Software-aided automatic laser optoporation and transfection of cells

Breunig, Hans Georg; Uchugonova, Aisada; Batista, Ana; König, Karsten

doi:10.1038/srep11185

Cited by 24 publications

(21 citation statements)

References 26 publications

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“…The non-linear nature of the excitation process provides intrinsic 3D-imaging capability by minimizing out-of-focus excitation. A similar reasoning applies to harmonic generation microscopy (Sun, 2005) and other nonlinear interactions between light and cells/ tissue like laser-assisted cell transfection (Breunig et al, 2015). Under ideal conditions, when the incident pulses are only minimally absorbed and/or scattered, high resolution imaging at depths in the mm range inside tissue can be achieved in vivo (Kobat et al, 2011).…”

Section: Introductionmentioning

confidence: 88%

Multiphoton imaging with a novel compact diode‐pumped Ti:sapphire oscillator

König

Andersen

Le³

et al. 2015

Microscopy Res & Technique

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Multiphoton laser scanning microscopy commonly relies on bulky and expensive femtosecond lasers. We integrated a novel minimal-footprint Ti:sapphire oscillator, pumped by a frequency-doubled distributed Bragg reflector tapered diode laser, into a clinical multiphoton tomograph and evaluated its imaging capability using different biological samples, i.e. cell monolayers, corneal tissue, and human skin. With the novel laser, the realization of very compact Ti:sapphire-based systems for high-quality multiphoton imaging at a significantly size and weight compared to current systems will become possible.

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Section: Introductionmentioning

confidence: 88%

Multiphoton imaging with a novel compact diode‐pumped Ti:sapphire oscillator

König

Andersen

Le³

et al. 2015

Microscopy Res & Technique

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“…For instance, the delivery of gene-editing tools could be used to manipulate cells and tissues for regenerative medicine or engineer cells for personalized cell therapies [4][5][6][7]. Intracellular delivery methods include biological vectors such as viruses, chemical modifications of delivery cargoes such as lipofection, and physical techniques such as microinjection, electroporation, and optoporation [11][12][13][14][15][16][17][18][19][20][21][22][23][24]. While research efforts have led to a continuous increase in efficiency and sophistication, each of the currently available approaches has its own advantages and disadvantages.…”

Section: Currently Available Intracellular Delivery Techniquesmentioning

confidence: 99%

“…Optoporation, a physical delivery technique, utilizes a tightly focused laser beam to create a transient pore in the cell membrane [18,19,33,34]. This technique offers high delivery efficiency, high cell viability and is versatile with respect to cargo and cell type.…”

Section: Laser-mediated Cell Poration For Intracellular Deliverymentioning

confidence: 99%

Plasmonic Intracellular Delivery

Madrid¹

2018

Plasmonics

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This chapter describes the significance of plasmonics to the field of intracellular delivery. We begin by discussing the significance of intracellular delivery, its applications in biology and medicine, and the currently available intracellular delivery techniques. Next, we discuss the field of plasmonic intracellular delivery, beginning with the discovery of optoporation. In optoporation, a laser beam is tightly focused onto a cell membrane to generate a transient pore, through which membrane-impermeable cargo can enter the cell. To improve the throughput of this technique, plasmonic materials were used for their ability to efficiently absorb laser light and generate spatially confined electric fields. Here, we describe the process by which plasmonic materials absorb laser light energy and generate plasmons. These plasmons transfer their energy to their surroundings, resulting in a rise in temperature and the subsequent creation of a bubble or shockwave. Finally, we describe how the properties of plasmons and plasmon-mediated effects facilitate cell poration for intracellular delivery.

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“…With image processing, the location of the individual cells can be determined. In combination with an auto-focus system to control the axial position of the photoporation laser beam, this allows cells to be photoporated in an automated fashion [107,108]. In one example, it was demonstrated that ~300 cells/min can be photoporated that way [107].…”

Section: Experimental Procedures For Direct Laser-induced Photoporationmentioning

confidence: 99%

“…In combination with an auto-focus system to control the axial position of the photoporation laser beam, this allows cells to be photoporated in an automated fashion [107,108]. In one example, it was demonstrated that ~300 cells/min can be photoporated that way [107]. Finally, a microfluidic approach has also developed in an attempt to increase photoporation throughput, with cells flowing one by one through the focused photoporation laser beam.…”

Section: Experimental Procedures For Direct Laser-induced Photoporationmentioning

confidence: 99%

Laser-assisted photoporation: fundamentals, technological advances and applications

Xiong

Samal

Demeester

et al. 2016

Advances in Physics: X

104

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Laser-assisted photoporation is a promising technique that is receiving increasing attention for the delivery of membrane impermeable nanoscopic substances into living cells. Photoporation is based on the generation of localized transient pores in the cell membrane using continuous or pulsed laser light. Increased membrane permeability can be achieved directly by focused laser light or in combination with sensitizing nanoparticles for higher throughput. Here, we provide a detailed account on the history and current state-ofthe-art of photoporation as a physical nanomaterial delivery technique. We first introduce with a detailed explanation of the mechanisms responsible for cell membrane pore formation, following an overview of experimental procedures for realizing direct laser photoporation. Next, we review the second and most recent method of photoporation that combines laser light with sensitizing NPs. The different mechanisms of pore formation are discussed and an overview is given of the various types of sensitizing nanomaterials. Typical experimental setups to achieve nanoparticlemediated photoporation are discussed as well. Finally, we discuss the biological and therapeutic applications enabled by photoporation and give our current view on this expanding research field and the challenges and opportunities that remain for the near future.

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Software-aided automatic laser optoporation and transfection of cells

Cited by 24 publications

References 26 publications

Multiphoton imaging with a novel compact diode‐pumped Ti:sapphire oscillator

Multiphoton imaging with a novel compact diode‐pumped Ti:sapphire oscillator

Plasmonic Intracellular Delivery

Laser-assisted photoporation: fundamentals, technological advances and applications

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