Versatile Delivery Platform for Nucleic Acids, Negatively Charged Protein Drugs, and Genome-editing Ribonucleoproteins Using a Multi-step Transformable Polyrotaxane

Overview

Journal Mater Today Bio

Specialty Biomedical Engineering

Date 2023 Jul 13

PMID 37441133

Authors

Toru Taharabaru

Takuya Kihara

Risako Onodera

Tetsuya Kogo

Yuting Wen

Jun Li

Keiichi Motoyama

Taishi Higashi

Affiliations

Soon will be listed here.

Abstract

Various biopharmaceuticals, such as nucleic acids, proteins, and genome-editing molecules, have been developed. Generally, carriers are prepared for each biopharmaceutical to deliver it intracellularly; thus, the applications of individual carriers are limited. Moreover, the development of carriers is laborious and expensive. Therefore, in the present study, versatile and universal delivery carriers were developed for various biopharmaceuticals using aminated polyrotaxane libraries. Step-by-step and logical screening revealed that aminated polyrotaxane, including the carbamate bond between the axile molecule and endcap, is suitable as a backbone polymer. Movable and flexible properties of the amino groups modified on polyrotaxane facilitated efficient complexation with various biopharmaceuticals, such as small interfering RNA, antisense oligonucleotides, messenger RNA, β-galactosidase, and genome-editing ribonucleoproteins. Diethylenetriamine and cystamine modifications of polyrotaxane provided endosomal-escape abilities and drug-release properties in the cytosol, allowing higher delivery efficacies than commercially available high-standard carriers without cytotoxicity. Thus, the resulting polyrotaxane might serve as a versatile and universal delivery platform for various biopharmaceuticals.

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