Small Particle Driven Chain Disentanglements in Polymer Nanocomposites.

Using neutron spin-echo spectroscopy, x-ray photon correlation spectroscopy, and bulk rheology, we studied the effect of particle size on the single-chain dynamics, particle mobility, and bulk viscosity in athermal polyethylene oxide-gold nanoparticle composites. The results reveal a ≈25% increase in the reptation tube diameter with the addition of nanoparticles smaller than the entanglement mesh size (≈5 nm), at a volume fraction of 20%. The tube diameter remains unchanged in the composite with larger (20 nm) nanoparticles at the same loading. In both cases, the Rouse dynamics is insensitive to particle size. These results provide a direct experimental observation of particle-size-driven disentanglements that can cause non-Einstein-like viscosity trends often observed in polymer nanocomposites.

pH Triggered Recovery and Reuse of Thiolated Poly(acrylic acid) Functionalized Gold Nanoparticles with Applications in Colloidal Catalysis.

Thiolated poly(acrylic acid) (PAA-SH) functionalized gold nanoparticles were explored as a colloidal catalyst with potential application as a recoverable catalyst where the PAA provides pH-responsive dispersibility and phase transfer capability between aqueous and organic media. This system demonstrates complete nanoparticle recovery and redispersion over multiple reaction cycles without changes in nanoparticle morphology or reduction in conversion. The catalytic activity (rate constant) was reduced in subsequent reactions when recovery by aggregation was employed, despite unobservable changes in morphology or dispersibility. When colloidal catalyst recovery employed a pH induced phase transfer between two immiscible solvents, the catalytic activity of the recovered nanoparticles was unchanged over four cycles, maintaining the original rate constant and 100% conversion. The ability to recover and reuse colloidal catalysts by aggregation/redispersion and phase transfer methods that occur at low and high pH, respectively, could be used for different gold nanoparticle catalyzed reactions that occur at different pH conditions.

Comparative study of the self-assembly of gold and silver nanoparticles onto thiophene oil.

Nanoparticle self-assembly is fundamentally important for bottom-up functional device fabrication. Currently, most nanoparticle self-assembly has been achieved with gold nanoparticles (AuNPs) functionalized with surfactants, polymeric materials, or cross-linkers. Reported herein is a facile synthesis of gold and silver nanoparticle (AgNP) films assembled onto thiophene oil by simply vortex mixing neat thiophene with colloidal AuNPs or AgNPs for ∼1 min. The AuNP film can be made using every type of colloidal AuNPs we have explored, including sodium borohydride-reduced AuNPs with a diameter of ∼5 nm, tannic acid-reduced AuNPs of ∼10 nm diameter, and citrate-reduced AuNPs with particle sizes of ∼13 and ∼30 nm diameter. The AuNP film has excellent stability and it is extremely flexible. It can be stretched, shrunken, and deformed accordingly by changing the volume or shape of the enclosed thiophene oil. However, the AgNP film is unstable, and it can be rapidly discolored and disintegrated into small flakes that float on the thiophene surface. The AuNP and AgNP films prepared in the glass vials can be readily transferred to glass slides and metal substrates for surface-enhanced Raman spectral acquisition.

Removal of molecular adsorbates on gold nanoparticles using sodium borohydride in water.

The mechanism of sodium borohydride removal of organothiols from gold nanoparticles (AuNPs) was studied using an experimental investigation and computational modeling. Organothiols and other AuNP surface adsorbates such as thiophene, adenine, rhodamine, small anions (Br(-) and I(-)), and a polymer (PVP, poly(N-vinylpyrrolidone)) can all be rapidly and completely removed from the AuNP surfaces. A computational study showed that hydride derived from sodium borohydride has a higher binding affinity to AuNPs than organothiols. Thus, it can displace organothiols and all the other adsorbates tested from AuNPs. Sodium borohydride may be used as a hazard-free, general-purpose detergent that should find utility in a variety of AuNP applications including catalysis, biosensing, surface enhanced Raman spectroscopy, and AuNP recycle and reuse.

Determination of colloidal gold nanoparticle surface areas, concentrations, and sizes through quantitative ligand adsorption.

