遗传 ›› 2021, Vol. 43 ›› Issue (2): 108-117.doi: 10.16288/j.yczz.20-363
王卓1(
), 申笑涵1, 施奇惠1()
收稿日期:2020-12-01
出版日期:2021-02-16
发布日期:2021-01-22
基金资助:
Zhuo Wang1(), Xiaohan Shen1, Qihui Shi1()
Received:2020-12-01
Online:2021-02-16
Published:2021-01-22
Supported by:摘要:
随着单细胞基因组测序技术的建立与发展,对细胞基因组特征的分析进入了单细胞水平。单细胞的基因组分辨率不但使研究人员能够在单细胞尺度上分析肿瘤细胞的异质性,也使得传统上难以检测的稀有细胞的基因组研究成为可能。这些稀有细胞往往具有重要的生物学意义或临床价值,如癌症患者血液中循环肿瘤细胞(circulating tumor cell, CTC)的基因组检测或三代试管婴儿植入前胚胎细胞的遗传缺陷诊断与筛查(preimplantation genetic diagnosis/screening, PGD/PGS)。本文总结了近年来发展的各种单细胞基因组扩增技术及其优缺点,并介绍了单细胞基因组测序技术在肿瘤生物学和临床检测中的应用,以期为单细胞基因组测序技术在临床检测中应用开发提供参考。
王卓, 申笑涵, 施奇惠. 单细胞基因组测序技术新进展及其在生物医学中的应用[J]. 遗传, 2021, 43(2): 108-117.
Zhuo Wang, Xiaohan Shen, Qihui Shi.
表1
单细胞分离技术优缺点比较"
| 技术方式 | 分选功能 | 通量 | 费用 | 自动化 | 操作难易 | 效率 |
|---|---|---|---|---|---|---|
| 口吸管或显微操作 | 不可分选 | 低 | 低 | 人工 | 难 | 低 |
| FACS | 可分选 | 高 | 低 | 自动化 | 容易 | 高 |
| LCM | 可分选 | 低 | 高 | 半自动化 | 难 | 低 |
| 微流控芯片 | 不可分选 | 高 | 低 | 自动化 | 容易 | 高 |
图1
单细胞全基因组扩增技术的发展 A:单细胞全基因组扩增技术发展时间轴;B:人工单细胞全基因组扩增技术;C:自动化单细胞基因组扩增技术。"
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