or patient, depending on different factors, such as increased complexity of the intervention, the experience of the radiologists performing the procedure, and out-of-plane trajectories [3, 5]
Summary
Percutaneous, needle-based interventions are being performed more and more frequently in clinical routine. M. Kostrzewa et al: Robotic Assistance System for Cone-Beam Computed Tomography-Guided Percutaneous Needle Placement gantry size and limited possibilities of gantry angulation, requiring out-of-plane interventions, and more time for more complex procedures [4]. CTGIs can lead to increased radiation exposure for the medical staff and/or patient, depending on different factors, such as increased complexity of the intervention, the experience of the radiologists performing the procedure, and out-of-plane trajectories [3, 5]. With the increasing complexity and frequency of CTGIs, assistance systems might be helpful to facilitate more complex multi-angulated needle trajectories, allow for precise and safe needle placement, and decrease interventional time and radiation exposure [6]
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