Stephen E. Rankin

Synthesis and biocompatibility evaluation of partially fluorinated pyridinium bromides

Although cationic surfactants are of general interest for a variety of consumer and biomedical applications, only a limited number of partially fluorinated, single-tailed, cationic surfactants have been synthesized. To study the potential usefulness of fluorinated cationic surfactants for these applications we synthesized a series of partially fluorinated pyridinium bromide surfactants. Three 10-perfluoroalkyldecyl pyridinium surfactants were synthesized by coupling a perfluoroalkyl iodide with 9-decene-1-yl acetate using an AIBN mediated radical reaction. The resulting 9-iodo-10-perfluoroalkyldec-1-yl acetates were deiodinated using HI–Zn–EtOH and hydrolyzed using KOH–EtOH to yield the corresponding 10-perfluoroalkyldecanol. The partially fluorinated alcohol was converted into the bromide using Br2–PPh3. Alkylation of excess pyridine with the bromides gave the desired 10-perfluoroalkyldecyl pyridinium bromides in good yields. Three 10-perfluoroalkylundecyl surfactants were synthesized using a similar approach with 10-undecenoic acid methyl ester as starting material. Based on an initial in vitro toxicity assessment, the toxicity of the partially fluorinated pyridinium surfactants was slightly lower or comparable to benzalkonium chloride, a typically cationic surfactant (with IC50s of tested compounds ranging from 5 to 15 μM). An increase in the length and/or the degree of fluorination of the hydrophobic tail correlated with a mild decrease of cytotoxicity and haemolytic activity. Partially fluorinated pyridinium surfactants may, therefore, be useful for biomedical applications such as components for novel gene and drug delivery systems.

Pore-Size Dependent Protein Adsorption and Protection from Proteolytic Hydrolysis in Tailored Mesoporous Silica Particles

Protein adsorption and interactions with mesoporous silica are of interest for a broad range of applications including drug delivery, chemical synthesis, biosensors, and bioseparations. A major challenge in designing mesoporous silica supports for tailored protein interaction is the differentiation of protein interactions at the surface of the particle from interactions within the pore, important features when considering mesoporous silica as a protective support for active proteins. In this investigation, the location of Enhanced Green Fluorescent Proteins (EGFPs) adsorbed on tailored mesoporous silica particles is examined as a function of pore diameter using proteolytic hydrolysis to distinguish between accessible and inaccessible proteins. Pore size control is achieved by tuning the hydrothermal aging temperature (60-110 °C) during synthesis, where the synthesis results in 5-15 μm diameter spherical particles appropriate for imaging by confocal scanning laser microscopy (CSLM). In low pH environments, EGFP unfolds within pores and on the surface of particles, rendering it susceptible to proteolytic hydrolysis by the protease Pepsin A. Upon return to neutral pH, un-hydrolyzed EGFP regains its fluorescence and can be visualized within the mesoporous particles. The pore-size dependent loading and protection of EGFP (2.4 nm diameter×4.2 nm) from proteolytic attack by Pepsin A (7.3 nm×3.6 nm×5.4 nm) is demonstrated by the retention of fluorescence in 7.3 nm pores. Larger-pored materials (>9 nm) provide diminishing protection for EGFP, and the protection is greatly reduced with increasing pore size and pore size distribution breadth. Proteolytic hydrolysis is used to delineate the activity of pore-loaded versus surface-bound proteins and to establish that there is an optimal pore diameter for loading EGFP while protecting it from attack by a larger proteolytic enzyme.

Hierarchically porous titania thin film prepared by controlled phase separation and surfactant templating.

Poly(propylene glycol) (PPG) of moderately high molecular weight (M(n) = 3500 Da) exhibits amphibious behavior in aqueous solution in that it is hydrophilic at low temperature but hydrophobic at high temperature. This property is utilized to generate porous titania thin films with a hierarchical structure consisting of macroporous voids/cracks in films with mesoporous walls. The smaller mesopores result from the self-assembly of the Pluronic block copolymer P123 to form micellar templates in well-ordered arrays with hexagonal symmetry. The larger pores are generated from the phase separation of PPG during aging of the films. The PPG acts to a limited degree as a swelling agent for the P123 micelles, but because the films are aged at a low temperature where PPG is hydrophilic, much of the PPG remains in the polar titania phase. Upon heating, the PPG phase separates to form randomly dispersed, large pores throughout the film while retaining the ordered mesoporous P123-templated structure in the matrix of the material. TEM and SEM imaging confirm that calcined titania thin films have interconnected hierarchical porous structures consisting of ordered mesopores 4-12 nm in diameter and macroporous voids >100 nm in size. The density and size of the voids increase as more PPG is added to the films.

