Infra-red laser ablative micromachining of parylene-C on SiO
                    <sub>2</sub>
                    substrates for rapid prototyping, high yield, human neuronal cell patterning

Raos, Brad; Unsworth, Charles P.; Costa, Jerome; Rohde, CA; Doyle, Carol; Bunting, Andrew; Delivopoulos, Evangelos; Murray, AF; Dickinson, Michelle; Simpson, M. Cather; Graham, Scott E.

doi:10.1088/1758-5082/5/2/025006

Cited by 16 publications

(21 citation statements)

References 51 publications

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“…This was extended by Unsworth who patterned rat primaries to the single cell level on ultra-thin parylene-C [37]. Unsworth also demonstrated how parylene-C could be used to pattern the hNT neuron [38] and hNT astrocyte [39] derived from the human teratocarcinoma cell line to the single cell level and Raos demonstrated how infra-red, laser ablated parylene-C [40] could be used for rapid pattern prototyping using hNT astrocytes. This work has been further extended by Hughes [41] who demonstrated how to modulate the pattern adhesion properties for HEK293 cells on parylene-C.…”

Section: Cell Patterning and Biomaterials Parylene-cmentioning

confidence: 95%

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

et al. 2016

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Recent literature suggests that glia, and in particular astrocytes, should be studied as organised networks which communicate through gap junctions. Astrocytes, however, adhere to most surfaces and are highly mobile cells. In order to study, such organised networks effectively in vitro it is necessary to influence them to pattern to certain substrates whilst being repelled from others and to immobilise the astrocytes sufficiently such that they do not continue to migrate further whilst under study. In this article, we demonstrate for the first time how it is possible to facilitate the study of organised patterned human astrocytic networks using hNT astrocytes in a SiO2 trench grid network that is inlayed with the biocompatible material, parylene-C. We demonstrate how the immobilisation of astrocytes lies in the depth of the SiO2 trench, determining an optimum trench depth and that the optimum patterning of astrocytes is a consequence of the parylene-C inlay and the grid node spacing. We demonstrate high fidelity of the astrocytic networks and demonstrate that functionality of the hNT astrocytes through ATP evoked calcium signalling is also dependent on the grid node spacing. Finally, we demonstrate that the location of the nuclei on the grid nodes is also a function of the grid node spacing. The significance of this work, is to describe a suitable platform to facilitate the study of hNT astrocytes from the single cell level to the network level to improve knowledge and understanding of how communication links to spatial organisation at these higher order scales and trigger in vitro research further in this area with clinical applications in the area of epilepsy, stroke and focal cerebral ischemia.

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Section: Cell Patterning and Biomaterials Parylene-cmentioning

confidence: 95%

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

et al. 2016

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“…Another method for Parylene removal includes laser ablation (266 nm), one of the first techniques employed for Parylene etching to expose electrode sites. Infrared (800 nm) and UV (248 nm) laser ablation of Parylene films (100 nm thickness) on wafer for direct writing were investigated for precise cell patterning . However, UV laser ablation was found to induce UV‐based photooxidation of the Parylene substrate and render the surface unideal for cell patterning applications .…”

Section: Fabrication Techniquesmentioning

confidence: 99%

“…Infrared (800 nm) and UV (248 nm) laser ablation of Parylene films (100 nm thickness) on wafer for direct writing were investigated for precise cell patterning . However, UV laser ablation was found to induce UV‐based photooxidation of the Parylene substrate and render the surface unideal for cell patterning applications . Manual removal of Parylene films has also been demonstrated, where a pre‐coating of release agents, such as 2% Micro‐90 lab cleaning solution (International Products Corporation, Burlington, NJ) on the substrate as well as immersion in water aided in the removal of the film without damage.…”

Section: Fabrication Techniquesmentioning

confidence: 99%

Micromachining of Parylene C for bioMEMS

Kim

Meng

2015

Polym. Adv. Technol.

157

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Recent advances in the micromachining of poly(p-xylylenes), commercially known as Parylenes, have enabled the development of novel structures and devices for microelectromechanical systems (MEMS). In particular, Parylene C (poly[chloro-p-xylylene]) has been explored extensively for biomedical applications of MEMS given its compatibility with micromachining processes, proven biocompatibility, and many advantageous properties including its chemical inertness, optical transparency, flexibility, and mechanical strength. Here we present a review of often used and recently developed micromachining process for Parylene C, as well as a high-level overview of state-of-the-art Parylene hybrid and free film devices for biomedical MEMS (bioMEMS) applications, including a discussion on its challenges and potential as a MEMS material.

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“…However, for the multiple pulse low power IR ablation, our recent study in [19] revealed that ragged veneers where also present around the edges of the parylene-C strips as opposed to the straight edges that occurred with the single pulse high power ablation. Hence, we elected to use the single pulse high power due to optimize the high resolution of the edges of the parylene-C strips.…”

Section: B Ir Laser Ablative Patterningmentioning

confidence: 96%

Low cost, patterning of human hNT brain cells on parylene-C with UV & IR laser machining

Raos

Unsworth

Costa

et al. 2013

2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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This paper describes the use of 800nm femtosecond infrared (IR) and 248nm nanosecond ultraviolet (UV) laser radiation in performing ablative micromachining of parylene-C on SiO2 substrates for the patterning of human hNT astrocytes. Results are presented that support the validity of using IR laser ablative micromachining for patterning human hNT astrocytes cells while UV laser radiation produces photo-oxidation of the parylene-C and destroys cell patterning. The findings demonstrate how IR laser ablative micromachining of parylene-C on SiO2 substrates can offer a low cost, accessible alternative for rapid prototyping, high yield cell patterning.

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Infra-red laser ablative micromachining of parylene-C on SiO ₂ substrates for rapid prototyping, high yield, human neuronal cell patterning

Cited by 16 publications

References 51 publications

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

Micromachining of Parylene C for bioMEMS

Low cost, patterning of human hNT brain cells on parylene-C with UV & IR laser machining

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Infra-red laser ablative micromachining of parylene-C on SiO 2 substrates for rapid prototyping, high yield, human neuronal cell patterning

Cited by 16 publications

References 51 publications

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

Human astrocytic grid networks patterned in parylene-C inlayed SiO2 trenches

Micromachining of Parylene C for bioMEMS

Low cost, patterning of human hNT brain cells on parylene-C with UV &amp; IR laser machining

Contact Info

Product

Resources

About

Infra-red laser ablative micromachining of parylene-C on SiO ₂ substrates for rapid prototyping, high yield, human neuronal cell patterning

Low cost, patterning of human hNT brain cells on parylene-C with UV & IR laser machining