Determination of the true surface areas, concentrations, and particle sizes of gold nanoparticles (AuNPs) is a challenging issue due to the nanoparticle morphological irregularity, surface roughness, and size distributions. A ligand adsorption-based technique for determining AuNP surface areas in solution is reported. Using a water-soluble, stable, and highly UV-vis active organothiol, 2-mercaptobenzimidazole (MBI), as the probe ligand, we demonstrated that the amount of ligand adsorbed is proportional to the AuNP surface area. The equivalent spherical AuNP sizes and concentrations were determined by combining the MBI adsorption measurement with Au(3+) quantification of aqua regia-digested AuNPs. The experimental results from the MBI adsorption method for a series of commercial colloidal AuNPs with nominal diameters of 10, 30, 50, and 90 nm were compared with those determined using dynamic light scattering, transmission electron microscopy, and localized surface plasmonic resonance methods. The ligand adsorption-based technique is highly reproducible and simple to implement. It only requires a UV-vis spectrophotometer for characterization of in-house-prepared AuNPs.

Inner filter effect on surface enhanced Raman spectroscopic measurement.

Presented herein is a combined experimental and computational study of the gold nanoparticle (AuNP) inner filter effect on surface enhanced Raman spectroscopic (SERS) measurements. Using a bianalyte strategy in which dithiopurine (DTP) and ethanol were employed as the model analytes, we demonstrated that AuNPs enhance DTP's Raman signal but attenuate ethanol's Raman intensity. Combined time-resolved UV-vis and Raman measurements showed that AuNP aggregation has significant and an exactly opposite impact on the AuNP inner filter effect and SERS enhancement. This research provides critical new insights regarding SERS signal variation and offers a simple methodology for reliable determination of the SERS enhancement factors.

Analysis of verteporfin liposomal formulations for phospholipids and phospholipid degradation products by liquid chromatography-mass spectrometry (LC-MS).

Lipid composition and lipid degradation are critical to the stability of liposomal formulations which can impact the safety and efficacy of the drug. Herein we developed and validated an ultrahigh performance liquid chromatography coupled with quadrupole time of flight mass spectrometry (UPLC-QTOF-MS) method for determining phospholipid composition and phospholipid degradation products in a verteporfin liposomal formulation (Visudyne). The high mass accuracy (<5 ppm) of the QTOF method coupled with database searching (SimLipid) and comparison with known standards accurately identified and quantified the phospholipid compositions and lipid degradation products. The analysis of Visudyne indicated that more than 50% (w/w) of the total phospholipids are composed of phosphatidylcholine (PC) 14:0-14:0 and major phosphatidylglycerol (PG) species found are PG 16:0-18:2, PG 16:0-18:1, PG 18:0-18:2, and PG 18:0-18:1. The LC-MS method developed is capable of separating structural isomers such as PG 18:1-18:1 versus PG 18:0-18:2 and the separation of PG stereoisomers, such as PG 18:1-18:1 cis and PG 18:1-18:1 trans. The major lipid degradation products in Visudyne includes lysophosphatidylcholine and a few saturated and unsaturated lysophosphatidylglycerols, and free fatty acids (FFA). Each degradation product is less than 1% of the total phospholipids (w/w). In addition, the lipid profiles of naturally sourced egg PG from six different vendors were compared with the PG composition in Visudyne. Differences in lipid composition in egg PGs from different vendors were observed and the PG composition in Visudyne is matched with the lipid profile of the some of the egg PGs from different vendors. Drug developers can utilize this method to assess raw materials and lipid-based drug product quality and regulatory scientists can monitor the quality of the drug available in the market using this validated method.

Ratiometric surface enhanced Raman quantification of ligand adsorption onto a gold nanoparticle.

Surface modification is essential in biomedical applications and nanotechnological developments. We report a novel method using surface-enhanced Raman spectroscopy (SERS) for quantifying ligand adsorption onto gold nanoparticles (AuNPs). After centrifugal or settlement removal of the AuNPs-ligand complex, the amount of unbound ligand in the supernatant was determined ratiometrically with an isotope-encoded SERS reference method where known amounts of isotope-substituted ligand were added to the supernatant as an internal reference. Not only is this ratiometric method robust and accurate but it is also very easy to perform. Using this technique, the binding constant and packing density of the model ligand mercaptobenzimidazole (MBI) on a AuNP was determined for the very first time.

Ultrasensitive detection of malondialdehyde with surface-enhanced Raman spectroscopy.

