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5. Light transmittance in human atrial tissue and transthoracic illumination in rats support translatability of optogenetic cardioversion of atrial fibrillation.

Author

Nyns, Emile C. A., Portero, Vincent, Deng, Shanliang, Jin, Tianyi, Harlaar, Niels, Bart, Cindy I., van Brakel, Thomas J., Palmen, Meindert, Hjortnaes, Jesper, Ramkisoensing, Arti A., Zhang, Guo Qi, Poelma, René H., Ördög, Balázs, de Vries, Antoine A. F., and Pijnappels, Daniël A.

Subjects
ATRIAL fibrillation, ELECTRIC countershock, RATS, ION channels, PHOTOMETRY
Abstract

Background: Optogenetics could offer a solution to the current lack of an ambulatory method for the rapid automated cardioversion of atrial fibrillation (AF), but key translational aspects remain to be studied. Objective: To investigate whether optogenetic cardioversion of AF is effective in the aged heart and whether sufficient light penetrates the human atrial wall. Methods: Atria of adult and aged rats were optogenetically modified to express light‐gated ion channels (i.e., red‐activatable channelrhodopsin), followed by AF induction and atrial illumination to determine the effectivity of optogenetic cardioversion. The irradiance level was determined by light transmittance measurements on human atrial tissue. Results: AF could be effectively terminated in the remodeled atria of aged rats (97%, n = 6). Subsequently, ex vivo experiments using human atrial auricles demonstrated that 565‐nm light pulses at an intensity of 25 mW/mm2 achieved the complete penetration of the atrial wall. Applying such irradiation onto the chest of adult rats resulted in transthoracic atrial illumination as evidenced by the optogenetic cardioversion of AF (90%, n = 4). Conclusion: Transthoracic optogenetic cardioversion of AF is effective in the aged rat heart using irradiation levels compatible with human atrial transmural light penetration. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Optical ventricular cardioversion by local optogenetic targeting and LED implantation in a cardiomyopathic rat model.

Author

Nyns, Emile C A, Jin, Tianyi, Fontes, Magda S, van den Heuvel, Titus, Portero, Vincent, Ramsey, Catilin, Bart, Cindy I, Zeppenfeld, Katja, Schalij, Martin J, Brakel, Thomas J van, Ramkisoensing, Arti A, Zhang, Guoqi, Poelma, René H, Ördög, Balazs, Vries, Antoine A F de, and Pijnappels, Daniël A

Subjects
ELECTRIC countershock, RENEWABLE energy sources, ANIMAL disease models, ARTIFICIAL implants, OPTICAL control, GENETIC transformation, VENTRICULAR remodeling
Abstract

Aims Ventricular tachyarrhythmias (VTs) are common in the pathologically remodelled heart. These arrhythmias can be lethal, necessitating acute treatment like electrical cardioversion to restore normal rhythm. Recently, it has been proposed that cardioversion may also be realized via optically controlled generation of bioelectricity by the arrhythmic heart itself through optogenetics and therefore without the need of traumatizing high-voltage shocks. However, crucial mechanistic and translational aspects of this strategy have remained largely unaddressed. Therefore, we investigated optogenetic termination of VTs (i) in the pathologically remodelled heart using an (ii) implantable multi-LED device for (iii) in vivo closed-chest, local illumination. Methods and results In order to mimic a clinically relevant sequence of events, transverse aortic constriction (TAC) was applied to adult male Wistar rats before optogenetic modification. This modification took place 3 weeks later by intravenous delivery of adeno-associated virus vectors encoding red-activatable channelrhodopsin or Citrine for control experiments. At 8–10 weeks after TAC, VTs were induced ex vivo and in vivo , followed by programmed local illumination of the ventricular apex by a custom-made implanted multi-LED device. This resulted in effective and repetitive VT termination in the remodelled adult rat heart after optogenetic modification, leading to sustained restoration of sinus rhythm in the intact animal. Mechanistically, studies on the single cell and tissue level revealed collectively that, despite the cardiac remodelling, there were no significant differences in bioelectricity generation and subsequent transmembrane voltage responses between diseased and control animals, thereby providing insight into the observed robustness of optogenetic VT termination. Conclusion Our results show that implant-based optical cardioversion of VTs is feasible in the pathologically remodelled heart in vivo after local optogenetic targeting because of preserved optical control over bioelectricity generation. These findings add novel mechanistic and translational insight into optical ventricular cardioversion. [ABSTRACT FROM AUTHOR]

Published
2022
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8. 3D interconnect technology based on low temperature copper nanoparticle sintering

Author

Zhang, B., Carisey, Y.C.P., Damian, A., Poelma, René H., Zhang, Kouchi, van Zeijl, H.W., Bi, Keyun, Liu, Sheng, and Zhou, Shengjun

