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Welcome to the da Vinci Research Kit wiki community

This wiki is home to users of the Research Kit for the da Vinci Surgical System.

The da Vinci Research Kit

The da Vinci Research Kit (dVRK) is a collection of first-generation da Vinci components that can be used to assemble a research platform for exploring telerobotics in medicine. The idea behind this initiative is to provide the core hardware to a network of researchers worldwide, by repurposing retired clinical systems. This hardware is provided in combination with dedicated electronics to create a system that enables researchers to access to any level of the control system of the robot as well as the data streams within it.

Background

The da Vinci Research Kit research platform was developed through a collaboration between academic institutions, Johns Hopkins University and Worcester Polytechnic Institute, and Intuitive Surgical Inc. in 2012. The introduction of the dVRK allowed research centers to share a common hardware platform without restricted access to the underlying back-and forward control system. This has led to a significant boost to the development of research in surgical robotics during the last decade and generated new opportunities for collaboration and to connect a surgical robot to other technologies. Today, the dVRK consortium includes mostly universities and academic centers within hospitals, and some companies.

Components

The Kit contains the following components:

• Two da Vinci Master Tool Manipulators (MTMs)
• Two da Vinci Patient Side Manipulators (PSMs)
• A stereo viewer
• A foot pedal tray
• Manipulator Interface Boards (dMIBs)
• Basic accessory kit

See the system in action on YouTube (credit: the JHU team).

MTM

PSM

Stereo Viewer

Foot Pedal Tray

Documentation

• Guide and Manuals
• Design and Implementation Topics
• PI and User Group Meetings

The User Group

Publications

Publications associated with the use of dVRK currently online are more than 290. And this includes international conferences or journals, as well as publications related to workshops or symposiums, and open-access articles stored in arXiv. The published works range between many fields like automation, skill assessment and gesture recognition, hardware implementation and integration, system simulation and modelling, imaging and vision.

Here are listed some of the most interesting and up to date reviews where you can find most of the dVRK related articles:
2022

• Zejian Cui et al., "Caveats on the first-generation da Vinci Research Kit: latent technical constraints and essential calibrations"

2021

• C. D’Ettorre et al., "Accelerating Surgical Robotics Research: A Review of 10 Years With the da Vinci Research Kit" in IEEE Robotics & Automation Magazine, vol. 28, no. 4, pp. 56-78, Dec. 2021, doi: 10.1109/MRA.2021.3101646.

2020

• R. H. Taylor, P. Kazanzides, G. S. Fischer, and N. Simaan, “Medical robotics and computer-integrated interventional medicine,” in Biomedical Information Technology, Elsevier, 2020.
• A. Lasso and P. Kazanzides, “System integration,” in Handbook of Medical Image Computing and Computer Assisted Intervention, Elsevier, 2020.
• A. E. Abdelaal, P. Mathur, and S. E. Salcudean, “Robotics In Vivo: A Perspective on Human–Robot Interaction in Surgical Robotics,” Annu. Rev. Control. Robot. Auton. Syst., vol. 3, 2020.

2019

• R. Nagyné Elek and T. Haidegger, “Robot-Assisted Minimally Invasive Surgical Skill Assessment—Manual and Automated Platforms,” Acta Polytech. Hungarica, vol. 16, no. 8, 2019.
• T. D. Nagy and T. Haidegger, “Recent Advances in Robot-Assisted Surgery: Soft Tissue Contact Identification,” in 2019 IEEE 13th International Symposium on Applied Computational Intelligence and Informatics (SACI), 2019.
• H. Nakawala et al., “Requirements elicitation for robotic and computer-assisted minimally invasive surgery,” Int. J. Adv. Robot. Syst., vol. 16, no. 4, 2019.
• T. Haidegger, “Autonomy for Surgical Robots: Concepts and Paradigms,” IEEE Trans. Med. Robot. Bionics, vol. 1, no. 2, 2019.
• F. Ficuciello, G. Tamburrini, A. Arezzo, L. Villani, and B. Siciliano, “Autonomy in surgical robots and its meaningful human control,” Paladyn, J. Behav. Robot., vol. 10, no. 1, 2019.
• S. O’Sullivan et al., “Legal, regulatory, and ethical frameworks for development of standards in artificial intelligence (AI) and autonomous robotic surgery,” Int. J. Med. Robot. Comput. Assist. Surg., vol. 15, no. 1, 2019.
• L. Qian, J. Y. Wu, S. DiMaio, N. Navab, and P. Kazanzides, “A Review of Augmented Reality in Robotic-Assisted Surgery,” IEEE Trans. Med. Robot. Bionics, 2019.

2018

• M. Shahbazi, S. F. Atashzar, and R. V Patel, “A systematic review of multilateral teleoperation systems,” IEEE Trans. Haptics, vol. 11, no. 3, 2018.

2017

• T. Haidegger, “Surgical robots of the next decade: New trends and paradigms in the 21th century,” in 2017 IEEE 30th Neumann Colloquium (NC), 2017.

2016

• R. Elek, T. D. Nagy, D. Á. Nagy, G. Kronreif, I. J. Rudas, and T. Haidegger, “Recent trends in automating robotic surgery,” in 2016 IEEE 20th Jubilee International Conference on Intelligent Engineering Systems (INES), 2016.

2015

• Á. Takács et al., “Joint platforms and community efforts in surgical robotics research,” MACRo 2015, vol. 1, no. 1, 2015.

Frequently Asked Questions

• FAQ