Chunhui Tian scite author profile

Chunhui Tian

5Publications

86Citation Statements Received

190Citation Statements Given

How they've been cited

152

How they cite others

196

190

Affiliations

University of Electronic Science and Technology of China, Indiana University Bloomington, National Engineering Research Center of Electromagnetic Radiation Control Materials

Publications

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Human Spinal Organoid-on-a-Chip to Model Nociceptive Circuitry for Pain Therapeutics Discovery

Cai

et al. 2021

Anal. Chem.

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The discovery of new pain therapeutics targeting human nociceptive circuitry is an emerging, exciting, and rewarding field. However, current models for evaluating prospective new therapeutics [e.g., animals and two-dimensional (2D) in vitro cultures] fail to fully recapitulate the complexity of human nociceptive neuron and dorsal horn neuron biology, significantly limiting the development of novel pain therapeutics. Here, we report human spinal organoid-on-a-chip devices for modeling the biology and electrophysiology of human nociceptive neurons and dorsal horn interneurons in nociceptive circuitry. Our device can be simply made through the integration of a membrane with a three-dimensional (3D)-printed organoid holder. By combining air−liquid interface culture and spinal organoid protocols, our devices can differentiate human stem cells into human sensori-spinal-cord organoids with dorsal spinal cord interneurons and sensory neurons. By easily transferring from culture well plates to the multiple-electrode array (MEA) system, our device also allows the plug-and-play measurement of organoid activity for testing nociceptive modulators (e.g., mustard oil, capsaicin, velvet ant venom, etc.). Our organoid-on-a-chip devices are cost-efficient, scalable, easy to use, and compatible with conventional well plates, allowing the plug-and-play measurement of spinal organoid electrophysiology. By the integration of human sensory-spinal-cord organoids with our organoid-on-a-chip devices, our method may hold the promising potential to screen and validate novel therapeutics for human pain medicine discovery.

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Acoustic metamaterials-driven transdermal drug delivery for rapid and on-demand management of acute disease

Cai

et al. 2023

Nat Commun

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Transdermal drug delivery provides convenient and pain-free self-administration for personalized therapy. However, challenges remain in treating acute diseases mainly due to their inability to timely administrate therapeutics and precisely regulate pharmacokinetics within a short time window. Here we report the development of active acoustic metamaterials-driven transdermal drug delivery for rapid and on-demand acute disease management. Through the integration of active acoustic metamaterials, a compact therapeutic patch is integrated for penetration of skin stratum corneum and active percutaneous transport of therapeutics with precise control of dose and rate over time. Moreover, the patch device quantitatively regulates the dosage and release kinetics of therapeutics and achieves better delivery performance in vivo than through subcutaneous injection. As a proof-of-concept application, we show our method can reverse life-threatening acute allergic reactions in a female mouse model of anaphylaxis via a multi-burst delivery of epinephrine, showing better efficacy than a fixed dosage injection of epinephrine, which is the current gold standard ‘self-injectable epinephrine’ strategy. This innovative method may provide a promising means to manage acute disease for personalized medicine.

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Understanding Immune‐Driven Brain Aging by Human Brain Organoid Microphysiological Analysis Platform

Song

Tian

et al. 2022

Advanced Science

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The aging of the immune system drives systemic aging and the pathogenesis of age‐related diseases. However, a significant knowledge gap remains in understanding immune‐driven aging, especially in brain aging, due to the limited current in vitro models of neuroimmune interaction. Here, the authors report the development of a human brain organoid microphysiological analysis platform (MAP) to discover the dynamic process of immune‐driven brain aging. The organoid MAP is created by 3D printing that confines organoid growth and facilitates cell and nutrition perfusion, promoting organoid maturation and their committment to forebrain identity. Dynamic rocking flow is incorporated into the platform that allows to perfuse primary monocytes from young (20 to 30‐year‐old) and aged (>60‐year‐old) donors and culture human cortical organoids to model neuroimmune interaction. The authors find that the aged monocytes increase infiltration and promote the expression of aging‐related markers (e.g., higher expression of p16) within the human cortical organoids, indicating that aged monocytes may drive brain aging. The authors believe that the organoid MAP may provide promising solutions for basic research and translational applications in aging, neural immunological diseases, autoimmune disorders, and cancer.

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Study on the mechanism of afterglow in CsI: Tl and the afterglow suppression in CsI: Tl, Eu

Tian

Liu

Xie

et al. 2019

J Radioanal Nucl Chem

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A plasmon-enhanced broadband absorber fabricated by black silicon with self-assembled gold nanoparticles

Song

Liu

et al. 2020

J Mater Sci: Mater Electron

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Chunhui Tian

Human Spinal Organoid-on-a-Chip to Model Nociceptive Circuitry for Pain Therapeutics Discovery

Acoustic metamaterials-driven transdermal drug delivery for rapid and on-demand management of acute disease

Understanding Immune‐Driven Brain Aging by Human Brain Organoid Microphysiological Analysis Platform

Study on the mechanism of afterglow in CsI: Tl and the afterglow suppression in CsI: Tl, Eu

A plasmon-enhanced broadband absorber fabricated by black silicon with self-assembled gold nanoparticles

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