Subjects
0209 industrial biotechnology, Materials science, Stencil printing, Metallurgy, chemistry.chemical_element, Sintering, Nanoparticle, 02 engineering and technology, Thermocompression bonding, 021001 nanoscience & nanotechnology, Copper, low-temperature sintering, 3D packaging, 020901 industrial engineering & automation, chemistry, Interconnect, Wafer, Composite material, opper nanoparticle paste, 0210 nano-technology, Forming gas, Porosity
Abstract

We explore a methodology for patterned copper nanoparticle paste for 3D interconnect applications in wafer to wafer (W2W) bonding. A novel fine pitch thermal compression bonding process (sintering) with coated copper nanoparticle paste was developed. Most of the particle size is between 10–30 nm. Lithographically defined stencil printing using photoresist and lift-off was used to apply and pattern the paste. Variations in sintering process parameters, such as: pressure, geometry and ambient atmosphere, were studied. Compared to Sn-Ag-Cu (SAC) microsolder bumps, we achieved better interconnect resistivity after sintering at 260 °C for 10 min, in a 700 mBar hydrogen forming gas (H 2 /N 2 ) environment. The electrical resistivity was 7.84 ± 1.45 µΩ·cm, which is about 4.6 times that of bulk copper. In addition, metallic nanoparticle interconnect porosity can influence the electrical properties of the interconnect. Consequently, we investigated the porosity effect on conductivity using finite element simulation. A linear relationship between the equivalent conductivity and particle overlapping ratio was found.

Published
2016

10. Effects of Nanostructure and Coating on the Mechanics of Carbon Nanotube Arrays.

Author

Poelma, René H., Fan, Xuejun, Hu, Zhi‐Yi, Van Tendeloo, Gustaaf, van Zeijl, Henk W., and Zhang, Guo Qi

Subjects
*NANOSTRUCTURED materials, *COATING processes, *CARBON nanotubes, *VAN der Waals forces, *CHEMICAL vapor deposition equipment
Abstract

Nanoscale materials are one of the few engineering materials that can be grown from the bottom up in a controlled manner. Here, the effects of nanostructure and nanoscale conformal coating on the mechanical behavior of vertically aligned carbon nanotube (CNT) arrays through experiments and simulation are systematically investigated. A modeling approach is developed and used to quantify the compressive strength and modulus of the CNT array under large deformation. The model accounts for the porous nanostructure, which contains multiple CNTs with random waviness, van der Waals interactions, fracture strain, contacts, and frictional forces. CNT array micropillars are grown and their porous nanostructure is controlled by the infiltration and deposition of thin conformal coatings using chemical vapor deposition. Flat-punch nanoindentation experiments reveal significant changes in material properties as a function of coating thickness. The simulations explain the experimental results and show the novel failure transition regime that changes from collective CNT buckling toward structural collapse due to fracture. The compressive strength and the elastic modulus increase exponentially as a function of the coating thickness and demonstrate a unique dependency on the CNT waviness. More interestingly, a design rule is identified that predicts the optimum coating thickness for porous materials. [ABSTRACT FROM AUTHOR]

Published
2016
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11. Tailoring the Mechanical Properties of High-Aspect-Ratio Carbon Nanotube Arrays using Amorphous Silicon Carbide Coatings.

Author

Poelma, René H., Morana, Bruno, Vollebregt, Sten, Schlangen, Erik, van Zeijl, Henk W., Fan, Xuejun, and Zhang, Guo Qi

Subjects
*CARBON nanotubes, *NANOTUBES, *NANOSTRUCTURED materials synthesis, *POROUS materials, *AMORPHOUS carbon, *SILICON carbide, *CONFORMAL coatings
Abstract

The porous nature of carbon nanotube (CNT) arrays allows for the unique opportunity to tailor their mechanical response by the infiltration and deposition of nanoscale conformal coatings. Here, we fabricate novel photo-lithographically defined CNT pillars that are conformally coated with amorphous silicon carbide (a-SiC) to strengthen the interlocking of individual CNTs at junctions using low pressure chemical vapor deposition (LPCVD). We further quantify the mechanical response by performing flat-punch nanoindentation measurements on coated CNT pillars with various high-aspect-ratios. We discovered new mechanical failure modes of coated CNT pillars, such as 'bamboo' and brittle-like composite rupture as coating thickness increases. Furthermore, a significant increase in strength and modulus is achieved. For CNT pillars with high aspect ratio (1:10) and coating thickness of 21.4 nm, the compressive strength increases by an order of magnitude of 3, towards 1.8 GPa (from below 1 MPa for uncoated CNT pillars) and the elastic modulus increases towards 125 GPa. These results show that our coated CNT pillars, which can serve as vertical interconnects and 3D super-capacitors, can be transformed into robust high-aspect-ratio 3D-micro architectures with semiconductor device compatible processes. [ABSTRACT FROM AUTHOR]

Published
2014
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12. Vertically-Aligned Multi-Walled Carbon Nano Tube Pillars with Various Diameters under Compression: Pristine and NbTiN Coated.

