Joan Estelrich

Nanoparticles in magnetic resonance imaging: from simple to dual contrast agents.

Magnetic resonance imaging (MRI) has become one of the most widely used and powerful tools for noninvasive clinical diagnosis owing to its high degree of soft tissue contrast, spatial resolution, and depth of penetration. MRI signal intensity is related to the relaxation times (T1, spin–lattice relaxation and T2, spin–spin relaxation) of in vivo water protons. To increase contrast, various inorganic nanoparticles and complexes (the so-called contrast agents) are administered prior to the scanning. Shortening T1 and T2 increases the corresponding relaxation rates, 1/T1 and 1/T2, producing hyperintense and hypointense signals respectively in shorter times. Moreover, the signal-to-noise ratio can be improved with the acquisition of a large number of measurements. The contrast agents used are generally based on either iron oxide nanoparticles or ferrites, providing negative contrast in T2-weighted images; or complexes of lanthanide metals (mostly containing gadolinium ions), providing positive contrast in T1-weighted images. Recently, lanthanide complexes have been immobilized in nanostructured materials in order to develop a new class of contrast agents with functions including blood-pool and organ (or tumor) targeting. Meanwhile, to overcome the limitations of individual imaging modalities, multimodal imaging techniques have been developed. An important challenge is to design all-in-one contrast agents that can be detected by multimodal techniques. Magnetoliposomes are efficient multimodal contrast agents. They can simultaneously bear both kinds of contrast and can, furthermore, incorporate targeting ligands and chains of polyethylene glycol to enhance the accumulation of nanoparticles at the site of interest and the bioavailability, respectively. Here, we review the most important characteristics of the nanoparticles or complexes used as MRI contrast agents.

Influence of cholesterol on liposome fluidity by EPR: Relationship with percutaneous absorption

The influence of liposome composition on bilayer fluidity and its effect on the percutaneous absorption into the skin were investigated. Liposomes formed with saturated or unsaturated phospholipids (H-PC or PC) with varying amounts of cholesterol were prepared and their penetration behaviour into the stratum corneum was followed up by means of the stripping method. The order and dynamics of the hydrophobic domain of the vesicles were studied using electron paramagnetic resonance (EPR) methodology. Phospholipid composition and the amount of cholesterol exert a considerable influence on the penetration behaviour of the probe encapsulated in the liposomes. This behaviour is closely related to the fluidity characteristics of these liposomes studied by EPR. Therefore, a penetration mechanism of the vesicles into the skin, based on the incorporation of lipids into the skin lipids and on fluidity behaviour, is suggested.

Liposomes obtained by the ethanol injection method

Abstract One of the most simple methods of obtaining liposomes is the so-called ethanol injection. This is a mild procedure which affords a reasonably homogeneous vesicle population, although rather diluted. We have observed the influence of lipid concentration, osmolality and pH of medium on the size distribution of liposomes. On the other hand, eight substances have been encapsulated in order to establish the relation between efficiency of encapsulation and chemical characteristics. Results obtained show that a 40 mg/ml lipid concentration procedures vesicles below 100 nm average diameter, this population being the most homogeneous. The effect of osmolality and pH is less important. With respect to drug encapsulation, drugs dissolved in the same ethanol as the lipid are relatively well encapsulated, whereas hydrophilic substances such as carboxyfluorescein show lower entrapment. Other kinds of drugs like the quinolones cyprofloxacin and enrofloxacin are associated with high encapsulation efficiencies but the final yield is low.

Iron Oxide Nanoparticles for Magnetically-Guided and Magnetically-Responsive Drug Delivery

In this review, we discuss the recent advances in and problems with the use of magnetically-guided and magnetically-responsive nanoparticles in drug delivery and magnetofection. In magnetically-guided nanoparticles, a constant external magnetic field is used to transport magnetic nanoparticles loaded with drugs to a specific site within the body or to increase the transfection capacity. Magnetofection is the delivery of nucleic acids under the influence of a magnetic field acting on nucleic acid vectors that are associated with magnetic nanoparticles. In magnetically-responsive nanoparticles, magnetic nanoparticles are encapsulated or embedded in a larger colloidal structure that carries a drug. In this last case, an alternating magnetic field can modify the structure of the colloid, thereby providing spatial and temporal control over drug release.

