Enhancing metabolic activity and differentiation potential in adipose mesenchymal stem cells via high-resolution surface-acoustic-wave contactless patterning

Villegas, Karina Martinez; Rasouli, Reza; Tabrizian, Maryam

doi:10.1038/s41378-022-00415-w

Cited by 14 publications

(7 citation statements)

References 48 publications

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“…However, the addition of GO to GelMA enhances this response, with GelMA-GO (striped pink) showing the most significant increase under both passive and stimulation regimes indicating a consistent enhancement independent of stimulation. 78 By day 3, cells across all hydrogels show enhanced metabolic activity under stimulation, suggesting either enhanced cell proliferation or increased metabolic functioning. 79 On day 7, the overall increase in metabolic activity under stimulation remains consistent, indicating a potential stimulation effectiveness over prolonged periods.…”

Section: Acsmentioning

confidence: 94%

Wired for Success: Probing the Effect of Tissue-Engineered Neural Interface Substrates on Cell Viability

Nascimento,

Mendes,

Duchi

et al. 2024

ACS Biomater. Sci. Eng.

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This study investigates the electrochemical behavior of GelMA-based hydrogels and their interactions with PC12 neural cells under electrical stimulation in the presence of conducting substrates. Focusing on indium tin oxide (ITO), platinum, and gold mylar substrates supporting conductive scaffolds composed of hydrogel, graphene oxide, and gold nanorods, we explored how the substrate materials affect scaffold conductivity and cell viability. We examined the impact of an optimized electrical stimulation protocol on the PC12 cell viability. According to our findings, substrate selection significantly influences conductive hydrogel behavior, affecting cell viability and proliferation as a result. In particular, the ITO substrates were found to provide the best support for cell viability with an average of at least three times higher metabolic activity compared to platinum and gold mylar substrates over a 7 day stimulation period. The study offers new insights into substrate selection as a platform for neural cell stimulation and underscores the critical role of substrate materials in optimizing the efficacy of neural interfaces for biomedical applications. In addition to extending existing work, this study provides a robust platform for future explorations aimed at tailoring the full potential of tissue-engineered neural interfaces.

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Section: Acsmentioning

confidence: 94%

Wired for Success: Probing the Effect of Tissue-Engineered Neural Interface Substrates on Cell Viability

Nascimento,

Mendes,

Duchi

et al. 2024

ACS Biomater. Sci. Eng.

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“…Martinez Villegas et al 142 demonstrated the enhancement of the osteogenic differentiation and proliferation of adipose-derived stem cells embedded into a photocurable hydrogel via acoustic patterning using a frequency of 13.11 MHz (SSAW). Furthermore, Devendran et al 143 scrutinized the phenotypes of four distinct human and mouse cell lines after exposure to 48.5 MHz (SAW).…”

Section: Acoustofluidics As a Functional Force For Investigating Phen...mentioning

confidence: 99%

Acoustofluidics – changing paradigm in tissue engineering, therapeutics development, and biosensing

2023

Self Cite

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“…In fact, there is increasing evidence that preparing cells as 3D tissue-like structures with a certain spatial structure enhances their secretory activity. [62] This may be related to the formation of more cell-cell and cell-ECM interactions, [74,75] as well as cell responses to changes in spatial curvature. [76] The distinct advantage of cell sheets over spheroids in the field of tissue engineering is that cell sheets can be relatively easily combined into macrostructures, so that scaffold-free multicellular platforms with multiple repair functions can be prepared.…”

Section: Cell Sheetsmentioning

confidence: 99%

“…[79] Because the relationship between cells is much closer to that of tissues, the cell behavior and growth reflected by the cells in cell sheets can better reflect the actual physiological situation. To reproduce the distribution of cells in complex tissues as much as possible, many researchers have used micropattern, [84,85] microcontact printing, [86] magnetic or acoustic control, [75,87] and other methods to regulate cell distribution and explore the crosstalk between different cells in complex models. However, the structural complexity obtained by these methods is still not enough.…”

Section: Magnetic Controlmentioning

confidence: 99%

Three‐dimensional multicellular biomaterial platforms for biomedical application

Hao,

Qin,

2023

Interdisciplinary Materials

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The three‐dimensional (3D) multicellular platforms prepared by cells or biomaterials have been widely applied in biomedical fields for the regeneration of complex tissues, the exploration of cell crosstalk, and the establishment of tissue physiological and pathological models. Compared with the traditional 2D culture methods, the 3D multicellular platforms are easier to adjust the components and structures of extracellular matrix (ECM) because of the synthesis of ECM by cells and the use of biomaterials. Moreover, the 3D multicellular platforms also can customize the cell distribution and precisely design micro and macro structures of the systems. Based on these typical advantages of 3D multicellular platforms and their increasingly important position in the biomedical field, this review summarizes the present 3D multicellular platforms. Herein, current 3D multicellular platforms are divided into two major types: scaffold‐free and scaffold‐based 3D multicellular platforms. The specific characteristics and applications of different types of 3D multicellular platforms are thoroughly introduced to help readers understand how different models affect and regulate cell behaviors and inspire researchers on how to select and design suitable 3D multicellular platforms according to different application scenarios.

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Enhancing metabolic activity and differentiation potential in adipose mesenchymal stem cells via high-resolution surface-acoustic-wave contactless patterning

Cited by 14 publications

References 48 publications

Wired for Success: Probing the Effect of Tissue-Engineered Neural Interface Substrates on Cell Viability

Wired for Success: Probing the Effect of Tissue-Engineered Neural Interface Substrates on Cell Viability

Acoustofluidics – changing paradigm in tissue engineering, therapeutics development, and biosensing

Three‐dimensional multicellular biomaterial platforms for biomedical application

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