<i>In Vitro</i> Development of Human iPSC-Derived Functional Neuronal Networks on Laser-Fabricated 3D Scaffolds

Koroleva, Anastasia; Deiwick, Andrea; El-Tamer, Ayman; Koch, Lothar; Shi, Yunfeng; Estévez-Priego, Estefanía; Ludl, Adriaan-Alexander; Soriano, Jordi; Guseva, Daria; Ponimaskin, Evgeni; Chichkov, Boris N.

doi:10.1021/acsami.0c16616

Cited by 37 publications

(42 citation statements)

References 63 publications

(108 reference statements)

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“…Cultured neuronal networks are the subject of many biological studies because they allow researchers to investigate neuronal activity in a controlled environment, in comparison to in a live organism. These experiments provide, for instance, a better understanding of the primary disease mechanisms and investigating the response to medicines [ 153 ]. TPP can be employed to produce 3D scaffolds, with high-resolution, using biocompatible and nondegradable photoreactive resins [ 153 ].…”

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

“…These experiments provide, for instance, a better understanding of the primary disease mechanisms and investigating the response to medicines [ 153 ]. TPP can be employed to produce 3D scaffolds, with high-resolution, using biocompatible and nondegradable photoreactive resins [ 153 ]. Figure 18 shows examples of 3D scaffolds fabricated using Dental LT Clear (DClear) resin employed in 3D neural cell culture and their characterization.…”

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

“…Still, in Figure 18 b the scaffold design allows a noninvasive high-resolution visualization of real-time cell growth and neuronal network formation in a 3D environment. Immunofluorescence analysis showed that the fabricated scaffold provides a suitable 3D environment for the rapid development of neural stem cells (NSCs), facilitating the growth and long-term viability of neuronal networks ( Figure 18 c) [ 153 ], which may be related to the increased cell density in the cylindrical areas of the scaffolds that leads to strengthened neurons communications. Figure 18 d represents a quantitative ratio of young (DCX+) and mature (NeuN+) neurons as well as SOX2+ multipotent neural progenitor cells in the scaffold at day 25 of culture/differentiation.…”

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

“…In Figure 18 , the expression of young and mature neuronal markers DCX/MAP2/NeuN and SOX2 indicate a healthy formation of a neuronal network. Finally, on day 25 of 3D culture, a large proportion of neurons already expressed the early-born cortical neuronal marker CTIP2 ( Figure 18 h) [ 153 ].…”

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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Two-Photon Polymerization: Functionalized Microstructures, Micro-Resonators, and Bio-Scaffolds

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The direct laser writing technique based on two-photon polymerization (TPP) has evolved considerably over the past two decades. Its remarkable characteristics, such as 3D capability, sub-diffraction resolution, material flexibility, and gentle processing conditions, have made it suitable for several applications in photonics and biosciences. In this review, we present an overview of the progress of TPP towards the fabrication of functionalized microstructures, whispering gallery mode (WGM) microresonators, and microenvironments for culturing microorganisms. We also describe the key physical-chemical fundamentals underlying the technique, the typical experimental setups, and the different materials employed for TPP.

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Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

Section: Devices Fabricated Via Tpp: General Applicationsmentioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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Two-Photon Polymerization: Functionalized Microstructures, Micro-Resonators, and Bio-Scaffolds

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Advanced Materials and Sensors for Microphysiological Systems: Focus on Electronic and Electrooptical Interfaces

2022

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Advanced in vitro cell culture systems or microphysiological systems (MPSs), including microfluidic organ‐on‐a‐chip (OoC), are breakthrough technologies in biomedicine. These systems recapitulate features of human tissues outside of the body. They are increasingly being used to study the functionality of different organs for applications such as drug evolutions, disease modeling, and precision medicine. Currently, developers and endpoint users of these in vitro models promote how they can replace animal models or even be a better ethically neutral and humanized alternative to study pathology, physiology, and pharmacology. Although reported models show a remarkable physiological structure and function compared to the conventional 2D cell culture, they are almost exclusively based on standard passive polymers or glass with none or minimal real‐time stimuli and readout capacity. The next technology leap in reproducing in vivo‐like functionality and real‐time monitoring of tissue function could be realized with advanced functional materials and devices. This review describes the currently reported electronic and optical advanced materials for sensing and stimulation of MPS models. In addition, an overview of multi‐sensing for Body‐on‐Chip platforms is given. Finally, one gives the perspective on how advanced functional materials could be integrated into in vitro systems to precisely mimic human physiology.

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Kirigami‐Inspired Biodesign for Applications in Healthcare

et al. 2022

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Mechanically flexible and conformable materials and integrated devices have found diverse applications in personalized healthcare as diagnostics and therapeutics, tissue engineering and regenerative medicine constructs, surgical tools, secure systems, and assistive technologies. In order to impart optimal mechanical properties to the (bio)materials used in these applications, various strategies have been explored—from composites to structural engineering. In recent years, geometric cuts inspired by the art of paper‐cutting, referred to as kirigami, have provided innovative opportunities for conferring precise mechanical properties via material removal. Kirigami‐based approaches have been used for device design in areas ranging from soft bioelectronics to energy storage. In this review, the principles of kirigami‐inspired engineering specifically for biomedical applications are discussed. Factors pertinent to their design, including cut geometry, materials, and fabrication, and the effect these parameters have on their properties and configurations are covered. Examples of kirigami designs in healthcare are presented, such as, various form factors of sensors (on skin, wearable), implantable devices, therapeutics, surgical procedures, and cellular scaffolds for regenerative medicine. Finally, the challenges and future scope for the successful translation of these biodesign concepts to broader deployment are discussed.

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In Vitro Development of Human iPSC-Derived Functional Neuronal Networks on Laser-Fabricated 3D Scaffolds

Cited by 37 publications

References 63 publications

Two-Photon Polymerization: Functionalized Microstructures, Micro-Resonators, and Bio-Scaffolds

Two-Photon Polymerization: Functionalized Microstructures, Micro-Resonators, and Bio-Scaffolds

Advanced Materials and Sensors for Microphysiological Systems: Focus on Electronic and Electrooptical Interfaces

Kirigami‐Inspired Biodesign for Applications in Healthcare

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