2023
DOI: 10.3390/gels9080642
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Rheological Characterization of Three-Dimensional Neuronal Cultures Embedded in PEGylated Fibrin Hydrogels

Abstract: Three-dimensional (3D) neuronal cultures are valuable models for studying brain complexity in vitro, and the choice of the bulk material in which the neurons grow is a crucial factor in establishing successful cultures. Indeed, neuronal development and network functionality are influenced by the mechanical properties of the selected material; in turn, these properties may change due to neuron–matrix interactions that alter the microstructure of the material. To advance our understanding of the interplay betwee… Show more

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Cited by 2 publications
(7 citation statements)
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“…This result may be attributed to the absence of living cells within its structure. This hypothesis is supported by our previous work [17], where we examined the evolution of T2-like hydrogels with and without cells. For matrices without cells we measured a Young's modulus of ≃420 Pa that did not change during development.…”
Section: Discussion: Hydrogel Stability and Network Formationsupporting
confidence: 79%
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“…This result may be attributed to the absence of living cells within its structure. This hypothesis is supported by our previous work [17], where we examined the evolution of T2-like hydrogels with and without cells. For matrices without cells we measured a Young's modulus of ≃420 Pa that did not change during development.…”
Section: Discussion: Hydrogel Stability and Network Formationsupporting
confidence: 79%
“…All hydrogel samples contain an ensemble of cortical neurons and glia cells that self-organize into a living neuronal network (Figure 1a), and will be referred to as T1, T2, and T3 PEGylated fibrin, respectively, (Figure 1b). We note that the mechanical characterization of T2 hydrogels was previously examined in a publication from our group [17]. In order to establish a relationship between the mechanical properties of the hydrogel scaffolds and the functional organization of the resultant neuronal network (Figure 1c), we present first the rheological characterization of the hydrogels with neurons, and then describe their functional organization as a living neuronal network.…”
Section: Resultsmentioning
confidence: 99%
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