Inkjet-Printed Phospholipid Bilayers on Titanium Oxide Surfaces: Towards Functional Membrane Biointerfaces.

Functional biointerfaces hold broad significance for designing cell-responsive medical implants and sensor devices. Solid-supported phospholipid bilayers are a promising class of biological materials to build bioinspired thin-film coatings, as they can facilitate interactions with cell membranes. However, it remains challenging to fabricate lipid bilayers on medically relevant materials such as titanium oxide surfaces. There are also limitations in existing bilayer printing capabilities since most approaches are restricted to either deposition alone or to fixed microarray patterning. By combining advances in lipid surface chemistry and on-demand inkjet printing, we demonstrate the direct deposition and patterning of covalently tethered lipid bilayer membranes on titanium oxide surfaces, in ambient conditions and without any surface pretreatment process. The deposition conditions were evaluated by quartz crystal microbalance-dissipation (QCM-D) measurements, with corresponding resonance frequency (Δf) and energy dissipation (ΔD) shifts of around −25 Hz and <1 × 10−6, respectively, that indicated successful bilayer printing. The resulting printed phospholipid bilayers are stable in air and do not collapse following dehydration; through rehydration, the bilayers regain their functional properties, such as lateral mobility (>1 µm2/s diffusion coefficient), according to fluorescence recovery after photobleaching (FRAP) measurements. By taking advantage of the lipid bilayer patterned architectures and the unique features of titanium oxide's photoactivity, we further show how patterned cell culture arrays can be fabricated. Looking forward, this work presents new capabilities to achieve stable lipid bilayer patterns that can potentially be translated into implantable biomedical devices.

Transformation of hard pollen into soft matter.

Pollen's practically-indestructible shell structure has long inspired the biomimetic design of organic materials. However, there is limited understanding of how the mechanical, chemical, and adhesion properties of pollen are biologically controlled and whether strategies can be devised to manipulate pollen beyond natural performance limits. Here, we report a facile approach to transform pollen grains into soft microgel by remodeling pollen shells. Marked alterations to the pollen substructures led to environmental stimuli responsiveness, which reveal how the interplay of substructure-specific material properties dictates microgel swelling behavior. Our investigation of pollen grains from across the plant kingdom further showed that microgel formation occurs with tested pollen species from eudicot plants. Collectively, our experimental and computational results offer fundamental insights into how tuning pollen structure can cause dramatic alterations to material properties, and inspire future investigation into understanding how the material science of pollen might influence plant reproductive success.

Molecular diffusion and nano-mechanical properties of multi-phase supported lipid bilayers.

Understanding the properties of cell membranes is important in the fields of fundamental and applied biology. While the characterization of simplified biological membrane mimics comprising liquid phase lipids has been routinely performed due to the ease of fabrication, the characterization of more realistic membrane mimics comprising multi-phase lipids remains challenging due to more complicated fabrication requirements. Herein, we report a convenient approach to fabricate and characterize multi-phase supported lipid bilayers (SLBs). We employed the solvent-assisted lipid bilayer (SALB) formation method to fabricate mixed lipid bilayers comprising liquid phase 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) and gel phase 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) lipids at room temperature. The fabrication procedure was performed inside a newly designed microfluidic chamber, which facilitated the subsequent characterization of the SLBs without exposure to air. The SLBs were then characterized via fluorescence microscopy, fluorescence recovery after photobleaching (FRAP), atomic force microscopy (AFM) and AFM-based force-distance measurements. Interestingly, results from these characterization techniques revealed that regardless of the gel phase composition, the SALB formation method consistently yielded uniform SLBs at room temperature, even though the transition temperature of DPPC is considerably higher. Furthermore, the composition ratio of DOPC and DPPC in the precursor solution is well reproduced in the fabricated SLBs. We also identified from diffusivity measurements that a high ratio of gel phase lipid revitalizes lipid-lipid interactions, which led to reduced molecular fluidity and the suppression of thermal undulation within the SLBs. Taken together, our results highlight the robustness of the SALB formation method that allows the fabrication of complex lipid bilayers with a high degree of precision, which is suitable for functional studies of biological membranes.

Solvent-assisted preparation of supported lipid bilayers.

The supported lipid bilayer (SLB) platform is a popular cell membrane mimic that is utilized in the chemical, biological, materials science, and medical fields. To date, SLB preparation has proven challenging because of the need for specialized fabrication equipment, domain-specific knowledge about topics relevant to lipid self-assembly, and extensive training in the interfacial science field. Existing methods, such as vesicle fusion, also work with only a narrow range of lipid compositions and material supports. Here, we describe a recently developed simple and versatile protocol to form SLBs. The protocol is simple because it requires minimal sample preparation and only basic microfluidics, making it technically accessible to researchers across different scientific disciplines. The protocol is versatile because it works on a wide range of material supports, such as silicon oxide, gold, and graphene, and is compatible with diverse lipid compositions, including sterols and signaling lipids. The main stages of the procedure involve dissolving a lipid sample in an organic solvent, depositing the lipid solution on a solid support, and replacing the organic solvent with aqueous buffer. In addition, we provide procedures for characterizing the quality of the prepared SLBs and present examples of biofunctionalization procedures. The protocol takes 1-2 h and is broadly useful in various application contexts, including clinical diagnostics, biosensing, and cellular interfaces.