Malondialdehyde (MDA) is a biomarker of lipid peroxidation that has been widely associated with food rancidity as well as many human diseases. Most current MDA detection methods involve MDA reaction with thiobarbituric acid (TBA), followed by UV-visible and/or fluorescence detection of high-performance liquid chromatography (HPLC)-separated TBA-MDA. Herein, we report the first proof-of-concept study of surface-enhanced Raman detection of a TBA-MDA adduct using silver nanoparticles as the SERS substrate and the 632.8 nm HeNe laser as a Raman excitation source. Current SERS detection limit of TBA-MDA is 0.45 nM, ~100 times higher than the 36 nM fluorescence sensitivity recently reported with the HPLC-purified TBA-MDA. Molecular specificity of the SERS technique was studied by comparing the SERS spectrum of TBA-MDA with those acquired with TBA adducts of other TBA-reactive compounds (TBARCs) that includes formaldehyde, acetaldehyde, butyraldehyde, trans-2-hexenal, and pyrimidine. Compared to TBA and TBA adducts with those TBARCs, the SERS activity of TBA-MDA adduct is significantly higher. The possibility of direct SERS detection of TBA-MDA in a reaction mixture (without HPLC separation) has also been investigated.

Characterization of doxorubicin liposomal formulations for size-based distribution of drug and excipients using asymmetric-flow field-flow fractionation (AF4) and liquid chromatography-mass spectrometry (LC-MS).

Doxorubicin liposomal formulations were characterized for the particle size distribution and size-based distribution of lipids and doxorubicin (DOX). An asymmetric flow-field flow fractionation (AF4) method was developed and employed for size-based fractionation of the doxorubicin liposomal formulations. Liposome size-fractions collected from AF4 were analyzed for particle size using nanoparticle tracking analysis (NTA) and dynamic light scattering (DLS). Three doxorubicin liposomal formulations (DLFs) were compared for liposome size distributions. We did not observe any statistically significant variation in D10, D50 and D90 value of size distributions of three fomulations. Lipids and DOX compositions in liposomal fractions from AF4 were determined using liquid chromatography-mass spectrometry (LC-MS) method. The lipid compositions are close to be constant as a function of liposomal size. The drug to lipid ratio was close to be constant for all the size fractions suggesting drug loading may be proportional to membrane surface area of liposomes as membrane surface area is proportional to the amount of lipid in a given liposome. This analytical method could be used in liposomal based drug development as a tool for comparison of generic versions against the reference standard drug.

Effect of gold nanoparticle incorporation into oil-swollen surfactant lamellar membranes.

An oil-swollen surfactant membrane is employed to measure the effects of incorporated hydrophobically functionalized gold nanoparticles (AuNPs) on the structure and dynamics of the membranes. While maintaining an average AuNP diameter of approximately 5 nm, the membrane thickness was varied from 5 nm to 7.5 nm by changing the amount of oil in the membrane. The membranes become softer as the proportion of oil is increased, while the thickness fluctuations become slower. We attribute this to an increased fluctuation wavelength. Incorporation of AuNPs in the membrane induces membrane thinning and softening. Oil molecules surround the nanoparticles in the membrane and help their relatively homogeneous distribution. AuNPs significantly alter the membrane's structure and dynamics through thinning of the membrane, increased compressibility, and possible diffusion of AuNPs inside the membrane.

Direct and simultaneous determination of intra-liposomal and external sulfate in liposomal doxorubicin formulations by capillary electrophoresis/inductively coupled plasma-tandem mass spectrometry (CE/ICP-MS/MS).

A capillary electrophoresis coupled to an inductively coupled plasma-tandem mass spectrometry (CE/ICP-MS/MS) method was developed and validated for the determination of external and intra-liposomal sulfate in doxorubicin liposomal formulations. Ammonium sulfate is a critical component of liposomes, in the loading and maintenance of drug in the intra-liposomal space. Complete separation of external and intra-liposomal sulfate was achieved using CE with minimal liposome disruption. The current filtration technique induces intra-liposomal sulfate leakage during the separation as a result of rupture of liposomes. CE was coupled to a triple quadrupole ICP-MS detection method that allows direct quantification of intra-liposomal sulfate without the need of disintegration of liposomes. Three FDA-approved brand name and generic doxorubicin liposomal formulations were compared for total sulfate and external sulfate. In addition, batch-to-batch product quality consistency was analyzed by comparing the total sulfate and external sulfate for the brand name formulation. Slight variations were observed in total sulfate among the different formulations, and the total sulfate was consistent between different batches of brand name formulation. However, the external sulfate concentration was significantly different among all the tested doxorubicin liposomal formulations. Nevertheless, the interior sulfate is higher than the exterior sulfate concentration to keep the doxorubicin encapsulated by maintaining the ion gradient. This fast and direct sulfur analysis method could be potentially used to quantitative analyze liposomal formulation for quality control.

