المؤلفون: Alarcón Apablaza, Josefa^1,2 (AUTHOR) josefa.alarcon@ufrontera.cl, Lezcano, María Florencia^1,3,4 (AUTHOR) florencia.lezcano@ufrontera.cl, Godoy Sánchez, Karina⁵ (AUTHOR) karina.godoy@ufrontera.cl, Oporto, Gonzalo H.^1,3 (AUTHOR) gonzalo.oporto@ufrontera.cl, Dias, Fernando José^1,3 (AUTHOR) fernando.dias@ufrontera.cl

المصدر: Polymers (20734360). Feb2022, Vol. 14 Issue 3, p397. 1p.

مصطلحات موضوعية: *NERVOUS system regeneration, *METAL scaffolding, *NERVE tissue, *RF values (Chromatography), *PERIPHERAL nervous system

مستخلص: Cellular behavior in nerve regeneration is affected by the architecture of the polymeric nerve guide conduits (NGCs); therefore, design features of polymeric NGCs are critical for neural tissue engineering. Hence, the purpose of this scoping review is to summarize the adequate quantitative/morphometric parameters of the characteristics of NGC that provide a supportive environment for nerve regeneration, enhancing the understanding of a previous study. 394 studies were found, of which 29 studies were selected. The selected studies revealed four morphometric characteristics for promoting nerve regeneration: wall thickness, fiber size, pore size, and porosity. An NGC with a wall thickness between 250–400 μm and porosity of 60–80%, with a small pore on the inner surface and a large pore on the outer surface, significantly favored nerve regeneration; resulting in an increase in nutrient permeability, retention of neurotrophic factors, and optimal mechanical properties. On the other hand, the superiority of electrospun fibers is described; however, the size of the fiber is controversial in the literature, obtaining optimal results in the range of 300 nm to 30 µm. The incorporation of these optimal morphometric characteristics will encourage nerve regeneration and help reduce the number of experimental studies as it will provide the initial morphometric parameters for the preparation of an NGC. [ABSTRACT FROM AUTHOR]

المؤلفون: Lopez Marquez, Alex, Gareis, Iván Emilio, Dias, Fernando José, Gerhard, Christoph, Lezcano, María Florencia

المصدر: Polymers (20734360); Feb2022, Vol. 14 Issue 3, p467, 1p

مصطلحات موضوعية: MORPHOLOGY, PHYSICAL measurements, TISSUE engineering, EXTRACELLULAR matrix, TISSUE scaffolds

مستخلص: Electrospun scaffolds can imitate the hierarchical structures present in the extracellular matrix, representing one of the main concerns of modern tissue engineering. They are characterized in order to evaluate their capability to support cells or to provide guidelines for reproducibility. The issues with widely used methods for morphological characterization are discussed in order to provide insight into a desirable methodology for electrospun scaffold characterization. Reported methods include imaging and physical measurements. Characterization methods harbor inherent limitations and benefits, and these are discussed and presented in a comprehensive selection matrix to provide researchers with the adequate tools and insights required to characterize their electrospun scaffolds. It is shown that imaging methods present the most benefits, with drawbacks being limited to required costs and expertise. By making use of more appropriate characterization, researchers will avoid measurements that do not represent their scaffolds and perhaps might discover that they can extract more characteristics from their scaffold at no further cost. [ABSTRACT FROM AUTHOR]

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المؤلفون: Apablaza, Josefa Alarcón^1,2 (AUTHOR) josefa.alarcon@ufrontera.cl, Lezcano, María Florencia^1,3,4 (AUTHOR) florencia.lezcano@ufrontera.cl, Lopez Marquez, Alex⁵ (AUTHOR) alexlopezmarquez@gmail.com, Godoy Sánchez, Karina^6,7 (AUTHOR) karina.godoy@ufrontera.cl, Oporto, Gonzalo H.^1,3 (AUTHOR) gonzalo.oporto@ufrontera.cl, Dias, Fernando José^1,3 (AUTHOR) fernando.dias@ufrontera.cl

المصدر: Polymers (20734360). Aug2021, Vol. 13 Issue 15, p2563-2563. 1p.

مصطلحات موضوعية: *NERVOUS system regeneration, *METAL scaffolding, *PERIPHERAL nervous system, *RF values (Chromatography), *DIGITAL libraries

مستخلص: The "nerve guide conduits" (NGC) used in nerve regeneration must mimic the natural environment for proper cell behavior. Objective: To describe the main morphological characteristics of polymeric NGC to promote nerve regeneration. Methods: A scoping review was performed following the Preferred Reporting Items for Systematic reviews and Meta-Analyses extension for Scoping Reviews (PRISMA-ScR) criteria in the PubMed, Web of Science, Science Direct, and Scientific Electronic Library Online (SciELO) databases. Primary studies that considered/evaluated morphological characteristics of NGC to promote nerve regeneration were included. Result: A total of 704 studies were found, of which 52 were selected. The NGC main morphological characteristics found in the literature were: (I) NGC diameter affects the mechanical properties of the scaffold. (II) Wall thickness of NGC determines the exchange of nutrients, molecules, and neurotrophins between the internal and external environment; and influences the mechanical properties and biodegradation, similarly to NGC (III) porosity, (IV) pore size, and (V) pore distribution. The (VI) alignment of the NGC fibers influences the phenotype of cells involved in nerve regeneration. In addition, the (VII) thickness of the polymeric fiber influences neurite extension and orientation. Conclusions: An NGC should have its diameter adjusted to the nerve with wall thickness, porosity, pore size, and distribution of pores, to favor vascularization, permeability, and exchange of nutrients, and retention of neurotrophic factors, also favoring its mechanical properties and biodegradability. [ABSTRACT FROM AUTHOR]