An Implantable Extracardiac Soft Robotic Device for the Failing Heart: Mechanical Coupling and Synchronization

Payne, Christopher J.; Wamala, Isaac; Abah, Colette; Thalhofer, Thomas; Saeed, Mossab; Bautista‐Salinas, Daniel; Horvath, Markus A.; Vasilyev, Nikolay V.; Roche, Ellen T.; Pigula, Frank A.; Walsh, Conor J.

doi:10.1089/soro.2016.0076

Cited by 66 publications

(63 citation statements)

References 31 publications

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“…Recently, the integration of soft robotics pioneered a new field of more active and multifunctional treatment devices called soft robotic sleeves (Figure c, bottom right) . A soft robotic sleeve is wrapped around both ventricles to augment heart function .…”

Section: Soft Bioelectronics–assisted Therapymentioning

confidence: 99%

Wearable and Implantable Devices for Cardiovascular Healthcare: from Monitoring to Therapy Based on Flexible and Stretchable Electronics

Hong

Jeong

Cho

et al. 2019

Adv Funct Materials

395

271

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Cardiovascular disease is the leading cause of death and has dramatically increased in recent years. Continuous cardiac monitoring is particularly important for early diagnosis and prevention, and flexible and stretchable electronic devices have emerged as effective tools for this purpose. Their thin, soft, and deformable features allow intimate and long-term integration with biotissues, which enables continuous, high-fidelity, and sometimes large-area cardiac monitoring on the skin and/or heart surface. In addition to monitoring, intimate contact is also crucial for high-precision therapies. Combined with tissue engineering, soft bioelectronics have also demonstrated the capability to repair damaged cardiac tissues. This review highlights the recent advances in wearable and implantable devices based on flexible and stretchable electronics for cardiovascular monitoring and therapy. First, wearable/implantable soft bioelectronics for cardiovascular monitoring (e.g., the electrocardiogram, blood pressure, and oxygen saturation level) are reviewed. Then, advances in cardiovascular therapy based on soft bioelectronics (e.g., mesh pacing, ablation, robotic sleeves, and electronic stents) are discussed. Finally, device-assisted tissue engineering therapy (e.g., functional electronic scaffolds and in vitro cardiac platforms) is discussed.

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Section: Soft Bioelectronics–assisted Therapymentioning

confidence: 99%

Wearable and Implantable Devices for Cardiovascular Healthcare: from Monitoring to Therapy Based on Flexible and Stretchable Electronics

Hong

Jeong

Cho

et al. 2019

Adv Funct Materials

395

271

View full text Add to dashboard Cite

show abstract

“…1) Pneumatic Technologies: Pneumatic technology has been applied to create artificial muscle in robot hands [85], [86] and to generate motion in soft-robotics [87], [88]. This kind of actuator is desirable in safety-conscious robotic design especially those intended to interact with human and delicate contact surfaces [87]. One of its drawbacks is that it is difficult to control due to the non-linearity of the actuator.…”

Section: B Actuators For Collaborative Robotsmentioning

confidence: 99%

Physical Human–Robot Collaboration: Robotic Systems, Learning Methods, Collaborative Strategies, Sensors, and Actuators

Ogenyi

Liu

Yang

et al. 2021

IEEE Trans. Cybern.

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This paper presents a state-of-the-art survey on robotic systems, sensors, actuators and collaborative strategies for Physical Human-Robot Collaboration (pHRC). The paper starts with an overview of some robotic systems with cuttingedge technologies (sensors and actuators) suitable for pHRC operations and the intelligent assist devices employed in pHRC. Sensors being among the essential components to establish communication between a human and a robotic system are surveyed. The sensor supplies the signal needed to drive the robotic actuators. The survey reveals that the design of new generation collaborative robots and other intelligent robotic systems has paved the way for sophisticated learning techniques and control algorithms to be deployed in pHRC. Furthermore, it revealed relevant components needed to be considered for effective pHRC to be accomplished. Finally, a discussion of the major advances made, some research directions, and future challenges are presented.

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“…Artificial organs supporting natural organs have the similar requirements of warranting safe synergistic interactions with humans. In addition, their materials are required to be mechanically coupled and synchronized because they are implanted . Flexible actuators have the ability to mimic the physiological functions of natural organs and maintain the aforementioned characteristics.…”

Section: Applications Of Flexible Actuators In Soft Roboticsmentioning

confidence: 99%

“…The heart has been the center of organ research due to its key role in human health. For example, Payne et al . presented an implantable robotic system for heart dysfunction.…”

Section: Applications Of Flexible Actuators In Soft Roboticsmentioning

confidence: 99%

Flexible Actuators for Soft Robotics

Yang

et al. 2019

Advanced Intelligent Systems

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Rigid robots have taken on a variety of automated manufacturing tasks and have made a huge contribution to industrial development; however, they are not suitable for further wearable applications due to their rigid and bulky structure, poor environmental adaptability, and low safety. Soft robots, which are mainly fabricated with flexible or elastomeric materials, can easily adjust to environmental changes and accomplish complex tasks, offering a new paradigm to achieve human-machine compliance. Soft robots do not replace rigid robots but add diverse features for softer robotic applications. In particular, the use of flexible actuators in robotic systems can realize certain intelligent functions, enrich soft robotic systems and migrate academic research to engineering applications. Currently, the application of flexible actuators in soft robotic fields is still at the embryonic stage. However, tremendous application spaces can be envisaged when combining flexible actuators with soft wearable robotics. Therefore, the current flexible actuators that rely on different external stimuli are addressed herein, and their materials, designs, and approaches suitable for soft robotic applications are highlighted. The application advancement and future perspective of flexible actuator prototypes toward various soft robotics are also discussed.

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An Implantable Extracardiac Soft Robotic Device for the Failing Heart: Mechanical Coupling and Synchronization

Cited by 66 publications

References 31 publications

Wearable and Implantable Devices for Cardiovascular Healthcare: from Monitoring to Therapy Based on Flexible and Stretchable Electronics

Wearable and Implantable Devices for Cardiovascular Healthcare: from Monitoring to Therapy Based on Flexible and Stretchable Electronics

Physical Human–Robot Collaboration: Robotic Systems, Learning Methods, Collaborative Strategies, Sensors, and Actuators

Flexible Actuators for Soft Robotics

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