In Vitro–In Vivo Fluctuation Spectroscopies

Fluorescence correlation spectroscopy (FCS) was first developed for biophysical studies in analogy with photon scattering correlation spectroscopy. Although it is mainly devoted to the study of freely diffusing particles, FCS is actually able to discern between different kinds of motions, such as diffusion, anomalous diffusion, or drift motions. The frontier application of FCS nowadays is in medical studies both within cells and on the cell membranes, and in the investigation of single molecules in solid matrices. In this field, FCS originated also image correlation spectroscopy methods. The whole field can be unified under the name of fluorescence fluctuation spectroscopy (FFS). We present here a short review of the theoretical bases of FFS under a unified vision and discuss some applications to the study of dynamics of nanoparticles in cells and to the investigation of the photodynamics of immobilized dyes

Si-based Nanoparticles: a biocompatibility study

International audienceExposure to silicon nanoparticles (Si-NPs) may occur in professional working conditions or for people undergoing a diagnostic screening test. Despite the fact that silicon is known as a non-toxic material, in the first case the risk is mostly related to the inhalation of nanoparticles, thus the most likely route of entry is across the lung alveolar epithelium. In the case of diagnostic imaging, nanoparticles are usually injected intravenously and Si-NPs could impact on the endothelial wall. In our study we investigated the interaction between selected Si-based NPs and an epithelial lung cell line. Our data showed that, despite the overall silicon biocompatibility, however accurate studies of the potential toxicity induced by the nanostructure and engineered surface characteristics need to be accurately investigated before Si nanoparticles can be safely used for in vivo applications as bio-imaging, cell staining and drug delivery

Congenital hypothyroidism and late-onset goiter: identification and characterization of a novel mutation in the sodium/iodide symporter of the proband and family members

Abstract BACKGROUND: Iodide transport defects (ITDs), rare causes of congenital hypothyroidism (CH), have been shown to arise from abnormalities of the sodium/iodide symporter (NIS). We describe a 16-year-old girl with CH caused by an ITD resulting from a novel mutation of NIS. SUMMARY: A 16-year-old girl with CH diagnosed by a neonatal screening program received early treatment with L-thyroxine replacement therapy. A (123)I scan had failed to reveal any iodide uptake by the thyroid and salivary glands; thus, thyroid agenesis was diagnosed. Thyroglobulin (Tg) was not measured when she was a neonate or infant. Unexpectedly, at the age of 14.5 years, a nodular goiter and high serum Tg concentrations (303 ng/mL; normal, <50) were identified. Her thyroid radioactive iodine uptake was very low as was the saliva to plasma iodide ratio (0.5). Analysis of her NIS gene revealed an in-frame six-nucleotide deletion of the coding sequence (1206-1211delGTCGGC) corresponding to the deletion of amino acids 287 and 288 of the human NIS protein located at the beginning of the VIII transmembrane segment. The proband was homozygous for this deletion, whereas both unrelated parents and her brother were heterozygous. COS-7 cells transfected with the mutant NIS failed to concentrate iodide, confirming that the mutation was the direct cause of the ITD in this patient. CONCLUSIONS: We describe a patient with CH caused by a previously not described mutation of the NIS gene that was inherited from her parents. We therefore recommend that thyroid ultrasonography be performed in CH patients with low radioactive iodine uptake and elevated serum Tg

Dynamic investigation of interaction of biocompatible iron oxide nanoparticles with epithelial cells for biomedical applications

Magnetic nanoparticles have emerged as important players in current research in modern medicine since they can be used in medicine for diagnosis and/or therapeutic treatment of diseases. Among many therapeutic applications of iron-based nanoparticles, drug delivery and photothermal therapy are of particular interest. At cellular level their uptake has been studied and the mechanism by which nanoparticles enter into the cell has important implication not only for their fate but also for their impact on the biological systems. We present here a dynamic investigation of interaction of biocompatible iron oxide nanoparticles coated with L-3,4-dihydroxyphenylalanine and labeled with tetra-methylrhodamine-5/6-isothiocyanate with lung epithelial cells. Our data show that after macropinocytosis-mediated internalization, nanoparticles in form of vesicles approach the nucleus and converge in the more acidic compartments of the cells in a microtubule-dependent manner. During progression the nanoparticles aggregate. Finally, we have demonstrated that a converging laser radiation on the cells, causes the increase in the local temperature and thus damages the cells, suggesting that these nanoparticles may be applied for photothermal therapy studies

Dynamic investigation of interaction of biocompatible iron oxide nanoparticles with epithelial cells for biomedical applications

Magnetic nanoparticles have emerged as important players in current research in modern medicine since they can be used in medicine for diagnosis and/or therapeutic treatment of diseases. Among many therapeutic applications of iron-based nanoparticles, drug delivery and photothermal therapy are of particular interest. At cellular level their uptake has been studied and the mechanism by which nanoparticles enter into the cell has important implication not only for their fate but also for their impact on the biological systems. We present here a dynamic investigation of interaction of biocompatible iron oxide nanoparticles coated with L-3,4-dihydroxyphenylalanine and labeled with tetra-methylrhodamine-5/6-isothiocyanate with lung epithelial cells. Our data show that after macropinocytosis-mediated internalization, nanoparticles in form of vesicles approach the nucleus and converge in the more acidic compartments of the cells in a microtubule-dependent manner. During progression the nanoparticles aggregate. Finally, we have demonstrated that a converging laser radiation on the cells, causes the increase in the local temperature and thus damages the cells, suggesting that these nanoparticles may be applied for photothermal therapy studies.