IL54 Professor Cameron Alexander

School of Pharmacy, Nottingham University

Functional polymers can be used for detecting disease and for delivering therapeutic agents to disease sites. The ability to synthesise very precise macromolecules is enabling polymer chemists to explore previously inaccessible aspects of pharmaceutical biology, such as trafficking of exogenous materials in cells in real time. In turn, these advances are allowing biologists to develop new understanding in the ways that healthy and diseased cells process drugs and macromolecular therapeutics. This talk will feature our latest results using polymers and polymer-bioconjugates to probe cellular mechanisms and exploit biological responses for therapy.

The University of Sydney

The ability to tune nanoparticle composition, nanostructural shape and particle behavior has the potential to provide new materials to address challenges in in vivo drug delivery and imaging applications, where the prospect for tailoring distribution patterns is particularly attractive.

To date, only a small number of in vitro reports have described potential biomedical applications of cylindrical polymer brushes (CPBs); showing composition-dependent cellular interactions and strategies to release drugs to kill cancer cells.

In order to access the usefulness of CPBs further, we initiated studies to investigate the in vivo behaviour of PEGMA-based CPBs. Control over particle properties enabled an investigation of the impact of size, aspect ratio and stiffness on pharmacokinetics and biodistribution in animal models.

UNSW

In this talk, photoenergy/electron transfer - reversible addition fragmentation chain transfer (PET-RAFT) polymerization will be discussed. We will present the recent progress in this technique. First, we were able to regulate the polymerization by varying the wavelengths (from blue light to near-infrared light) using various types of catalysts. More recently, we were able to selectively activate polymerization and generate complex macromolecular architectures, such as graft copolymers, in one-pot synthesis by changing the wavelengths. Finally, we will present potential application of this process for the synthesis of sequence control polymers.

Postnova Analytics

Warwick University

Soochow University

TBC

AIBN

Recently there has been intense interest in fluorinated molecules to allow tracking of therapeutic particles and cells in vivo. The motivation for this is the very high selectivity of the ¹⁹F imaging experiment, since unlike in ¹H MRI, the body does not contain a confounding fluorine background signal. In principle therefore, highly-selective 19F images can be superimposed on high-resolution anatomical ¹H images, allowing tracking of suitably-labelled cells or biomarker molecules. Here I describe the motivation for the development of new partly-fluorinated copolymers with outstanding potential as ¹⁹F MRI imaging agents, and in particular as agents sensitive to the biological environment. The discussion will focus on macromolecules incorporating the monomers DMAEMA and/or OEGMA which respond to external stimuli, for example local temperature, pH or ionic strength. I will also describe our programs in imaging and delivery to small animal models of glioma, prostate and skin cancer.

UNC

Nitric oxide (NO) is a reactive free radical that exhibits broad-spectrum antibacterial properties due to multiple modes of action. Recent work has focused on the development of NO-releasing macromolecular scaffolds (e.g., dendrimers) as antibacterial agents. Developing an understanding of how a dendrimer's physicochemical properties influence antibacterial activity is essential in designing new therapeutics. This presentation will describe the effects of dendrimer composition, size, and exterior chemical modification on bacterial killing and cytotoxicity.

Sungkyunkwan University

The design concept of the injectable block copolymer hydrogels responding to pH and temperature, and their potential biomedical applications will be discussed. These copolymers usually contain tertiary amine and sulfone amide groups as pH-sensitive moieties and many different chemical groups, such as ester, amide, urethane, urea… to control the hydrogel properties. These copolymer aqueous solutions existed in the sol states at low pH and low temperature with low viscosity, which are suitable for formulation with proteins or bioactive molecules, and exhibited a sol-gel transition to be the gel states with high viscosity by changing to physiological conditions (37 °C, pH 7.4). Or after being injected into the body, it could let them serve as proteins/bioactive molecules depots for long term sustained release. The potential applications of these hydrogels as drugs/proteins carriers will also be suggested.

Polymers are widely used to alter the biodistribution and to extend the duration of action of drugs. Polymers in orally administered dosage forms readily clear the gastrointestinal track without uptake in the the body. Oral dosage forms often exploit non-covalent polymer properties (e.g. coating, wettability, dispersibility, etc). There are greater challenges for polymers used to develop injectable drugs (e.g. haemolytic toxicity, propensity for accumulation). Covalent approaches tend to focus on drug conjugation to the polymer while non-covalent properties are used to form colloids. We are examining both non-covalent and covalent approaches to utilise polymers in injectable medicines. This talk will describe (i) a conjugation strategy to make protein mimetics that cannot be easily made by recombinant means alone and (ii) a liposome replacement strategy based on the non-covalent complexation of poorly soluble and toxic drugs to a water-soluble polymer.

