PCL-based 3D nanofibrous structure with well-designed morphology and enhanced specific surface area for tissue engineering application

• Published in: Progress in biomaterials Vol. 12; no. 2; pp. 113 - 122
• Main Authors: Hejazi, Fatemeh, Mirzadeh, Hamid, Shojaei, Shahrokh
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.06.2023; Springer Nature B.V
• Subjects: Biocompatibility; Biomaterials; Cell proliferation; Chemistry and Materials Science; Cooling effects; Electrospinning; Electrospraying; Extracellular matrix; Materials Science; Microparticles; Morphology; Nanofibers; Nitrogen; Original Research; Porosity; Scaffolds; Substrates; Surface area; Thin films; Tissue engineering; Water absorption; Straticulated structure; Nitrogen flush; Surface area; 3D scaffold; Electrospinning/electrospraying
• ISSN: 2194-0509; 2194-0517
• DOI: 10.1007/s40204-022-00215-5

Tissue engineering opens a new horizon for biological tissue replacement applications. Scaffolds, appropriate cells, and signaling induction are the main three determinant parameters in any tissue engineering applications. Designing a suitable scaffold which can mimic the cellular inherent and natural habitation is of great importance for cellular growth and proliferation. Just like a natural extracellular matrix (ECM), scaffolds provide the cells with an environment for performing biological functions. Accordingly, vast surface area and three-dimensional nanofibrous structures are among the pivotal characteristics of functional scaffolds in tissue engineering, and enhancement of their properties is the main purpose of the present research. In our previous study, a patterned structure composed of continuous nanofibers and microparticles was introduced. In this work, a new modification is applied for adjustment of the surface area of an electrospun/electrosprayed scaffold. For this purpose, at predetermined stages during electrospinning/electrospraying, the nitrogen gas is flushed through the mesh holes of the collector in the opposite direction of the jet movement. This method has led to the formation of very thin nanofibrous layers at nitrogen flush intervals by providing a cooling effect of the sweeping nitrogen. As a consequence, a straticulated structure has been fabricated which possesses extremely high surface/volume ratio. The porosity, water absorption, and morphological analysis were conducted on the obtained scaffold. In vitro cytocompatibility assessments as well as histological analysis demonstrated that the fabricated scaffold provides a proper substrate for cellular attachment, proliferation and infiltration. These findings can be advantageous in three-dimensional tissue engineering such as bone tissue engineering applications. Furthermore, according to the advanced microstructure and vast surface area of the fabricated samples, they can be applied in many other applications, such as membrane, filtration, etc.