Transition-metal-catalyzed polymerization of heteroatom-functionalized cyclohexadienes: stereoregular precursors to poly(p-phenylene)

Poly(p-phenylene) (PPP) is an insoluble rigid-rod polymer that possesses remarkable thermal stability, chemical resistance, and electrical conductivity when doped. The structural properties that make PPP such an attractive engineering material also make it difficult to synthesize and process. Direct synthetic approaches have given either ill-defined material with a mixture of para, meta, and ortho linkages and crosslink or insoluble oligomers. Precursor strategies to PPP have been devised in which the synthetic and processing difficulties of the direct methods have been overcome through the use of a soluble intermediate polymer. The most successful of the precursor strategies was developed at ICI by Ballard et al. This process involves the radical polymerization of the bis(acetyl) or bis(methoxycarbonyl) derivatives of cis-5,ddihydroxy- 1,3-cyclohexadiene (l), a microbial oxidation product of benzene. The resulting polymers are subsequently aromatized to yield PPP by thermally induced acid elimination. This process, however, yields only phenylene oligomers due to fracturing of the precursors during pyrolysis. Fracturing is believed to arise from the 90% 1,4-linkages, 10% 1,2-linkages, and random stereochemistry along the precursor backbones which result from the nonstereospecific nature of the radical polymerization. A route to 100% 1,4-linked PPP precursors with the correct stereochemistry for facile cis-pyrolytic elimination of the pendant groups has been developed which combines the efficiency and processability of the ICI process with the regio- and stereochemical control possible through transition-metal catalysts (Scheme I)

Transition-metal-catalyzed polymerization of heteroatom-functionalized cyclohexadienes: stereoregular precursors to poly(p-phenylene)

Poly(p-phenylene) (PPP) is an insoluble rigid-rod polymer that possesses remarkable thermal stability, chemical resistance, and electrical conductivity when doped. The structural properties that make PPP such an attractive engineering material also make it difficult to synthesize and process. Direct synthetic approaches have given either ill-defined material with a mixture of para, meta, and ortho linkages and crosslink or insoluble oligomers. Precursor strategies to PPP have been devised in which the synthetic and processing difficulties of the direct methods have been overcome through the use of a soluble intermediate polymer. The most successful of the precursor strategies was developed at ICI by Ballard et al. This process involves the radical polymerization of the bis(acetyl) or bis(methoxycarbonyl) derivatives of cis-5,ddihydroxy- 1,3-cyclohexadiene (l), a microbial oxidation product of benzene. The resulting polymers are subsequently aromatized to yield PPP by thermally induced acid elimination. This process, however, yields only phenylene oligomers due to fracturing of the precursors during pyrolysis. Fracturing is believed to arise from the 90% 1,4-linkages, 10% 1,2-linkages, and random stereochemistry along the precursor backbones which result from the nonstereospecific nature of the radical polymerization. A route to 100% 1,4-linked PPP precursors with the correct stereochemistry for facile cis-pyrolytic elimination of the pendant groups has been developed which combines the efficiency and processability of the ICI process with the regio- and stereochemical control possible through transition-metal catalysts (Scheme I)

Ring-opening metathesis polymerization of substituted bicyclo[2.2.2]octadienes: a new precursor route to poly(1,4-phenylenevinylene)

Poly(1,4-phenylenevinylene) (PPV), a perfectly alternating copolymer of p-phenylene and trans-vinylene units, possesses attractive material properties. Thin films of PPV display high electrical conductivity when doped (σ = 5000 S/cm), a large, third-order nonlinear optical response (χ^3 = 1.5 X 10^(-10) esu), and photo- and electroluminescence in the visible region. However, the extended planar topology of the PPV backbone, which renders it infusible and insoluble in nonreactive media, limits the capacity for post-synthesis fabrication of the material. A convenient method to circumvent this problem consists of a two-step synthesis via a processable intermediate polymer. This precursor polymer can be fabricated into the desired form and subsequently converted to the target polymer by a clean, intramolecular chemical reaction. Wessling and Zimmerman have reported the synthesis of a processable, water-soluble poly(l,4-xylylenesulfonium salt) that undergoes a thermally-induced elimination to PPV under mild conditions

Ring-opening metathesis polymerization of substituted bicyclo[2.2.2]octadienes: a new precursor route to poly(1,4-phenylenevinylene)

Poly(1,4-phenylenevinylene) (PPV), a perfectly alternating copolymer of p-phenylene and trans-vinylene units, possesses attractive material properties. Thin films of PPV display high electrical conductivity when doped (σ = 5000 S/cm), a large, third-order nonlinear optical response (χ^3 = 1.5 X 10^(-10) esu), and photo- and electroluminescence in the visible region. However, the extended planar topology of the PPV backbone, which renders it infusible and insoluble in nonreactive media, limits the capacity for post-synthesis fabrication of the material. A convenient method to circumvent this problem consists of a two-step synthesis via a processable intermediate polymer. This precursor polymer can be fabricated into the desired form and subsequently converted to the target polymer by a clean, intramolecular chemical reaction. Wessling and Zimmerman have reported the synthesis of a processable, water-soluble poly(l,4-xylylenesulfonium salt) that undergoes a thermally-induced elimination to PPV under mild conditions

High catalytic efficiency of palladium nanoparticles immobilized in a polymer membrane containing poly(ionic liquid) in Suzuki–Miyaura cross-coupling reaction

