Quantitative micro-Raman analysis of micro-particles in drug delivery.

Polymeric micro and nanoconstructs are emerging as promising delivery systems for therapeutics and contrast agents in microcirculation. Excellent assets associated with polymeric particulates of tunable shape, size, mechanical and chemical properties may improve the efficiency of delivery and represent the basis of personalized medicine and treatment. Nevertheless, lack of effective techniques of analysis may limit their use in biomedicine and bioengineering.

Improvement of the therapeutic treatment of inflammatory bowel diseases following rectal administration of mesalazine-loaded chitosan microparticles vs Asamax.

The development of innovative strategies for the efficacious treatment of inflammatory bowel diseases (IBD) still remains a goal for pharmaceutical research. Targeting the lower section of the intestine is the main aim of therapy because it is the compartment primarily affected by IBDs. Mesalazine was microencapsulated in chitosan particles in order to modulate its unfavorable pharmacokinetic profile exploiting the bioadhesive feature of the polysaccharide and increase the anti-inflammatory effect of the drug following its rectal administration in an in vivo model of induced IBD.

Spherical polymeric nanoconstructs for combined chemotherapeutic and anti-inflammatory therapies.

Nanoparticles can simultaneously deliver multiple agents to cancerous lesions enabling de facto combination therapies. Here, spherical polymeric nanoconstructs (SPNs) are loaded with anti-cancer - docetaxel (DTXL) - and anti-inflammatory - diclofenac (DICL) - molecules. In vitro, combination SPNs kill U87-MG cells twice as efficiently as DTXL SPNs, achieving a IC of 90.

Selective on site separation and detection of molecules in diluted solutions with super-hydrophobic clusters of plasmonic nanoparticles.

Super-hydrophobic surfaces are bio-inspired interfaces with a superficial texture that, in its most common evolution, is formed by a periodic lattice of silicon micro-pillars. Similar surfaces reveal superior properties compared to conventional flat surfaces, including very low friction coefficients. In this work, we modified meso-porous silicon micro-pillars to incorporate networks of metal nano-particles into the porous matrix.

Electroless deposition and nanolithography can control the formation of materials at the nano-scale for plasmonic applications.

The new revolution in materials science is being driven by our ability to manipulate matter at the molecular level to create structures with novel functions and properties. The aim of this paper is to explore new strategies to obtain plasmonic metal nanostructures through the combination of a top down method, that is electron beam lithography, and a bottom up technique, that is the chemical electroless deposition. This technique allows a tight control over the shape and size of bi- and three-dimensional metal patterns at the nano scale.

Raman database of amino acids solutions: a critical study of extended multiplicative signal correction.

The Raman spectra of biological materials always exhibit complex profiles, constituting several peaks and/or bands which arise due to the large variety of biomolecules. The extraction of quantitative information from these spectra is not a trivial task. While qualitative information can be retrieved from the changes in peaks frequencies or from the appearance/disappearance of some peaks, quantitative analysis requires an examination of peak intensities.

A facile in situ microfluidic method for creating multivalent surfaces: toward functional glycomics.

An in situ method of modifying the chemistry and topology of microfluidic surfaces in order to mimic the cellular environment is described. The binding of functionalised microbeads to microfluidic channels allows the surface-to-volume ratio of the system, and thus the number of biomolecules available for reaction, to be vastly increased, thereby enhancing the sensitivity of biochemical analyses. The sensitivity and specificity of the technique were first investigated via the study of carbohydrate-protein interactions.

Magnetic imaging in photonic crystal microcavities.

We demonstrate the nonresonant magnetic interaction at optical frequencies between a photonic crystal microcavity and a metallized near-field microscopy probe. This interaction can be used to map and control the magnetic component of the microcavity modes. The metal coated tip acts as a microscopic conductive ring, which induces a magnetic response opposite to the inducing magnetic field.