Spatially-Resolved Organoid Transfection by Porous Silicon-Mediated Optoporation

Chantelle Spiteri; Valeria Caprettini; Yikai Wang; Sofia Dominguez-Gil; Martti Kaasalainen; Cong Wang; Davide Alessandro Martella; Samuel McLennan; Priya Vashisth; Magali Gary-Bobo; Christophe Nguyen; Mads Bergholt; Jean Olivier Durand; Frédérique Cunin; Ciro Chiappini

doi:10.1002/adma.202407650

Spatially-Resolved Organoid Transfection by Porous Silicon-Mediated Optoporation

Chantelle Spiteri, Valeria Caprettini, Yikai Wang, Sofia Dominguez-Gil, Martti Kaasalainen, Cong Wang, Davide Alessandro Martella, Samuel McLennan, Priya Vashisth, Magali Gary-Bobo, Christophe Nguyen, Mads Bergholt, Jean Olivier Durand, Frédérique Cunin, Ciro Chiappini^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Engineering the spatial organisation of organotypic cultures is pivotal for refining tissue models that are useful for gaining deeper insights into complex, non-cell autonomous processes. These advanced models are key to improving the understanding of fundamental biological mechanisms and therapeutic strategies. Controlling gene regulation through spatially-resolved delivery of nucleic acids provides an attractive approach to produce such tissue models. An emerging strategy for spatially-resolved transfection uses photosensitizing nanoparticles coupled with laser pulses to optoporate cells in culture and locally mediate gene delivery. However, localized optoporation in 3D systems remains challenging. Here we propose a solution to this longstanding hurdle, demonstrating that porous silicon nanoparticles are a safe and bioresorbable photosensitising nanomaterial capable of spatially-resolved transfection of mRNA in MCF-7 organoids by near-infrared two-photon optoporation. Functionalization with an azobenzene–lysine photo-switchable moiety enhances the transfection efficiency of the nanoparticles up to 84% in a 2D cell system. Moreover, the nanoparticles enable spatially selective mRNA transfection to MCF-7 spheroids, demonstrating targeted gene delivery in complex 3D cellular environments. The approach for spatially-resolved 3D optoporation offers a way forward for the design of tailored spheroids and organoids by spatially selective nucleic acids delivery.

Original language	English
Article number	2407650
Journal	Advanced Materials
Volume	36
Issue number	49
DOIs	https://doi.org/10.1002/adma.202407650
Publication status	Accepted/In press - 2024

Keywords

gene delivery
optoporation
organoids
porous silicon
transfection

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10.1002/adma.202407650

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Spiteri, C., Caprettini, V., Wang, Y., Dominguez-Gil, S., Kaasalainen, M., Wang, C., Martella, D. A., McLennan, S., Vashisth, P., Gary-Bobo, M., Nguyen, C., Bergholt, M., Durand, J. O., Cunin, F., & Chiappini, C. (Accepted/In press). Spatially-Resolved Organoid Transfection by Porous Silicon-Mediated Optoporation. Advanced Materials, 36(49), Article 2407650. https://doi.org/10.1002/adma.202407650

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title = "Spatially-Resolved Organoid Transfection by Porous Silicon-Mediated Optoporation",

abstract = "Engineering the spatial organisation of organotypic cultures is pivotal for refining tissue models that are useful for gaining deeper insights into complex, non-cell autonomous processes. These advanced models are key to improving the understanding of fundamental biological mechanisms and therapeutic strategies. Controlling gene regulation through spatially-resolved delivery of nucleic acids provides an attractive approach to produce such tissue models. An emerging strategy for spatially-resolved transfection uses photosensitizing nanoparticles coupled with laser pulses to optoporate cells in culture and locally mediate gene delivery. However, localized optoporation in 3D systems remains challenging. Here we propose a solution to this longstanding hurdle, demonstrating that porous silicon nanoparticles are a safe and bioresorbable photosensitising nanomaterial capable of spatially-resolved transfection of mRNA in MCF-7 organoids by near-infrared two-photon optoporation. Functionalization with an azobenzene–lysine photo-switchable moiety enhances the transfection efficiency of the nanoparticles up to 84% in a 2D cell system. Moreover, the nanoparticles enable spatially selective mRNA transfection to MCF-7 spheroids, demonstrating targeted gene delivery in complex 3D cellular environments. The approach for spatially-resolved 3D optoporation offers a way forward for the design of tailored spheroids and organoids by spatially selective nucleic acids delivery.",

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doi = "10.1002/adma.202407650",

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AU - Wang, Yikai

AU - Dominguez-Gil, Sofia

AU - Kaasalainen, Martti

AU - Wang, Cong

AU - Martella, Davide Alessandro

AU - McLennan, Samuel

AU - Vashisth, Priya

AU - Gary-Bobo, Magali

AU - Nguyen, Christophe

AU - Bergholt, Mads

AU - Durand, Jean Olivier

AU - Cunin, Frédérique

AU - Chiappini, Ciro

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AB - Engineering the spatial organisation of organotypic cultures is pivotal for refining tissue models that are useful for gaining deeper insights into complex, non-cell autonomous processes. These advanced models are key to improving the understanding of fundamental biological mechanisms and therapeutic strategies. Controlling gene regulation through spatially-resolved delivery of nucleic acids provides an attractive approach to produce such tissue models. An emerging strategy for spatially-resolved transfection uses photosensitizing nanoparticles coupled with laser pulses to optoporate cells in culture and locally mediate gene delivery. However, localized optoporation in 3D systems remains challenging. Here we propose a solution to this longstanding hurdle, demonstrating that porous silicon nanoparticles are a safe and bioresorbable photosensitising nanomaterial capable of spatially-resolved transfection of mRNA in MCF-7 organoids by near-infrared two-photon optoporation. Functionalization with an azobenzene–lysine photo-switchable moiety enhances the transfection efficiency of the nanoparticles up to 84% in a 2D cell system. Moreover, the nanoparticles enable spatially selective mRNA transfection to MCF-7 spheroids, demonstrating targeted gene delivery in complex 3D cellular environments. The approach for spatially-resolved 3D optoporation offers a way forward for the design of tailored spheroids and organoids by spatially selective nucleic acids delivery.

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KW - organoids

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Spatially-Resolved Organoid Transfection by Porous Silicon-Mediated Optoporation

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