Your search keyword '"Ren, Yubin"' showing total 6 results

1. Strong Protein Adhesives through Lanthanide‐enhanced Structure Folding and Stack Density.

Author

Chen, Jing, Shi, Weiwei, Ren, Yubin, Zhao, Kelu, Liu, Yangyi, Jia, Bo, Zhao, Lai, Li, Ming, Liu, Yawei, Su, Juanjuan, Ma, Chao, Wang, Fan, Sun, Jing, Tian, Yang, Li, Jingjing, Zhang, Hongjie, and Liu, Kai

Subjects

ADHESIVES, SUPRAMOLECULAR polymers, TISSUE adhesions, MOLECULAR interactions, PROTEINS, RARE earth metals

Abstract

Generating strong adhesion by engineered proteins has the potential for high technical applications. Current studies of adhesive proteins are primarily limited to marine organisms, e.g., mussel adhesive proteins. Here, we present a modular engineering strategy to generate a type of exotic protein adhesives with super strong adhesion behaviors. In the protein complexes, the lanmodulin (LanM) underwent α‐helical conformational transition induced by lanthanides, thereby enhancing the stacking density and molecular interactions of adhesive protein. The resulting adhesives exhibited outstanding lap‐shear strength of ≈31.7 MPa, surpassing many supramolecular and polymer adhesives. The extreme temperature (−196 to 200 °C) resistance capacity and underwater adhesion performance can significantly broaden their practical application scenarios. Ex vivo and in vivo experiments further demonstrated the persistent adhesion performance for surgical sealing and healing applications. [ABSTRACT FROM AUTHOR]

Published

2023

2. Preservation and Encryption in DNA Digital Data Storage.

Author

Zhang, Yi, Ren, Yubin, Liu, Yangyi, Wang, Fan, Zhang, Hongjie, and Liu, Kai

Subjects

*DATA encryption, *DATA warehousing, *CIRCULATING tumor DNA

Abstract

The exponential growth of the total amount of global data presents a huge challenge to mainstream storage media. The emergence of molecular digital storage inspires the development of the new‐generation higher‐density digital data storage. In particular, DNA with high storage density, reproducibility, and long recoverable lifetime behaves the ideal representative of molecular digital storage media. With the development of DNA synthesis and sequencing technologies and the reduction of cost, DNA digital storage has attracted more and more attention and achieved significant breakthroughs. Herein, this Review briefly describes the workflow of DNA storage, and highlights the storage step of DNA digital data storage. Then, according to different information storage forms, the current DNA information encryption methods are emphatically expounded. Finally, the brief perspectives on the current challenges and optimizing proposals in DNA information preservation and encryption are presented. [ABSTRACT FROM AUTHOR]

Published

2022

3. Molecular Engineered Crown‐Ether‐Protein with Strong Adhesion over a Wide Temperature Range from −196 to 200 °C.

Author

Zhao, Kelu, Liu, Yawei, Ren, Yubin, Li, Bo, Li, Jingjing, Wang, Fan, Ma, Chao, Ye, Fangfu, Sun, Jing, Zhang, Hongjie, and Liu, Kai

Subjects

PHASE transitions, CROWN ethers, MOLECULAR interactions, SHEAR strength, TEMPERATURE

Abstract

The inherently tenuous adhesion strength and limited environmental tolerance of supramolecular adhesives severely restrict their application scenarios. It is challenging for the development of robust adhesives with extreme temperature tolerance. Herein, we report a new type of temperature‐resistant crown‐ether‐protein (CEP) adhesive by harnessing synergistic host–guest molecular interactions between engineered crown ether and protein building blocks. The outputs of CEP adhesive demonstrate ultrahigh shearing adhesion strength of ≈22 MPa over a wide temperature range from −196 to 200 °C, superior to other established supramolecular or polymeric adhesives. The temperature‐induced phase transition and internal bound water stabilized the system and led to superb adhesion under extreme conditions. Thus, this work pioneers a molecular engineering approach for the generation of adhesives with tailored applications in extreme settings. [ABSTRACT FROM AUTHOR]

Published

2022

4. DNA‐Based Concatenated Encoding System for High‐Reliability and High‐Density Data Storage.

Author

Ren, Yubin, Zhang, Yi, Liu, Yawei, Wu, Qinglin, Su, Juanjuan, Wang, Fan, Chen, Dong, Fan, Chunhai, Liu, Kai, and Zhang, Hongjie

