1(Department of Anesthesiology, Peking Union Medical College Hospital, Chinese Academy of Medical Science & Peking Union Medical College, Beijing 100730, China) 2(Institute of Basic Medical Sciences, Chinese Academy of Medical Sciences & Peking Union Medical College, Beijing 100005, China)
Abstract:The effects of hydrogel dressings on the immune cells and vascular endothelial cells are closely related to wound healing. This work is aimed to investigate the effects of a carbon fiber reinforced polyvinyl alcohol conductive hydrogel (PVA/CFs) on inflammatory response in mouse macrophages and the formation of adherent junctions between HUVEC cells. The above two kinds of cells were cultured on PVA and PVA/CFs with CF content of 1.5%, 3% and 5%, respectively. The expression of TNF-α, IL-1β and IL-6 in inflammatory response genes of macrophages (RAW264.7) was detected by real-time PCR. The cytokins secretion of TNF-α, IL-1β and IL-6 were tested by ELISA kits. The growth and proliferation of human umbilical vein endothelial cells (HUVEC) and RAW264.7 on PVA/CFs were detected by CCK-8 assay. The protein expression of VE-Cadherin in HUVEC was determined by laser scanning confocal microscopy and western blot assay. All quantitative detection experiments were set at least three replicates (n≥3). PVA/CFs did not significantly change the gene expression levels of TNF-α, IL-1β and IL-6 and the cytokins secretion levels in RAW264.7 cells compared with PVA. All groups were no significant difference (P>0.05). However, the secretion of TNF-α, IL-1β and IL-6 in RAW264.7 cells treated with LPS was increased by 2.35, 4.27 and 27.1 folds of that in the control group, respectively. The expression of VE-cadherin in HUVEC cells on PVA/CFs was increased, suggesting that PVA/CFs could strengthen adherent junctions of endothelial cells. In addition, PVA/CFs could support the growth and proliferation of RAW264.7 and HUVEC cells, and there was no significant difference in cell viability between PVA/CFs and PVA groups (P>0.05). PVA/CFs not only did not cause any severe inflammatory responses of macrophages, but also supported the growth and proliferation of macrophages and endothelial cells, and promoted the formation of integrated adherent junctions between endothelial cells.
[1] Magalhaes RS, Williams JK, Yoo KW, et al. A tissue-engineered uterus supports live births in rabbits[J]. Nature Biotechnology,2020,38(11):1280-1287. [2] Chazaud B. Macrophages: supportive cells for tissue repair and regeneration[J]. Immunobiology,2014,219(3):172-178. [3] Cao Haoqing, Mchugh K, Chew SY, et al. The topographical effect of electrospun nanofibrous scaffolds on the in vivo and in vitro foreign body reaction[J]. Journal of Biomedical Materials Research Part A, 2010,93(3):1151-1159. [4] Taraballi F, Corradetti B, Minardi S, et al. Biomimetic collagenous scaffold to tune inflammation by targeting macrophages[J]. Journal of tissue engineering,2016,7:1547613221. [5] Spiller KL, Anfang RR, Spiller KJ, et al. The role of macrophage phenotype in vascularization of tissue engineering scaffolds[J]. Biomaterials,2014,35(15):4477-4488. [6] Wang Zhihong, Cui Yun, Wang Jianing, et al. The effect of thick fibers and large pores of electrospun poly (ε-caprolactone) vascular grafts on macrophage polarization and arterial regeneration[J]. Biomaterials, 2014,35(22):5700-5710. [7] Novak ML, Koh TJ. Macrophage phenotypes during tissue repair[J]. Journal of Leukocyte Biology,2013,93(6):875-881. [8] Netea MG, Joosten LA. Master and commander: epigenetic regulation of macrophages[J]. Cell Research,2016,26(2):145-146. [9] Anderson JM, Rodriguez A, Chang DT. Foreign body reaction to biomaterials[J]. Seminars