Synthesis and tuning of bimodal mesoporous silica by combined hydrocarbon/fluorocarbon surfactant templating.

Hydrocarbon and fluorocarbon surfactants show highly nonideal mixing that under some conditions results in demixing of the two types of surfactants into distinct populations of fluorocarbon-rich and hydrocarbon-rich aggregates. This also occurs in materials prepared by cooperative assembly of hydrolyzed tetraethoxysilane with mixtures of cetyltrimethylammonium chloride (CTAC) and 1,1,2,2-tetrahydro-perfluorodecylpyridinium chloride (HFDePC). Here, we report conditions under which demixed micelles lead to bimodal mesoporous materials (including specific concentrations of ammonia and salt in the synthesis solution) and show that the sizes of the hydrocarbon-templated and fluorocarbon-templated pores can be finely and independently controlled by adding lipophilic or fluorophilic oils, respectively. Nitrogen sorption isotherms and transmission electron microscopy provide clear evidence for a single phase of demixed but disordered wormhole-like pores.

Synthesis and biocompatibility evaluation of fluorinated, single-tailed glucopyranoside surfactants

Partially fluorinated non-ionic surfactants are of interest for a range of biomedical applications, such as the pulmonary administration of drugs using reverse water-in-perfluorocarbon microemulsions. We herein report the synthesis and characterization of a series of partially fluorinated β-D-glucopyranoside surfactants from the respective alcohols and peracetylated β-D-glucopyranoside using BF3·Et2O as catalyst. The surfactant packing parameter of the fluorinated surfactants ranged from 0.472 to 0.534 (MOPAC calculations) or 0.562 to 0.585 (calculated from literature values), which is comparable to surfactants with a similar partially fluorinated tail. Based on an initial biocompatibility assessment, the β-D-glucopyranoside surfactants have low toxicities in the B16F10 mouse melanoma cell line and comparatively low haemolytic activities towards rabbit red blood cells. The fluorinated surfactants appear to be less toxic towards cells in culture and to have a lower haemolytic activity compared to their hydrocarbon analogs. Furthermore, an increasing degree of fluorination appears to reduce both the cytotoxicity and the haemolytic activity. Similar structure–activity relationships have been reported for other partially fluorinated surfactants. Overall, these findings suggest that the surfactants may be useful for biomedical applications, such as novel drug delivery systems.

Synthesis, Thermal Properties and Cytotoxicity Evaluation of Hydrocarbon and Fluorocarbon Alkyl β-D-xylopyranoside Surfactants

Alkyl β-d-xylopyranosides are highly surface active, biodegradable surfactants that can be prepared from hemicelluloses and are of interest for use as pharmaceuticals, detergents, agrochemicals, and personal care products. To gain further insights into their structure-property and structure-activity relationships, the present study synthesized a series of hydrocarbon (-C(6)H(13) to -C(16)H(33)) and fluorocarbon (-(CH(2))(2)C(6)F(13)) alkyl β-d-xylopyranosides in four steps from d-xylose by acylation or benzoylation, bromination, Koenigs-Knorr reaction, and hydrolysis, with the benzoyl protecting group giving better yields compared to the acyl group in the Koenigs-Knorr reaction. All alkyl β-d-xylopyranosides formed thermotropic liquid crystals. The phase transition of the solid crystalline phase to a liquid crystalline phase increased linearly with the length of the hydrophobic tail. The clearing points were near constant for alkyl β-d-xylopyranosides with a hydrophobic tail ⩾8, but occurred at a significantly lower temperature for hexyl β-d-xylopyranoside. Short and long-chain alkyl β-d-xylopyranosides displayed no cytotoxicity at concentration below their aqueous solubility limit. Hydrocarbon and fluorocarbon alkyl β-d-xylopyranosides with intermediate chain length displayed some toxicity at millimolar concentrations due to apoptosis.

