Characterization of Novel Poly(lipid) BLMs for Long-Term Ion Channel Scaffolds Towards the Development of High-Throughput Screening Devices

Heitz, Benjamin Arthur

January 2010

Suspended lipid bilayers, or black lipid membranes (BLMs), have been used to study the electrophysiological properties of ion channels (ICs); however, BLMs assembled from natural, non-polymerizable lipids are inherently unstable due to the non-covalent associations on which they are based. Lifetimes of several hours are commonly observed in BLMs until rupture due to mechanical, thermal, or chemical insults. One potential improvement is the use of polymerizable phospholipids (poly(lipids)). BLMs prepared using dienoyl functionalized poly(lipids) and binary mixtures of fluid, non-polymerizable lipids with poly(lipids) were investigated for IC recordings.poly(BLMs) exhibited enhanced lifetimes from several hours to upwards of 4 weeks while maintaining IC functionality for one week. Activity of ICs that require membrane fluidity was retained using binary phospholipid mixtures of fluid and polymeric phospholipids. IC activity was retained by inducing domain formation, wherein ICs incorporated into the fluid domains. The binary membranes exhibited marked enhancement in stability resulting from fractional poly(lipids) polymerization. Additionally, ICs can be reconstituted into the fluid domains following photopolymerization and subsequent domain formation, a key requirement when UV-sensitive ICs are utilized. Here, the electrical properties, stability, and incorporation of pore-forming ICs, including hemolysin, alamethicin, and gramicidin, into poly(lipid) membranes are reported. Potential applications developing ligand-gated IC based sensors for high throughput screening are being investigated.In parallel to the characterization of poly(lipids) for potential long-term IC membranes, a model ligand-gated IC was expressed, characterized, and reconstituted into non-polymerizable lipids. Mutant K_ATP channels were expressed in mammalian and yeast systems. The orientations of mutant K_ATP channels were studied using electrophysiological and immunohistochemical techniques. Large quantities were expressed and purified from <italic>Pichia pastoris</italic> and functionally reconstituted into BLMs. ATP and long-chaing coenzyme A ester sensitivity was maintained in reconstituted in BLMs. K_ATP channels will serve as a model system for testing the effect of poly(lipid) BLMs on IC function. Future utilization of poly(lipid) BLMs in combination with ligand-gated ICs offer major advancements to potential increased throughput for IC screening.

Biosensors

BLMs

Ion channels

Polymerizable lipids

Advanced clay nanocomposites based on in situ photopolymerization utilizing novel polymerizable organoclays

Kim, Soon Ki

01 May 2012

Polymer nanocomposite technology has had significant impact on material design. With the environmental advantages of photopolymerization, a research has recently focused on producing nanocomposites utilizing inexpensive clay particles based on in situ photopolymerization. In this research, novel polymerizable organoclays and thiol-ene photopolymerization have been utilized to develop advanced photopolymer clay nanocomposites and to overcome several limitations in conventional free radical photopolymers. To this end, factors important in nanocomposite processes such as monomer composition, clay dispersion, and photopolymerization behavior in combination with the evolution of ultimate nanocomposite properties have been investigated. For monomer-organoclay compositions, higher chemical compatibility of components induces enhanced clay exfoliation, resulting in photopolymerization rate increases due to an amplified clay template effect. Additionally, by affecting the stoichiometric ratio between thiol and acrylate double bond in the clay gallery, thiolated organoclays enhance thiol-ene copolymerization with increased final thiol conversion while acrylated organoclays encourage acrylate homopolymerization. In accordance with the reaction behavior, incorporation of thiolated organoclays makes polymer chains more flexible with decreased glass transition temperature due to higher formation of thio-ether linkages while adding acrylated organoclays significantly increases the modulus. Photopolymer nanocomposites also help overcome two major drawbacks in conventional free radical photopolymerization, namely severe polymerization shrinkage and oxygen inhibition during polymerization. With addition of a low level of thiol monomers, the oxygen inhibition in various acrylate systems can be overcome by addition of only 5wt% thiolated organoclay. The same amount of polymerizable organoclay also induces up to 90% decreases in the shrinkage stress for acrylate or thiol-acrylate systems. However, nonreactive clays do not reduce the stress substantially and even decreases the polymerization rate in air. Additionally, the clay morphology and polymerization behavior are closely related with evolution of ultimate nanocomposite performance. Use of polymerizable organoclay significantly improves overall toughness of nanocomposites by increasing either modulus or elongation at break based on the type of polymerizable organoclay, which demonstrates the promise of this technology as a modulation and/or optimization tool for nanocomposite properties.

