Session Item

High-dose-rate (HDR) brachytherapy (BT) implant needles are rigid and restricted to linear insertion paths. Steerable instruments allow for precise access to deeply-seated targets while sparing sensitive tissues and avoiding anatomical structures. In addition, steerable instruments can enlarge the potential patient group eligible for HDR prostate BT, as generally patients with a prostate volume > 50-60 cm³ are excluded from this treatment modality due to pubic arch interference (PAI). In this study, we present and evaluate a novel omnidirectional steerable needle for HDR BT of the prostate.

The instrument utilizes the commercial HDR BT outer catheter and an inner needle with internal compliant mechanism. This mechanism enables distal tip steering through proximal instrument bending while preserving high axial and flexural rigidity. Active steering of the instrument allows for adjustments of the catheter pathway and withdrawal of the inner needle creates a work channel for remote afterloading.

Finite element analysis evaluates the design and the prototype is validated in experiments involving tissue simulants and ex-vivo bovine tissue. US images are used to provide visualization and shape-reconstruction of the instrument during the insertions.

Manually controlled active needle tip steering in inhomogeneous tissue simulants and ex-vivo tissue resulted in mean targeting errors of 1.4 mm and 2 mm in 3D position, respectively. We found lateral tip steering up to 20 mm. The experiments showed that the steering response of the instrument is history-independent.

The results indicate that the endpoint variability of the steerable needle is similar to that of a conventional rigid HDR BT implant needle while adding the ability to steer along curved paths. High axial and flexural rigidity enable puncturing and path control within various heterogeneous tissues. The developed steerable instrument has the potential to overcome problems currently unavoidable with rigid HDR BT implant needles, such as PAI, without major changes to the clinical workflow.