2020
DOI: 10.1021/acsabm.0c00768
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Rapid Microfluidic Formation of Uniform Patient-Derived Breast Tumor Spheroids

Abstract: Breast cancer is a highly complex, heterogeneous, and multifactorial disease that poses challenges for rapid and efficient treatment and development of personalized therapy. Here, we describe a rapid and reliable method to generate threedimensional (3D) tumor spheroids in vitro that recapitulate an individual patient's tumor for testing treatments. By employing droplet microfluidics and scaffold materials, tumor cells were encapsulated into a large number of Matrigel-in-oil droplets with precise control over c… Show more

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Cited by 34 publications
(35 citation statements)
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“…[5] Animal models and 2D cell culture models are widely used in the study of human diseases, whereas animal models are limited by the physiological differences between humans and animals, which makes it difficult to simulate the histological and pathological characteristics of patients; while 2D cell culture models cannot reflect the complexity and cellular diversity of 3D solid tumors. [6][7][8][9] Therefore, it is of great significance to construct a 3D model in vitro to reproduce the physiological characteristics of patients and realistically simulate the tumor microenvironment.…”
Section: Introductionmentioning
confidence: 99%
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“…[5] Animal models and 2D cell culture models are widely used in the study of human diseases, whereas animal models are limited by the physiological differences between humans and animals, which makes it difficult to simulate the histological and pathological characteristics of patients; while 2D cell culture models cannot reflect the complexity and cellular diversity of 3D solid tumors. [6][7][8][9] Therefore, it is of great significance to construct a 3D model in vitro to reproduce the physiological characteristics of patients and realistically simulate the tumor microenvironment.…”
Section: Introductionmentioning
confidence: 99%
“…Organoid is a miniaturized organ model cultured in vitro in three dimensions, capable of recreating the internal complexity of tissues, derived from cells from patient tissues, embryonic stem cells, or induced pluripotent stem cells through selforganized 3D culture, [10][11][12] while some organoids can be constructed by various biofabrication strategies, such as 3D bioprinting methods and microfluidic chips. [2,6] Organoid models have been used in a variety of tumor biology studies. [13][14][15] Due to the highly consistent pathological characteristics of the tumor organoid and the patient's tumor, they are mainly used for personalized and precise treatments for patients, as well as for pharmacokinetic experiments before the drug enters clinical trials and researches on tumor mechanisms, cell migration, and metastatic.…”
Section: Introductionmentioning
confidence: 99%
“…This can enable multiple cell type coā€cultures in predefined microenvironments, that better simulate in vivo tissue complexity, thus making possible the development of high throughput platforms for drug treatments tailored to patients (Figure 2d ). [ 64 ]…”
Section: Introductionmentioning
confidence: 99%
“…[12,13] Furthermore, microfluidic integration on a large-scale enables highthroughput operation and investigation of cell/tumor samples. [14,15] In the past several decades, research scholars around the globe have developed many microfluidic tumor manipulation systems that depend on passive microwells, [16][17][18][19] microdroplets, [20,21] microhydrogels, [22][23][24] active pneumatic microstructures (PĪ¼Ss), [25][26][27] as well as 3D acoustic tweezers [28,29] for controllable 3D tumor cultivation. These advances have provided several beneficial properties, such as facile and efficient operation, homogeneous and large-scale tumor production, and throughput monitoring.…”
Section: Introductionmentioning
confidence: 99%
“…These advances have provided several beneficial properties, such as facile and efficient operation, homogeneous and large-scale tumor production, and throughput monitoring. In addition, microfluidic tumor platforms have been widely applied for exploration of the tumor microenvironment, [16,24,30,31] tumor progression, [21,32] chemotherapy, [18][19][20]27,28,33] imaging, [25,34] and tumor-specific molecule detection. [35] However, microfluidic progress enabling the real-time detection and synchronous evaluation of 3D tumor responses to drugs at various concentrations by using a single device, was limited.…”
Section: Introductionmentioning
confidence: 99%