36 research outputs found
Multi-Technique Investigation of a Biomimetic Insect Tarsal Adhesive Fluid
There is substantial motivation to develop novel adhesives which take advantage of the
superior adhesive strength and adaptability of many natural animal adhesives; however,
the tools typically used to study these mechanisms are incapable of determining the
precise interactions of molecules at an adhesive interface. In this study, a surface
specific, order sensitive vibrational spectroscopy called sum frequency generation (SFG)
is, for the first time, combined with multiple bulk characterization techniques to examine
a novel, simple biomimetic adhesive fluid inspired by tarsal fluid of insects. Insects
perform complex adhesive demands, including sticking, climbing vertically and running
upside-down with little difficulty. Thus, we hypothesize that both bulk and surface specific
properties of the fluid contribute to the success of this wet adhesive mechanism.
SFG spectra of biomimetic emulsion exhibited similar hydrocarbon organization on
hydrophobic and hydrophilic substrates to natural beetle fluid previously studied with
the same method. Bulk characterization techniques indicated that the emulsion had
a shear-thinning profile with the ability to enhance traction forces during climbing
and low surface tension ideal for surface wetting on the majority of natural surfaces.
Multi-technique comparisons between emulsion and pure squalane revealed that a
hydrocarbon only based fluid could not replicate the traction promoting properties
of the emulsion. We conclude that the insect tarsal fluid adhesive mechanism relies
upon contributions from both surface-specific properties optimizing traction force and
bulk properties promoting rapid surface wetting and maintaining pull-off force for
fast detachment
Recommended from our members
Probing the orientation of electrostatically immobilized cytochrome C by time of flight secondary ion mass spectrometry and sum frequency generation spectroscopy
By taking advantage of the electron pathway through the heme group in cytochrome c (CytoC) electrochemists
have built sensors based upon CytoC immobilized onto metal electrodes. Previous studies have shown that the
electron transfer rate through the protein is a function of the position of this heme group with respect to the
electrode surface. In this study a detailed examination of CytoC orientation when electrostatically immobilized onto
both amine (NH₃⁺) and carboxyl (COO⁻) functionalized gold is presented. Protein coverage, on both surfaces, was
monitored by the change in the atomic % N, as determined by x-ray photoelectron spectroscopy. Spectral features
within the in situ sum frequency generation vibrational spectra, acquired for the protein interacting with positively
and negatively charged surfaces, indicates that these electrostatic interactions do induce the protein into a well
ordered film. Time of flight secondary ion mass spectrometry data demonstrated a clear separation between the
two samples based on the intensity differences of secondary ions stemming from amino acids located
asymmetrically within CytoC (cysteine: C₂H₆NS⁺; glutamic acid: C₄H₆NO⁺ and C₄H₈NO₂⁺; leucine: C₅H₁₂N⁺). For a
more quantitative examination of orientation, we developed a ratio comparing the sum of the intensities of
secondary-ions stemming from the amino acid residues at either end of the protein. The 50 % increase in this ratio,
observed between the protein covered NH₃⁺ and COO⁻ substrates, indicates opposite orientations of the CytoC on
the two different surfaces
Recommended from our members
Differential surface activation of the A1 domain of von Willebrand factor
The clotting protein von Willebrand factor (VWF) binds to platelet receptor glycoprotein Ibα (GPIbα) when VWF is activated by chemicals, high shear stress, or immobilization onto surfaces. Activation of VWF by surface immobilization is an important problem in the failure of cardiovascular implants, but is poorly understood. Here, the authors investigate whether some or all surfaces can activate VWF at least in part by affecting the orientation or conformation of the immobilized GPIbα-binding A1 domain of VWF. Platelets binding to A1 adsorbed onto polystyrene surfaces translocated rapidly at moderate and high flow, but detached at low flow, while platelets binding to A1 adsorbed onto glass or tissue-culture treated polystyrene surfaces translocated slowly, and detached only at high flow. Both x-ray photoelectron spectroscopy and conformation independent antibodies reported comparable A1 amounts on all surfaces. Time-of-flight secondary ion mass spectrometry (ToF-SIMS) and near-edge x-ray absorption fine structure spectra suggested differences in orientation on the three surfaces, but none that could explain the biological data. Instead, ToF-SIMS data and binding of conformation-dependent antibodies were consistent with the stabilization of an alternative more activated conformation of A1 by tissue culture polystyrene and especially glass. These studies demonstrate that different materialsurfaces differentially affect the conformation of adsorbed A1 domain and its biological activity. This is important when interpreting or designing in vitro experiments with surface-adsorbed A1 domain, and is also of likely relevance for blood-contacting biomaterials
Recommended from our members
Biomimetic vaterite formation at surfaces structurally templated by oligo(glutamic acid) peptides
Previous studies have reported that the metastable vaterite phase of calcium carbonate can be stabilized in solution by acidic additives. Here we demonstrate that vaterite can also be stabilized directly at surfaces by engineered peptides. Our data show that the mineralisation occurs in a 'self-templating' process where calcium ions restructure the peptide backbone, which in turn allows for effective vaterite precipitation.This is the publisher’s final pdf. The published article is copyrighted by the Royal Society of Chemistry and can be found at: http://pubs.rsc.org/en/Journals/JournalIssues/CC#!recentarticles&ad
