Your search keyword '"Rivkin, Boris"' showing total 6 results

1. Surgical Instruments based on flexible micro-electronics

Author

Schmidt, Oliver G., Cuniberti, Gianaurelio, Technischen Universität Chemnitz, Leibniz IFW Dresden, Rivkin, Boris, Schmidt, Oliver G., Cuniberti, Gianaurelio, Technischen Universität Chemnitz, Leibniz IFW Dresden, and Rivkin, Boris

Abstract

This dissertation explores strategies to create micro-scale tools with integrated electronic and mechanical functionalities. Recently developed approaches to control the shape of flexible micro-structures are employed to fabricate micro-electronic instruments that embed components for sensing and actuation, aiming to expand the toolkit of minimally invasive surgery. This thesis proposes two distinct types of devices that might expand the boundaries of modern surgical interventions and enable new bio-medical applications. First, an electronically integrated micro-catheter is developed. Electronic components for sensing and actuation are embedded into the catheter wall through an alternative fabrication paradigm that takes advantage of a self-rolling polymeric thin-film system. With a diameter of only 0.1 mm, the catheter is capable of delivering fluids in a highly targeted fashion, comprises actuated opposing digits for the efficient manipulation of microscopic objects, and a magnetic sensor for navigation. Employing a specially conceived approach for position tracking, navigation with a high resolution below 0.1 mm is achieved. The fundamental functionalities and mechanical properties of this instrument are evaluated in artificial model environments and ex vivo tissues. The second development explores reshapeable micro-electronic devices. These systems integrate conductive polymer actuators and strain or magnetic sensors to adjust their shape through feedback-driven closed loop control and mechanically interact with their environment. Due to their inherent flexibility and integrated sensory capabilities, these devices are well suited to interface with and manipulate sensitive biological tissues, as demonstrated with an ex vivo nerve bundle, and may facilitate new interventions in neural surgery.:List of Abbreviations 1 Introduction 1.1 Motivation 1.2 Objectives and structure of this dissertation 2 Background 2.1 Tools for minimally invasive surgery 2.1.1 Catheters 2

Published

2022

2. Surgical Instruments based on flexible micro-electronics

Author

Schmidt, Oliver G., Cuniberti, Gianaurelio, Technischen Universität Chemnitz, Leibniz IFW Dresden, Rivkin, Boris, Schmidt, Oliver G., Cuniberti, Gianaurelio, Technischen Universität Chemnitz, Leibniz IFW Dresden, and Rivkin, Boris

Abstract

This dissertation explores strategies to create micro-scale tools with integrated electronic and mechanical functionalities. Recently developed approaches to control the shape of flexible micro-structures are employed to fabricate micro-electronic instruments that embed components for sensing and actuation, aiming to expand the toolkit of minimally invasive surgery. This thesis proposes two distinct types of devices that might expand the boundaries of modern surgical interventions and enable new bio-medical applications. First, an electronically integrated micro-catheter is developed. Electronic components for sensing and actuation are embedded into the catheter wall through an alternative fabrication paradigm that takes advantage of a self-rolling polymeric thin-film system. With a diameter of only 0.1 mm, the catheter is capable of delivering fluids in a highly targeted fashion, comprises actuated opposing digits for the efficient manipulation of microscopic objects, and a magnetic sensor for navigation. Employing a specially conceived approach for position tracking, navigation with a high resolution below 0.1 mm is achieved. The fundamental functionalities and mechanical properties of this instrument are evaluated in artificial model environments and ex vivo tissues. The second development explores reshapeable micro-electronic devices. These systems integrate conductive polymer actuators and strain or magnetic sensors to adjust their shape through feedback-driven closed loop control and mechanically interact with their environment. Due to their inherent flexibility and integrated sensory capabilities, these devices are well suited to interface with and manipulate sensitive biological tissues, as demonstrated with an ex vivo nerve bundle, and may facilitate new interventions in neural surgery.:List of Abbreviations 1 Introduction 1.1 Motivation 1.2 Objectives and structure of this dissertation 2 Background 2.1 Tools for minimally invasive surgery 2.1.1 Catheters 2

Published

2022

3. Shape-Controlled Flexible Microelectronics Facilitated by Integrated Sensors and Conductive Polymer Actuators

Author

Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, Schmidt, Oliver G., Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, and Schmidt, Oliver G.