clay modification

nanocomposite

photopolymerization

polymerizable organoclays

thiol-ene

Chemical Engineering

Oligoethyleneoxide spacer groups in polymerizable surfactants

Laschewsky, André

January 1991

Cationic and zwitterionic polymerizable surfactants bearing tri- and tetraethyleneglycol spacer groups between the polymerizable moiety and the surfactant structure were prepared and polymerized. Monomers and polymers were investigated with respect to their aggregation behavior in aqueous systems and compared to analogous monomers and polymers lacking spacer groups. In the case of the monomeric surfactants, the spacer groups depress both the Kraffttemperature and the critical micelle concentration. the area occupied per molecule at the air-water interface is substantially enlarged by the spacers, whereas the depression of surface tension is nearly constant. Although the monomers with and without spacers are true surfactants, all the polymers are water-insoluble, but form monomolecular layers at the air-water interface. In analogy to the monomer behavior, the incorporation of the spacer groups increases the area occupied per repeat unit at the air-water interface substantially, but hardly affects the surface activity.

Polymerizable surfactant

polysoap

sulfobetain

spacer

micelle

monolayer

Chemistry and allied sciences

Preparation and Characterization of Novel Lipid and Proteolipid Membranes from Polymerizable Lipids

Subramaniam, Varuni

January 2006

The work described here has focused on two types of supramolecular assemblies, supported lipid bilayers (SLBs) and giant vesicles (GVs) from polymerizable lipids. SLBs are explored extensively as structural models in biophysical studies of cell membranes and biosensor coatings. With regard to implementation as biocompatible scaffoldings for receptor-based molecular devices, fluid SLBs lack chemical, thermal and mechanical stability as lipids are self-organized by weak, noncovalent forces. One possible solution is to use synthetic lipid monomers that can be polymerized to form robust bilayers. A key question is how polymerization affects transmembrane protein structure and activity. Specifically it is unclear if lipid cross-linking can be achieved without adversely affecting the activity of incorporated proteins. In this work the effect of lipid polymerization on transmembrane protein activity was studied with rhodopsin. The protein was reconstituted into SLBs composed of polymerizable lipids, bis-SorbPC, bis-SorbPC:mono-SorbPC, bis-DenPC and bis-SorbPC:mono-SorbPE. Rhodopsin photoactivity was monitored using plasmon waveguide spectroscopy. The results show that reconstitution of rhodopsin into SLBs composed of phosphatidylcholine with the polymerizable moiety in the acyl chain terminus, followed by photoinduced cross-linking of the lipids, does not significantly perturb protein function. A possible explanation is that a bilayer with relatively low Xn retains sufficient elasticity to accommodate the membrane deformation that accompanies the conformational change associated with rhodopsin photoactivation when polymerized in the acyl chain terminus. GVs have diameters ranging from several to few hundred micrometers and thus can be observed by optical microscopic methods. This allows manipulation of individual vesicles and observation of their transformations in real time. GVs have attracted attention as microcontainers for enzymes and drugs, and as biosensors. With the aim of increasing stability for these types of applications, GVs were prepared from synthetic dienoyl lipids that can be polymerized to form robust vesicles. The stability of these vesicles after polymerization was investigated by surfactant treatment, drying and rehydration, and temperature variations. The structure of poly(GVs) was largely retained under these conditions which destroy unpolymerized vesicles. Permeability studies on poly(GVs) suggests that they could be potentially used in a variety of technological applications, including sensors, macromolecular carriers, and microreactors.

Polymerizable lipids

Supported lipid membranes

Rhodopsin

Giant Vesicles

STUDY OF TRANSMEMBRANE PROTEIN ACTIVITY IN STABILIZED LIPID MEMBRANES AND DEVELOPMENT AND APPLICATIONS OF SURFACE SENSITIVE PLASMON WAVEGUIDE RESONANCE SPECTROSCOPY