Recommended from our members
Full membrane spanning self-assembled monolayers as model systems for UHV-based studies of cell-penetrating peptides
Biophysical studies of the interaction of peptides with model membranes provide a simple yet effective approach to understand the transport of peptides and peptide based drug carriers across the cell membrane. Herein, the authors discuss the use of self-assembled monolayers fabricated from the full membrane-spanning thiol (FMST) 3-((14-((40-((5-methyl-1-phenyl-35-(phytanyl)oxy- 6,9,12,15,18,21,24,27,30,33,37-undecaoxa-2,3-dithiahenpentacontan-51-yl)oxy)-[1,10-biphenyl]-4- yl)oxy)tetradecyl)oxy)-2-(phytanyl)oxy glycerol for ultrahigh vacuum (UHV) based experiments. UHV-based methods such as electron spectroscopy and mass spectrometry can provide important information about how peptides bind and interact with membranes, especially with the hydrophobic core of a lipid bilayer. Near-edge x-ray absorption fine structure spectra and x-ray photoelectron spectroscopy (XPS) data showed that FMST forms UHV-stable and ordered films on gold. XPS and time of flight secondary ion mass spectrometry depth profiles indicated that a proline-rich amphipathic cell-penetrating peptide, known as sweet arrow peptide is located at the outer perimeter of the model membrane.This is the publisher’s final pdf. The article is copyrighted by the American Vacuum Society and published by the American Institute of Physics Publishing. It can be found at: http://scitation.aip.org/content/avs/journal/bip;jsessionid=1g93rvqb7shb6.x-aip-live-03
Recommended from our members
Multiscale Effects of Interfacial Polymer Confinement in Silica Nanocomposites
Dispersing hydrophilic nanofillers in highly hydrophobic polymer matrices is widely used to tune the mechanical properties of composite material systems. The ability to control the dispersion of fillers is closely related to the mechanical tunability of such composites. In this work, we investigate the physical–chemical underpinnings of how simple end-group modification to one end of a styrene–butadiene chain modifies the dispersion of silica fillers in a polymer matrix. Using surface-sensitive spectroscopies, we directly show that polymer molecular orientation at the silica surface is strongly constrained for silanol functionalized polymers compared to nonfunctionalized polymers because of covalent interaction of silanol with silica. Silanol functionalization leads to reduced filler aggregation in composites. The results from this study demonstrate how minimal chemical modifications of polymer end groups are effective in modifying microstructural properties of composites by inducing molecular ordering of polymers at the surface of fillers
Size-Dependent Interactions of Lipid-Coated Gold Nanoparticles: Developing a Better Mechanistic Understanding Through Model Cell Membranes and in vivo Toxicity
Introduction: Humans are intentionally exposed to gold nanoparticles (AuNPs) where they are used in variety of biomedical applications as imaging and drug delivery agents as well as diagnostic and therapeutic agents currently in clinic and in a variety of upcoming clinical trials. Consequently, it is critical that we gain a better understanding of how physiochemical properties such as size, shape, and surface chemistry drive cellular uptake and AuNP toxicity in vivo. Understanding and being able to manipulate these physiochemical properties will allow for the production of safer and more efficacious use of AuNPs in biomedical applications.Methods and Materials: Here, AuNPs of three sizes, 5 nm, 10 nm, and 20 nm, were coated with a lipid bilayer composed of sodium oleate, hydrogenated phosphatidylcholine, and hexanethiol. To understand how the physical features of AuNPs influence uptake through cellular membranes, sum frequency generation (SFG) was utilized to assess the interactions of the AuNPs with a biomimetic lipid monolayer composed of a deuterated phospholipid 1.2-dipalmitoyl-d62-sn-glycero-3-phosphocholine (dDPPC).Results and Discussion: SFG measurements showed that 5 nm and 10 nm AuNPs are able to phase into the lipid monolayer with very little energetic cost, whereas, the 20 nm AuNPs warped the membrane conforming it to the curvature of hybrid lipid-coated AuNPs. Toxicity of the AuNPs were assessed in vivo to determine how AuNP curvature and uptake influence cell health. In contrast, in vivo toxicity tested in embryonic zebrafish showed rapid toxicity of the 5 nm AuNPs, with significant 24 hpf mortality occurring at concentrations ≥ 20 mg/L, whereas the 10 nm and 20 nm AuNPs showed no significant mortality throughout the five-day experiment.Conclusion: By combining information from membrane models using SFG spectroscopy with in vivo toxicity studies, a better mechanistic understanding of how nanoparticles (NPs) interact with membranes is developed to understand how the physiochemical features of AuNPs drive nanoparticle–membrane interactions, cellular uptake, and toxicity
NHC-Based Self-Assembled Monolayers on Solid Gold Substrates
Thin films of 1,3-diethylbenzimidazol-2-ylidene (BIEt) were fabricated from THF solution on solid gold substrates and characterised by high-resolution X-ray photoelectron and near-edge X-ray absorption fine structure spectroscopy. The surface-analytical data are in accord with the formation of self-assembled monolayers of BIEt molecules exhibiting an approximately vertical orientation on the substrate. The crystal structure of (BIEt)(2) was also determined
Recommended from our members
LuBiomimeticVateriteFormationSupportingInformation.pdf
Previous studies have reported that the metastable vaterite phase of calcium carbonate can be stabilized in solution by acidic additives. Here we demonstrate that vaterite can also be stabilized directly at surfaces by engineered peptides. Our data show that the mineralisation occurs in a 'self-templating' process where calcium ions restructure the peptide backbone, which in turn allows for effective vaterite precipitation