| |
Genetically engineering of Escherichia coli and immobilization on electrospun fibers for drug delivery purposes.
S.Z. Xie, S.H. Tai, H.X. Song, X.M. Luo, H. Zhang, X.H. Li*. Genetically engineering of Escherichia coli and immobilization on electrospun fibers for drug delivery purposes. J.
Mater. Chem. B., 4, 6820–6829 (2016).
http://www.polymer.cnt//ss/xiaohongli/publicationsshow_9917.html |
| |
Engineering of fluorescent emission of silk fibroin composite materials by material assembly
This novel materials assembly technology endows the designated materials with additional/enhanced performance by fi xing “functional components” into the materials. Such functional components are molecularly recognized and accommodated by the designated materials. In this regard, two-photon fluorescence (TPF) organic molecules and CdTe quantum dots (QDs) are adopted as func...
http://www.polymer.cnt//ss/lnb/publicationsshow_9445.html |
| |
Structural engineering of waterborne polyurethane for high performance waterproof coatings
A series of modified waterborne polyurethanes were synthesized using a self-emulsifying method for high performance waterproof coatings, such as fluoride polyurethane (FPU), siloxane modified waterborne polyurethane (SPU) and the polyurethane containing fluorine and siloxane (FSPU). The structures of waterborne polyurethane were designed from scratch, and the contents of fluoride ...
http://www.polymer.cnt//ss/lnb/publicationsshow_9443.html |
| |
Crystal Network in Supramolecular gels: Formation Kinetics and Mesoscopic Engineering Principles
For many functional materials, the functionality that is critical to macroscopic behavior begins to manifest itself at the mesoscale. To control the macroscopic properties, knowledge of the structural characteristics in relation to the properties of the mesoscopic materials is crucial. To a large extent, the mesoscopic structure of the crystal networks in supramolecular materials ...
http://www.polymer.cnt//ss/lnb/publicationsshow_9442.html |
| |
2016-Macrmol Chem Phys:Engineering of Tough Double Network Hydrogels
Double-network (DN) hydrogel has intrinsic tough mechanical properties due to its unique two contrasting network structures. The research on DN hydrogel is a fast growing field, mainly focusing on double-network structures, formation, and interactions at the molecular level. In this trend article, we take a critical review at the latest and important research findings, c...
http://www.polymer.cnt//ss/qiangchen/publicationsshow_8955.html |
| |
Methylsulfonylmethane-loaded electrospun poly(lactide-coglycolide) mats for cartilage tissue engineering
Abstract Methylsulfonylmethane (MSM) is popularly used for the therapy of arthritic and rheumatic diseases but seldom in tissue engineering applications for cartilage regeneration. In this study, biodegradable poly(lactide-co-glycolide) (PLGA) fibrous mats containing MSM with different doping levels were fabricated by electrospinning. The MSM-loaded mats were interc...
http://www.polymer.cnt//ss/pbzhang/publicationsshow_8741.html |
| |
Silk sericin: A versatile material for tissue engineering and drug delivery
Abstract
Sericin is an inexpensive glycoprotein obtained as a by-product in the silk industry. Its variable amino acid composition and diverse functional groups confer upon it attractive bioactive properties, which are particularly interesting for biomedical applications. Because of its antioxidant character, moisturizing ability, and mitogenic effect on mammalian cells, sericin is useful in...
http://www.polymer.cnt//ss/yangguang/publicationsshow_8728.html |
| |
A biodegradable PEG-based micro-cavitary hydrogel as scaffold for cartilage tissue engineering
We developed a micro-cavitary hydrogel (MCG) via photo-polymerization of biodegradable
oligo(trimethylene carbonate)–poly(ethylene glycol)–oligo(trimethylene carbonate)
diacrylate (TPT-DA) macromer, in which cavities with hundreds of microns in diameter
were created using gelatin micro-spherical porogens. The capacity of this TPT-DA based
MCG (TPT-MCG) as scaffolds for cartilage tissue engineeri...
http://www.polymer.cnt//ss/fanchangjiang/publicationsshow_8626.html |
| |
Surface modification and endothelialization of biomaterials as potential scaffolds for vascular tissue engineering applications
Surface modification and endothelialization of vascular biomaterials are two usually used approaches to resist the nonspecific adhesion of proteins, and to improve hemocompatibility and long term patency of artificial vascular grafts. Surface modification of vascular biomaterials by hydrophilic poly(ethylene glycol), zwitterionic polymers, gelatin, heparin and other bioactive molecules can effic...
http://www.polymer.cnt//ss/renxiangkui/publicationsshow_8547.html |
| |
Click Hydrogels, Microgels and Nanogels: Emerging Platforms for Drug Delivery and Tissue Engineering
Hydrogels, microgels and nanogels have emerged as versatile and viable platforms for sustained protein release, targeted drug delivery, and tissue engineering due to excellent biocompatibility, a microporous structure with tunable porosity and pore size, and dimensions spanning from human organs, cells to viruses. In the past decade, remarkable advances in hydrogels, microgels and nanogels have be...
http://www.polymer.cnt//ss/dengchao/publicationsshow_7435.html |
| |