ABSTRACT
The development of smart delivery systems able to deliver and target a drug to the site of action is one of the major challenges in the field of pharmaceutical technology. The surface modification of nanocarriers, such as liposomes, is widely investigated either for increasing the blood circulation time (by pegylation) or for interacting with specific tissues or cells (by conjugation of a selective ligand as a monoclonal antibody, mAb). Microscopical analysis thereby is a useful approach to evaluate the morphology and the size owing to resolution and versatility in defining either surface modification or the architecture and the internal structure of liposomes. This contribution aims to connect the outputs obtained by transmission electron (TEM) and atomic force (AFM) microscopical techniques for identifying the modifications on the liposomal surface. To reach this objective, we prepared liposomes applying two different pegylation technologies and further modifying the surface by mAb conjugation. This work demonstrates the feasibility to apply the combined approach (TEM and AFM analysis) in the evaluation of the efficacy of a surface engineering process.
Subject(s)
Liposomes/chemistry , Microscopy, Atomic Force , Particle Size , Surface PropertiesABSTRACT
Poly-L-lactide (PLLA) is one of the most used polymers for biomedical application; its use in sutures and other implants has been widely investigated. Although the knowledge of PLLA biodegradation and biocompatibility features is deep, PLLA screws used to correct the flat foot deformity have deserved attention since they are not degraded in most of cases after a long period of years (3-7) from the implantation. In this article, a clinical and radiological evaluation (NMR, histological and clinical outcomes) on patients was correlated with physico-chemical characterization (by SEM, DSC, GPC and XRD analysis at different temperatures) on both native and patient-recovered screws together with the theoretical degradation processes of PLLA-based implants. The data demonstrated the need for crossing the biodegradation and bioabsorption of the polymer with the characteristics of both the device (geometry, structure and fabrication process) and the implantation site.
Subject(s)
Absorbable Implants , Biocompatible Materials , Bone Screws , Device Removal , Flatfoot/surgery , Absorption , Adolescent , Calorimetry, Differential Scanning , Child , Chromatography, Gel , Crystallization , Female , Flatfoot/pathology , Humans , Inflammation/pathology , Male , Microscopy, Electron, Scanning , Molecular Weight , Polyesters , Spectrometry, X-Ray Emission , X-Ray DiffractionABSTRACT
Despite of the several approaches applied to the physicochemical characterization of liposomes, few techniques are really useful to obtain information about the surface properties of these colloidal drug-delivery systems. In this paper, we demonstrate a possible new application of tapping mode atomic force microscopy (AFM) to discriminate between conventional and pegylated liposomes. We showed that the differences on liposomal surface properties revealed by the phase images AFM approach well correlate with the data obtained using classical methods, such as light scattering, hydrodynamic, and nuclear magnetic resonance analysis.
Subject(s)
Liposomes/chemistry , Microscopy, Atomic Force/methods , Polyethylene Glycols/chemistry , Magnetic Resonance Spectroscopy/methods , Surface PropertiesABSTRACT
The thermal transformation of asbestos into non-hazardous crystalline phases and their recycling is a promising solution for the "asbestos problem". The most common asbestos-containing industrial material produced worldwide is cement-asbestos. Knowledge of the kinetics of thermal transformation of asbestos fibers in cement-asbestos is of paramount importance for the optimization of the firing process at industrial scale. Here, environmental scanning electron microscopy (ESEM) was used for the first time to follow in situ the thermal transformation of chrysotile fibers present in cement-asbestos. It was found that the reaction kinetics of thermal transformation of chrysotile was highly slowed down in the presence of water vapor in the experimental chamber with respect to He. This was explained by chemisorbed water on the surface of the fibers which affected the dehydroxylation reaction and consequently the recrystallization into Mg-silicates. In the attempt to investigate alternative and faster firing routes for the decomposition of asbestos, a low melting glass was mixed with cement-asbestos and studied in situ to assess to which extent the decomposition of asbestos is favored. It was found that the addition of a low melting glass to cement-asbestos greatly improved the decomposition reaction and decreased the transformation temperatures.
Subject(s)
Asbestos, Serpentine/chemistry , Conservation of Natural Resources , Microscopy, Electron, Scanning , X-Ray DiffractionABSTRACT
A method is described that could be of potential use for the rapid ultrastructural identification of abnormal and fragmented elastic fibers in very small wet samples of dermal biopsies from patients affected by Pseudoxanthoma elasticum (PXE). Moreover, the method, which consists of the use of sealed capsules transparent to electrons, allows the rapid and accurate localization and detection of mineralized areas in PXE patients and of their ion composition by X-ray microanalysis. This methodology could be of great help in any tissue disorder, especially in connective tissue disorders, characterized by structural alterations associated with ion precipitation.
Subject(s)
Calcinosis , Elastic Tissue/ultrastructure , Elastin/ultrastructure , Pseudoxanthoma Elasticum/pathology , Skin/ultrastructure , Biopsy , Connective Tissue Diseases/diagnosis , Elastin/chemistry , Electron Probe Microanalysis , Humans , Ions/analysis , Pseudoxanthoma Elasticum/diagnosis , Skin/chemistryABSTRACT
The polymer framework of a resin-based catalyst built up with Pd nanoclusters (ca. 3 nm) dispersed inside the nanoporous domains of a thermally stable gel-type polyacrylic resin exhibits a good chemical stability under 5 bar H(2) at 40 degrees C for reasonable contact times. Chemical and physico-chemical integrity of the polymer framework are checked with a variety of instrumental analytical methods. Catalyst reusability turns out to be quite good.