6 research outputs found
Natural Organic Matter Concentration Impacts the Interaction of Functionalized Diamond Nanoparticles with Model and Actual Bacterial Membranes
Changes to nanoparticle surface charge,
colloidal stability, and
hydrodynamic properties induced by interaction with natural organic
matter (NOM) warrant consideration in assessing the potential for
these materials to adversely impact organisms in the environment.
Here, we show that acquisition of a coating, or “corona”,
of NOM alters the hydrodynamic and electrokinetic properties of diamond
nanoparticles (DNPs) functionalized with the polycation polyÂ(allylamine
HCl) in a manner that depends on the NOM-to-DNP concentration ratio.
The NOM-induced changes to DNP properties alter subsequent interactions
with model biological membranes and the Gram-negative bacterium <i>Shewanella oneidensis</i> MR-1. Suwannee River NOM induces changes
to DNP hydrodynamic diameter and apparent ζ-potential in a concentration-dependent
manner. At low NOM-to-DNP ratios, DNPs aggregate to a limited extent
but retain a positive ζ-potential apparently due to nonuniform
adsorption of NOM molecules leading to attractive electrostatic interactions
between oppositely charged regions on adjacent DNP surfaces. Diamond
nanoparticles at low NOM-to-DNP ratios attach to model membranes to
a larger extent than in the absence of NOM (including those incorporating
lipopolysaccharide, a major bacterial outer membrane component) and
induce a comparable degree of membrane damage and toxicity to <i>S. oneidensis</i>. At higher NOM-to-DNP ratios, DNP charge is
reversed, and DNP aggregates remain stable in suspension. This charge
reversal eliminates DNP attachment to model membranes containing the
highest LPS contents studied due to electrostatic repulsion and abolishes
membrane damage to <i>S. oneidensis</i>. Our results demonstrate
that the effects of NOM coronas on nanoparticle properties and interactions
with biological surfaces can depend on the relative amounts of NOM
and nanoparticles
Lipid Corona Formation from Nanoparticle Interactions with Bilayers and Membrane-Specific Biological Outcomes
While mixing nanoparticles with certain
biological molecules can result in coronas that afford some control over how engineered
nanomaterials interact with living systems, corona formation mechanisms remain
enigmatic. Here, we report spontaneous lipid
corona formation, i.e. without active mixing, upon attachment to stationary lipid
bilayer model membranes and bacterial cell envelopes, and present ribosome-specific
outcomes for multi-cellular organisms. Experiments show that polycation-wrapped
particles disrupt the tails of zwitterionic lipids, increase bilayer fluidity, and
leave the membrane with reduced ζ-potentials. Computer simulations show contact
ion pairing between the lipid headgroups and the polycations’ ammonium groups leads
to the formation of stable, albeit fragmented, lipid bilayer coronas, while microscopy
shows fragmented bilayers around nanoparticles after interacting with Shewanella oneidensis. Our mechanistic insight
can be used to improve control over nano-bio interactions and to help understand
why some nanomaterial/ligand combinations are detrimental to organisms, like Daphnia magna, while others are not. </a
Direct Probes of 4 nm Diameter Gold Nanoparticles Interacting with Supported Lipid Bilayers
This work presents molecular-level
investigations of how well-characterized
silica-supported phospholipid bilayers formed from either pure DOPC
or a 9:1 mixture of DOPC:DOTAP interact with positively and negatively
charged 4 nm gold metal nanoparticles at pH 7.4 and NaCl concentrations
ranging from 0.001 to 0.1 M. Second harmonic generation (SHG) charge
screening measurements indicate the supported bilayers carry a negative
interfacial potential. Resonantly enhanced SHG measurements probing
electronic transitions within the gold core of the nanoparticles show
the particles interact irreversibly with the supported bilayers at
a range of concentrations. At 0.1 M NaCl, surface coverages for the
particles functionalized with the negatively charged ligand mercaptopropionic
acid (MPA) or wrapped in the cationic polyelectrolyte polyÂ(allylamine)
hydrochloride (PAH) are estimated from a joint analysis of QCM-D,
XPS, AFM, and ToF-SIMS to be roughly 1 Ă— 10<sup>7</sup> and 1
× 10<sup>11</sup> particles cm<sup>–2</sup>, respectively.
Results from complementary SHG charge screening experiments point
to the possibility that the surface coverage of the MPA-coated particles
is more limited by interparticle Coulomb repulsion due to the charges
within their hydrodynamic volumes than with the PAH-wrapped particles.
Yet, SHG adsorption isotherms indicate that the interaction strength
per particle is independent of ionic strength and particle coating,
highlighting the importance of multivalent interactions. <sup>1</sup>H NMR spectra of the lipids within vesicles suspended in solution
show little change upon interaction with either particle type but
indicate loosening of the gold-bound PAH polymer wrapping upon attachment
to the vesicles. The thermodynamic, spectroscopic, and electrostatic
data presented here may serve to benchmark experimental and computational
studies of nanoparticle attachment processes at the nano–bio
interface
Lipid Corona Formation from Nanoparticle Interactions with Bilayers and Membrane-Specific Biological Outcomes
<a></a><a>While mixing nanoparticles with certain
biological molecules can result in coronas that afford some control over how engineered
nanomaterials interact with living systems, corona formation mechanisms remain
enigmatic. Here, we report spontaneous lipid
corona formation, i.e. without active mixing, upon attachment to stationary lipid
bilayer model membranes and bacterial cell envelopes, and present ribosome-specific
outcomes for multi-cellular organisms. Experiments show that polycation-wrapped
particles disrupt the tails of zwitterionic lipids, increase bilayer fluidity, and
leave the membrane with reduced ζ-potentials. Computer simulations show contact
ion pairing between the lipid headgroups and the polycations’ ammonium groups leads
to the formation of stable, albeit fragmented, lipid bilayer coronas, while microscopy
shows fragmented bilayers around nanoparticles after interacting with <i>Shewanella oneidensis</i>. Our mechanistic insight
can be used to improve control over nano-bio interactions and to help understand
why some nanomaterial/ligand combinations are detrimental to organisms, like <i>Daphnia magna</i>, while others are not. </a