Robotic System Development for Precision MRI-Guided Needle-Based Interventions

Li, Gang

11 August 2016

"This dissertation describes the development of a methodology for implementing robotic systems for interventional procedures under intraoperative Magnetic Resonance Imaging (MRI) guidance. MRI is an ideal imaging modality for surgical guidance of diagnostic and therapeutic procedures, thanks to its ability to perform high resolution, real-time, and high soft tissue contrast imaging without ionizing radiation. However, the strong magnetic field and sensitivity to radio frequency signals, as well as tightly confined scanner bore render great challenges to developing robotic systems within MRI environment. Discussed are potential solutions to address engineering topics related to development of MRI-compatible electro-mechanical systems and modeling of steerable needle interventions. A robotic framework is developed based on a modular design approach, supporting varying MRI-guided interventional procedures, with stereotactic neurosurgery and prostate cancer therapy as two driving exemplary applications. A piezoelectrically actuated electro-mechanical system is designed to provide precise needle placement in the bore of the scanner under interactive MRI-guidance, while overcoming the challenges inherent to MRI-guided procedures. This work presents the development of the robotic system in the aspects of requirements definition, clinical work flow development, mechanism optimization, control system design and experimental evaluation. A steerable needle is beneficial for interventional procedures with its capability to produce curved path, avoiding anatomical obstacles or compensating for needle placement errors. Two kinds of steerable needles are discussed, i.e. asymmetric-tip needle and concentric-tube cannula. A novel Gaussian-based ContinUous Rotation and Variable-curvature (CURV) model is proposed to steer asymmetric-tip needle, which enables variable curvature of the needle trajectory with independent control of needle rotation and insertion. While concentric-tube cannula is suitable for clinical applications where a curved trajectory is needed without relying on tissue interaction force. This dissertation addresses fundamental challenges in developing and deploying MRI-compatible robotic systems, and enables the technologies for MRI-guided needle-based interventions. This study applied and evaluated these techniques to a system for prostate biopsy that is currently in clinical trials, developed a neurosurgery robot prototype for interstitial thermal therapy of brain cancer under MRI guidance, and demonstrated needle steering using both asymmetric tip and pre-bent concentric-tube cannula approaches on a testbed."

Image-guided therapy

Needle-based interventions

MRI compatible robot

Towards Hands-On Cooperative Control for Closed-Loop MRI-Guided Targeted Prostate Biopsy

Wartenberg, Marek

05 April 2018

Intra-operative imaging is sometimes available to assist in needle biopsy, but typical open- loop insertion does not account for unmodeled needle deflection or target shift. Robotic closed-loop compensation for deviation from an initial straight-line trajectory can reduce the targeting error, using image-guidance for rotational control of an asymmetric bevel tip. By pairing closed-loop trajectory compensation with a hands-on cooperatively controlled needle insertion, a physician's control of the procedure can be maintained while incorporating benefits of robotic accuracy. Additionally, if puncture of a membrane can be detected, an enhanced haptic response can assist the physician in perceived anatomical localization of the needle tip. Functionality was implemented on a needle placement robot suitable for use in the MR environment and capable of holding a typical clinically used biopsy gun. The robot is configured for cooperatively controlled needle insertion with continuous closed-loop image- guided needle rotation. The robot and custom controller were tested for their effect on the Signal-to-Noise ratio (SNR) of MR images, and the results showed an approximate drop of only 12% in signal when the robot was present, and no additional signal drop when the robot was powered on or moving. The hardware and software subsystems were developed for clinical translation, and after each was validated in the lab they were integrated into the clinical environment to mimic the workflow of MRI-guided targeted biopsy. The full system was evaluated in-bore at Brigham and Women’s Hospital in Boston, MA where experiments for real-time puncture detection and MR image-guided targeted needle insertions under cooperative control were performed. Results showed overall targeting accuracy was 3.42mm RMS, improving accuracy by approximately 50% as compared to clinical trials of prostate biopsy using manual needle insertion. A cooperatively controlled robotic biopsy is more likely to gain acceptance by physicians over teleoperation due to maintaining proximity to the surgical site, but regulatory hurdles regarding robotic needle insertion still exist. The current robotic system framework is suitable for clinical use as it was fully validated in-bore, but some modifications could be made to increase the likelihood of regulatory approval. With these modifications the system could be ready for cadaver and pre- clinical animal trials within one year, and ready for in-human clinical trials in the next two to three years.

Teleoperation

Cooperative Control

Needle-based interventions

Prostate Cancer

Surgical Robotics

MRI-Compatible Robot

Image-Guided Therapy