Sequence-defined non-natural polymers: synthesis and applications

Pandurangan Nanjan; Mintu Porel

doi:10.1039/c9py00886a

Sequence-defined non-natural polymers: synthesis and applications

Polymer Chemistry ◽

10.1039/c9py00886a ◽

2019 ◽

Vol 10 (40) ◽

pp. 5406-5424 ◽

Cited By ~ 4

Author(s):

Pandurangan Nanjan ◽

Mintu Porel

Keyword(s):

Functional Diversity ◽

Biomedical Applications ◽

Polymeric Materials ◽

Next Generation ◽

Natural Polymers

Sequence-defined polymer: A promising gateway for the next generation polymeric materials and vast opportunities for new synthetic strategies, functional diversity and its material and biomedical applications.

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Biomedical Applications of Natural Polymers for Drug Delivery

Current Organic Chemistry ◽

10.2174/138527281802140129104525 ◽

2014 ◽

Vol 18 (2) ◽

pp. 152-164 ◽

Cited By ~ 11

Author(s):

Mariana Chifiriuc ◽

Alexandru Grumezescu ◽

Valentina Grumezescu ◽

Eugenia Bezirtzoglou ◽

Veronica Lazar ◽

...

Keyword(s):

Drug Delivery ◽

Biomedical Applications ◽

Natural Polymers

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Functional Two-Dimensional Black Phosphorus Nanostructures towards Next-Generation Devices

Journal of Materials Chemistry A ◽

10.1039/d1ta02027g ◽

2021 ◽

Author(s):

Mengke Wang ◽

Jun Zhu ◽

You Zi ◽

Zheng-Guang Wu ◽

Haiguo Hu ◽

...

Keyword(s):

Surface Area ◽

Biomedical Applications ◽

Black Phosphorus ◽

Large Surface Area ◽

Two Dimensional ◽

Next Generation

In recent years, two-dimensional (2D) black phosphorus (BP) has been widely applied in many fields, such as (opto)electronics, transistors, catalysis and biomedical applications due to its large surface area, tunable...

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Recent Advances and Applications of Bacterial Cellulose in Biomedicine

Polymers ◽

10.3390/polym13030412 ◽

2021 ◽

Vol 13 (3) ◽

pp. 412

Author(s):

Sam Swingler ◽

Abhishek Gupta ◽

Hazel Gibson ◽

Marek Kowalczuk ◽

Wayne Heaselgrave ◽

...

Keyword(s):

Bacterial Cellulose ◽

Biomedical Applications ◽

High Water ◽

Next Generation ◽

High Tensile Strength ◽

Ideal Candidate ◽

Chemical Purity ◽

High Level ◽

Water Holding ◽

Extracellular Polymer

Bacterial cellulose (BC) is an extracellular polymer produced by Komagateibacter xylinus, which has been shown to possess a multitude of properties, which makes it innately useful as a next-generation biopolymer. The structure of BC is comprised of glucose monomer units polymerised by cellulose synthase in β-1-4 glucan chains which form uniaxially orientated BC fibril bundles which measure 3–8 nm in diameter. BC is chemically identical to vegetal cellulose. However, when BC is compared with other natural or synthetic analogues, it shows a much higher performance in biomedical applications, potable treatment, nano-filters and functional applications. The main reason for this superiority is due to the high level of chemical purity, nano-fibrillar matrix and crystallinity. Upon using BC as a carrier or scaffold with other materials, unique and novel characteristics can be observed, which are all relatable to the features of BC. These properties, which include high tensile strength, high water holding capabilities and microfibrillar matrices, coupled with the overall physicochemical assets of bacterial cellulose makes it an ideal candidate for further scientific research into biopolymer development. This review thoroughly explores several areas in which BC is being investigated, ranging from biomedical applications to electronic applications, with a focus on the use as a next-generation wound dressing. The purpose of this review is to consolidate and discuss the most recent advancements in the applications of bacterial cellulose, primarily in biomedicine, but also in biotechnology.

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CeO2 Nanoparticle-Containing Polymers for Biomedical Applications: A Review

Polymers ◽

10.3390/polym13060924 ◽

2021 ◽

Vol 13 (6) ◽

pp. 924

Author(s):

Alexander B. Shcherbakov ◽

Vladimir V. Reukov ◽

Alexander V. Yakimansky ◽

Elena L. Krasnopeeva ◽

Olga S. Ivanova ◽

...

