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Related Concept Videos

Varicose Veins II: Diagnostic Studies and Interprofessional Care01:26

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Varicose veins, or varicosities, develop when the valves in the veins, which control blood flow, weaken or damage. It causes blood to pool and the veins to enlarge. Understanding the clinical manifestations, diagnostic approaches, and management options for varicose veins is crucial for effective treatment and relief.Clinical manifestationsClinical manifestations of varicose veins include a heavy, achy feeling or pain after prolonged standing or sitting. This discomfort can often be relieved by...
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Updated: Sep 28, 2025

A Teleoperated Robotic System-Assisted Percutaneous Transiliac-Transsacral Screw Fixation Technique
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Endovascular Robotic Interventions.

Kareem El Naamani1, Rawad Abbas1, Georgios S Sioutas1

  • 1Department of Neurological Surgery, Thomas Jefferson University Hospital, 901 Walnut Street 3rd Floor, Philadelphia, PA 19107, USA.

Neurosurgery Clinics of North America
|March 29, 2022
PubMed
Summary
This summary is machine-generated.

Robotic systems offer a safe and effective approach for carotid interventions, reducing radiation and injury risks for physicians. Future applications may enable remote treatment for rural stroke patients.

Keywords:
Carotid angioplasty stentingPeripheral vascular interventionsRobotic-assistedTechnology

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Area of Science:

  • Vascular Surgery
  • Medical Robotics
  • Interventional Cardiology

Background:

  • Robotic systems are increasingly adopted for peripheral vascular interventions.
  • Carotid artery interventions are a significant area of application for these technologies.
  • Physicians face risks of radiation exposure and musculoskeletal injuries during traditional procedures.

Purpose of the Study:

  • To evaluate the efficiency, feasibility, and safety of robotic systems in treating carotid diseases.
  • To highlight the advantages of robotic-assisted interventions, including reduced radiation and physician strain.
  • To explore the future potential of robotic systems in expanding access to care, particularly for remote populations.

Main Methods:

  • Review of institutional experience and multi-center data on robotic-assisted carotid interventions.
  • Analysis of procedural outcomes, safety metrics, and interventionalist well-being.
  • Assessment of technological capabilities and limitations, such as the absence of haptic feedback.

Main Results:

  • Robotic systems demonstrated efficiency, feasibility, and safety in carotid disease treatment.
  • Key benefits include the elimination of radiation exposure for interventionalists.
  • Reduced rates of musculoskeletal injuries among physicians utilizing robotic technology were observed.

Conclusions:

  • Robotic systems are a viable and beneficial technology for carotid interventions.
  • The technology enhances physician safety and procedural efficiency.
  • Remote treatment capabilities hold promise for improving stroke care accessibility in rural areas.