Polymerization‐Mediated Multifunctionalization of Living Cells for Enhanced Cell‐Based Therapy

Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell‐based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply...

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Published in	Advanced materials (Weinheim) Vol. 33; no. 13; pp. e2007379 - n/a
Main Authors	Pan, Chao, Li, Juanjuan, Hou, Weiliang, Lin, Sisi, Wang, Lu, Pang, Yan, Wang, Yufeng, Liu, Jinyao
Format	Journal Article
Language	English
Published	Germany Wiley Subscription Services, Inc 01.04.2021
Subjects	Animals Bacteria Bioavailability Cell- and Tissue-Based Therapy - methods Cells (biology) cell‐based therapy Coatings colitis Colitis - chemically induced Colitis - drug therapy Decoration Dopamine Dopamine - chemistry Gastrointestinal Microbiome Humans Inflammatory bowel disease Materials science Mice multifunctionalization oral delivery Polymerization Polymers - chemistry surface decoration Therapy surface decoration multifunctionalization colitis cell-based therapy oral delivery
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Abstract	Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell‐based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply co‐depositing with dopamine under a cytocompatible condition, various functional small molecules and polymers can be encoded to form a multifunctional coating on a cell's surface. The accessibility and versatility of this method to decorate diverse cells, including bacteria, fungi, and mammalian cells is demonstrated. With the ability to tune surface functions, ligand co‐deposited gut microbiota is prepared as oral therapeutics for targeted treatment of colitis. Given the dual cytoprotective and targeting effects of the coating, decorated cells show more than 30‐times higher bioavailability in the gut and fourfold higher accumulation in the inflamed tissue in comparison with those of uncoated bacteria. Multimodal therapeutic cells further validate strikingly increased treatment efficacy over clinical aminosalicylic acid in colitis mice. Decorating with multifunctional coatings proposes a robust platform for developing multimodal cells for enhanced cell‐based therapy. Surface decoration of living cells by exogenous substances offers a unique tool for tuning cell behaviors, which plays critical roles in cell‐based therapy. A facile, yet versatile approach for decorating individual living cells with multimodal coatings by simply co‐depositing dopamine with functional small molecules or polymers is reported. Decorated cells show strikingly enhanced treatment efficacy in colitis mice.
AbstractList	Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell-based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply co-depositing with dopamine under a cytocompatible condition, various functional small molecules and polymers can be encoded to form a multifunctional coating on a cell's surface. The accessibility and versatility of this method to decorate diverse cells, including bacteria, fungi, and mammalian cells is demonstrated. With the ability to tune surface functions, ligand co-deposited gut microbiota is prepared as oral therapeutics for targeted treatment of colitis. Given the dual cytoprotective and targeting effects of the coating, decorated cells show more than 30-times higher bioavailability in the gut and fourfold higher accumulation in the inflamed tissue in comparison with those of uncoated bacteria. Multimodal therapeutic cells further validate strikingly increased treatment efficacy over clinical aminosalicylic acid in colitis mice. Decorating with multifunctional coatings proposes a robust platform for developing multimodal cells for enhanced cell-based therapy. Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell-based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply co-depositing with dopamine under a cytocompatible condition, various functional small molecules and polymers can be encoded to form a multifunctional coating on a cell's surface. The accessibility and versatility of this method to decorate diverse cells, including bacteria, fungi, and mammalian cells is demonstrated. With the ability to tune surface functions, ligand co-deposited gut microbiota is prepared as oral therapeutics for targeted treatment of colitis. Given the dual cytoprotective and targeting effects of the coating, decorated cells show more than 30-times higher bioavailability in the gut and fourfold higher accumulation in the inflamed tissue in comparison with those of uncoated bacteria. Multimodal therapeutic cells further validate strikingly increased treatment efficacy over clinical aminosalicylic acid in colitis mice. Decorating with multifunctional coatings proposes a robust platform for developing multimodal cells for enhanced cell-based therapy.Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell-based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply co-depositing with dopamine under a cytocompatible condition, various functional small molecules and polymers can be encoded to form a multifunctional coating on a cell's surface. The accessibility and versatility of this method to decorate diverse cells, including bacteria, fungi, and mammalian cells is demonstrated. With the ability to tune surface functions, ligand co-deposited gut microbiota is prepared as oral therapeutics for targeted treatment of colitis. Given the dual cytoprotective and targeting effects of the coating, decorated cells show more than 30-times higher bioavailability in the gut and fourfold higher accumulation in the inflamed tissue in comparison with those of uncoated bacteria. Multimodal therapeutic cells further validate strikingly increased treatment efficacy over clinical aminosalicylic acid in colitis mice. Decorating with multifunctional coatings proposes a robust platform for developing multimodal cells for enhanced cell-based therapy. Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in cell‐based therapy. Here, a facile yet versatile approach for decorating individual living cells with multimodal coatings is reported. By simply co‐depositing with dopamine under a cytocompatible condition, various functional small molecules and polymers can be encoded to form a multifunctional coating on a cell's surface. The accessibility and versatility of this method to decorate diverse cells, including bacteria, fungi, and mammalian cells is demonstrated. With the ability to tune surface functions, ligand co‐deposited gut microbiota is prepared as oral therapeutics for targeted treatment of colitis. Given the dual cytoprotective and targeting effects of the coating, decorated cells show more than 30‐times higher bioavailability in the gut and fourfold higher accumulation in the inflamed tissue in comparison with those of uncoated bacteria. Multimodal therapeutic cells further validate strikingly increased treatment efficacy over clinical aminosalicylic acid in colitis mice. Decorating with multifunctional coatings proposes a robust platform for developing multimodal cells for enhanced cell‐based therapy. Surface decoration of living cells by exogenous substances offers a unique tool for tuning cell behaviors, which plays critical roles in cell‐based therapy. A facile, yet versatile approach for decorating individual living cells with multimodal coatings by simply co‐depositing dopamine with functional small molecules or polymers is reported. Decorated cells show strikingly enhanced treatment efficacy in colitis mice.
Author	Wang, Yufeng Wang, Lu Lin, Sisi Pang, Yan Hou, Weiliang Li, Juanjuan Liu, Jinyao Pan, Chao
Author_xml	– sequence: 1 givenname: Chao surname: Pan fullname: Pan, Chao organization: Shanghai Jiao Tong University – sequence: 2 givenname: Juanjuan surname: Li fullname: Li, Juanjuan organization: Shanghai Jiao Tong University – sequence: 3 givenname: Weiliang surname: Hou fullname: Hou, Weiliang organization: Shanghai Jiao Tong University – sequence: 4 givenname: Sisi surname: Lin fullname: Lin, Sisi organization: Shanghai Jiao Tong University – sequence: 5 givenname: Lu surname: Wang fullname: Wang, Lu organization: Shanghai Jiao Tong University – sequence: 6 givenname: Yan surname: Pang fullname: Pang, Yan organization: Shanghai Jiao Tong University – sequence: 7 givenname: Yufeng surname: Wang fullname: Wang, Yufeng organization: The University of Hong Kong – sequence: 8 givenname: Jinyao orcidid: 0000-0002-6044-2033 surname: Liu fullname: Liu, Jinyao email: jyliu@sjtu.edu.cn organization: Shanghai Jiao Tong University
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Snippet	Surface decoration of living cells by exogenous substances offers a unique tool for understanding and tuning cell behaviors, which plays a critical role in...
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SubjectTerms	Animals Bacteria Bioavailability Cell- and Tissue-Based Therapy - methods Cells (biology) cell‐based therapy Coatings colitis Colitis - chemically induced Colitis - drug therapy Decoration Dopamine Dopamine - chemistry Gastrointestinal Microbiome Humans Inflammatory bowel disease Materials science Mice multifunctionalization oral delivery Polymerization Polymers - chemistry surface decoration Therapy
Title	Polymerization‐Mediated Multifunctionalization of Living Cells for Enhanced Cell‐Based Therapy
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