Virginia Tech

Tailoring morphology requires the design of sequenced polymers using a complement of synthetic strategies, ranging from living anionic polymerization and controlled radical polymerization to segmented copolymers with step-growth polymerization. This lecture will focus on the structure-property-processing relationships of novel multiphase polymer systems with a focus on the formation of block copolymers in concert with intermolecular interactions. Particular attention is devoted to the roles of hydrogen bonding and ionic interactions on phase separation at the nanoscale with implications on thermomechanical properties. Recent efforts have involved the role of multiphase architecture in 3D printing, and ionic liquids and block copolymers offer exciting opportunities to tune performance of 3D printed objects. This lecture will also describe our efforts in mask projection microstereolithography to prepare diverse micron-scale objects with topological and geometric control.

Monash University and the University of Warwick

There are several routes described in the literature for the production of highly porous and permeable polymer materials for use as tissue engineering scaffolds. However, many of these methods result in poorly defined materials with void sizes that are difficult to control and limited connectivity. One method that has the ability to create well-defined porous polymers (foams) is the so-called emulsion templating process, whereby a high internal phase emulsion (HIPE) is used as a precursor to a porous material. The presentation will describe the preparation of HIPEs

and the resulting porous polymers (polyHIPEs) together with methods by which the morphology, properties and surface chemistry can be varied. In particular, the use of photopolymerization as a means to prepare porous

materials from relatively unstable HIPEs will be presented. Subsequently, the application of these materials as matrices for tissue engineering and in vitro 3D cell culture will be discussed.

Monash University, Dept of Materials Science & Engineering

There are several routes described in the literature for the production of highly porous and permeable polymer materials for use as tissue engineering scaffolds. However, many of these methods result in poorly defined materials with void sizes that are difficult to control and limited connectivity. One method that has the ability to create well-defined porous polymers (foams) is the so-called emulsion templating process, whereby a high internal phase emulsion (HIPE) is used as a precursor to a porous material. The presentation will describe the preparation of HIPEs

and the resulting porous polymers (polyHIPEs) together with methods by which the morphology, properties and surface chemistry can be varied. In particular, the use of photopolymerization as a means to prepare porous

materials from relatively unstable HIPEs will be presented. Subsequently, the application of these materials as matrices for tissue engineering and in vitro 3D cell culture will be discussed.

Institut Charles Sadron

Information-containing macromolecules are polymers that contain a message encrypted in their comonomer sequences. The archetypal example of such a polymer is DNA, which is used in biology to store genetic information. However, DNA is not the only polymer that can store molecular information. In principle, a string of information can be created in any copolymer using two comonomers defined intentionally as 0- and 1-bits. However, such polymers have to be monodisperse and perfectly sequence-defined. In addition, the message encoded in their chains should be easily read. In this lecture, I will present recent achievements obtained in my laboratory for the synthesis of information-containing macromolecules. For instance, monodisperse sequence-defined polymers were prepared using chemoselective iterative solid-phase strategies. Furthermore, the sequencing of these polymers by tandem mass spectrometry will be discussed.

Soochow University

Sugar chain is widely recognized as the signal antenna localized on cell surface. All living cells are coated with glycan polymers on their cell walls. They play diverse roles, including critical functions in the areas of cell signaling, molecular recognition, immunity, and so on. It is also noted that non-sugar moities such as sulfonic acid or proteins are found to be important elements to complex with sugar for the proper function of glycans. Herein, by picking the important elements, we rebuild them to form synthetic complex glycopolymers. We designed and synthesized functional glycopolymers that can recognize cancer cells, or used as the ‘antenna’ on stem cell surface for cell fate regulation.

Chemical Engineering & Chemistry, TU Eindhoven

In this contribution we will present our recent efforts in the preparation of nanocapsules and polymer-Gibbsite nanocomposites via reversible deactivation emulsion polymerization. The former structures are prepared by chain extension of anionic cooligomers of butyl acrylate and acrylic acid containing a trithiocarbonate group, adsorbed onto cationic DODAB vesicles, using a starved-feed emulsion polymerization. Different nanocapsule morphologies are obtained in this process and in the current presentation we will highlight our recent efforts in controlling these morphologies. Furthermore we will present our recent results on the extension of this RAFT-based approach to ATRP in the preparation of polymer-Gibbsite nanocomposites. Unlike the RAFT approach, which leads to fully encapsulated Gibbsite platelets, the ATRP approach results in very different morphologies and here we present our efforts in controlling these morphologies.

Karlsruhe Institute of Technology (KIT)

Multicomponent reactions are an established tool in organic chemistry. They offer high atom-economy, straightforward practical procedures and most importantly structural diversity can easily be achieved by variation of the used components. Only recently, the benefit of these one-pot reactions was realized for macromolecular engineering. Especially the Passerini three-component and Ugi four-component reactions demonstrate attractive tools for polymer synthesis. Here, two different approaches to form polymers can be followed: either synthesizing the monomer first via an isocyanide-based MCR (IMCR) or forming the polymer directly by the use of IMCR-reactive

bifunctional components. Both approaches will be discussed in detail and led to a large variety of different polymer architectures offering a variety of tunable properties. Moreover, multicomponent reactions are an excellent tool for the design of highly defined polymer architectures, including dendrimers and sequence defined polymers.

