Endovascular robotics

A Novel Endovascular Robotic System for Treatment of Lower Extremity Peripheral Arterial Disease: First-in-Human Experience

BACKGROUND

To assess the feasibility and first-in-human experience of a novel endovascular robotic system for treatment of lower extremity peripheral arterial disease (PAD).

METHODS

Between November 2021 and January 2022, consecutive patients with obstructive lower extremity PAD and claudication (Rutherford 2-5) with >50% stenosis demonstrated on angiography were enrolled in this study. Lower extremity peripheral arterial intervention was performed using the endovascular robotic system, which consisted of a bedside unit and an interventional console. The primary endpoints were technical success, defined as the successful manipulation of the lower extremity peripheral arterial devices using the robotic system, and safety. The secondary endpoints were clinical success, defined as 50% residual stenosis at the completion of the robot-assisted procedure without major adverse cardiac events and radiation exposure.

RESULTS

In total, 5 patients with PAD were enrolled in this study (69.2±6.0 years; 80% men). The novel endovascular robotic system successfully completed the entire procedure of endovascular treatment of lower extremity PAD. Conversion to manual operation, including advancement, retracement, rotation of the guidewires, catheters, sheaths, deployment, and release of the balloons and stent grafts, was not necessary. We achieved the criteria for clinical procedural and technical success in all patients. No deaths, myocardial infarctions, or ruptures occurred in the period up to 30 days after the procedure, and no device-related complications were observed. The robotic system operator had 97.6% less radiation exposure than that at the procedure table, with a mean of 1.40±0.49 μGy.

CONCLUSIONS

This study demonstrated the safety and feasibility of the robotic system. The procedure reached technical and clinical performance metrics and resulted in significantly lower radiation exposure to the operators at the console compared with that at the procedure table.

CLINICAL IMPACT

There were some reports about several robotic systems used in the peripheral arterial disease, but no robotic system was able to perform entire procedure of endovascular treatment of lower extremity peripheral arterial disease (PAD).To solve this problem, we designed a remote-control novel endovascular robotic system. It was the first robotic system that can perform entire procedure of endovascular treatment of PAD worldwide. A novelty retrieval report about this is provided in the supplementary materials.The robotic system is compatible with all commercial endovascular surgical devices currently available in the market, including guidewires, catheters and stent delivery systems. It can perform all types of motion, such as forward, backward, and rotation to meet the requirements of all types of endovascular procedures. During the operation, the robotic system can perform these operations in a fine-tuned manner, so it is easy to cross the lesions, which is the key factor influencing the success rate of the operation. In addition, the robotic system can effectively reduce the exposure time to radiation, thereby reducing the risk of occupational injury.

Role of Robotics in Image-Guided Trans-Arterial Interventions

The integration of robotic systems in image-guided trans-arterial interventions has revolutionized the field of Interventional Radiology (IR), offering enhanced precision, safety, and efficiency. These advancements are particularly impactful for acute conditions such as stroke, pulmonary embolism, and STEMI, where timely intervention is critical. Robotic platforms like the CorPath GRX and Magellan allow for remote navigation and catheter-based interventions, making it possible to extend specialized services to remote and underserved areas. These systems reduce radiation exposure for operators and enable safer, more complex procedures such as neurovascular interventions, pulmonary embolism treatment, and trans-arterial chemoembolization. By allowing specialists to control procedures remotely, robotic systems can dramatically improve outcomes in regions lacking immediate access to expert care for acute diseases. However, challenges such as high costs, the need for robust telecommunication infrastructure, and the absence of tactile feedback still exist. Future innovations, including untethered micro-robots and MR-guided robotics, hold promise for addressing these limitations. As these technologies evolve, robotic systems are expected to play a vital role in improving access to life-saving interventions in remote areas, transforming how trans-arterial procedures for acute diseases are performed while reducing risks to both patients and operators.