Physicochemical properties of enrofloxacin

The physicochemical properties of enrofloxacin, a fluoroquinolone that inhibits the activity of bacterial DNA gyrase, are described. Its spectral, solubility and related physicochemical characteristics are discussed. The dissociation behaviour of enrofloxacin was examined by UV spectrophotometry at 25 degrees C in a series of buffers ranging from pH 1 to 10. The corresponding macro- and microscopic dissociation constants were calculated. The apparent n-octanol-water partition coefficients were measured from pH 2 to 10.

An autocatalytic reaction as a model for the kinetics of the aggregation of β‐amyloid

Alzheimers disease is the commonest form of senile dementia, affecting almost 20 million people worldwide. This neurodegenerative disorder is characterized by amyloid deposition in senile plaques, composed primarily of fibrils of an aggregated peptide, β‐amyloid. Fibrillation of β‐amyloid is a nucleation‐dependent polymerization process, which is controlled by two kinetics parameters: the nucleation rate and the elongation or growth rate. As the kinetics of fibrillation is strongly dependent on the presence of trace amounts of fibrils, we suggest that the aggregation of β‐amyloid is a model of autocatalytic reaction. A mathematical analysis, permitting quantitative monitoring of the kinetics of fibrillogenesis of β‐amyloid, nucleation, and elongation constants, is presented. The model was checked by applying it to the aggregation of the fragment 1–40 of the β‐amyloid. Understanding of these rate constants may facilitate the study of the effect of substances used for controlling fibril creation and growth. The disaggregating effect of dodecyl trimethylammonium bromide, a cationic surfactant, was easily quantified by means of the model.

Soft nanoparticles (thermo-responsive nanogels and bicelles) with biotechnological applications: from synthesis to simulation through colloidal characterization

The use of nanotechnology in biotechnological applications has attracted tremendous attention from researchers. Currently many nanomaterials, such as soft nanoparticles, are under investigation and development for their use in biomedicine. Among soft nanoparticles, polymeric gels in the nanometre range, known as nanogel particles, have received considerable attention. Nanogel particles, which are formed by polymeric chains loosely cross-linked to form a three-dimensional network, swell by a thermodynamically good solvent but do not dissolve in it. Nanogels are composed of hydrophilic polymers capable of undergoing reversible volume-phase transitions in response to environmental stimuli. Among them, temperature-sensitive nanogels showing a volume phase transition temperature (VPTT) near physiological temperature have been investigated in detail. Nanogels based on biocompatible and temperature-sensitive polymers having a lower critical solution temperature (LCST) around 32 °C in aqueous solutions swell at low temperatures and collapse at high ones. This unique behavior makes these nanogels attractive for pharmaceutical, therapeutical, and biomedical applications. In this review, different synthesis strategies to produce this type of nanogels in dispersed media are revised. Special attention is paid to poly(N-vinylcaprolactam) (PVCL)-based nanogels due to their proven biocompatibility. On the other hand, an extensive review on the characteristics, preparation, and physicochemical properties of another type of soft nanoparticles, which are the bicelles, is presented. The different morphologies obtained depending on experimental conditions such as temperature, lipid concentration, and long- and short-chain phospholipids molar ratio are revised, emphasizing on an important property of bicelles: their alignment in the presence of a magnetic field, and presenting the most important applications of bicelles as membrane models in diverse conformational studies of proteins and membrane peptides, together with the possibilities of administration of such vesicles by systemic routes. A key challenge for the characterization of both soft nanoparticles (nanogels and bicelles) involves the elucidation of their colloidal properties. In this work, some colloidal features of these nanoparticles such as their size, electric double layer or the internal structure and motions of their chains are analyzed. In addition, an overview on the previous and current understanding of the methods and techniques employed in this colloidal characterization is presented, mainly from an experimental point of view. Finally, the most recent results on polyelectrolyte gels and bicelles obtained from computer simulations are also briefly commented. Concerning polyelectrolyte gels, this review is mainly focused on the most important feature of these systems, their large capacity of swelling, which has been explored by simulation in the last decade.