Zhang, Han

January 2010

This dissertation covers a broad range of research topics all towards the ultimate goal establishing of a novel type of biosensor in which the biocompatible membrane structure reconstituted with functional transmembrane proteins is utilized as the sensing element. It focuses on 1) examining the activity of a model transmembrane protein, bovine rhodopsin (Rho) when reconstituted into stabilized lipid membranes and 2) the instrumentation of a novel type of optical spectroscopy, plasmon waveguide resonance (PWR), which is a surface sensitive technique and its application in sensing biological events.Lipid membrane play crucial roles in cell function. Their biophysical properties affect the activity of a large amount of transmembrane receptors. They are great candidates for biosensing/ biomedical coating. However, the intrinsic instability of natural or fluid membranes prevents them to be used in a device. Studies have been done to show indirect evidence that the activity of Rho maybe maintained in polymerized membrane composed of bis-SorbPC lipids. The activity of Rho reconstituted into vesicular membranes comprised of various lipids was studied by a more direct technique, UV-Vis. It was found Rho activity was maintained to 66% of that in natural Egg PC lipid in the mixture of Egg PC:(poly)bis-SorbPC (1:1 mol:mol) as opposed to minimal values in 100 % (poly)lipids.A new type of spectral PWR was developed. The working concept, technical characterization and comparisons with similar techniques were discussed and compared in this work. A modified version of angular PWR in which lipid bilayers were formed by vesicle fusion was also developed. This method excludes possible effects from a high boiling point organic solvent on either the lipid bilayer itself or the membrane proteins associated with it. A calculating program NphaseAll for PWR was developed to do predictions of waveguide properties can be made to provide guidance for waveguide design. Theoretical calculations were done for PWR and experimental results were compared with the theoretical predictions.PWR was used to detect the formation of a biological lipid membrane, the association of alpha synuclein with membranes and the binding activity of human melanarcortin to its ligands in fluid and polymerized/dried membranes.

Plasmon Waveguide Resonance Spectroscopy

Polymerizable Lipid Membrane

Transmembrane Protein

Diffusion Coefficients and Mechanical Properties of Polymerizable Lipid Membranes

Orosz, Kristina Suzanne

January 2011

It would be beneficial to incorporate transmembrane proteins (TMPs) into biosensors, because TMPs are important for cell function in healthy and diseased states. These devices would employ an artificial cell membrane to maintain TMP function since cell membranes, which are mostly lipids, are necessary for the TMPs to function. These artificial lipid membranes must be robust for sensor applications. The ruggedness of these artificial membranes can be increased by using polymerizable lipids. Some polymerized lipid membranes exhibit increased stability, while successfully incorporating TMPs.Some polymerized membranes do not support the activity of certain TMPs, while maintaining the function of others. It is believed the physical properties of the membranes are important for TMP function. Some important physical properties of polymerizable lipid membranes have not yet been measured. Here, fluidity and mechanical properties of polymerizable dienoylPC lipid membranes were investigated.Fluorescence Recovery After Photobleaching was used to measure the fluidity of polymerizable dienoylPC membranes. Unpolymerized, UV-polymerized, and redox-polymerized membranes were investigated. Three types of membranes were found: fluid, partially fluid, and immobile. Unpolymerized and some polymerized membranes were fluid, while only polymerized membranes were partially fluid or immobile. Polymer size is believed to cause the differences in fluidity. This study highlights how polymerization parameters can influence membrane fluidity.Micropipette Aspiration was used to measure the mechanical properties of Giant Unilamellar Vesicles (GUVs) composed of dienolyPC lipids. Unpolymerized and UV-polymerized GUVs were investigated. Strength measurements showed that denoylPC GUVs were stronger than sorbylPC GUVs. Area expansion moduli of denoylPCs and mono-SorbPC GUVs were slightly lower than SOPC GUVs, while bis-SorbPC GUVs were substantially easier to stretch. The bending moduli of all GUVs was similar. UV-polymerization had no significant effect on the parameters. The difference in strength between denoylPCs and sorbylPCs is hypothesized to be due to the porous nature of sorbylPCs. It is thought UV-polymerization of these GUVs created polymers too small to significantly alter mechanical properties.It was demonstrated that some stable membranes are also fluid, which is important for the function of certain TMPs. A correlation cannot be made between the bending and stretching moduli of polymerizable membranes and function of TMPs.

Lipid membranes

Mechanical Properties

micropipette Aspiration

Polymerizable Lipids

Chemistry

Diffusion Coefficient

FRAP

Formation and Characterization of Hybrid Bilayers and Diffusion of Cations Across Liposomal Membranes: Studies Based on Polymerizable Lipids