Author

Mirza Gheitaghy, Amir, Poelma, René H., Sacco, Leandro, Vollebregt, Sten, and Zhang, Guo Qi

Subjects
*HIGH temperature superconductivity, *ATOMIC layer deposition, *CHEMICAL vapor deposition, *DIFFUSION coatings, *ELASTIC modulus
Abstract

In this paper, the compressive stress of pristine and coated vertically-aligned (VA) multi-walled (MW) carbon nanotube (CNT) pillars were investigated using flat-punch nano-indentation. VA-MWCNT pillars of various diameters (30–150 µm) grown by low-pressure chemical vapor deposition on silicon wafer. A conformal brittle coating of niobium-titanium-nitride with high superconductivity temperature was deposited on the VA-MWCNT pillars using atomic layer deposition. The coating together with the pillars could form a superconductive vertical interconnect. The indentation tests showed foam-like behavior of pristine CNTs and ceramic-like fracture of conformal coated CNTs. The compressive strength and the elastic modulus for pristine CNTs could be divided into three regimes of linear elastic, oscillatory plateau, and exponential densification. The elastic modulus of pristine CNTs increased for a smaller pillar diameter. The response of the coated VA-MWCNTs depended on the diffusion depth of the coating in the pillar and their elastic modulus increased with pillar diameter due to the higher sidewall area. Tuning the material properties by conformal coating on various diameter pillars enhanced the mechanical performance and the vertical interconnect access (via) reliability. The results could be useful for quantum computing applications that require high-density superconducting vertical interconnects and reliable operation at reduced temperatures. [ABSTRACT FROM AUTHOR]

Published
2020
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13. An automated hybrid bioelectronic system for autogenous restoration of sinus rhythm in atrial fibrillation.

Author

Nyns, Emile C.A., Poelma, René H., Volkers, Linda, Plomp, Jaap J., Bart, Cindy I., Kip, Annemarie M., Brakel, Thomas J., Zeppenfeld, Katja, Schalij, Martin J., Zhang, Guo Qi, Vries, Antoine A.F., and Pijnappels, Daniël A.

Subjects
ATRIAL fibrillation, BIOELECTRONICS, ELECTROCONVULSIVE therapy, MYOCARDIAL depressants, TRANSGENE expression, GENE expression
Abstract

An implanted light source coupled with local gene therapy generates an automated shock-free system to treat atrial fibrillation in rats. Atrial fibrillation treatment lightens up: Atrial fibrillation is an irregular, rapid heartbeat that interrupts normal blood flow and increases risk of stroke and clots. Normal heart rhythm can be restored by electroshock (electrical cardioversion), but implantable cardioverter defibrillators can cause pain and damage myocardial tissue. Rather than supply exogenous current, Nyns et al. combined atrial gene painting to deliver viral vectors encoding light-activatable ion channels with an implantable light source and rhythm detector, developing an autogenous arrhythmia termination system. This optogenetic approach restored normal heart rhythm in rat hearts ex vivo and in vivo under closed-chest conditions. Further testing in larger animal models is necessary, but results suggest that this could be a pain-free alternative to electroshock. Because of suboptimal therapeutic strategies, restoration of sinus rhythm in symptomatic atrial fibrillation (AF) often requires in-hospital delivery of high-voltage shocks, thereby precluding ambulatory AF termination. Continuous, rapid restoration of sinus rhythm is desired given the recurring and progressive nature of AF. Here, we present an automated hybrid bioelectronic system for shock-free termination of AF that enables the heart to act as an electric current generator for autogenous restoration of sinus rhythm. We show that local, right atrial delivery of adenoassociated virus vectors encoding a light-gated depolarizing ion channel results in efficient and spatially confined transgene expression. Activation of an implanted intrathoracic light-emitting diode device allows for termination of AF by illuminating part of the atria. Combining this newly obtained antiarrhythmic effector function of the heart with the arrhythmia detector function of a machine-based cardiac rhythm monitor in the closed chest of adult rats allowed automated and rapid arrhythmia detection and termination in a safe, effective, repetitive, yet shock-free manner. These findings hold translational potential for the development of shock-free antiarrhythmic device therapy for ambulatory treatment of AF. [ABSTRACT FROM AUTHOR]

Published
2019
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15. Carbon Nanotubes: Tailoring the Mechanical Properties of High-Aspect-Ratio Carbon Nanotube Arrays using Amorphous Silicon Carbide Coatings (Adv. Funct. Mater. 36/2014).

