Small- and wide-angle X-ray scattering (SWAXS) for quantification of aspirin content in a binary powder mixture.

This article presents a novel application of small and wide angle X-ray scattering (SWAXS) in the assessment of aspirin and lactose content in a binary pharmaceutical powder formulation. It is shown that the content correlates with the intensity of the SAXS signal and the intensity of polymorph fingerprints in the WAXS spectra that are collected from the same samples. Because the polymorph WAXS fingerprints and the SAXS signal are two independent characteristics of the same sample, simultaneous SWAXS analysis provides the basis for a dual independent assessment of the same contents.

Non-destructive analysis of tablet coatings with optical coherence tomography.

Optical coherence tomography (OCT) is a non-invasive analysis technique allowing fast and high-quality cross-sectional imaging of scattering media. OCT is based on the physical phenomenon of low coherence interferometry and is thus well suited to image layered structures. In this paper, high-speed spectral domain OCT was used for the characterization of pharmaceutical tablet coatings, sampled at different stages of an industrial drum spray coating process, comprising tablets with a coating thickness ranging from uncoated to a target coating thickness of about 70 µm. In addition to the OCT investigation of layer thickness and homogeneity, tablet weight gain and tablet diameters were determined on a single-tablet level. Scanning electron microscopy (SEM) was applied for referencing the coating thickness obtained with OCT. We demonstrated that OCT allows rapid evaluation of coating properties, such as thickness and homogeneity independently from variations of the tablet core. In contrast to indirect methods, deviations observed with OCT can be related directly to the coating properties. Furthermore, for an extended morphological coating characterization, three dimensional images were reconstructed. Pending further developments, the high axial resolution and fast data acquisition rate of OCT has the potential for highly accurate, fast and low-cost coating control during and after manufacturing.

Superresolution Moiré mapping of particle plasmon modes.

The spontaneous emission rate of a fluorophore provides a direct probe of the photonic local density of states at the fluorophore position. Here we exploit this capability to map the plasmonic modes of gold nanoparticles by imaging the fluorescence intensity in combined regular arrays of identical gold and fluorophore-doped polymer nanoparticles. By varying the distance between gold and polymer particles across the array, the fluorophore emission generates an optical Moiré pattern corresponding to a magnified spatial map of the plasmonic mode, which can be directly imaged with an optical microscope. Our results are corroborated by supplementary theoretical model calculations.

Coupling dielectric waveguide modes to surface plasmon polaritons.

We study dielectric/metal thin film multilayers designed for the coupling of dielectric waveguide modes and surface plasmons. The coupling as identified in calculated dispersion relations for extended multilayers is confirmed by measured angle-resolved reflectance data. By lateral structuring of the multilayers the mutual coupling of dielectric and plasmonic modes is directly observed by fluorescence based microscopy. For a light wavelength of 514nm we find a coupling length of 15microm. Our results highlight the potential of hybrid dielectric/metal waveguides for integrating surface plasmon based photonic circuitry or sensing elements into conventional optical devices.