Subjects

*DATA warehousing, *NUCLEOTIDE sequence, *DNA sequencing, *NUCLEOTIDES

Abstract

Information storage based on DNA molecules provides a promising solution with advantages of low‐energy consumption, high storage efficiency, and long lifespan. However, there are only four natural nucleotides and DNA storage is thus limited by 2 bits per nucleotide. Here, artificial nucleotides into DNA data storage to achieve higher coding efficiency than 2 bits per nucleotide is introduced. To accommodate the characteristics of DNA synthesis and sequencing, two high‐reliability encoding systems suitable for four, six, and eight nucleotides, i.e., the RaptorQ‐Arithmetic‐LZW‐RS (RALR) and RaptorQ‐Arithmetic‐Base64‐RS (RABR) systems, are developed. The two concatenated encoding systems realize the advantages of correcting DNA sequence losses, correcting errors within DNA sequences, reducing homopolymers, and controlling specific nucleotide contents. The average coding efficiencies with error correction and without arithmetic compression by the RALR system using four, six, and eight nucleotides reach 1.27, 1.61, and 1.85 bits per nucleotide, respectively. While the average coding efficiencies by the RABR system are up to 1.50, 2.00, and 2.35 bits per nucleotide, respectively. The coding efficiency, versatility, and tunability of the developed artificial DNA systems might provide significant guidance for high‐reliability and high‐density data storage. [ABSTRACT FROM AUTHOR]

Published

2022

5. Biosynthetic Structural Proteins with Super Plasticity, Extraordinary Mechanical Performance, Biodegradability, Biocompatibility and Information Storage Ability.

Author

Su, Juanjuan, Zhao, Kelu, Ren, Yubin, Zhao, Lai, Wei, Bo, Liu, Bin, Zhang, Yi, Wang, Fan, Li, Jingjing, Liu, Yawei, Liu, Kai, and Zhang, Hongjie

Subjects

CYTOSKELETAL proteins, BIODEGRADABLE plastics, BIOCOMPATIBILITY, ESCHERICHIA coli, ORGANIC solvents, BIOMATERIALS

Abstract

Degradable bioplastics have attracted growing interest worldwide. However, it is challenging to develop bioplastics with a simple processing procedure, strong mechanical performance, good biocompatibility, and adjustable physicochemical properties. Herein, we introduced structural proteins as building blocks and developed a simple environmentally friendly approach to fabricate diverse protein‐based plastics. A cost‐effective and high‐level production approach was developed through batch fermentation of Escherichia coli to produce the biomaterials. These bioplastics possess super plasticity, biocompatibility, biodegradability, and high resistance to organic solvents. Their structural and mechanical properties can be precisely controlled. Besides, high density information storage and hemostatic applications were realized in the bioplastic system. The customizable bioplastics have great potential for applications in numerous fields and are capable to scale up to the industrial level. [ABSTRACT FROM AUTHOR]

Published

2022

6. Highly Plasticized Lanthanide Luminescence for Information Storage and Encryption Applications.

Author

Liu, Yawei, Zhao, Kelu, Ren, Yubin, Wan, Sikang, Yang, Chenjing, Li, Jingjing, Wang, Fan, Chen, Chunying, Su, Juanjuan, Chen, Dong, Zhao, Yuliang, Liu, Kai, and Zhang, Hongjie

Subjects

LUMINESCENCE, ELECTROSTATIC interaction, STORAGE, INFORMATION storage & retrieval systems, INFORMATION design

Abstract

The development of new storage media to meet the demands for diverse information storage scenarios is a great challenge. Here, a series of lanthanide‐based luminescent organogels with ultrastrong mechanical performance and outstanding plasticity are developed for patterned information storage and encryption applications. The organogels possessing outstanding mechanical properties and tunable luminescent colors are prepared by electrostatic and coordinative interactions between natural DNA, synthetic ligands, and rare earth (RE) ions. The organogel‐REs can be stretched by 180 times and show an ultrastrong breaking strength of 80 MPa. A series of applications with both information storage and encryption, such as self‐information pattern, quick response (QR) code, and barcode, are successfully demonstrated by the organogel‐REs. The developed information storage systems have various advantages of good processability, high stretchability, excellent stability, and versatile design of information patterns. Therefore, the organogel‐RE‐based information storage systems are suitable for applications under different scenarios, such as flexible devices under repeating rude operations. The advancements will enable the design and development of luminescent organogel‐REs as information storage and encryption media for various scenarios. [ABSTRACT FROM AUTHOR]

Published

2022