A nanovector with complete discrimination for targeted delivery to Plasmodium falciparum-infected versus non-infected red blood cells in vitro

Current administration methods of antimalarial drugs deliver the free compound in the blood stream, where it can be unspecifically taken up by all cells, and not only by Plasmodium-infected red blood cells (pRBCs). Nanosized carriers have been receiving special attention with the aim of minimizing the side effects of malaria therapy by increasing drug bioavailability and selectivity. Liposome encapsulation has been assayed for the delivery of compounds against murine malaria, but there is a lack of cellular studies on the performance of targeted liposomes in specific cell recognition and on the efficacy of cargo delivery, and very little data on liposome-driven antimalarial drug targeting to human-infecting parasites. We have used fluorescence microscopy to assess in vitro the efficiency of liposomal nanocarriers for the targeted delivery of their contents to pRBCs. 200-nm liposomes loaded with quantum dots were covalently functionalized with oriented, specific half-antibodies against P. falciparum late form-infected pRBCs. In less than 90min, liposomes dock to pRBC plasma membranes and release their cargo to the cell. 100.0% of late form-containing pRBCs and 0.0% of non-infected RBCs in P. falciparum cultures are recognized and permeated by the content of targeted immunoliposomes. Liposomes not functionalized with antibodies are also specifically directed to pRBCs, although with less affinity than immunoliposomes. In preliminary assays, the antimalarial drug chloroquine at a concentration of 2nM, ≥10 times below its IC(50) in solution, cleared 26.7±1.8% of pRBCs when delivered inside targeted immunoliposomes.

The Effect of Liposomes on Skin Barrier Structure

The present work deals with the ‘in vivo’ stripping technique to evaluate the percutaneous absorption of sodium fluorescein (NaFl) vehiculized in two different liposome preparations formed by phosphatidylcholine (PC) and lipids mimicking the stratum corneum (SC; ceramides, cholesterol, palmitic acid and cholesteryl sulphate), respectively. Furthermore, the possible effect of these vesicles on the SC lipid alkyl chain conformational order were evaluated at different depths of SC by non-invasive biophysical techniques: Corneometer, Tewameter and especially ATR-FTIR. The results of NaFl percutaneous absorption indicate the highest penetration in the case of incorporation in PC liposomes, which could be related to the increase in SC lipid disorder detected by ATR-FTIR, i.e. a decrease in skin barrier function. On the other hand, SC lipid liposomes have been shown to have a higher affinity for SC owing to the high amount of NaFl found in this layer, suggesting a greater reservoir capacity of SC when similar lipid composition formulation is applied. A lipid order increase is observed by infrared spectroscopy, when these types of liposomes are topically applied, resulting in a strong barrier effect. These results could be useful in designing specific liposomal topical applications.

Physical stability of different liposome compositions obtained by extrusion method.

Six different liposome compositions were evaluated according their physical stability. The compositions used were (in mole ratio): dipalmitoylphosphatidylcholine (DPPC): DPPC:cholesterol (CHOL) (1:1), DPPC:CHOL (1:6:1), DPPC:CHOL:sphingomyelin (SFM) (7:2:1), DPPC:CHOL:stearylamine (STE) (8:5:1) and DPPC:CHOL:dicetyl phosphate (DCP) (8:5:1). The liposomes were obtained by the extrusion method, through polycarbonate membranes of 0.1 micron pore size. The captured volume, number of lamellae, size and polydispersity of the vesicle populations were determined for all compositions. The physical stability was checked at -20 degrees C, room temperature, 4 degrees C and 50 degrees C by determining the changes in vesicle size over a maximum of 40 days. The process of aggregation and/or fusion was observed by photon correlation spectroscopy. From the results, we can establish that the above compositions are metastable at a temperature of 50 degrees C. On the other hand, values of captured volume were smaller than predicted by theory. This fact can be explained by the non-sphericity of extruded vesicles. In relation to the stability, the introduction of CHOL in the formulation allows keeping the vesicles at 4 degrees C. In contrast, liposomes containing only DPPC are very stable at room temperature. Compositions with a high stability are those that have present SFM or STE. The latter keeps the structural bilayer at temperatures < 0 degrees C without cryoprotectors. Both the lipids, STE and DCP, form vesicles with a higher number of lamellae.