Response of microbial membranes to butanol: interdigitation vs. disorder.

Biobutanol production by fermentation is potentially a sustainable alternative to butanol production from fossil fuels. However, the toxicity of butanol to fermentative bacteria, resulting largely from cell membrane fluidization, limits production titers and is a major factor limiting the uptake of the technology. Here, studies were undertaken, in vitro and in silico, on the butanol effects on a representative bacterial (i.e. Escherichia coli) inner cell membrane. A critical butanol : lipid ratio for stability of 2 : 1 was observed, computationally, consistent with complete interdigitation. However, at this ratio the bilayer was ∼20% thicker than for full interdigitation. Furthermore, butanol intercalation induced acyl chain bending and increased disorder, measured as a 27% lateral diffusivity increase experimentally in a supported lipid bilayer. There was also a monophasic Tm reduction in butanol-treated large unilamellar vesicles. Both behaviours are inconsistent with an interdigitated gel. Butanol thus causes only partial interdigitation at physiological temperatures, due to butanol accumulating at the phospholipid headgroups. Acyl tail disordering (i.e. splaying and bending) fills the subsequent voids. Finally, butanol short-circuits the bilayer and creates a coupled system where interdigitated and splayed phospholipids coexist. These findings will inform the design of strategies targeting bilayer stability for increasing biobutanol production titers.

Microfluidic liquid cell chamber for scanning probe microscopy measurement application.

In this paper, we present a universal microfluidic liquid chamber device platform for atomic force microscopy (AFM), which enables to fabricate the uniform lipid bilayer on the hydrophilic surface using the solvent-assisted lipid bilayer formation method. Using this device enables us to acquire the various properties of delicate soft matter, including morphological data, and mechanical property measurements, using high-resolution AFM systems. The proposed technology is expected to provide an understanding of complicated biological materials.

Dynamic Control of Intramolecular Rotation by Tuning the Surrounding Two-Dimensional Matrix Field.

The intramolecular rotation of 4-farnesyloxyphenyl-4,4-difluoro-4-bora-3a,4a-diaza- s-indacene (BODIPY-ISO) was controlled by tuning its local physical environment within a mixed self-assembled monolayer at an air-water interface. Intramolecular rotation was investigated by considering the twisted intramolecular charge transfer (TICT) fluorescence of BODIPY-ISO, which increases in intensity with increasing viscosity of the medium. In situ fluorescence spectroscopy was performed on mixed monolayers of BODIPY-ISO with several different lipids at the air-water interface during in-plane compression of the monolayers. Depending on the identity of the lipid used, the fluorescence of the mixed monolayers could be enhanced by mechanical compression, indicating that the rotation of BODIPY-ISO can be controlled dynamically in mixtures with lipids dispersed at the air-water interface. Taken together, our findings provide insight into strategies for controlling the dynamic behavior of molecular machines involving mechanical stimuli at interfaces.

Amyloid-ß Peptide Triggers Membrane Remodeling in Supported Lipid Bilayers Depending on Their Hydrophobic Thickness.

Amyloid-ß (Aß) peptide has been implicated in Alzheimer's disease, which is a leading cause of death worldwide. The interaction of Aß peptides with the lipid bilayers of neuronal cells is a critical step in disease pathogenesis. Recent evidence indicates that lipid bilayer thickness influences Aß membrane-associated aggregation, while understanding how Aß interacts with lipid bilayers remains elusive. To address this question, we employed supported lipid bilayer (SLB) platforms composed of different-length phosphatidylcholine (PC) lipids (C12:0 DLPC, C18:1 DOPC, C18:1-C16:0 POPC), and characterized the resulting interactions with soluble Aß monomers. Quartz crystal microbalance-dissipation (QCM-D) experiments identified concentration-dependent Aß peptide adsorption onto all tested SLBs, which was corroborated by fluorescence recovery after photobleaching (FRAP) experiments indicating that higher Aß concentrations led to decreased membrane fluidity. These commonalities pointed to strong Aß peptide-membrane interactions in all cases. Notably, time-lapsed fluorescence microscopy revealed major differences in Aß-induced membrane morphological responses depending on SLB hydrophobic thickness. For thicker DOPC and POPC SLBs, membrane remodeling involved the formation of elongated tubule and globular structures as a passive means to regulate membrane stress depending on Aß concentration. In marked contrast, thin DLPC SLBs were not able to accommodate extensive membrane remodeling. Taken together, our findings reveal that membrane thickness influences the membrane morphological response triggered upon Aß adsorption.