Characterizing circulating tumor cells using affinity-based microfluidic capture and AFM-based biomechanics

被引：5

作者：

Deliorman, Muhammedin ^{[1
]}

Glia, Ayoub ^{[1
]}

Qasaimeh, Mohammad A. ^{[1
,2
]}

机构：

[1] New York Univ Abu Dhabi NYUAD, Div Engn, POB 129188, Abu Dhabi, U Arab Emirates

[2] NYU, Tendon Sch Engn, Brooklyn, NY 11201 USA

来源：

STAR PROTOCOLS | 2022年 / 3卷 / 02期

关键词：

Atomic Force Microscopy (AFM); Biotechnology and bioengineering; Cell isolation; Single Cell;

D O I：

10.1016/j.xpro.2022.101433

中图分类号：

Q5 [生物化学];

学科分类号：

071010 ; 081704 ;

摘要：

Elasticity and bio-adhesiveness of circulating tumor cells (CTCs) are important biomarkers of cancer. CTCs are rare in blood, thus their capture and atomic force microscopy (AFM)-based biomechanical characterization require use of multi-functional microfluidic device. Here, we describe procedures for fabrication of such device, AFM-Chip, and give details on its use in affinity-based CTC capture, and integration with AFM via reversable physical assembly. In the AFM- Chip, CTC capture is efficient, and transition to AFM characterization is seamless with minimal cell loss. For complete details on the use and execution of this protocol, please refer to Deliorman et al. (2020).

引用

页数：20

共 17 条

[1] Nanorheology of living cells measured by AFM-based force-distance curves
Garcia, Pablo D.
Guerrero, Carlos R.
Garcia, Ricardo
NANOSCALE, 2020, 12 (16) : 9133 - 9143
[2] Vibration Assisted AFM-Based Nanomachining under Elevated Temperatures using Soft and Stiff Probes
Zhou, Huimin
Deng, Jia
48TH SME NORTH AMERICAN MANUFACTURING RESEARCH CONFERENCE, NAMRC 48, 2020, 48 : 508 - 513
[3] The Combination of Immunomagnetic Bead-Based Cell Isolation and Optically Induced Dielectrophoresis (ODEP)-Based Microfluidic Device for the Negative Selection-Based Isolation of Circulating Tumor Cells (CTCs)
Chu, Po-Yu
Hsieh, Chia-Hsun
Wu, Min-Hsien
FRONTIERS IN BIOENGINEERING AND BIOTECHNOLOGY, 2020, 8
[4] The Utilization of Optically Induced Dielectrophoresis (ODEP)-Based Cell Manipulation in a Microfluidic System for the Purification and Sorting of Circulating Tumor Cells (CTCs) with Different Sizes
Chu, Po-Yu
Nguyen, Thi Ngoc Anh
Wu, Ai-Yun
Huang, Po-Shuan
Huang, Kai-Lin
Liao, Chia-Jung
Hsieh, Chia-Hsun
Wu, Min-Hsien
MICROMACHINES, 2023, 14 (12)
[5] Spectrally Combined Encoding for Profiling Heterogeneous Circulating Tumor Cells Using a Multifunctional Nanosphere-Mediated Microfluidic Platform
Wu, Ling-Ling
Zhang, Zhi-Ling
Tang, Man
Zhu, Dong-Liang
Dong, Xiao-Juan
Hu, Jiao
Qi, Chu-Bo
Tang, Hong-Wu
Pang, Dai-Wen
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2020, 59 (28) : 11240 - 11244
[6] Integrative Analysis and Machine Learning based Characterization of Single Circulating Tumor Cells
Iyer, Arvind
Gupta, Krishan
Sharma, Shreya
Hari, Kishore
Lee, Yi Fang
Ramalingam, Neevan
Yap, Yoon Sim
West, Jay
Bhagat, Ali Asgar
Subramani, Balaram Vishnu
Sabuwala, Burhanuddin
Tan, Tuan Zea
Thiery, Jean Paul
Jolly, Mohit Kumar
Ramalingam, Naveen
Sengupta, Debarka
JOURNAL OF CLINICAL MEDICINE, 2020, 9 (04)
[7] Linking Metastatic Behavior and Metabolic Heterogeneity of Circulating Tumor Cells at Single-Cell Level Using an Integrative Microfluidic System
Hou, Ying
Lin, Jiaxu
Yao, Hongren
Wu, Zengnan
Lin, Yongning
Lin, Jin-Ming
ADVANCED SCIENCE, 2025,
[8] Aptamer-Based Methods for Detection of Circulating Tumor Cells and Their Potential for Personalized Diagnostics
Zamay, Anna S.
Zamay, Galina S.
Kolovskaya, Olga S.
Zamay, Tatiana N.
Berezovski, Maxim V.
ISOLATION AND MOLECULAR CHARACTERIZATION OF CIRCULATING TUMOR CELLS, 2017, 994 : 67 - 81
[9] Towards single-cell genome analysis of circulating tumor cells based on microcavity array
Yoshino, Tomoko
Kanbara, Hisashige
Negishi, Ryo
Takai, Kaori
Matsunaga, Tadashi
Tanaka, Tsuyoshi
2016 WORLD AUTOMATION CONGRESS (WAC), 2016,
[10] Separation and Analysis of Rare Tumor Cells in Various Body Fluids Based on Microfluidic Technology for Clinical Applications
Xu, Chang
Du, Dexin
Han, Zhaojun
Si, Haibin
Li, Wei
Li, Lu
Tang, Bo
ANALYTICAL CHEMISTRY, 2025,

← 1 2 →