Hannah Lomas

Block copolymer nanostructures

One of the most important classes of synthetic systems for creating self-assembled nanostructures is amphiphilic block copolymers. By controlling the architecture of individual molecules, it is possible to generate nanostructures either in an undiluted melt or in solution. These ordered nanostructures are tunable over a broad variety of morphologies, ranging from discrete micelles and vesicles to continuous network structures. Their synthetic nature allows the design of interfaces with different chemical functional groups and geometrical properties. This, in combination with molecular architecture, determines the levels of ordering in self-organizing polymeric materials. For these and other reasons, block copolymer micelles, vesicles, and mesophases are finding applications in several areas, ranging from nanocomposites to biomedical devices.

Polymersomes: nature inspired nanometer sized compartments

Provided the right hydrophilic/hydrophobic balance can be achieved, amphiphilic block copolymers are able to assemble in water into membranes. These membranes can enclose forming spheres with an aqueous core. Such structures, known as polymer vesicles or polymersomes (from the Greek “-some” = “body of”), have sizes that vary from tens to thousands of nanometers. The wholly synthetic nature of block copolymers affords control over parameters such as the molar mass and composition which ultimately determine the structure and properties of the species in solution. By varying the copolymer molecular mass it is possible to adjust the mechanical properties and permeability of the polymersomes, while the synthetic nature of copolymers allows the design of interfaces containing various biochemically-active functional groups. In particular, non-fouling and non-antigenic polymers have been combined with hydrophobic polymers in the design of biocompatible nano-carriers that are expected to exhibit very long circulation times. Stimulus-responsive block copolymers have also been used to exploit the possibility to trigger the disassembly of polymersomes in response to specific external stimuli such as pH, oxidative species, and enzyme degradation. Such bio-inspired ‘bottom-up’ supramolecular design principles offer outstanding advantages in engineering structures at a molecular level, using the same long-studied principles of biological molecules. Thanks to their unique properties, polymersomes have already been reported and studied as delivery systems for both drugs, genes, and image contrast agents as well as nanometer-sized reactors.

Non-cytotoxic polymer vesicles for rapid and efficient intracellular delivery

We have recently achieved efficient cytosolic delivery by using pH-sensitive poly(2-(methacryloyloxy)ethylphosphorylcholine)-co-poly(2-(diisopropylamino)ethylmethacrylate) (PMPC-PDPA) diblock copolymers that self-assemble to form vesicles, known as polymersomes, in aqueous solution. It is particularly noteworthy that these diblock copolymers form stable polymersomes at physiological pH but rapidly dissociate below pH 6 to give molecularly-dissolved copolymer chains (unimers). These PMPC-PDPA polymersomes are used to encapsulate nucleic acids for efficient intracellular delivery. Confocal laser scanning microscopy and fluorescence flow cytometry are used to quantify cellular uptake and to study the kinetics of this process. Finally, we examine how PMPC-PDPA polymersomes affect the viability of primary human cells (human dermal fibroblasts (HDF)), paying particular regard to whether inflammatory responses are triggered.

Biocompatible Wound Dressings Based on Chemically Degradable Triblock Copolymer Hydrogels

The synthesis of a series of thermo-responsive ABA triblock copolymers in which the outer A blocks comprise poly(2-hydroxypropyl methacrylate) and the central B block is poly(2-(methacryloyloxy)ethyl phosphorylcholine) is achieved using atom transfer radical polymerization. These novel triblock copolymers form thermo-reversible physical gels with critical gelation temperatures and mechanical properties that are highly dependent on the copolymer composition and concentration. TEM studies on dried dilute copolymer solutions indicate the presence of colloidal aggregates, which is consistent with micellar gel structures. This hypothesis is consistent with the observation that incorporating a central disulfide bond within the B block leads to thermo-responsive gels that can be efficiently degraded using mild reductants such as dithiothreitol (DTT) over time scales of minutes at 37 degrees C. Moreover, the rate of gel dissolution increases at higher DTT/disulfide molar ratios. Finally, these copolymer gels are shown to be highly biocompatible. Only a modest reduction in proliferation was observed for monolayers of primary human dermal fibroblasts, with no evidence for cytotoxicity. Moreover, when placed directly on 3D tissue-engineered skin, these gels had no significant effect on cell viability. Thus, we suggest that these thermo-responsive biodegradable copolymer gels may have potential applications as wound dressings.

Efficient Encapsulation of Plasmid DNA in pH‐Sensitive PMPC–PDPA Polymersomes: Study of the Effect of PDPA Block Length on Copolymer–DNA Binding Affinity

We report the self-assembly of a series of amphiphilic diblock copolymers comprising a biocompatible, hydrophilic block, poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC) and a pH-sensitive block, poly(2-(diisopropylamino)ethyl methacrylate) (PDPA), into a dispersion of colloidally stable, nanometer-sized polymersomes at physiological pH and salt concentration. The pH-sensitivity of the PDPA block affords the electrostatic interaction of these block copolymers with nucleic acids at endocytic pH, as a result of the protonation of its tertiary amine groups at pH values below its pK(a). Herein we investigate the effect of PDPA block length on the binding affinity of the block copolymer to plasmid DNA.

Polymersomes: A Synthetic Biological Approach to Encapsulation and Delivery

Compartmentalization, i.e. the ability to create controlled volumes and separate molecules one from another is possibly the most important requisite for complex manipulations. Indeed, compartmentalization has been the first step to isolate the building blocks of life and ensure the dynamic nature that today makes the complexity of any living system. For decades scientists have tried using many synthetic approaches to imitate such ability and one the most successful comes from mimicking the biological component responsible for the compartmentalization: the phospholipid. We are now able to synthesize macromolecular analogues of the phospholipid using advanced co-polymerization techniques. Copolymers that comprise hydrophilic and hydrophobic components (i.e. amphiphilic) can be designed to self assemble into membrane enclosed structures. The simplest of those is represented by a sac resulting from the enclosure of a membrane into a sphere: the vesicle. Vesicles made of amphiphilic copolymers are commonly known as polymersomes and are now one of the most important nanotechnological tool for many applications spanning from drug delivery, gene therapy, medical imaging, electronics and nanoreactors. Herein we review the molecular properties, the fabrication processes and the most important applications of polymersomes.