Rathnapala S. Vithanage

Bio: Rathnapala S. Vithanage is an academic researcher from Texas Tech University. The author has contributed to research in topics: Sulfonic acid & Quenching (fluorescence). The author has an hindex of 5, co-authored 5 publications receiving 416 citations.

Fluorescence Properties of Metal Complexes of 8-Hydroxyquinoline-5-sulfonic Acid and Chromatographic Applications

Abstract: Seventy-eight metal species are examined for fluorescence properties of their chelates with 8-hydroxyquinoline-5-sutfonic acid (HQS); 42 of these fluoresce, many intensely. The optimum pH, determined by ligand ionization vs. hydroxo compiex formation, iles between 5 and 8. Cadmlum forms the most fluorescent complex In a purely aqueous solution. Fluorescence Is enhanced for many metals in surfactant (hexadecyltrlmethyiammonlum ion, HTA') containing media and in a water:dimethytformamide solvent. A number of metal ions quench the fluorescence of other metal-HQS chelates, Fe(II1) being by far the most effective, and such quenching is accentuated in media contalnlng HTA'. The fluorescence propertles can be exploited by introducing the ligand through a postcolumn reactor or by Incorporating it in the eluent in a chromatographic system. Subpicomole detection limits are attainable for Cd, Mg, and Zn.

Quantitative study of chemical equilibria by flow injection analysis with diode array detection

Abstract: Controlled dispersion as generated in flow injection analysis permits essentially infinite known compositional variations. If carrier-sample compositions are appropriately chosen, reasonably accurate values of equilibrium constants are easily obtained in proton-ligand and metal-ligand systems with multidimensional spectral detection. Choice of an appropriate carrier-sample buffer system is critical in proton-ligand studies and is discussed in detail. Metal-ligand association constants are reliably obtained with both high and low conditional stability constants. 10 references, 4 figures.

Metal ion chromatography with fluorescence detection

Abstract: Nonpolar, agglomerated anion exchanger, and surface-sulfonated cation exchanger stationary phases have been used in conjunction with 8-hydroxyquinoline-5-sulfonic acid (HQS) in the eluent or as a postcolumn reagent for the separation and detection of a number of metals that form fluorescent HQS complexes. Several metals, notably those classified as transition metals, form nonfluorescent HQS chelates and quenches the fluorescence of other metal-HQS metal chelates. Such transition metals have been detected by introducing the fluorescent Al-HQS chelate postcolumn. Cation exchange stationary phases are the most useful for chromatographic applications involving HQS and are able to provide a variety of useful separations by tailoring elution conditions. Although not sensitive to Ba, the approach may be particularly good for the determination of the other alkaline earth metals. Fluorescence quenching resulting from Fe and Ni leaching from stainless steel chromatographic systems present a problem for tra...

Enhancement and quenching of fluorescence of metal chelates of 8-hydroxyquinoline-5-sulfonic acid

Abstract: Fluorescence enhancement of 8-hydroxyquinoline-5-sulfonic acid complexes of Mg, Ca, Sr, Ba, Al, Zn and Cd were studied in micellar and hydroorganic solvents Al is extraordinarily amenable to both types of fluorescence enhancement, an order of magnitude to two order of magnitude enhancement of fluorescence intensity has been observed with aqueous hexadecyltrimethylammonium chloride (HTAC) and certain mixed aqueous-organic solvents Fe(III) appears to be an unusually powerful fluorescence quencher in these systems — the effect is noticeable in low micromolar concentrations and is greatly amplified by cationic surfactants such as HTAC

Metals in Neurobiology: Probing Their Chemistry and Biology with Molecular Imaging

Abstract: The brain is a singular organ of unique biological complexity that serves as the command center for cognitive and motor function. As such, this specialized system also possesses a unique chemical composition and reactivity at the molecular level. In this regard, two vital distinguishing features of the brain are its requirements for the highest concentrations of metal ions in the body and the highest per-weight consumption of body oxygen. In humans, the brain accounts for only 2% of total body mass but consumes 20% of the oxygen that is taken in through respiration. As a consequence of high oxygen demand and cell complexity, distinctly high metal levels pervade all regions of the brain and central nervous system. Structural roles for metal ions in the brain and the body include the stabilization of biomolecules in static (e.g., Mg2+ for nucleic acid folds, Zn2+ in zinc-finger transcription factors) or dynamic (e.g., Na+ and K+ in ion channels, Ca2+ in neuronal cell signaling) modes, and catalytic roles for brain metal ions are also numerous and often of special demand.

Biomedical Photonics Handbook

Abstract: Biomedical Diagnostics. Edited by Tuan Vo-Dinh Edited by Tuan VoDinh. CRC Press 20142014. Pages 311–356. Print ISBN: 978-1-42008514-3. eBook ISBN:. Bjorn Kemper is a senior researcher at the Biomedical Technology Center of the Srirang Manohar is an associate professor of biomedical photonic imaging. This volume discusses biomedical photonics, spectroscopy and microscopy, the basic physical principles underlying the technology and its applications.