Direct quantification of unencapsulated doxorubicin in liposomal doxorubicin formulations using capillary electrophoresis.

To understand the quality, efficacy, and safety of liposomal drugs, it is necessary to develop a robust and accurate method for the separation and the quantification of unencapsulated and liposome-associated drugs (or liposomal encapsulated drugs). Conventional methods involve separation of unencapsulated and liposome-associated drug using solid phase extraction and further drug quantification. This is a lengthy process, and sometimes solid phase extraction induces drug leakage from the liposomes causing erroneous results. In this study, a capillary electrophoresis (CE) with UV-Vis detection method was developed for the simultaneous separation and quantification of unencapsulated drug from liposome-associated drug using a doxorubicin-containing liposome formulation as the model drug. CE separates the unencapsulated drug and liposomal drugs based on their electrophoretic mobility under the electric field. Liposomal drugs were diluted to the appropriate concentrations with running buffer or 5% dextrose before hydrodynamic sample injection. Using a high-sensitivity detection cell, the doxorubicin detection sensitivity was enhanced about 10-fold compared to the conventional on-column UV-Vis detection with a 75 µm i.d. capillary column. The optimal separation of unencapsulated doxorubicin from liposome-associated doxorubicin with minimal perturbation of liposomes was accomplished using phosphate buffer (20 mM, pH 6.5) in the presence of 10% sucrose.

pH-Responsive Mercaptoundecanoic Acid Functionalized Gold Nanoparticles and Applications in Catalysis.

Mercaptoundecanoic acid (MUA) functionalized gold nanoparticles (AuNP-MUA) were synthesized and demonstrated to possess pH-triggered aggregation and re-dispersion, as well as the capability of phase transfer between aqueous and organic phases in response to changes in pH. The pH of aggregation for AuNP-MUA is consistent with the pKa of MUA (pH ~4) in solution, while AuNP-MUA phase transition between aqueous and organic phases occurs at pH ~9. The ion pair formation between the amine group in octadecylamine (ODA), the carboxylate group in MUA, and the hydrophobic alkyl chain of ODA facilitates the phase transfer of AuNP-MUA into an organic medium. The AuNP-MUA were investigated as a reusable catalyst in the catalytic reduction of 4-nitrophenol by borohydride-a model reaction for AuNPs. It was determined that 100% MUA surface coverage completely inhibits the catalytic activity of AuNPs. Decreasing the surface coverage was shown to increase catalytic activity, but this decrease also leads to decreased colloidal stability, recoverability, and reusability in subsequent reactions. At 60% MUA surface coverage, colloidal stability and catalytic activity were achieved, but the surface coverage was insufficient to enable redispersion following pH-induced recovery. A balance between AuNP colloidal stability, recoverability, and catalytic activity with reusability was achieved at 90% MUA surface coverage. The AuNP-MUA catalyst can also be recovered at different pH ranges depending on the recovery method employed. At pH ~4, protonation of the MUA results in reduced surface charge and aggregation. At pH ~9, ODA will form an ion-pair with the MUA and induce phase transfer into an immiscible organic phase. Both the pH-triggered aggregation/re-dispersion and aqueous/organic phase transfer methods were employed for catalyst recovery and reuse in subsequent reactions. The ability to recover and reuse the AuNP-MUA catalyst by two different methods and different pH regimes is significant, based on the fact that nanoparticle-catalyzed reactions may occur under different pH conditions.

Quantitative Comparison of Raman Activities, SERS Activities, and SERS Enhancement Factors of Organothiols: Implication to Chemical Enhancement.

Studying the correlation between the molecular structures of SERS-active analytes and their SERS enhancement factors is important to our fundamental understanding of SERS chemical enhancement. Using a common internal reference method, we quantitatively compared the Raman activities, SERS activities, and SERS enhancement factors for a series of organothiols that differ significantly in their structural characteristics and reported chemical enhancements. We find that while the tested molecules vary tremendously in their normal Raman and SERS activities (by more than 4 orders of magnitude), their SERS enhancement factors are very similar (the largest difference is less than 1 order of magnitude). This result strongly suggests that SERS chemical enhancement factors are not as diverse as initially believed. In addition to shedding critical insight on the SERS phenomena, the common internal reference method developed in this work provides a simple and reliable way for systematic investigation of the correlation between molecular structures and their normal Raman and SERS activities.