Abstract

The next generation of biomedical tools requires reshapeable electronics to closely interface with biological tissues. This will offer unique mechanical properties and the ability to conform to irregular geometries while being robust and lightweight. Such devices can be achieved with soft materials and thin-film structures that are able to reshape on demand. However, reshaping at the submillimeter scale remains a challenging task. Herein, shape-controlled microscale devices are demonstrated that integrate electronic sensors and electroactive polymer actuators. The fast and biocompatible actuators are capable of actively reshaping the device into flat or curved geometries. The curvature and position of the devices are monitored with strain or magnetic sensors. The sensor signals are used in a closed feedback loop to control the actuators. The devices are wafer-scale microfabricated resulting in multiple functional units capable of grasping, holding, and releasing biological tissues, as demonstrated with a neuronal bundle.

Published

2021

4. Shape-Controlled Flexible Microelectronics Facilitated by Integrated Sensors and Conductive Polymer Actuators

Author

Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, Schmidt, Oliver G., Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, and Schmidt, Oliver G.

Abstract

The next generation of biomedical tools requires reshapeable electronics to closely interface with biological tissues. This will offer unique mechanical properties and the ability to conform to irregular geometries while being robust and lightweight. Such devices can be achieved with soft materials and thin-film structures that are able to reshape on demand. However, reshaping at the submillimeter scale remains a challenging task. Herein, shape-controlled microscale devices are demonstrated that integrate electronic sensors and electroactive polymer actuators. The fast and biocompatible actuators are capable of actively reshaping the device into flat or curved geometries. The curvature and position of the devices are monitored with strain or magnetic sensors. The sensor signals are used in a closed feedback loop to control the actuators. The devices are wafer-scale microfabricated resulting in multiple functional units capable of grasping, holding, and releasing biological tissues, as demonstrated with a neuronal bundle.

Published

2021

5. Shape-Controlled Flexible Microelectronics Facilitated by Integrated Sensors and Conductive Polymer Actuators

Author

Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, Schmidt, Oliver G., Rivkin, Boris, Becker, Christian, Akbar, Farzin, Ravishankar, Rachappa, Karnaushenko, Dmitriy D., Naumann, Ronald, Mirhajivarzaneh, Alaleh, Medina-Sánchez, Mariana, Karnaushenko, Daniil, and Schmidt, Oliver G.

Abstract

The next generation of biomedical tools requires reshapeable electronics to closely interface with biological tissues. This will offer unique mechanical properties and the ability to conform to irregular geometries while being robust and lightweight. Such devices can be achieved with soft materials and thin-film structures that are able to reshape on demand. However, reshaping at the submillimeter scale remains a challenging task. Herein, shape-controlled microscale devices are demonstrated that integrate electronic sensors and electroactive polymer actuators. The fast and biocompatible actuators are capable of actively reshaping the device into flat or curved geometries. The curvature and position of the devices are monitored with strain or magnetic sensors. The sensor signals are used in a closed feedback loop to control the actuators. The devices are wafer-scale microfabricated resulting in multiple functional units capable of grasping, holding, and releasing biological tissues, as demonstrated with a neuronal bundle.

Published

2021

6. Role of Microstructure in Oxygen Induced Photodegradation of Methylammonium Lead Triiodide Perovskite Films

Author

Sun, Qing, Fassl, Paul, Becker-Koch, David, Bausch, Alexandra, Rivkin, Boris, Bai, Sai, Hopkinson, Paul E., Snaith, Henry J., Vaynzof, Yana, Sun, Qing, Fassl, Paul, Becker-Koch, David, Bausch, Alexandra, Rivkin, Boris, Bai, Sai, Hopkinson, Paul E., Snaith, Henry J., and Vaynzof, Yana

Abstract

This paper investigates the impact of microstructure on the degradation rate of methylammonium lead triiodide (MAPbI(3)) perovskite films upon exposure to light and oxygen. By comparing the oxygen induced degradation of perovskite films of different microstructure-fabricated using either a lead acetate trihydrate precursor or a solvent engineering technique-it is demonstrated that films with larger and more uniform grains and better electronic quality show a significantly reduced degradation compared to films with smaller, more irregular grains. The effect of degradation on the optical, compositional, and microstructural properties of the perovskite layers is characterized and it is demonstrated that oxygen induced degradation is initiated at the layer surface and grain boundaries. It is found that under illumination, irreversible degradation can occur at oxygen levels as low as 1%, suggesting that degradation can commence already during the device fabrication stage. Finally, this work establishes that improved thin-film microstructure, with large uniform grains and a low density of defects, is a prerequisite for enhanced stability necessary in order to make MAPbI(3) a promising long lived and low cost alternative for future photovoltaic applications., Funding Agencies|HGSFP

Published

2017