Shin, Young Min Shin, Hyeok Jun Heo, Yunhoe Jun, Indong Chung, Yong-Woo Kim, Kyeongsoo Lim, Youn Mook Jeon, Hojeong Shin, Heungsoo 2024-01-20T02:31:32Z 2024-01-20T02:31:32Z 2021-09-05 2017-01 2050-750X https://pubs.kist.re.kr/handle/201004/123201 A monolayer of endothelial cells (ECs) aligned along the direction of blood flow plays crucial roles in the regulation of anti-thrombogenic and pro-inflammatory reactions in the blood vessel wall. Thus, many researchers have attempted to mimic the aligned structure of ECs in vascular grafts or tissue-engineered blood vessels. In the present study, we fabricated micro-groove patterned nanofibers using a femtosecond laser ablation technique to recapitulate the densely organized anisotropic architecture of the endothelial layer. Femtosecond laser ablation enabled us to generate high-resolution groove patterns (10 mm width) with 20 or 80 mm gaps on randomly oriented electrospun nanofibers. The patterned nanofibers exhibited anisotropic (transverse: 101.1 +/- 4.0 degrees and longitudinal: 123.5 +/- 9.4 degrees) water contact angles; however, the mechanical properties were consistent in both directions. The micropatterned nanofibers modulated the aligned structure or aspect ratio (20 mm: 0.23 +/- 0.11 and 80 mm: 0.42 +/- 0.18) of ECs along the pattern direction. In particular, the engineered aligned endothelial layer was effective in eliciting an anti-inflammatory response (approximately 50% greater than that of random or aligned nanofibers), thereby effectively preventing monocyte adhesion following activation by TNF-alpha treatment. Therefore, micropatterning by laser ablation can be utilized to generate high-resolution microgrooves on various substrates, thereby providing fundamental platforms for vascular tissue engineering. English Royal Society of Chemistry Engineering an aligned endothelial monolayer on a topologically modified nanofibrous platform with a micropatterned structure produced by femtosecond laser ablation Article 10.1039/c6tb02258h 1 Journal of Materials Chemistry B, v.5, no.2, pp.318 - 328 Journal of Materials Chemistry B 5 2 318 328 N scie scopus 000392418800013 2-s2.0-85009133591 Materials Science, Biomaterials Materials Science Article CORONARY-ARTERY-DISEASE SHEAR-STRESS TISSUE SCAFFOLDS STEM-CELLS ORGANIZATION TOPOGRAPHIES MIGRATION PROPERTY PATTERNS MYOTUBES endothelial monolayer topography nanofiber femtosecond laser