Cytocompatibility of nano-hydroxyapatite/bacterial cellulose nanocomposites and its residues
10.3969/j.issn.1673-8225.2010.03.007
- VernacularTitle:纳米羟基磷灰石/细菌纤维素复合材料及其降解物的细胞相容性评价
- Author:
Qi ZHENG
;
Tingfei XI
;
Yanmei CHEN
;
Zhaoxu WANG
;
Yizao WAN
;
Chuan GAO
- Publication Type:Journal Article
- From:
Chinese Journal of Tissue Engineering Research
2010;14(3):405-409
- CountryChina
- Language:Chinese
-
Abstract:
BACKGROUND: The nano-hydroxyapatite/bacterial cellulose (nHAP/BC) nanocomposites has a good prospect of application in bone tissue engineering, and the bone tissue engineered materials and its degradation products Should have excellent compatibility. This study further assessed DAN synthesis cycle using flow cytometry on the basis of evaluating cell compatibility by metabolic 3-(4, 5-dim ethylthiazo 1-2-y 1) -2, 5-Dipheny 1-2H-tetrazolium (MTT) assay. OBJECTIVE: To evaluate the cytocompatibility of a new-pattern nHAP/BC nanocomposites and its residues. METHODS: Effects of nHAP/BC nanocomposites and its residues on morphclogicel changes in osteoblasts were observed using in vitro cell culture method. Effects of nHAP/BC nanocomposites and its residues on osteoblast growth and prclifera'don were evaluated by MTT assay. Cell cycle phase changes were detected using flow cytometry to evaluate matsdal effects on cell proliferation on molecular levels. RESULTS AND CONCLUSION: The nHAP/BC nanocomposites and its residues had neither remarkable effects on cell morphology, nor significant inhibition on osteoblast growth and proliferation. Test of MTT cytotoxicity showed that the average cell proliferation rate was over 80% after treated with the material and its residues, with the cytotoxity grade of 1 (non-toxic). Flow cytometry indicated that the rate of G_0/G_1 was reduced, and the rates of S, G2/M were increased, and the synthesis of DNA was increased, the cellular growth and repair in osteoblasts was accelerated. These indicated that nHAP/BC nanocomposites have good cytocompatibility, and it will be safe and prospected scaffolds in bone tissue engineering.