Anisotropic methacrylated network for the development of an in vitro three-dimensional neural model

last updated: 2020-01-31
ProjectHierarchiTech :: publications list
TitleAnisotropic methacrylated network for the development of an in vitro three-dimensional neural model
Publication TypeComunication - Oral
Year of Publication2017
AuthorsCanadas R. F., Marques A. P., Tocchio A., Karaca E., Miansari M., Ren T., Dr. Oliveira J. M., Reis R. L., and Demirci U.
Abstract

In nature anisotropic geometries are present in several tissues such as muscle fibers, tendon or cerebral cortex. Since different tissues present different specificities as organization, mechanical properties, and extracellular matrix (ECM), engineering techniques are needed to tune specific in vitro tissues models, especially for 3-D1 anisotropic arranges. While progress was made to obtain cells aligned in two-dimensions (2-D), the reported techniques for 3-D alignment are limited and present limitations controlling mechanical and porosity properties2,3. Here, we describe the use of a hybrid polymeric system mimicking ECM while controlling mechanical and geometrical properties in 3-D. Controlling polymeric ratios, and using crosslinking and freezing as a mechanism to guide porosity, 3-D structures are programmed regarding stiffness, shape and directionality with tunable micro-porosity to direct cellular responses. We demonstrate that crosslinking plus freezing temperature uniaxial gradients grant control over 3-D anisotropy, pore diameter, and structure stiffness, showing broad applications in modelling human tissues, such as 3-D neural constructs. Using methacrylated gelatin and gellan gum as a polymeric blend and running a precise fabrication technique, we achieved in vitro anisotropic neurites outgrowth as it happens in brain cortex. Furthermore, the applied strategy also allow the alignment of other cell types arranged in cylindrical clusters, as tested with a co-culture of mesenchymal stem cells and endothelial cells.

 

References

  1. Griffith, L. G. & Swartz, M. A. Capturing complex 3D tissue physiology in vitro. Nat. Rev. Mol. Cell Biol. 7, 211–224 (2006)
  2. Johnson, B. N. et al. 3D printed nervous system on a chip. Lab Chip 16, 1393–1400 (2016)
  3. Jalil Razavi, M., Zhang, T., Liu, T. & Wang, X. Cortical Folding Pattern and its Consistency Induced by Biological Growth. Sci. Rep. 5, 14477 (2015)

Acknowledgments

This study received funding from Portuguese Foundation for Science and Technology (FCT) through the project OsteoCart (PTDC/CTMBPC/115977/2009). The authors also thank FCT for the Ph.D. scholarship provided to R. F. Canadas (SFRH/BD/92565/2013). This work also had the support of the LusoAmerican Development Foundation (FLAD)

Conference NameTERMIS-AP17
Date Published2017-09-21
Conference LocationNantong, China
URLhttps://www.termis.org/sites/default/files/Newsletter_Volume_XII_Issue_I_2017_1.pdf
Keywords3D, In Vitro Model, Neocortex
RightsopenAccess
Peer reviewedyes
Statuspublished

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