Anja Car scite author profile

Biological membranes play an essential role in living organisms by providing stable and functional compartments, preserving cell architecture, whilst supporting signalling and selective transport that are mediated by a variety of proteins embedded in the membrane. However, mimicking cell membranes - to be applied in artificial systems - is very challenging because of the vast complexity of biological structures. In this respect a highly promising strategy to designing multifunctional hybrid materials/systems is to combine biological molecules with polymer membranes or to design membranes with intrinsic stimuli-responsive properties. Here we present supramolecular polymer assemblies resulting from self-assembly of mostly amphiphilic copolymers either as 3D compartments (polymersomes, PICsomes, peptosomes), or as planar membranes (free-standing films, solid-supported membranes, membrane-mimetic brushes). In a bioinspired strategy, such synthetic assemblies decorated with biomolecules by insertion/encapsulation/attachment, serve for development of multifunctional systems. In addition, when the assemblies are stimuli-responsive, their architecture and properties change in the presence of stimuli, and release a cargo or allow "on demand" a specific in situ reaction. Relevant examples are included for an overview of bioinspired polymer compartments with nanometre sizes and membranes as candidates in applications ranging from drug delivery systems, up to artificial organelles, or active surfaces. Both the advantages of using polymer supramolecular assemblies and their present limitations are included to serve as a basis for future improvements.

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PEG modified poly(amide-b-ethylene oxide) membranes for CO2 separation

Car

Stropnik

Yave³

et al. 2008

Journal of Membrane Science

431

250

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CO₂-Philic Polymer Membrane with Extremely High Separation Performance

Yave

Car

Funari³

et al. 2009

Macromolecules

301

213

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Polymeric membranes are attractive for CO2 separation and concentration from different gas streams because of their versatility and energy efficiency; they can compete with, and they may even replace, traditional absorption processes. Here we describe a simple and powerful method for developing nanostructured and CO2-philic polymer membranes for CO2 separation. A poly(ethylene oxide)−poly(butylene terephthalate) multiblock copolymer is used as membrane material. Smart additives such as polyethylene glycol dibutyl ether are incorporated as spacers or fillers for producing nanostructured materials. The addition of these specific additives produces CO2-philic membranes and increases the CO2 permeability (750 barrer) up to five-fold without the loss of selectivity. The membranes present outstanding performance for CO2 separation, and the measured CO2 flux is extremely high (>2 m3 m−2 h−1 bar−1) with selectivity over H2 and N2 of 10 and 40, respectively, making them attractive for CO2 capture.

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Tailor‐made Polymeric Membranes based on Segmented Block Copolymers for CO₂ Separation

Car

Stropnik

Yave³

et al. 2008

Adv Funct Materials

235

177

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This paper reports the design of a tailor made polymeric membrane by using poly(ethylene oxide)–poly(butylene terephthalate) (PEO‐PBT) multi‐block copolymers. Their properties are controlled by the fraction of the PEO phase and its molecular weight. To explain the effect of structural changes in copolymer membranes, transport properties of four gases (CO2, H2, N2, and CH4) are discussed. After characterization, the two best copolymers are selected in order to prepare tailor made blends by adding poly(ethylene glycol) (PEG). The best selected copolymer that contained 55 wt. % of 4000 g mol−1 PEO produced a blend with high CO2 permeability (∼190 barrer), which is twice the permeability of the pure copolymer. At the same time, an enhancement of CO2/H2 selectivity is observed (∼13). These results suggest that the morphology of PEO‐PBT can be well controlled by the addition of low‐molecular‐weight PEG, and consequently the gas transport properties can be tuned.

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Nanometric thin film membranes manufactured on square meter scale: ultra-thin films for CO₂capture

Yave

Car

Wind³

et al. 2010

Nanotechnology

213

179

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Miniaturization and manipulation of materials at nanometer scale are key challenges in nanoscience and nanotechnology. In membrane science and technology, the fabrication of ultra-thin polymer films (defect-free) on square meter scale with uniform thickness (<100 nm) is crucial. By using a tailor-made polymer and by controlling the nanofabrication conditions, we developed and manufactured defect-free ultra-thin film membranes with unmatched carbon dioxide permeances, i.e. > 5 m(3) (STP) m(-2) h(-1) bar(-1). The permeances are extremely high, because the membranes are made from a CO(2) philic polymer material and they are only a few tens of nanometers thin. Thus, these thin film membranes have potential application in the treatment of large gas streams under low pressure like, e.g., carbon dioxide separation from flue gas.

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Anja Car

Bioinspired polymer vesicles and membranes for biological and medical applications

PEG modified poly(amide-b-ethylene oxide) membranes for CO2 separation

CO₂-Philic Polymer Membrane with Extremely High Separation Performance

Tailor‐made Polymeric Membranes based on Segmented Block Copolymers for CO₂ Separation

Nanometric thin film membranes manufactured on square meter scale: ultra-thin films for CO₂capture

Contact Info

Product

Resources

About

Anja Car

Bioinspired polymer vesicles and membranes for biological and medical applications

PEG modified poly(amide-b-ethylene oxide) membranes for CO2 separation

CO2-Philic Polymer Membrane with Extremely High Separation Performance

Tailor‐made Polymeric Membranes based on Segmented Block Copolymers for CO2 Separation

Nanometric thin film membranes manufactured on square meter scale: ultra-thin films for CO2capture

Contact Info

Product

Resources

About

CO₂-Philic Polymer Membrane with Extremely High Separation Performance

Tailor‐made Polymeric Membranes based on Segmented Block Copolymers for CO₂ Separation

Nanometric thin film membranes manufactured on square meter scale: ultra-thin films for CO₂capture