Performance Evaluation of a Miniature and Disposable Endovascular Robotic Device

PURPOSE

The LIBERTY® Robotic System is a miniature, single-use device designed to facilitate remote-controlled navigation to intravascular targets. We aim to evaluate the robot's performance to manipulate a range of microguidewires and microcatheters during percutaneous endovascular procedures.

MATERIALS AND METHODS

Six interventional radiologists performed selective robotic-assisted catheterization of eight pre-determined vascular targets in a pig model. The navigation time from the guiding catheter tip to the target vessel was recorded. Each physician with a clinical experience of 20 years completed a questionnaire to evaluate the ease of use, accuracy, and safety of the robotic operation.

RESULTS

Most of the physicians reached the vascular targets in less than one minute. There was no angiographic evidence of vascular injury such as artery laceration or contusion. All physicians reported consensus about the high performance of the robot.

CONCLUSION

The miniature disposable robot is effective at reaching a range of vessels in a porcine model. Physicians found the device intuitive and easy to operate remotely.

Current State of Robotics in Interventional Radiology

As a relatively new specialty with a minimally invasive nature, the field of interventional radiology is rapidly growing. Although the application of robotic systems in this field shows great promise, such as with increased precision, accuracy, and safety, as well as reduced radiation dose and potential for teleoperated procedures, the progression of these technologies has been slow. This is partly due to the complex equipment with complicated setup procedures, the disruption to theatre flow, the high costs, as well as some device limitations, such as lack of haptic feedback. To further assess these robotic technologies, more evidence of their performance and cost-effectiveness is needed before their widespread adoption within the field. In this review, we summarise the current progress of robotic systems that have been investigated for use in vascular and non-vascular interventions.

Technical and Clinical Progress on Robot-Assisted Endovascular Interventions: A Review

Prior methods of patient care have changed in recent years due to the availability of minimally invasive surgical platforms for endovascular interventions. These platforms have demonstrated the ability to improve patients' vascular intervention outcomes, and global morbidities and mortalities from vascular disease are decreasing. Nonetheless, there are still concerns about the long-term effects of exposing interventionalists and patients to the operational hazards in the cath lab, and the perioperative risks that patients undergo. For these reasons, robot-assisted vascular interventions were developed to provide interventionalists with the ability to perform minimally invasive procedures with improved surgical workflow. We conducted a thorough literature search and presented a review of 130 studies published within the last 20 years that focused on robot-assisted endovascular interventions and are closely related to the current gains and obstacles of vascular interventional robots published up to 2022. We assessed both the research-based prototypes and commercial products, with an emphasis on their technical characteristics and application domains. Furthermore, we outlined how the robotic platforms enhanced both surgeons' and patients' perioperative experiences of robot-assisted vascular interventions. Finally, we summarized our findings and proposed three key milestones that could improve the development of the next-generation vascular interventional robots.

Current utilization and future directions of robotic-assisted endovascular surgery

INTRODUCTION

Endovascular surgery has become the standard of care to treat most vascular diseases using a minimally invasive approach. The CorPath system further enhances the potential and enables surgeons to perform robotic-assisted endovascular procedures in interventional cardiology, peripheral vascular surgery, and neurovascular surgery. With the introduction of this technique, the operator can perform multiple steps of endovascular interventions outside of the radiation field with high precision movements even from long-geographical distances.

AREAS COVERED

The first and second-generation CorPath systems are currently the only commercially available robotic devices for endovascular surgery. This review article discusses the clinical experiences and outcomes with the robot, the advanced navigational features, and the results with recent hardware and software modifications, which enables the use of the system for neurovascular interventions, and long-distance interventional procedures.

EXPERT OPINION

A high procedural success was achieved with the CorPath robotic systems in coronary and peripheral interventions, and the device seems promising in neurovascular procedures. More experience is needed with robotic neurovascular interventions and with complex peripheral arterial cases. In the future, long-distance endovascular surgery can potentially transform the management and treatment of acute myocardial infarction and stroke, with making endovascular care more accessible for patients in remote areas.