Wet Electrospinning and its Applications:  A Review

Mejía Suaza, Mónica Liliana; Hurtado Henao , Yarledis; Moncada Acevedo , María Elena

Wet Electrospinning and its Applications: A Review

dc.creator	Mejía Suaza, Mónica Liliana
dc.creator	Hurtado Henao , Yarledis
dc.creator	Moncada Acevedo , María Elena
dc.date	2022-06-28
dc.date.accessioned	2025-10-01T23:52:46Z
dc.description	In wet electrospinning, a natural or synthetic polymer solution is deposited on a non-solvent liquid coagulant used as collector. This technique can create 3D nanofiber scaffolds with better properties (e.g., porosity and high surface area) than those of traditional 2D scaffolds produced by standard electrospinning. Thanks to these characteristics, wet electrospinning can be employed in a wide range of tissue engineering and industrial applications. This review aims to broaden the panorama of this technique, its possible fields of action, and its range of common materials. Moreover, we also discuss its future trends. In this study, we review papers on this method published between 2017 and 2021 to establish the state of the art of wet electrospinning and its most important applications in cardiac, cartilage, hepatic, wound dressing, skin, neural, bone, and skeletal muscle tissue engineering. Additionally, we examine its industrial applications in water purification, air filters, energy, biomedical sensors, and textiles. The main results of this review indicate that 3D scaffolds for tissue engineering applications are biocompatible; mimic the extracellular matrix (ECM); allow stem cell viability and differentiation; and have high porosity, which provides greater cell infiltration compared to 2D scaffolds. Finally, we found that, in industrial applications of wet electrospinning: (1) additives improve the performance of pure polymers; (2) the concentration of the solution influences porosity and fiber packing; (3) flow rate, voltage, and distance modify fiber morphology; (4) the surface tension of the non-solvent coagulant on which the fibers are deposited has an effect on their porosity, compaction, and mechanical properties; and (5) deposition time defines scaffold thickness.	en-US
dc.description	En el electrospinning húmedo, se deposita una solución de polímero natural o sintético sobre un coagulante líquido no disolvente utilizado como colector. Esta técnica puede crear andamios de nanofibras en 3D con mejores propiedades (por ejemplo, porosidad y alta superficie) que las de los andamios tradicionales en 2D producidos por electrospinning estándar. Gracias a estas características, el electrospinning húmedo puede emplearse en una amplia gama de aplicaciones industriales y de ingeniería de tejidos. Esta revisión pretende ampliar el panorama de esta técnica, sus posibles campos de actuación y su gama de materiales habituales. Además, también se discuten sus tendencias futuras. En este estudio, revisamos los artículos sobre este método publicados entre 2017 y 2021 para establecer el estado del arte del electrospinning húmedo y sus aplicaciones más importantes en ingeniería de tejidos cardíacos, cartilaginosos, hepáticos, apósitos para heridas, cutáneos, neuronales, óseos y musculares esqueléticos. Adicionalmente, examinamos sus aplicaciones industriales en la purificación del agua, los filtros de aire, la energía, los sensores biomédicos y los textiles. Los principales resultados de esta revisión indican que los andamios 3D para aplicaciones de ingeniería tisular son biocompatibles; imitan la matriz extracelular (MEC); permiten la viabilidad y diferenciación de las células madre; y tienen una alta porosidad, lo que proporciona una mayor infiltración celular en comparación con los andamios 2D. Por último, descubrimos que, en las aplicaciones industriales del electrospinning húmedo: (1) los aditivos mejoran el rendimiento de los polímeros puros; (2) la concentración de la solución influye en la porosidad y el empaquetamiento de las fibras; (3) la velocidad de flujo, el voltaje y la distancia modifican la morfología de las fibras; (4) la tensión superficial del coagulante no solvente sobre el que se depositan las fibras tiene un efecto sobre su porosidad, compactación y propiedades mecánicas; y (5) el tiempo de deposición define el espesor del andamio.	es-ES
dc.format	application/pdf
dc.format	application/zip
dc.format	text/xml
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dc.identifier	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/2223
dc.identifier	10.22430/22565337.2223
dc.identifier.uri	https://hdl.handle.net/20.500.12622/7815
dc.language	eng
dc.publisher	Instituto Tecnológico Metropolitano (ITM)	es-ES
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/2223/2450
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/2223/2453
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/2223/2454
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/2223/2466
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dc.rights	Derechos de autor 2022 TecnoLógicas	es-ES
dc.rights	http://creativecommons.org/licenses/by-nc-sa/4.0	es-ES
dc.source	TecnoLógicas; Vol. 25 No. 54 (2022); e2223	en-US
dc.source	TecnoLógicas; Vol. 25 Núm. 54 (2022); e2223	es-ES
dc.source	2256-5337
dc.source	0123-7799
dc.subject	Wet electrospinning	en-US
dc.subject	Electrospinning	en-US
dc.subject	Wet spinning	en-US
dc.subject	Scaffolds	en-US
dc.subject	Electrohilado en húmedo	es-ES
dc.subject	Electrohilado	es-ES
dc.subject	Hilado en húmedo	es-ES
dc.subject	Andamios	es-ES
dc.title	Wet Electrospinning and its Applications: A Review	en-US
dc.title	Electrospinning húmedo y sus aplicaciones: una revisión	es-ES
dc.type	info:eu-repo/semantics/article
dc.type	info:eu-repo/semantics/publishedVersion
dc.type	Review Article	en-US
dc.type	Artículos de revisión	es-ES