Restricted accessResearch articleFirst published online 2017-10
Cytocompatibility and biologic characteristics of synthetic scaffold materials of rabbit acellular vascular matrix combining with human-like collagen I
Scaffold material provides a three-dimensional growing environment for seed cells in the research field of tissue engineering. In the present study, rabbit arterial blood vessel cells were chemically removed with trypsin and Triton X-100 to prepare rabbit acellular vascular matrix scaffold material. Observation by He&Masson staining revealed that no cellular components or nuclei existed in the vascular intima and media after decellularization. Human-like collagen I was combined with acellular vascular matrix by freeze-drying to prepare an acellular vascular matrix-0.25% human-like collagen I scaffold to compensate for the extracellular matrix loss during the decellularization process. We next performed a series of experiments to test the water absorbing quality, biomechanics, pressure resistance, cytotoxicity, and ultra-micro structure of the acellular vascular matrix composite material and natural rabbit artery and found that the acellular vascular matrix-0.25% human-like collagen I material behaved similarly to natural rabbit artery. In conclusion, the acellular vascular matrix-0.25% human-like collagen I composite material provides a new approach and lays the foundation for novel scaffold material research into tissue engineering of blood vessels.
DevitoFZitoADachilleAet al.Bioresorbable vascular scaffolds: design, clinical trials, and current applications. Coronary Artery Dis2016; 27: 151–158.
2.
ElsayedYLekakouCLabeedFet al.Fabrication and characterisation of biomimetic, electrospun gelatin fibre scaffolds for tunica media-equivalent, tissue engineered vascular grafts. Mater Sci Eng C, Mater Biol Appl2016; 61: 473–483.
3.
FournierNMLeeBBanasrMet al.Vascular endothelial growth factor regulates adult hippocampal cell proliferation through MEK/ERK- and PI3K/Akt-dependent signaling. Neuropharmacology2012; 63: 642–652.
4.
ZhuCYingDMiJet al.Development of anti-atherosclerotic tissue-engineered blood vessel by A20-regulated endothelial progenitor cells seeding decellularized vascular matrix. Biomaterials2008; 29: 2628–2636.
5.
Liu X, Wang J, Dong F, et al. Study of composite vascular scaffold combining with differentiated VSMC- and VEC-like cells in vitro and in vivo. J Biomater Appl 2017; 32: 219–229.
6.
SchneiderKHAignerPHolnthonerWet al.Decellularized human placenta chorion matrix as a favorable source of small-diameter vascular grafts. Acta Biomaterialia2016; 29: 125–134.
7.
SchmidtCEBaierJM. Acellular vascular tissues: natural biomaterials for tissue repair and tissue engineering. Biomaterials2000; 21: 2215–2231.
8.
ZhuCFanDWangY. Human-like collagen/hyaluronic acid 3D scaffolds for vascular tissue engineering. Mater Sci Eng C, Mater Biol Appl2014; 34: 393–401.
9.
LiuXWangJDongFet al.Human gingival fibroblasts induced and differentiated into vascular endothelial-like cells. Develop Growth Differentiat2016; 58: 702–713.
10.
GongWLeiDLiSet al.Hybrid small-diameter vascular grafts: anti-expansion effect of electrospun poly epsilon-caprolactone on heparin-coated decellularized matrices. Biomaterials2016; 76: 359–370.
11.
YaoYWangJCuiYet al.Effect of sustained heparin release from PCL/chitosan hybrid small-diameter vascular grafts on anti-thrombogenic property and endothelialization. Acta Biomater2014; 10: 2739–2749.
12.
LutolfMPLauer-FieldsJLSchmoekelHGet al.Synthetic matrix metalloproteinase-sensitive hydrogels for the conduction of tissue regeneration: engineering cell-invasion characteristics. Proc Natl Acad Sci U S A2003; 100: 5413–5418.
13.
ThottappillilNNairPD. Scaffolds in vascular regeneration: current status. Vasc Health Risk Manage2015; 11: 79–91.
14.
McBaneJESharifpoorSLabowRSet al.Tissue engineering a small diameter vessel substitute: engineering constructs with select biomaterials and cells. Curr Vasc Pharmacol2012; 10: 347–360.
15.
WongMLGriffithsLG. Immunogenicity in xenogeneic scaffold generation: antigen removal vs. decellularization. Acta Biomater2014; 10: 1806–1816.
16.
PuLWuJPanXet al.Determining the optimal protocol for preparing an acellular scaffold of tissue engineered small-diameter blood vessels. J Biomed Mater Res Part B, Appl Biomater2017. DOI: 10.1002/jbm.b.33827.
17.
ZhuCFanDDuanZet al.Initial investigation of novel human-like collagen/chitosan scaffold for vascular tissue engineering. J Biomed Mater Res Part A2009; 89: 829–840.
18.
ZhengSWangMBaiYet al.Impact of family members and health care providers on the use of folic acid in pregnant women. Wei sheng yan jiu = J Hygiene Res2011; 40: 71–73, 77.
19.
GroverCNCameronREBestSM. Investigating the morphological, mechanical and degradation properties of scaffolds comprising collagen, gelatin and elastin for use in soft tissue engineering. J Mech Behav Biomed Mater2012; 10: 62–74.
20.
NillesenSTGeutjesPJWismansRet al.Increased angiogenesis and blood vessel maturation in acellular collagen-heparin scaffolds containing both FGF2 and VEGF. Biomaterials2007; 28: 1123–1131.
21.
SimionescuDTLuQSongYet al.Biocompatibility and remodeling potential of pure arterial elastin and collagen scaffolds. Biomaterials2006; 27: 702–713.
22.
LiuXZhangHChangLet al.Human-like collagen protein-coated magnetic nanoparticles with high magnetic hyperthermia performance and improved biocompatibility. Nanoscale Res Lett2015; 10: 28–28.
23.
ZhuCMaXXianLet al.Characterization of a co-electrospun scaffold of HLC/CS/PLA for vascular tissue engineering. Biomed Mater Eng2014; 24: 1999–2005.
24.
FanHHuiJDuanZet al.Novel scaffolds fabricated using oleuropein for bone tissue engineering. BioMed Res Int2014; 2014: 652432–652432.
25.
DavisLMCallananACarrollGTet al.On the potential of hydrated storage for naturally derived ECMs and associated effects on mechanical and cellular performance. J Biomed Mater Res Part B, Appl Biomater2014; 102: 89–97.
MuraseYNaritaYKagamiHet al.Evaluation of compliance and stiffness of decellularized tissues as scaffolds for tissue-engineered small caliber vascular grafts using intravascular ultrasound. ASAIO J2006; 52: 450–455.
28.
SaberiEAKarkehabadiHMollashahiNF. Cytotoxicity of various endodontic materials on stem cells of human apical papilla. Iran Endodontic J2016; 11: 17–22.
29.
YeattsABChoquetteDTFisherJP. Bioreactors to influence stem cell fate: augmentation of mesenchymal stem cell signaling pathways via dynamic culture systems. Biochim Biophys Acta2013; 1830: 2470–480.
