Tumor-on-a-chip models combined with mini-tissues or organoids for engineering tumor tissues

被引：15

作者：

Hwangbo, Hanjun ^{[1
]}

Chae, Soojung ^{[1
]}

Kim, Wonjin ^{[1
]}

Jo, Seoyul ^{[1
]}

Kim, Geun Hyung ^{[1
]}

机构：

[1] Sungkyunkwan Univ SKKU SOM, Sch Med, Dept Precis Med, Suwon 16419, South Korea

来源：

THERANOSTICS | 2024年 / 14卷 / 01期

基金：

新加坡国家研究基金会;

关键词：

Tumor-on-a-chip; Tumor microenvironment; Organoids; Biofabrication; Cancer research; IN-VITRO; BIOPRINTING PROCESS; DRUG-DELIVERY; 3D; LADEN; FABRICATION; SPHEROIDS; CONSTRUCTS; SCAFFOLDS; CELLS;

D O I：

10.7150/thno.90093

中图分类号：

R-3 [医学研究方法]; R3 [基础医学];

学科分类号：

1001 ;

摘要：

The integration of tumor-on-a-chip technology with mini-tissues or organoids has emerged as a powerful approach in cancer research and drug development. This review provides an extensive examination of the diverse biofabrication methods employed to create mini-tissues, including 3D bioprinting, spheroids, microfluidic systems, and self-assembly techniques using cell-laden hydrogels. Furthermore, it explores various approaches for fabricating organ-on-a-chip platforms. This paper highlights the synergistic potential of combining these technologies to create tumor-on-a-chip models that mimic the complex tumor microenvironment and offer unique insights into cancer biology and therapeutic responses.

引用

页码：33 / 55

页数：23

共 163 条

[1] Establishment of a heart-on-a-chip microdevice based on human iPS cells for the evaluation of human heart tissue function
Abulaiti, Mosha
Yalikun, Yaxiaer
Murata, Kozue
Sato, Asako
Sami, Mustafa M.
Sasaki, Yuko
Fujiwara, Yasue
Minatoya, Kenji
Shiba, Yuji
Tanaka, Yo
Masumoto, Hidetoshi
[J]. SCIENTIFIC REPORTS, 2020, 10 (01)
[2] Paper-Based Cell Culture: Paving the Pathway for Liver Tissue Model Development on a Cellulose Paper Chip
Agarwal, Tarun
Borrelli, Mimi R.
Makvandi, Pooyan
Ashrafizadeh, Milad
Maiti, Tapas Kumar
[J]. ACS APPLIED BIO MATERIALS, 2020, 3 (07) : 3956 - 3974
[3] A novel lab-on-a-chip platform for spheroid metabolism monitoring
Alexander, Frank, Jr.
Eggert, Sebastian
Wiest, Joachim
[J]. CYTOTECHNOLOGY, 2018, 70 (01) : 375 - 386
[4] Recent Advances in 3D Printing of Biomedical Sensing Devices
Ali, Md Azahar
Hu, Chunshan
Yttri, Eric A.
Panat, Rahul
[J]. ADVANCED FUNCTIONAL MATERIALS, 2022, 32 (09)
[5] A Review of the Properties and Applications of Poly (Methyl Methacrylate) (PMMA)
Ali, Umar
Abd Karim, Khairil Juhanni Bt.
Buang, Nor Aziah
[J]. POLYMER REVIEWS, 2015, 55 (04) : 678 - 705
[6] 3D microfluidics via cyclic olefin polymer-based in situ direct laser writing
Alsharhan, Abdullah T.
Acevedo, Ruben
Warren, Roseanne
Sochol, Ryan D.
[J]. LAB ON A CHIP, 2019, 19 (17) : 2799 - 2810
[7] Anderson NM, 2020, CURR BIOL, V30, pR921, DOI 10.1016/j.cub.2020.06.081
[8] Tumor Microenvironment
Arneth, Borros
[J]. MEDICINA-LITHUANIA, 2020, 56 (01):
[9] Design and fabrication of a scalable liver-lobule-on-a-chip microphysiological platform
Banaeiyan, Amin A.
Theobald, Jannick
Paukstyte, Jurgita
Woelfl, Stefan
Adiels, Caroline B.
Goksor, Mattias
[J]. BIOFABRICATION, 2017, 9 (01)
[10] Engineering Breast Cancer Microenvironments and 3D Bioprinting
Belgodere, Jorge A.
King, Connor T.
Bursavich, Jacob B.
Burow, Matthew E.
Martin, Elizabeth C.
Jung, Jangwook P.
[J]. FRONTIERS IN BIOENGINEERING AND BIOTECHNOLOGY, 2018, 6

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