循环肿瘤细胞                        
                
                                
                        
                            生物界面                        
                
                                
                        
                            材料科学                        
                
                                
                        
                            纳米棒                        
                
                                
                        
                            脱氧核酶                        
                
                                
                        
                            检出限                        
                
                                
                        
                            纳米技术                        
                
                                
                        
                            DNA                        
                
                                
                        
                            外周血                        
                
                                
                        
                            生物物理学                        
                
                                
                        
                            癌症研究                        
                
                                
                        
                            转移                        
                
                                
                        
                            化学                        
                
                                
                        
                            癌症                        
                
                                
                        
                            生物化学                        
                
                                
                        
                            色谱法                        
                
                                
                        
                            生物                        
                
                                
                        
                            免疫学                        
                
                                
                        
                            遗传学                        
                
                        
                    
            作者
            
                Jinxiang Li,Yuan Yugang,Hongyu Gan,Dong Chen,Bin Cao,Jinliang Ni,Xueliang Li,Wenjie Gu,Chunyuan Song,Lianhui Wang            
         
                    
        
    
            
            标识
            
                                    DOI:10.1021/acsami.2c06005
                                    
                                
                                 
         
        
                
            摘要
            
            Circulating tumor cells (CTCs) are indicative of tumorigenesis, metastasis, and recurrence; however, it is still a great challenge to efficiently analyze the extremely rare CTCs in peripheral blood. Herein, a novel nanobiointerface integrating high affinities of arrayed silver nanorods (Ag NRs) and double-tetrahedral DNA (DTDN) probes by a clever strategy is proposed for the efficient capture, highly sensitive detection, and nondestructive release of CTCs. Under the optimal conditions, the DTDN-probe-functionalized Ag NRs nanobiointerface can capture 90.2% of SGC-7901 cells in PBS, and the capture efficiency is 2.8 times and 50 times those of a DTDN-probe-functionalized Ag film and unfunctionalized Ag NRs, respectively, benefiting from the nanorough interface of the Ag NRs array and multivalent recognition of the DTDN probe. In addition, 93.4% of cells was released via Zn2+-assisted DNAzyme cleavage, and the viability of the postreleased CTCs is about 98.0%. The potential practicality of the nanobiointerface for testing CTCs in blood was further characterized by spiking SGC-7901 cells in leukocytes collected from human blood, and the results show that 83.8% capture efficiency, 91.2% release efficiency, and single-cell detection limit were achieved, which indicates that the nanobiointerface has great potential in clinical applications for reliable CTC analyses.
         
            
 
                 
                
                    
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