**Chapter 7**

*Latest Developments in Medical Robotics Systems*

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[31] Britz GW, Tomas J, Lumsden A. Feasibility of Robotic-Assisted Neurovascular Interventions: Initial Experience in Flow Model and Porcine Model. Neurosurgery. 2020;86(2):309-14.

[32] Tsafrir Z, Janosek-Albright K, Aoun J, Diaz-Insua M, Abd-El-Barr AE, Schiff L, et al. The impact of a wireless audio system on communication in robotic-assisted laparoscopic surgery: A prospective controlled trial. PLoS One.

[33] Madder RD, VanOosterhout S, Parker J, Sconzert K, Li Y, Kottenstette N, et al. Robotic telestenting performance in transcontinental and regional pre-clinical models. Catheter Cardiovasc Interv. 2020.

[34] Madder RD, VanOosterhout S, Mulder A, Bush J, Martin S, Rash AJ, et al. Network latency and long-distance robotic telestenting: Exploring the potential impact of network delays on telestenting performance. Catheter Cardiovasc Interv. 2020;95(5):914-9.

[35] Madder RD, VanOosterhout S, Mulder A, Bush J, Martin S, Rash A, et al. Feasibility of robotic telestenting over long geographic distances: a pre-clinical ex vivo and in vivo study. EuroIntervention. 2019;15(6):e510-e2.

[36] Patel TM, Shah SC, Pancholy SB. Long Distance Tele-Robotic-Assisted Percutaneous Coronary Intervention: A Report of First-in-Human Experience. EClinicalMedicine. 2019;14:53-8.

2020;12(4):338-40.

2020;15(1):e0220214.

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