Ratnayaka, Saliya Nalin

January 2007

Cellular energy transduction processes are often driven by transmembrane ion gradients, and a number of artificial membrane systems have been developed that allow for chemically or light-induced transport of ions across lipid bilayers. These liposomal architectures, however, are not readily interfaced to a solid-state transducer. A significant step toward this goal is described here by assessing the possibility of coupling a lipid bilayer directly to a transducer to form a stable uniform film using hybrid bilayer membranes (HBMs).Although the surface attachment of self-assembled monolayer increases the robustness of the lipid assembly, HBMs cannot maintain film uniformity under harsher conditions due to the absence of strong lipid-lipid interactions. Therefore, HBMs were prepared and characterized using a cross-linking polymerizable lipid, bis-SorbPC. Several parameters relating to lipid deposition and film stabilization through polymerization were examined. Film characterization strongly suggests that polymerization of bis-SorbPC stabilizes the HBM such that its structure is largely preserved even after the dehydration process. This work suggests that network formation in the upper monolayer is not enough to prevent oligomer desorption, intermonolayer covalent linking is also a prerequisite in making uniform, defect-free planar supported lipid assemblies.Some of the challenges associated with the application of lipids involve the creation of supported bilayers that are stable to chemical and physical disruptions, yet retain their ion barrier properties, and allow transmembrane ion transport by lipid-soluble shuttles. Polymerized lipid films provide the stability required for these structures, but permeability properties of cations across poly(lipid) membranes are not known. Therefore, convenient liposome-based proton and calcium permeability assays were developed. These assays were applied to various poly(lipid) compositions.In addition, three novel sorbyl-substituted head group polymerizable lipids, which have been synthesized based on a strategy that head group polymerization would minimally perturb the characteristic ion impermeability of the membrane, were evaluated for their lipid characteristics and ability to form polymers. None of these compounds forms vesicles by itself. Therefore, attempts were made to form mixed vesicles with other fluid lipids. The miscibility of the mixed monolayers was assessed using Langmuir isotherms.

polymerizable lipids

sorbyl lipids

hybrid bilayers

proton permeability

calcium permeability

bola lipids

Functionalized Crosslinked Matrices And Counter-Ion Crosslinked Surfactant Systems

Paul, Geeta Kheter

01 1900

No description available.

Surfactants

Cross-linked Matrices

Polymerizable Surfactants

Polymerization

Crosslinked Surfactant Systems

Organic Chemistry

DEVELOPMENT OF THERMALLY CONTROLLED LANGMUIR–SCHAEFER CONVERSION TECHNIQUES FOR SUB-10-NM HIERARCHICAL PATTERNING ACROSS MACROSCOPIC SURFACE AREAS

Tyler R Hayes (9754796)

14 December 2020

<div> As hybrid 2D materials are incorporated into next-generation device designs, it becomes more and more pertinent that methods are being developed which can facilitate large-area structural control of noncovalent monolayers assembled at 2D material interfaces. Noncovalent functionalization is often leveraged to modulate the physical properties of the underlying 2D material without disrupting the extended electronic delocalization networks intrinsic to its basal plane. The bottom-up nanofabrication technique of self-assembly permits sub-10-nm chemical patterning with low operational costs and relatively simple experimental designs.</div><div> The Claridge Group is interested in leveraging the unique chemical orthogonality intrinsic to the cellular membrane as a means of creating sub-10-nm hydrophilic-hydrophobic striped patterns across 2D material interfaces for applications ranging from interfacial wetting to large-area molecular templates to guide heterogeneous nanoparticle assembly. Using Langmuir–Schaefer conversion, standing phases of polymerizable amphiphiles at the air-water interfaces of a Langmuir trough are converted (through rotation) to lying-down phases on 2D material substrates. Using room temperature substrates, transfer of amphiphiles to a lowered substrate results in small domains and incomplete surface coverage.</div><div> Recognizing that heating the substrate during the LS conversion process may lower the energy barriers to molecular reorientation, and promote better molecular domain assembly, we developed a thermally controlled heated transfer stage that can maintain the surface temperature of the substrate throughout the deposition process. We found that heating during transfer results in the assembly of domains with edge lengths routinely an order of magnitude larger than transfer using room temperature substrates that are more stable towards rigorous repeat washing cycles with both polar and nonpolar solvents.</div><div> To promote the effectiveness of the LS conversion technique beyond academic environments for the noncovalent functionalization 2D material substrates for next-generation device designs, we designed and built a thermally controlled rotary stage to address the longstanding scaling demerit of LS conversion. First, we report the development of a flexible HOPG substrate film that can wrap around the perimeter of the heated disk and can be continuously cycled through the Langmuir film. We found that thermally controlled rotary (TCR) LS conversion can achieve nearly complete surface coverage at the slowest translation speed tested (0.14 mm/s). TCR–LS facilitates the assembly of domains nearly 10,000 μm² which were subsequently used as molecular templates to guide the assembly of ultranarrow AuNWs from solution in a non-heated rotary transfer step. Together, these findings provide the foundation for the use of roll-to-roll protocols to leverage LS conversion for noncovalent functionalization of 2D materials. A true roll-to-roll thermally controlled LS conversion system may prove to be advantageous and a cost-efficient process in applications that require large areas of functional surface, or benefit from long-range ordering within the functional film.</div>

self-assembly

noncovalent functionalization

2D materials

self-assembled monolayer

Langmuir–Schaefer transfer

polymerizable amphiphile

thin films

thermally controlled transfer

long-range ordering

large-area functionalization

Langmuir–Schaefer conversion

layer-by-layer processing

roll-to-roll processing