IL70

Professor Ben Boyd, Kristian Tangso, Patrick T. Spicer

Monash University

The interface between oppositely-charged surfactant and polymer solutions can generate self-assembled structures with thermodynamically stable and reversible stimuli responsive order not achievable in coacervated polymer-polymer systems. We have been using spatially-resolved X-ray scattering approaches to understand the structures formed at these interfaces. The structures formed can be used to form capsules, and can be manipulated through changes in variables such as temperature or pH to yield stimuli responsive materials. Industrially relevant systems as well as biocompatible and biological surfactants and polymer pairs have demonstrated such behaviour, yielding new opportunities for controlled release applications in a wide range of fields.

UCL

Getting through the biological barrier that limits access to all the different parts of our body is paramount for enhancing and enabling both drug delivery and diagnostic development. This requires a level of engineering that requires both synthetic and supramolecular design. In the last year, we approached this problem using systems that mimic natural carriers such as vesicles and viruses and yet implement their design with new features such as responsiveness, active diffusion, and moreover using materials that guarantee easy clinical translation. We synthesise amphiphilic copolymers that comprise all the necessary requisites such as immune compatibility, molecular recognition and responsiveness, we then combined this into supramolecular structures that fulfil all the requirements imposed by the different barrier, tissue penetration, selectivity, intracellular delivery and more. The result is a technology platform that we are now applying to several clinical settings.

Monash University

Protein aggregation is a ubiquitous phenomenon occurring in neurological disorders and type-2 diabetes (T2D). Aggregation of human islet amyloid polypeptide (hIAPP), specifically, is associated with the loss of pancreatic cells and, consequently, insulin resistance and deficiency in T2D. Here we show the use of OH-terminated dendrimers and polyphenols for effective inhibition of hIAPP aggregation and cytotoxicity in vitro, ex vivo and in silico.

Protein adsorption determines the biological identity of the nanoparticle core. We have devised a synthesis scheme by grafting phosphorylcholine (PC) brushes onto iron oxide nanoparticles (IONPs). PC displayed a comparable or better performance over PEG in affording the IONPs stability and biocompatibility while computer simulations further examined the capacities of PC and PEG brushes in albumin avoidance. Towards application the transcytosis of the IONPs across a model blood brain barrier is briefly discussed.

IL73

Professor Matthew Becker,

The University of Akron

Chemical approaches to functionalize polymers with bioactive groups are evolving rapidly to enhance interactions at the biotic-synthetic interface. Further advances in both synthetic methodology and scaffold fabrication are needed to drive these efforts forward. Many strategies have involved doping polymers with proteins or peptides or decorating the substrates bioactive groups. While these approached have been demonstrated to aid the biochemical signaling and integration into host tissues, they generally reduce the mechanical properties of the material. This presentation will describe the use of several translationally relevant functionalization strategies to functionalize polymeric materials in nanofiber, scaffold and hydrogel technologies

UNSW

Polymeric nano-objects find a wide variety of applications in areas as diverse as material science, health care products and nanomedicine. We have been exploring the use of low pressure CO₂ as an environmentally friendly and versatile tool to exert influence on heterogeneous polymerization systems. Examples include the synthesis of hollow particles via CO₂-assisted photoinitiated polymerization using vesicles templates, tuning of particle morphology via CO₂-pressure in polymerization-induced self-assembly (PISA), as well as synthesis of aqueous polyethylene latexes using CO₂-induced miniemulsions.

Hungarian Academy of Sciences

Amphiphilic conetworks (APCNs) composed of covalently bonded, otherwise immiscible hydrophilic and hydrophobic polymer chains belong to a new group of rapidly emerging nanostructured materials. Such macromolecular assemblies are prepared by utilizing telechelic polymers obtained by living polymerization techniques. Due to the strong chemical bonds between the immiscible chains, unique bicontinuous nanophase separated morphology exists in APCNs in a broad composition window. This is the basis for the preparation of various specialty new intelligent (responsive) gels and unique organic-inorganic nanohybrids by applying one of the nanophases as nanoreactor. The resulting novel materials have a variety of high added-value potential applications from nanocatalysis and photonics to biomaterials etc.

Technion City, Haifa

The demand for new, better materials increasingly directs materials science towards a profound understanding of the relation between the nanoscopic and macroscopic worlds. The mechanical properties of materials, as well as the mechanical response to stress are a direct consequence of molecular friction (non-covalent bonds) and polymer architecture. The mechanical response of linear and cross-linked polymers is well described and understood. In this talk, I’ll describe the effect of intramolecular cross-links on the mechanical response of polymer chains. Intramolecular cross-links influence the mechanochemical stability of the chains, the mechanical properties of the chain as well as of the material, since these physical barriers affect the entanglement between chains. Importantly, since these cross-links are intramolecular, the polymer remains a thermoplastic material, with easy processability.