Amir Degani scite author profile

We have developed a novel highly articulated robotic probe (HARP) that can thread through tightly packed volumes without disturbing the surrounding tissues and organs. We use cardiac surgery as the focal application of this work. As such, we have designed the HARP to enter the pericardial cavity through a subxiphoid port. The surgeon can effectively reach remote intrapericardial locations on the epicardium and deliver therapeutic interventions under direct control. Our device differs from others in that we use conventional actuation and still have great maneuverability. We have performed proof-of-concept clinical experiments to give us preliminary validation of the ideas presented here.

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A Highly Articulated Robotic Surgical System for Minimally Invasive Surgery

Ota

Degani

Schwartzman

et al. 2009

The Annals of Thoracic Surgery

111

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Percutaneous Intrapericardial Interventions Using a Highly Articulated Robotic Probe

Degani

Choset

Wolf

et al.

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-In order to overcome the limitations of currently available assistive technologies for minimally invasive surgery (MIS), we have developed a novel highly articulated robotic probe (HARP) that can exploit its snake-like structure to navigate in a confined anatomical environment while minimally interacting with the environment along its path. We believe that for procedures involving epicardial interventions on the beating heart, cardiac MIS can be effectively realized with the HARP, entering the pericardial cavity through a subxiphoid port, reaching remote intrapericardial locations on the epicardium without causing hemodynamic and electrophysiologic interference and delivering therapeutic interventions under the direct control of the surgeon.

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On the Mechanics of Functional Asymmetry in Bipedal Walking

Gregg

Dhaher

Degani

et al. 2012

IEEE Trans. Biomed. Eng.

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This paper uses two symmetrical models, the passive compass-gait biped and a five-link 3D biped, to computationally investigate the cause and function of gait asymmetry. We show that for a range of slope angles during passive 2D walking and mass distributions during controlled 3D walking, these models have asymmetric walking patterns between the left and right legs due to the phenomenon of spontaneous symmetry-breaking. In both cases a stable asymmetric family of gaits emerges from a symmetric family of gaits as the total energy increases (e.g., fast speeds). The ground reaction forces of each leg reflect different roles, roughly corresponding to support, propulsion, and motion control as proposed by the hypothesis of functional asymmetry in able-bodied human walking. These results suggest that body mechanics, independent of neurophysiological mechanisms such as leg dominance, may contribute to able-bodied gait asymmetry.

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Highly articulated robotic probe for minimally invasive surgery

Degani

Choset

Zubiate³

et al.

171

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Amir Degani

Highly articulated robotic probe for minimally invasive surgery

A Highly Articulated Robotic Surgical System for Minimally Invasive Surgery

Percutaneous Intrapericardial Interventions Using a Highly Articulated Robotic Probe

On the Mechanics of Functional Asymmetry in Bipedal Walking

Highly articulated robotic probe for minimally invasive surgery

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