Conformal Hermetic Sealing of Wireless Microelectronic Implantable Chiplets by Multilayered Atomic Layer Deposition (ALD)

Jeong, Jena; Laiwalla, Farah; Lee, Ji-Hun; Ritasalo, Riina; Pudas, Marko; Larson, L.E.; Leung, Vincent; Nurmikko, A. V.

doi:10.1002/adfm.201806440

Cited by 75 publications

(72 citation statements)

References 48 publications

(45 reference statements)

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“…This technique has been demonstrated in the post-processing of wireless microimplant, which mainly requires single-layer lift-off for electrode patterning. However, other microfabrication processes, such as dry etching, can be combined, as shown in our previous work [ 41 ], to make the opening in hermetic packaging. The deformation of PDMS during processing was not observed in this work, even with the use of various chemicals, including photoresists, developers, and stripper.…”

Section: Discussionmentioning

confidence: 99%

A Scalable and Low Stress Post-CMOS Processing Technique for Implantable Microsensors

et al. 2020

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Implantable active electronic microchips are being developed as multinode in-body sensors and actuators. There is a need to develop high throughput microfabrication techniques applicable to complementary metal–oxide–semiconductor (CMOS)-based silicon electronics in order to process bare dies from a foundry to physiologically compatible implant ensembles. Post-processing of a miniature CMOS chip by usual methods is challenging as the typically sub-mm size small dies are hard to handle and not readily compatible with the standard microfabrication, e.g., photolithography. Here, we present a soft material-based, low chemical and mechanical stress, scalable microchip post-CMOS processing method that enables photolithography and electron-beam deposition on hundreds of micrometers scale dies. The technique builds on the use of a polydimethylsiloxane (PDMS) carrier substrate, in which the CMOS chips were embedded and precisely aligned, thereby enabling batch post-processing without complication from additional micromachining or chip treatments. We have demonstrated our technique with 650 μm × 650 μm and 280 μm × 280 μm chips, designed for electrophysiological neural recording and microstimulation implants by monolithic integration of patterned gold and PEDOT:PSS electrodes on the chips and assessed their electrical properties. The functionality of the post-processed chips was verified in saline, and ex vivo experiments using wireless power and data link, to demonstrate the recording and stimulation performance of the microscale electrode interfaces.

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Section: Discussionmentioning

confidence: 99%

A Scalable and Low Stress Post-CMOS Processing Technique for Implantable Microsensors

et al. 2020

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“…4b right) for use as intracortical electrodes such as used in the microstimulation experiments. For long term chronic device implantation, not the goal of this paper, we have reported elsewhere the development of ultrathin dielectric coatings, applied by atomic vapor deposition, to obtain biocompatible, hermetically sealed neurograins [36].…”

Section: Wireless Recording and Microstimulation By Neurograinsmentioning

confidence: 99%

Wireless Ensembles of Sub-mm Microimplants Communicating as a Network near 1 GHz in a Neural Application

Leung

Lee

et al. 2020

Preprint

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Multichannel electrophysiological sensors and stimulators, especially those used for studying the nervous system, are most commonly based on monolithic microelectrode arrays. Such architecture limits the spatial flexibility of individual electrode placement, posing constraints for scaling to a large number of nodes, particularly across non-contiguous locations. We describe the design and fabrication of sub-millimeter size electronic microchips (Neurograins) which autonomously perform neural sensing or electrical microstimulation, with emphasis on their wireless networking and powering. An ~1 GHz electromagnetic transcutaneous link to an external telecom hub enables bidirectional communication and control at the individual neurograin level. The link operates on a customized time division multiple access (TDMA) protocol designed to scale up to 1000 neurograins. The system is demonstrated as a cortical implant in a small animal (rat) model with anatomical limitations restricting the implant to 48 neurograins. We suggest that the neurograin approach can be generalized to overcome many scalability issues for wireless sensors and actuators as implantable microsystems

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“…Despite their long-term reliability, these implants end up having large volumes, are heavy, and unlike biological tissue, are stiff and rigid. For this reason, a great deal of research has been dedicated to replacing the bulky titanium cases with flexible polymers and thin-film coating layers [1], [2]. Recently, these efforts have been further endorsed by the new field of bioelectronic medicine, in which small, flexible, and lightweight implants are needed for targeting the delicate nerve structures within the body [3].…”

Section: A Chip Integrity Monitor For Evaluating Long-term Encapsulatmentioning

confidence: 99%

A Chip Integrity Monitor for Evaluating Long-term Encapsulation Performance Within Active Flexible Implants

Akgun

Nanbakhsh

Giagka

et al. 2019

2019 IEEE Biomedical Circuits and Systems Conference (BioCAS)

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One key obstacle in employing silicon integrated circuits in flexible implants is ensuring a long-term operation of the chip within the wet corrosive environment of the body. For this reason, throughout the years, various biocompatible insulating materials have been proposed, yet, evaluating their long-term encapsulation performance on representative silicon samples still remains to be the main challenge. For this aim, in this work, a sensitive platform is introduced that can track the integrity of the chip against water and ion ingress. This platform is developed to be used for long-term monitoring of chip integrity and study of encapsulation layers in wet environments. The platform comprises a sensing array and a measurement engine and operates by tracking the changes in the inter-layer dielectric resistance within the chip. The proposed system uses a novel charge/discharge-based time-mode resistance sensor that can be implemented using simple yet highly robust circuitry. The sensor array is implemented together with the measurement engine in a standard 0.18 µm 6-metal CMOS process. For chip validation, dry and wet measurements in saline are presented in this paper.

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Conformal Hermetic Sealing of Wireless Microelectronic Implantable Chiplets by Multilayered Atomic Layer Deposition (ALD)

Cited by 75 publications

References 48 publications

A Scalable and Low Stress Post-CMOS Processing Technique for Implantable Microsensors

A Scalable and Low Stress Post-CMOS Processing Technique for Implantable Microsensors

Wireless Ensembles of Sub-mm Microimplants Communicating as a Network near 1 GHz in a Neural Application

A Chip Integrity Monitor for Evaluating Long-term Encapsulation Performance Within Active Flexible Implants

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