Hydrolysis pseudoequilibrium: challenges and opportunities to sol–gel silicate kinetics

Abstract We quantitatively model the kinetics of acid-catalyzed hydrolytic condensation of trimethylethoxysilane, a representative monomer for “sol–gel” inorganic polymerization chemistry. Sol–gel processing is of interest as a flexible route to new ceramic gels, silicone resins, inorganic/organic hybrids, and micro- or meso- porous catalysts such as zeolites. Using principal component analysis of the sensitivity matrix for this model, we quantitatively demonstrate that hydrolysis pseudoequilibrium is not only appropriate but also demanded if unique rate coefficients are to be determined. While this provides a challenge in the sense that hydrolysis kinetics may be difficult to measure, it also provides the opportunity to model alkoxysilane polymerization using only condensation kinetics. Parametric sensitivities are not directly observable however, so we also present an experimentally observable phase portrait signature of hydrolysis pseudoequilibrium. Finally, we discuss why, under hydrolysis pseudoequilibrium, the condensation route (water producing or alcohol producing) is virtually impossible to distinguish from a single batch experiment.

Engineered silica nanocarriers as a high-payload delivery vehicle for antioxidant enzymes.

Antioxidant enzymes for the treatment of oxidative stress-related diseases remain a highly promising therapeutic approach. As poor localization and stability have been the greatest challenges to their clinical translation, a variety of nanocarrier systems have been developed to directly address these limitations. In most cases, there has been a trade-off between the delivered mass of enzyme loaded and the carriers ability to protect the enzyme from proteolytic degradation. One potential method of overcoming this limitation is the use of ordered mesoporous silica materials as potential antioxidant enzyme nanocarriers. The present study compared the loading, activity and retention activity of an anti-oxidant enzyme, catalase, on four engineered mesoporous silica types: non-porous silica particles, spherical silica particles with radially oriented pores and hollow spherical silica particles with pores oriented either parallel to the hollow core or expanded, interconnected bimodal pores. All these silica types, except non-porous silica, displayed potential for effective catalase loading and protection against the proteolytic enzyme, pronase. Hollow particles with interconnected pores exhibit protein loading of up to 50 wt.% carrier mass, while still maintaining significant protection against proteolysis.

29Si NMR study of base‐catalyzed polymerization of dimethyldiethoxysilane

When moving from acidic to basic conditions for polycondensation of tetrafunctional alkoxysilanes, significant complications inhibit quantitative modeling of the polymerization process— most significantly formation of new liquid and solid phases. To understand what chemical processes influence the evolution of alkoxysilanes under basic conditions, we study the behavior of a model difunctional system which remains homogeneous during polycondensation and is of interest for preparing hybrid materials and elastomers. Characterizing the system by time‐resolved 29Si NMR, we found direct quantitative evidence for three important differences in behavior from polymerization of alkoxysilanes under acidic conditions: (1) monomer consumption rate limited by hydrolysis rather than condensation; (2) a different substitution effect of siloxane connectivity on condensation reactivity; and (3) substantial reduction of the formation of small (six‐ or eight‐atom) cycles. These results are consistent with the hypothesis of Chojnowski and coworkers that deprotonation of silanols destabilizes neighboring silicon–oxygen bonds. Additional chemistry, including deprotonation, siloxane solvolysis and disproportionation must be considered under alkaline conditions. Copyright

Copolymerization kinetics of a model siloxane system

Using 29Si NMR, we monitor the copolymerization of trimethylethoxysilane and dimethyldiethoxysilane (model compounds for more complex sol-gel copolymer systems) in a batch reactor. Under the chosen conditions, the extents of self- and cross-condensation reactions are readily determined. Using a nonideal polycondensation kinetic model, we show that the copolymerization rate coefficient for a pair of sites of differing functionality is bounded by their homopolymerization rate coefficients, lying closer to the larger one. This reactivity pattern generates a heterogeneous monomer distribution in the copolymerization products.