in Immunology, 2008,20(2):86-100. [10] Vestweber D. VE-cadherin: the major endothelial adhesion molecule controlling cellular junctions and blood vessel formation[J]. Arteriosclerosis, Thrombosis, and Vascular Biology,2008,28(2):223-232. [11] Maltabe V, Kouklis P. Vascular Endothelial (VE)-Cadherin-mediated adherens junctions involvement in cardiovascular progenitor cell specification[J]. International Journal of Developmental Biology, 2021, 66(1-2-3):77-83. [12] Wu Fengxin, Gao Aijun, Liu Jian, et al. High modulus conductive hydrogels enhance in vitro maturation and contractile function of primary cardiomyocytes for uses in drug screening[J]. Advanced Healthcare Materials,2018,7(24):1800990. [13] Morsink M, Severino P, Luna-Ceron E, et al. Effects of electrically conductive nano-biomaterials on regulating cardiomyocyte behavior for cardiac repair and regeneration[J]. Acta Biomaterialia,2021,139:141-156. [14] Esmaeili H, Patino-Guerrero A, Hasany M, et al. Electroconductive biomaterials for cardiac tissue engineering[J]. Acta Biomaterialia, 2021,139:118-140. [15] Guo Baolin, Ma PX. Conducting polymers for tissue engineering[J]. Biomacromolecules,2018,19(6):1764-1782. [16] Eming SA, Wynn TA, Martin P. Inflammation and metabolism in tissue repair and regeneration[J]. Science,2017,356(6342):1026-1030. [17] Wang Kai, Hou Wenda, Wang Xi, et al. Overcoming foreign-body reaction through nanotopography: Biocompatibility and immunoisolation properties of a nanofibrous membrane[J]. Biomaterials,2016,102:249-258. [18] Jing Lin, Li Hongling, Tay RY, et al. Biocompatible hydroxylated boron nitride nanosheets/poly (vinyl alcohol) interpenetrating hydrogels with enhanced mechanical and thermal responses[J]. ACS Nano,2017,11(4):3742-3751. [19] Bodugoz-Senturk H, Macias CE, Kung JH, et al. Poly (vinyl alcohol)-acrylamide hydrogels as load-bearing cartilage substitute[J]. Biomaterials,2009,30(4):589-596. [20] Xu Lizhi, Zhao Xueli, Xu Chuanlai, et al. Water‐rich biomimetic composites with abiotic self‐organizing nanofiber network[J]. Advanced Materials, 2018,30(1):1703343. [21] Nuttelman CR, Henry SM, Anseth KS. Synthesis and characterization of photocrosslinkable, degradable poly (vinyl alcohol)-based tissue engineering scaffolds[J]. Biomaterials, 2002,23(17):3617-3626. [22] Firkowska Boden I, Zhang Xiaoyuan, Jandt K D. Controlling protein adsorption through nanostructured polymeric surfaces[J]. Advanced healthcare materials,2018,7(1):1700995. [23] Fedel M, Motta A, Maniglio D, Migliaresi C. Carbon coatings for cardiovascular applications: physico-chemical properties and blood compatibility [J]. J Biomater, 2010,25(1):57-74. [24] Meng Jie, Kong Hua, Xu Haiyan, et al. Improving the blood compatibility of polyurethane using carbon nanotubes as fillers and its implications to cardiovascular surgery [J]. J Biomed Mater Res A, 2005,74(2):208-214. [25] Coulombe KL, Bajpai VK, Andreadis ST, et al. Heart regeneration with engineered myocardial tissue[J]. Annual review of Biomedical Engineering,2014,16:1-28. [26] Shu Yao, Hao Tong, Yao Fanglian, et al. RoY peptide-modified chitosan-based hydrogel to improve angiogenesis and cardiac repair under hypoxia[J]. ACS Applied Materials & Interfaces,2015,7(12):6505-6517. [27] Hesam Mahmoudinezhad M, Karkhaneh A, Jadidi K. Effect of PEDOT: PSS in tissue engineering composite scaffold on improvement and maintenance of endothelial cell function[J]. Journal of Biosciences,2018,43(2):307-319. [28] Merkle VM, Tran PL, Hutchinson M, et al. Core-shell PVA/gelatin electrospun nanofibers promote human umbilical vein endothelial cell and smooth muscle cell proliferation and migration[J]. Acta Biomaterialia, 2015,27:77-87.
