Biopolymeric Coacervate Microvectors for the Delivery of Functional Proteins to Cells

The extent to which biologic payloads can be effectively delivered to cells is a limiting factor in the development of new therapies. Limitations arise from the lack of pharmacokinetic stability of biologics in vivo. Encapsulating biologics in a protective delivery vector has the potential to improv...

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Veröffentlicht in:	Advanced biosystems 2020-11, Vol.4 (11), p.e2000101-n/a
Hauptverfasser:	Xiao, Wenjin, Jakimowicz, Monika D., Zampetakis, Ioannis, Neely, Sarah, Scarpa, Fabrizio, Davis, Sean A., Williams, David S., Perriman, Adam W.
Format:	Artikel
Sprache:	eng
Schlagworte:	Amylose - chemistry biologics Biopolymers - chemistry Bone Morphogenetic Protein 2 - chemistry Bone Morphogenetic Protein 2 - pharmacokinetics Bone Morphogenetic Protein 2 - pharmacology Cell Differentiation - drug effects Cells, Cultured complex coacervates drug delivery Drug Delivery Systems - methods Humans Mesenchymal Stem Cells - metabolism microvectors protein delivery
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container_issue	11
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container_title	Advanced biosystems
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creator	Xiao, Wenjin Jakimowicz, Monika D. Zampetakis, Ioannis Neely, Sarah Scarpa, Fabrizio Davis, Sean A. Williams, David S. Perriman, Adam W.
description	The extent to which biologic payloads can be effectively delivered to cells is a limiting factor in the development of new therapies. Limitations arise from the lack of pharmacokinetic stability of biologics in vivo. Encapsulating biologics in a protective delivery vector has the potential to improve delivery profile and enhance performance. Coacervate microdroplets are developed as cell‐mimetic materials with established potential for the stabilization of biological molecules, such as proteins and nucleic acids. Here, the development of biodegradable coacervate microvectors (comprising synthetically modified amylose polymers) is presented, for the delivery of biologic payloads to cells. Amylose‐based coacervate microdroplets are stable under physiological conditions (e.g., temperature and ionic strength), are noncytotoxic owing to their biopolymeric structure, spontaneously interacted with the cell membrane, and are able to deliver and release proteinaceous payloads beyond the plasma membrane. In particular, myoglobin, an oxygen storage and antioxidant protein, is successfully delivered into human mesenchymal stem cells (hMSCs) within 24 h. Furthermore, coacervate microvectors are implemented for the delivery of human bone morphogenetic protein 2 growth factor, inducing differentiation of hMSCs into osteoprogenitor cells. This study demonstrates the potential of coacervate microdroplets as delivery microvectors for biomedical research and the development of new therapies. Biocompatible and biostable coacervate microdroplets, comprising amylose‐based polyelectrolytes, are used for the delivery of biologics (i.e., proteins) to cells. Such biopolymeric coacervates show exquisite noncytotoxicity and are able to effectively deliver a proteinaceous cargo into cells, showcased by the delivery of human growth factor to mesenchymal stem cells in order to trigger their differentiation.
doi_str_mv	10.1002/adbi.202000101
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Limitations arise from the lack of pharmacokinetic stability of biologics in vivo. Encapsulating biologics in a protective delivery vector has the potential to improve delivery profile and enhance performance. Coacervate microdroplets are developed as cell‐mimetic materials with established potential for the stabilization of biological molecules, such as proteins and nucleic acids. Here, the development of biodegradable coacervate microvectors (comprising synthetically modified amylose polymers) is presented, for the delivery of biologic payloads to cells. Amylose‐based coacervate microdroplets are stable under physiological conditions (e.g., temperature and ionic strength), are noncytotoxic owing to their biopolymeric structure, spontaneously interacted with the cell membrane, and are able to deliver and release proteinaceous payloads beyond the plasma membrane. In particular, myoglobin, an oxygen storage and antioxidant protein, is successfully delivered into human mesenchymal stem cells (hMSCs) within 24 h. Furthermore, coacervate microvectors are implemented for the delivery of human bone morphogenetic protein 2 growth factor, inducing differentiation of hMSCs into osteoprogenitor cells. This study demonstrates the potential of coacervate microdroplets as delivery microvectors for biomedical research and the development of new therapies. Biocompatible and biostable coacervate microdroplets, comprising amylose‐based polyelectrolytes, are used for the delivery of biologics (i.e., proteins) to cells. 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Limitations arise from the lack of pharmacokinetic stability of biologics in vivo. Encapsulating biologics in a protective delivery vector has the potential to improve delivery profile and enhance performance. Coacervate microdroplets are developed as cell‐mimetic materials with established potential for the stabilization of biological molecules, such as proteins and nucleic acids. Here, the development of biodegradable coacervate microvectors (comprising synthetically modified amylose polymers) is presented, for the delivery of biologic payloads to cells. Amylose‐based coacervate microdroplets are stable under physiological conditions (e.g., temperature and ionic strength), are noncytotoxic owing to their biopolymeric structure, spontaneously interacted with the cell membrane, and are able to deliver and release proteinaceous payloads beyond the plasma membrane. 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subjects	Amylose - chemistry biologics Biopolymers - chemistry Bone Morphogenetic Protein 2 - chemistry Bone Morphogenetic Protein 2 - pharmacokinetics Bone Morphogenetic Protein 2 - pharmacology Cell Differentiation - drug effects Cells, Cultured complex coacervates drug delivery Drug Delivery Systems - methods Humans Mesenchymal Stem Cells - metabolism microvectors protein delivery
title	Biopolymeric Coacervate Microvectors for the Delivery of Functional Proteins to Cells
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