Microdissected "cuboids" for Microfluidic Drug Testing of Intact Tissues

Overview

Journal Lab Chip

Publisher Royal Society of Chemistry

Specialties Biotechnology
Chemistry

Date 2020 Nov 11

PMID 33174580

Citations 20

Authors

Lisa F Horowitz

Adan D Rodriguez

Allan Au-Yeung

Kevin W Bishop

Lindsey A Barner

Gargi Mishra

Aashik Raman

Priscilla Delgado

Jonathan T C Liu

Taranjit S Gujral

Mehdi Mehrabi

Mengsu Yang

Robert H Pierce

Albert Folch

Affiliations

Soon will be listed here.

Abstract

As preclinical animal tests often do not accurately predict drug effects later observed in humans, most drugs under development fail to reach the market. Thus there is a critical need for functional drug testing platforms that use human, intact tissues to complement animal studies. To enable future multiplexed delivery of many drugs to one small biopsy, we have developed a multi-well microfluidic platform that selectively treats cuboidal-shaped microdissected tissues or "cuboids" with well-preserved tissue microenvironments. We create large numbers of uniformly-sized cuboids by semi-automated sectioning of tissue with a commercially available tissue chopper. Here we demonstrate the microdissection method on normal mouse liver, which we characterize with quantitative 3D imaging, and on human glioma xenograft tumors, which we evaluate after time in culture for viability and preservation of the microenvironment. The benefits of size uniformity include lower heterogeneity in future biological assays as well as facilitation of their physical manipulation by automation. Our prototype platform consists of a microfluidic circuit whose hydrodynamic traps immobilize the live cuboids in arrays at the bottom of a multi-well plate. Fluid dynamics simulations enabled the rapid evaluation of design alternatives and operational parameters. We demonstrate the proof-of-concept application of model soluble compounds such as dyes (CellTracker, Hoechst) and the cancer drug cisplatin. Upscaling of the microfluidic platform and microdissection method to larger arrays and numbers of cuboids could lead to direct testing of human tissues at high throughput, and thus could have a significant impact on drug discovery and personalized medicine.

Citing Articles

Vascularised organoids: Recent advances and applications in cancer research.

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Microfluidics as a promising technology for personalized medicine.

Oushyani Roudsari Z, Esmaeili Z, Nasirzadeh N, Heidari Keshel S, Sefat F, Bakhtyari H Bioimpacts. 2025; 15:29944.

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Microfluidic Modulation of Microvasculature in Microdissected Tumors.

Nguyen T, Horowitz L, Nguyen B, Lockhart E, Zhu S, Gujral T bioRxiv. 2024; .

PMID: 39386436 PMC: 11463410. DOI: 10.1101/2024.09.26.615278.

Label-free, real-time monitoring of cytochrome C drug responses in microdissected tumor biopsies with a multi-well aptasensor platform.

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