Evaluation of parylene derivatives for use as biomaterials for human astrocyte cell patterning.

Cell patterning is becoming increasingly popular in neuroscience because it allows for the control in the location and connectivity of cells. A recently developed cell patterning technology uses patterns of an organic polymer, parylene-C, on a background of SiO2. When cells are cultured on the parylene-C/SiO2 substrate they conform to the underlying parylene-C geometry. Parylene-C is, however, just one member of a family of parylene polymers that have varying chemical and physical properties. In this work, we investigate whether two commercially available mainstream parylene derivatives, parylene-D, parylene-N and a more recent parylene derivative, parylene-HT to determine if they enable higher fidelity hNT astrocyte cell patterning compared to parylene-C. We demonstrate that all parylene derivatives are compatible with the existing laser fabrication method. We then demonstrate that parylene-HT, parylene-D and parylene-N are suitable for use as an hNT astrocyte cell attractive substrate and result in an equal quality of patterning compared to parylene-C. This work supports the use of alternative parylene derivatives for applications where their different physical and chemical properties are more suitable.

Manipulation of spray-drying conditions to develop dry powder particles with surfaces enriched in hydrophobic material to achieve high aerosolization of a hygroscopic drug.

This study aimed to develop dry powder particles with surfaces enriched in hydrophobic material by manipulation of spray-drying conditions and to investigate the effect of hydrophobic surface enrichment on aerosolization of hygroscopic drug. The composite dry powder formulations of kanamycin (hygroscopic drug) and rifampicin (hydrophobic drug) were produced by systematically (23 full factorial design) varying the drug ratio, co-solvent composition and inlet temperature using Buchi B-290 Mini Spray-Dryer. All the composite powder particles were inhalable in size (3.1-3.9 µm), wrinkled, flake-shaped and amorphous. X-ray photoelectron spectroscopy and time-of-flight secondary ion mass spectrometry showed that hydrophobic surface enrichment was significantly affected by co-solvent composition. Complete hydrophobic surface enrichment was achieved in one formulation (F7). The aerosolization efficiency by next generation impactor (NGI) showed that the composite formulations had higher fine particle fraction (FPF: >48.0%) than kanamycin-only formulation (FPF: 27.6%). Increase in hydrophobic surface enrichment (from 80.8 to 100%) decreased the powder density and increased FPF (from 48.0 to 77.2%). This is the first systematic study reporting the manipulation of spray-drying conditions for hydrophobic surface enrichment in composite dry powder particles and its effect on aerosolization. The high aerosolization efficiency of the combination formulations may be useful to deliver high doses of these drugs to treat lung infections.

Atomic Force Microscopy and Angular-Dependent X-ray Photoelectron Spectroscopy Studies of Anchored Quaternary Ammonium Salt Biocides on Quartz Surfaces.

A siloxane surface-anchored quaternary ammonium salt (AQAS: BIOSAFE HM4100 in this study) has been chemisorbed onto a quartz substrate. The aim of this study is to elucidate, using atomic force microscopy (AFM) and X-ray photoelectron spectroscopy (XPS), the structure of the chemisorbed AQAS layers. The AQAS biocide includes a C18 alkyl chain previously invoked in lysis potency. The AQAS coverage appears in zones on the surface, which include a first layer (2.6 ± 0.1 nm) and multilayering that were explored using AFM. The XPS data exhibited two N 1s signals at about 402 and 399 eV, with only the former exhibiting angular dependence. This signal at 402 eV was assigned to the first anchored layer with perpendicular orientation determined by the AQAS anchoring to the surface. In preliminary AFM studies of bacteria on these AQAS surfaces, perturbations on the Staphylococcus aureus cells and the degradation of Escherichia coli cells suggest lysis potency.

Co-spray drying of hygroscopic kanamycin with the hydrophobic drug rifampicin to improve the aerosolization of kanamycin powder for treating respiratory infections.

High dose delivery of drugs to the lung using a dry powder inhaler (DPI) is an emerging approach to combat drug-resistant local infections. To achieve this, highly aerosolizable powders are required. We hypothesized that co-spray-drying kanamycin, a hydrophilic hygroscopic antibiotic, with rifampicin, a hydrophobic antibiotic, would produce inhalable particles with surfaces enriched in rifampicin. Such particles would have higher aerosolization than kanamycin alone, and minimise the mass of powder for inhalation avoiding use of non-active excipients. Kanamycin was co-spray-dried with rifampicin using a Buchi Mini Spray-dryer. All powders were inhalable in size (1.1-5.9 µm) and noncrystalline. X-ray photoelectron spectroscopy (XPS) and time-of-flight secondary ion mass spectrometry (ToF-SIMS) showed the surface of the combination powder was enriched with rifampicin. In vitro aerosolization (fine particle fraction) determined by next generation impactor (NGI), dramatically improved from 29.5 ±â€¯0.2% (kanamycin-only) to 78.2 ±â€¯1.3% (kanamycin-rifampicin combination). The combination powder was flake-shaped in morphology, stable at 15% and 53% RH and 25 ±â€¯2 °C during one-month storage in an open Petri dish, and non-toxic (up to 50 µg/mL) to human alveolar and bronchial cell-lines. Surface enrichment of kanamycin by hydrophobic rifampicin improves aerosolization, which may help to combat drug-resistant local infections by facilitating high dose delivery to deep lung.

In situ characterization of aluminum-containing mineral-microorganism aqueous suspensions using scanning transmission X-ray microscopy.

In situ characterization of colloidal particles under hydrous conditions is one of the key requirements for understanding their state of aggregation and impact on the transport of pollutants in aqueous environments. Scanning transmission X-ray microscopy (STXM) is one of the few techniques that can satisfy this need by providing element- and chemical-state-specific 2-D maps at a spatial resolution better than 50 nm using soft X-rays from synchrotron radiation wiggler or undulator sources tuned to the absorption edges of different elements. X-ray absorption near-edge structure (XANES) spectra can also be collected simultaneously at a similar spatial resolution and can provide phase identification in many cases. In this study, we report STXM images and XANES spectroscopy measurements at or above the Al K-edge (E = 1559.6 eV) of various Al-containing minerals and synthetic oxides [alpha-Al2O3 (corundum), gamma-Al2O3, gamma-AlOOH (boehmite), alpha-Al(OH)3 (bayerite), KAl2(AlSi3O10)(OH)2 (muscovite), (Al,Mg)8(Si4O10)4(OH)8.nH2O (montmorillonite), and Mg6Al2(OH)16CO3.4H2O (hydrotalcite)] and demonstrate the capability of this spectromicroscopic tool to identify different Al-containing mineral colloids in multiphase mixtures in aqueous solution. We also demonstrate that STXM imaging at or above the C K-edge (E = 284.2 eV) and Al K-edge can provide unique information on the interactions between bacteria and Al-containing nanoparticles in aqueous suspensions. STXM images of a mixture of Caulobacter crescentus and montmorillonite and corundum particles just above the C and Al K-edges show that the mineral particles and bacteria are closely associated in aggregates, which is likely due to the binding of bacteria to clay and corundum particles by extracellular polysaccharides.