Zhiyi Gong scite author profile

Prenatal cannabis exposure (PCE) influences human brain development, but it is challenging to model PCE using animals and current cell culture techniques. Here, we developed a one-stop microfluidic platform to assemble and culture human cerebral organoids from human embryonic stem cells (hESC) to investigate the effect of PCE on early human brain development. By incorporating perfusable culture chambers, air-liquid interface, and one-stop protocol, this microfluidic platform can simplify the fabrication procedure, and produce a large number of organoids (169 organoids per 3.5 cm x 3.5 cm device area) without fusion, as compared with conventional fabrication methods. These one-stop microfluidic assembled cerebral organoids not only recapitulate early human brain structure, biology, and electrophysiology but also have minimal size variation and hypoxia. Under on-chip exposure to the psychoactive cannabinoid, delta-9tetrahydrocannabinol (THC), cerebral organoids exhibited reduced neuronal maturation, downregulation of cannabinoid receptor type 1 (CB1) receptors, and impaired neurite outgrowth. Moreover, transient on-chip THC treatment also decreased spontaneous firing in microfluidic assembled brain organoids. This one-stop microfluidic technique enables a simple, scalable, and repeatable organoid culture method that can be used not only for human brain organoids, but also for many other human organoids including liver, kidney, retina, and tumor organoids. This technology could be widely used in modeling brain and other organ development, developmental disorders, developmental pharmacology and toxicology, and drug screening.

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The acoustic droplet printing of functional tumor microenvironments

Chen

Jiang

Wei

et al. 2021

Lab Chip

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Enhanced performance of piezoelectric nanogenerator based on aligned nanofibers and three-dimensional interdigital electrodes

Zhang

Gui

et al. 2019

Nano Energy

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Acoustic Droplet Printing Tumor Organoids for Modeling Bladder Tumor Immune Microenvironment within a Week

Gong

Huang

Tang

et al. 2021

Adv Healthcare Materials

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Current organoid models are limited by the incapability of rapidly fabricating organoids that can mimic the immune microenvironment for a short term.Here, an acoustic droplet-based platform is presented to facilitate the rapid formation of tumor organoids, which retains the original tumor immune microenvironment and establishes a personalized bladder cancer tumor immunotherapy model. In combination with a hydrophobic substrate, the acoustic droplet printer can yield a large number of homogeneous and highly viable bladder tumor organoids in vitro within a week. The generated organoids consist of all components of bladder tumor, including diverse immune elements and tumor cells. By coculturing tumor organoids with autologous immune cells for 2 days, tumor reactive T cells are induced in vitro. Furthermore, it is also demonstrated that these tumor-reactive T cells can also enhance the killing efficiency of matched organoids. Because of the easy operation, repeatability, and stability, the proposed acoustic droplet platform will provide a reliable approach for personalized tumor immunotherapy.

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Rapid Microfluidic Formation of Uniform Patient-Derived Breast Tumor Spheroids

Gong

et al. 2020

ACS Appl. Bio Mater.

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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 cell numbers and components per droplet. After removal of the oil, large numbers of uniform tumor spheroids were formed within a few hours via Matrigel-supported cell selfassembly. Our microfluidic technique produces uniform-sized tumor spheroids in less than 1 day. This method was used to reproducibly and rapidly generate uniform-sized tumor spheroids derived from patients' breast tumor tissues. As a proof-of-concept application, this method was used to quickly evaluate cancer treatments. We demonstrated that our microfluidic patient-derived tumor cultures not only preserve the genetic characteristics of the original tumor tissue but also provide heterogeneous responses to targeted therapies within 2 days. We believe this method will enable a timely and reliable 3D in vitro culture model, which may be applicable to personalized treatment prediction, drug discovery, and toxicity testing.

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Zhiyi Gong

One-Stop Microfluidic Assembly of Human Brain Organoids To Model Prenatal Cannabis Exposure

The acoustic droplet printing of functional tumor microenvironments

Enhanced performance of piezoelectric nanogenerator based on aligned nanofibers and three-dimensional interdigital electrodes

Acoustic Droplet Printing Tumor Organoids for Modeling Bladder Tumor Immune Microenvironment within a Week

Rapid Microfluidic Formation of Uniform Patient-Derived Breast Tumor Spheroids

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