The elaboration of a polymeric catalytic membrane containing palladium nanoparticles is presented. The membrane was prepared using a photo-grafting process with imidazolium-based ionic liquid monomers as modifying agent and microPES® as support membrane. Ionic liquid serves as a stabilizer and immobilizer for the catalytic species, i.e. palladium nanoparticles. The Suzuki–Miyaura cross-coupling reaction was carried out on the catalytic membrane in flow-through configuration. Complete conversion was achieved in 10 s through one single filtration, without formation of byproducts. The apparent reaction rate constant was three orders of magnitude greater than in a batch reactor. No catalyst leaching was detected. This membrane offers the possibility of continuous production with no need for a separation step of the catalyst from the reaction medium

Study protocol: Australasian Registry of Severe Cutaneous Adverse Reactions (AUS-SCAR)

Introduction Severe cutaneous adverse reactions (SCAR) are a group of T cell-mediated hypersensitivities associated with significant morbidity, mortality and hospital costs. Clinical phenotypes include Stevens-Johnson syndrome (SJS), toxic epidermal necrolysis (TEN), drug reaction with eosinophilia and systemic symptoms (DRESS) and acute generalised exanthematous pustulosis (AGEP). In this Australasian, multicentre, prospective registry, we plan to examine the clinical presentation, drug causality, genomic predictors, potential diagnostic approaches, treatments and long-term outcomes of SCAR in Australia and New Zealand. Methods and analysis Adult and adolescent patients with SCAR including SJS, TEN, DRESS, AGEP and another T cell-mediated hypersensitivity, generalised bullous fixed drug eruption, will be prospectively recruited. A waiver of consent has been granted for some sites to retrospectively include cases which result in early mortality. DNA will be collected for all prospective cases. Blood, blister fluid and skin biopsy sampling is optional and subject to patient consent and site capacity. To develop culprit drug identification and prevention, genomic testing will be performed to confirm human leukocyte antigen (HLA) type and ex vivo testing will be performed via interferon-γ release enzyme linked immunospot assay using collected peripheral blood mononuclear cells. The long-term outcomes of SCAR will be investigated with a 12-month quality of life survey and examination of prescribing and mortality data. Ethics and dissemination This study was reviewed and approved by the Austin Health Human Research Ethics Committee (HREC/50791/Austin-19). Results will be published in peer-reviewed journals and presented at relevant conferences

Potassium-selective block of barium permeation through single KcsA channels

Ba2+, a doubly charged analogue of K+, specifically blocks K+ channels by virtue of electrostatic stabilization in the permeation pathway. Ba2+ block is used here as a tool to determine the equilibrium binding affinity for various monovalent cations at specific sites in the selectivity filter of a noninactivating mutant of KcsA. At high concentrations of external K+, the block-time distribution is double exponential, marking at least two Ba2+ sites in the selectivity filter, in accord with a Ba2+-containing crystal structure of KcsA. By analyzing block as a function of extracellular K+, we determined the equilibrium dissociation constant of K+ and of other monovalent cations at an extracellular site, presumably S1, to arrive at a selectivity sequence for binding at this site: Rb+ (3 µM) > Cs+ (23 µM) > K+ (29 µM) > NH4+ (440 µM) >> Na+ and Li+ (>1 M). This represents an unusually high selectivity for K+ over Na+, with |ΔΔG0| of at least 7 kcal mol−1. These results fit well with other kinetic measurements of selectivity as well as with the many crystal structures of KcsA in various ionic conditions

Energy applications of ionic liquids

Ionic liquids offer a unique suite of properties that make them important candidates for a number of energy related applications. Cation–anion combinations that exhibit low volatility coupled with high electrochemical and thermal stability, as well as ionic conductivity, create the possibility of designing ideal electrolytes for batteries, super-capacitors, actuators, dye sensitised solar cells and thermoelectrochemical cells. In the field of water splitting to produce hydrogen they have been used to synthesize some of the best performing water oxidation catalysts and some members of the protic ionic liquid family co-catalyse an unusual, very high energy efficiency water oxidation process. As fuel cell electrolytes, the high proton conductivity of some of the protic ionic liquid family offers the potential of fuel cells operating in the optimum temperature region above 100 °C. Beyond electrochemical applications, the low vapour pressure of these liquids, along with their ability to offer tuneable functionality, also makes them ideal as CO2 absorbents for post-combustion CO2 capture. Similarly, the tuneable phase properties of the many members of this large family of salts are also allowing the creation of phase-change thermal energy storage materials having melting points tuned to the application. This perspective article provides an overview of these developing energy related applications of ionic liquids and offers some thoughts on the emerging challenges and opportunities

Symmetries of the Central Vestibular System: Forming Movements for Gravity and a Three-Dimensional World

Intrinsic dynamics of the central vestibular system (CVS) appear to be at least partly determined by the symmetries of its connections. The CVS contributes to whole-body functions such as upright balance and maintenance of gaze direction. These functions coordinate disparate senses (visual, inertial, somatosensory, auditory) and body movements (leg, trunk, head/neck, eye). They are also unified by geometric conditions. Symmetry groups have been found to structure experimentally-recorded pathways of the central vestibular system. When related to geometric conditions in three-dimensional physical space, these symmetry groups make sense as a logical foundation for sensorimotor coordination