Keyword(s):

Biomedical Applications ◽

Metal Oxide Nanoparticles ◽

Polymeric Materials ◽

Negative Effects ◽

New Horizons ◽

Beneficial Effects ◽

Advanced Composite ◽

Unique Material ◽

Biomedical Polymers ◽

Biomedical Potential

The development of advanced composite biomaterials combining the versatility and biodegradability of polymers and the unique characteristics of metal oxide nanoparticles unveils new horizons in emerging biomedical applications, including tissue regeneration, drug delivery and gene therapy, theranostics and medical imaging. Nanocrystalline cerium(IV) oxide, or nanoceria, stands out from a crowd of other metal oxides as being a truly unique material, showing great potential in biomedicine due to its low systemic toxicity and numerous beneficial effects on living systems. The combination of nanoceria with new generations of biomedical polymers, such as PolyHEMA (poly(2-hydroxyethyl methacrylate)-based hydrogels, electrospun nanofibrous polycaprolactone or natural-based chitosan or cellulose, helps to expand the prospective area of applications by facilitating their bioavailability and averting potential negative effects. This review describes recent advances in biomedical polymeric material practices, highlights up-to-the-minute cerium oxide nanoparticle applications, as well as polymer-nanoceria composites, and aims to address the question: how can nanoceria enhance the biomedical potential of modern polymeric materials?

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Topographical and Biomechanical Guidance of Electrospun Fibers for Biomedical Applications

Polymers ◽

10.3390/polym12122896 ◽

2020 ◽

Vol 12 (12) ◽

pp. 2896

Author(s):

Sara Ferraris ◽

Silvia Spriano ◽

Alessandro Calogero Scalia ◽

Andrea Cochis ◽

Lia Rimondini ◽

...

Keyword(s):

Surface Modification ◽

Biomedical Applications ◽

Biomedical Application ◽

Electrospun Fibers ◽

Natural Polymers ◽

Polymeric Fibers ◽

Biological Phenomena ◽

Proper Design ◽

Synthetic And Natural Polymers ◽

Selection Of

Electrospinning is gaining increasing interest in the biomedical field as an eco-friendly and economic technique for production of random and oriented polymeric fibers. The aim of this review was to give an overview of electrospinning potentialities in the production of fibers for biomedical applications with a focus on the possibility to combine biomechanical and topographical stimuli. In fact, selection of the polymer and the eventual surface modification of the fibers allow selection of the proper chemical/biological signal to be administered to the cells. Moreover, a proper design of fiber orientation, dimension, and topography can give the opportunity to drive cell growth also from a spatial standpoint. At this purpose, the review contains a first introduction on potentialities of electrospinning for the obtainment of random and oriented fibers both with synthetic and natural polymers. The biological phenomena which can be guided and promoted by fibers composition and topography are in depth investigated and discussed in the second section of the paper. Finally, the recent strategies developed in the scientific community for the realization of electrospun fibers and for their surface modification for biomedical application are presented and discussed in the last section.

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New Carbohydrate-Based Polymeric Materials

MRS Bulletin ◽

10.1557/s0883769400046492 ◽

1992 ◽

Vol 17 (10) ◽

pp. 54-59 ◽

Cited By ~ 1

Author(s):

Matthew R. Callstrom ◽

Mark D. Bednarski

Keyword(s):

Food Additives ◽

Polymeric Materials ◽

Water Soluble ◽

Natural Polymers ◽

Water Soluble Polymers ◽

Soluble Polymers ◽

Chemically Modified ◽

Stereochemical Control ◽

Natural Polysaccharide ◽

Image Position

The total world production of water-soluble polymers is estimated to be greater than five million tons per year. Water-soluble polymers are most conveniently described according to their origin in three classes (see Structures 1-6):∎ Natural polymers, including starch (1) and cellulose (2);∎ chemically modified natural polymers, including, for example, hydroxyethyl starch (3) and cellulose acetate (4); and∎ synthetic polymers, the most important of which are polyacrylamide (5) and polyvinyl alcohol (6), (commonly composed of both alcohol and acetate groups as shown). The widespread use of these materials is due to both their availability and the range of useful physical properties found in the various natural and chemically modified natural polymers.Of the commercial water-soluble polymers, approximately 50–80% are based on natural polysaccharide materials. One of the primary reasons that these materials find such widespread use is the dramatic response of their properties to changes in their functionality and stereochemistry: chemical modification or the combination of polysaccharides with other polymeric materials has yielded materials whose applications range from explosives to food additives. Although efforts directed at controlling the properties of polysaccharides has resulted in a wide variety of useful materials, we felt control of the composition of carbohydrate-based polymers at the molecular level would provide materials with properties superior to those derived from natural and chemically modified polysaccharide materials.Our approach for the preparation of new carbohydrate-based materials is to use the carbohydrate as a template for the introduction of desired functionality with complete regiochemical and stereochemical control by both chemical and enzymatic methods (Scheme I).

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