Author

Poelma, René H., Morana, Bruno, Vollebregt, Sten, Schlangen, Erik, van Zeijl, Henk W., Fan, Xuejun, and Zhang, Guo Qi

Subjects
*CARBON nanotubes, *SILICON carbide, *CONFORMAL coatings
Abstract

The effects of nanoscale conformal coatings of amorphous silicon carbide on the mechanical properties of carbon nanotube pillars are investigated. Several interesting mechanical failure modes such as bamboo and brittle‐like composite rupture are observed as coating thickness increases. On page 5737, G. Q. Zhang and co‐workers report on their remarkable increase in strength, making the fast growing coated CNT arrays useful as structural material for high‐aspect‐ratio 3D micro‐architectures. [ABSTRACT FROM AUTHOR]

Published
2014
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16. Effects of Conformal Nanoscale Coatings on Thermal Performance of Vertically Aligned Carbon Nanotubes

Author

Pasqualina M. Sarro, C. Silvestri, Aleksandar Jovic, Andrea Irace, Sten Vollebregt, Bruno Morana, R. H. Poelma, Guoqi Zhang, Michele Riccio, Silvestri, Cinzia, Riccio, Michele, Poelma, René H, Jovic, Aleksandar, Morana, Bruno, Vollebregt, Sten, Irace, Andrea, Zhang, Guo Qi, and Sarro, Pasqualina

Subjects
Nanotube, Nanostructure, Materials science, Carbon nanotubes, 02 engineering and technology, Carbon nanotube, thermal property, engineering.material, 010402 general chemistry, 01 natural sciences, law.invention, Biomaterials, Thermal conductivity, Coating, law, vertically aligned, General Materials Science, Composite material, carbon nanotube, Porosity, conformal coating, Conformal coating, General Chemistry, Epoxy, epoxy molding, 021001 nanoscience & nanotechnology, 0104 chemical sciences, visual_art, engineering, visual_art.visual_art_medium, 0210 nano-technology, Biotechnology
Abstract

The high aspect ratio and the porous nature of spatially oriented forest-like carbon nanotube (CNT) structures represent a unique opportunity to engineer a novel class of nanoscale assemblies. By combining CNTs and conformal coatings, a 3D lightweight scaffold with tailored behavior can be achieved. The effect of nanoscale coatings, aluminum oxide (Al2O3) and nonstoichiometric amorphous silicon carbide (a-SiC), on the thermal transport efficiency of high aspect ratio vertically aligned CNTs, is reported herein. The thermal performance of the CNT-based nanostructure strongly depends on the achieved porosity, the coating material and its infiltration within the nanotube network. An unprecedented enhancement in terms of effective thermal conductivity in a-SiC coated CNTs has been obtained: 181% compared to the as-grown CNTs and Al2O3 coated CNTs. Furthermore, the integration of coated high aspect ratio CNTs in an epoxy molding compound demonstrates that, next to the required thermal conductivity, the mechanical compliance for thermal interface applications can also be achieved through coating infiltration into foam-like CNT forests.

Published
2018

17. Effects of Conformal Nanoscale Coatings on Thermal Performance of Vertically Aligned Carbon Nanotubes.

Author

Silvestri C, Riccio M, Poelma RH, Jovic A, Morana B, Vollebregt S, Irace A, Zhang GQ, and Sarro PM

Abstract

The high aspect ratio and the porous nature of spatially oriented forest-like carbon nanotube (CNT) structures represent a unique opportunity to engineer a novel class of nanoscale assemblies. By combining CNTs and conformal coatings, a 3D lightweight scaffold with tailored behavior can be achieved. The effect of nanoscale coatings, aluminum oxide (Al 2 O 3 ) and nonstoichiometric amorphous silicon carbide (a-SiC), on the thermal transport efficiency of high aspect ratio vertically aligned CNTs, is reported herein. The thermal performance of the CNT-based nanostructure strongly depends on the achieved porosity, the coating material and its infiltration within the nanotube network. An unprecedented enhancement in terms of effective thermal conductivity in a-SiC coated CNTs has been obtained: 181% compared to the as-grown CNTs and Al 2 O 3 coated CNTs. Furthermore, the integration of coated high aspect ratio CNTs in an epoxy molding compound demonstrates that, next to the required thermal conductivity, the mechanical compliance for thermal interface applications can also be achieved through coating infiltration into foam-like CNT forests., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2018
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