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Your search keyword '"Wu, Sareina Chiung‐Yuan"' showing total 13 results
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13 results on '"Wu, Sareina Chiung‐Yuan"'

1. Manufacturing CD20/CD19-targeted iCasp9 regulatable CAR-TSCM cells using a Quantum pBac-based CAR-T engineering system.

Author

Chang, Peter S., Chen, Yi-Chun, Hua, Wei-Kai, Hsu, Jeff C., Tsai, Jui-Cheng, Huang, Yi-Wun, Kao, Yi-Hsin, Wu, Pei-Hua, Wang, Po-Nan, Chang, Yi-Fang, Chang, Ming-Chih, Chang, Yu-Cheng, Jian, Shiou-Ling, Lai, Jiann-Shiun, Lai, Ming-Tain, Yang, Wei-Cheng, Shen, Chia-Ning, Wen, Kuo-Lan Karen, and Wu, Sareina Chiung-Yuan

Subjects
PATIENT experience, CHIMERIC antigen receptors, CELL physiology, DISEASE progression, CLINICAL medicine
Abstract

CD19-targeted chimeric antigen receptor (CAR) T cell therapies have driven a paradigm shift in the treatment of relapsed/refractory B-cell malignancies. However, >50% of CD19-CAR-T-treated patients experience progressive disease mainly due to antigen escape and low persistence. Clinical prognosis is heavily influenced by CAR-T cell function and systemic cytokine toxicities. Furthermore, it remains a challenge to efficiently, cost-effectively, and consistently manufacture clinically relevant numbers of virally engineered CAR-T cells. Using a highly efficient piggyBac transposon-based vector, Quantum pBac™ (qPB), we developed a virus-free cell-engineering system for development and production of multiplex CAR-T therapies. Here, we demonstrate in vitro and in vivo that consistent, robust and functional CD20/CD19 dual-targeted CAR-T stem cell memory (CAR-TSCM) cells can be efficiently produced for clinical application using qPB™. In particular, we showed that qPB™-manufactured CAR-T cells from cancer patients expanded efficiently, rapidly eradicated tumors, and can be safely controlled via an iCasp9 suicide gene-inducing drug. Therefore, the simplicity of manufacturing multiplex CAR-T cells using the qPB™ system has the potential to improve efficacy and broaden the accessibility of CAR-T therapies. [ABSTRACT FROM AUTHOR]

Published
2024
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2. QuantumpBac: An effective, high‐capacity piggyBac‐based gene integration vector system for unlocking gene therapy potential

Author

Hua, Wei‐Kai, primary, Hsu, Jeff C., additional, Chen, Yi‐Chun, additional, Chang, Peter S., additional, Wen, Kuo‐Lan Karen, additional, Wang, Po‐Nan, additional, Yang, Wei‐Cheng, additional, Shen, Chia‐Ning, additional, Yu, Yi‐Shan, additional, Chen, Ying‐Chun, additional, Cheng, I‐Cheng, additional, and Wu, Sareina Chiung‐Yuan, additional

Published
2023
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4. Quantum CART(qCART), apiggyBac-basedsystem for development and production of virus-free multiplex CAR-T cell therapy

Author

Chen, Yi-Chun, primary, Hua, Wei-Kai, additional, Hsu, Jeff C., additional, Chang, Peter S., additional, Wen, Kuo-Lan Karen, additional, Huang, Yi-Wun, additional, Tsai, Jui-Cheng, additional, Kao, Yi-Hsin, additional, Wu, Pei-Hua, additional, Wang, Po-Nan, additional, Chen, Ke-Fan, additional, Liao, Wan-Ting, additional, and Wu, Sareina Chiung-Yuan, additional

Published
2022
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5. Manufacturing CD20/CD19-targeted iCasp9 regulatable CAR-TSCMcells usingqCART, theQuantum pBac-based CAR-T system

Author

Chang, Peter S., primary, Chen, Yi-Chun, additional, Hua, Wei-Kai, additional, Hsu, Jeff C., additional, Tsai, Jui-Cheng, additional, Huang, Yi-Wun, additional, Kao, Yi-Hsin, additional, Wu, Pei-Hua, additional, Chang, Yi-Fang, additional, Chang, Ming-Chih, additional, Chang, Yu-Cheng, additional, Jian, Shiou-Ling, additional, Lai, Jiann-Shiun, additional, Lai, Ming-Tain, additional, Yang, Wei-Cheng, additional, Shen, Chia-Ning, additional, Wen, Kuo-Lan Karen, additional, and Wu, Sareina Chiung-Yuan, additional

Published
2022
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8. Comparison of chimeric antigen receptor‐T cell‐mediated cytotoxicity assays with suspension tumor cells using plate‐based image cytometry method.

Author

Sun, Yu‐Jun, Chen, Yi‐Chun, Hua, Wei‐Kai, Wu, Sareina Chiung‐Yuan, and Chan, Leo Li‐Ying

Abstract

In the recent decade, chimeric antigen receptor (CAR)‐T cell therapy has revolutionized strategies for cancer treatments due to its highly effective clinical efficacy and response for B cell malignancies. The success of CAR‐T cell therapy has stimulated the increase in the research and development of various CAR constructs to target different tumor types. Therefore, a robust and efficient in vitro potency assay is needed to quickly identify potential CAR gene design from a library of construct candidates. Image cytometry methodologies have been utilized for various CAR‐T cell‐mediated cytotoxicity assay using different fluorescent labeling methods, mainly due to their ease‐of‐use, ability to capture cell images for verification, and higher throughput performance. In this work, we employed the Celigo Image Cytometer to evaluate and compare two CAR‐T cell‐mediated cytotoxicity assays using GFP‐expressing or fluorescent dye‐labeled myeloma and plasmacytoma cells. The GFP‐based method demonstrated higher sensitivity in detecting CAR‐T cell‐mediated cytotoxicity when compared to the CMFDA/DAPI viability method. We have established the criteria and considerations for the selection of cytotoxicity assays that are fit‐for‐purpose to ensure the results produced are meaningful for the specific testing conditions. [ABSTRACT FROM AUTHOR]

Published
2023
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13. Transposon-based vector systems for gene therapy clinical trials: challenges and considerations.

Author

Meir YJ and Wu SC

Subjects
Clinical Trials as Topic, Genetic Vectors, Humans, DNA Transposable Elements, Genetic Therapy methods, Nerve Tissue Proteins, Transposases
Abstract

Much progress has been made in gene therapy, but significant challenges remain. One is development of a range of different tools that can be used for different therapeutic purposes. Another is site-specific gene targeting for safe and faithful therapeutic gene expression. Viruses have long been considered the most promising tools for human gene therapy. However, fatal side effects associated with viral vectors have hampered their clinical application. DNA transposons, widely utilized for decades as genetic tools in plants and insects, are now emerging as viable vectors for gene therapy. In this article, we will give a brief review of the adverse effects associated with virus-based gene therapy followed by a glimpse of the adeno-associated virus vector system, which is currently the most promising viral vector for gene therapy. The development of DNA transposon-based gene delivery systems and the advantages and limits of the most commonly used DNA transposon systems, Sleeping Beauty, Tol2, and piggyBac, will be extensively discussed Finally, we will focus on the most promising transposon system for gene therapy, piggyBac. Challenges and considerations for advancing piggyBac for therapeutic application will be critically addressed.

Published
2011

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