Controls and Constructive Applications of Defects in Local Area of Oxides Using Femtosecond Laser / フェムト秒レーザーを用いた酸化物内部局所領域における欠陥制御および応用

MOON, Chiwon

23 March 2010

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第15385号 / 工博第3264号 / 新制||工||1491(附属図書館) / 27863 / 京都大学大学院工学研究科材料化学専攻 / (主査)教授 平尾 一之, 教授 横尾 俊信, 教授 田中 勝久 / 学位規則第4条第1項該当

Defect

Femtosecond laser

Dislocation

Luminescence

500

Verres et céramiques de chalcogénures pour applications en optiques actives / Chalcogenide glasses and glass-ceramics pour application in optical active

Bai, Xue

01 October 2013

L'objectif de ce travail est de développer des matériaux pour une conversion efficace de fréquences. Deux types de matériaux ont été étudiés. Le premier type concerne des matériaux pour le doublage de fréquence par la génération de second harmonique. Nous avons sélectionné des vitrocéramiques de chalcogénures GeS₂+βGeS₂ et Ge₂₀Sb₁₂S₆₈+Cds pour cette étude avec une différence d'indice faible entre la phase vitreuse et les cristaux. Ces vitrocéramiques ont été élaborées avec une technique originale en associant la mécano-synthèse et le pressage flash (Spark Plasma Sintering). Elles présentent une grande compacité supérieure à 99,9%. Les pertes optiques par diffusion, en particulier dans les courtes longueurs d'onde, doivent encore être améliorées pour rend possible les mesures de génération de second harmonique. Cette nouvelle technique de synthèse a également permis la fabrication des verres de chalcogénures qui ont une forte tendance à cristalliser. L'exemple a été donné par la synthèse du verre Ge₁₅Ga₂₀S₆₅, situé en dehors du domaine vitreux déterminé par la méthode de synthèse classique (fusion-trempe). Le deuxième type de matériaux étudiés concerne des matériaux luminescents à large bande d'absorption et d'émission. Les ions de métaux de transition Fe, Ni et Mn et l'ion de terre rare bivalent Eu ont été sélectionnés en raison des transitions électroniques impliquant des électrons de la couche d. Des émissions larges et parfois intenses ont été obtenues avec des ions Eu²⁺ dans les céramiques SrS/ZnS et CaS/ZnS. La largeur à mi-hauteur peut même dépasser 100 nm. Il a été démontré que la position de l'émission dépend fortement de l'environnement chimique des ions Eu²⁺. Afin d'ajuster continuellement la position de cette émission, des couches minces contenant différents rapports Sr/Ca ont été déposées par co-pulvérisation cathodique assistée par un magnétron. Des émissions larges et ajustables ont été obtenues. / The objective of this work is to develop materials for efficient frequency conversion. Two types of materials were studied. The first type relates to materials for frequency doubling by using second harmonic generation. We selected chalcogenide glass ceramics GeS₂+βGeS₂ and Ge₂₀Sb₁₂S₆₈+Cds for this study with a low difference of refractive index between the glass phase and the crystals. These ceramics were synthesized by melt-quenching technique and by combination of mechanical milling and Spark Plasma Sintering. The obtained glass ceramics have a high compactness greater than 99.9%. The optical losses due to scattering, particularly at shorter wavelengths, must be further improved before measurement of second harmonic generation. This new synthesis technique also allowed the manufacture of chalcogenide glasses which have a strong tendency to crystallize. The example was given by the synthesis of the glass Ge₁₅Ga₂₀S₆₅, located outside of the glass forming region determined by using the conventional melt-quenching method. The second type of the studied materials was related to luminescent materials with broadband absorption and emission. Transition metal ions, Fe, Ni and Mn, and divalent rare earth ion Eu were selected for its electronic transitions involving d-shell electrons. Wide and intense emissions were obtained with Eu²⁺ ions in CaS/ZnS and SrS/ZnS ceramics. The FWHM may exceed 100 nm. It has been demonstrated that the position of the emission strongly depends on the chemical environment of Eu²⁺ ions. In order to continuously adjust the position of the emission, thin films containing different Sr/Ca ratios were deposited by magnetron sputtering. Wide and adjustable emissions were obtained.

Chalcogénure

Mécanosynthèse

Optique non-linéaire

Couche mince

Luminescence

Targeted multi-modal imaging : using the Ugi reaction with metals

Mera-Pirttijarvi, Ross Jalmari

January 2012

The current 'gold standard method' of detecting cancer relies on microscopic examination by specialised pathologists. However, there are risks associated with surgery and biopsies and so the ability to diagnose cancer and other diseases in a non-invasive manner is highly attractive. There are many imaging techniques suitable for this, each with their own advantages and disadvantages, which can be improved by the use of contrast agents. The incorporation of targeting vectors allows for the specific imaging of desired tissues. Further to this, the incorporation of more than one contrast agent into one imaging agent allows for multi-modal imaging of cancerous tissue and other diseases. This allows for the advantages of different techniques to be used simultaneously and is an emerging field. The methods for the synthesis of these drugs can be synthetically demanding and low yielding due to linear synthetic strategies. The use of multi-component reactions would be a major benefit and the Ugi reaction is particularly attractive due to the incorporation of four components and the biocompatible bis-amide motif of Ugi products. This work serves as an extension to previous work based on Ugi reactions of metal complexes, which showed that amine and carboxylic acid appended lanthanide and carboxylic acid appended d-metal complexes can be used as stable building blocks in the formation of mono-metallic complexes. This work presents the synthesis of aldehyde appended lanthanide complexes and their use in Wittig and Ugi chemistry in the synthesis of mono-metallic complexes. The previously synthesised amine appended lanthanide complexes 1, 3, 4 were also synthesised to be used as a feedstock in subsequent Ugi reactions. A number of carboxylic acid appended d-metal complexes and cyanine dyes were synthesised according literature procedures. Both the bis-acid appended d-metal complexes and cyanine dyes were used unsuccessfully in the Ugi reaction. However, the mono-acid d-metal complexes were used successfully in the Ugi reaction in keeping with previous reports. These were used as the third feedstock for the synthesis of trimetallic complexes along with the aldehyde and amine appended lanthanide complexes via the Ugi reaction. In addition, a number of Ugi reactions were performed on organic compounds. The use of p-toluic acid gave five Ugi compounds, which were characterised and gave the expected results. However, the use of biotin as the carboxylic acid component gave four compounds that were complex to characterise and suggested that the incorporated biotin may not serve as a viable targeting vector. One of the p-toluic acid Ugi products was reacted further and a biotin moiety was incorporated with a (CH2)6 spacer. Spectroscopic evidence suggested that the biotin would still act as a viable targeting vector. Overall, this work serves to set the scene for the synthesis of targeted tri-metallic multi-modal imaging agents using stable metal complexes as building blocks in the Ugi reaction.

616.994

Photophysics and Photochemistry of Copper(I) Phosphine and Collidine Complexes: An Experimental/Theoretical Investigation

Determan, John J.

08 1900

Copper(I) complexes have been studied through both experimental and computational means in the presented work. Overall, the work focuses on photophysical and photochemical properties of copper(I) complexes. Photophysical and photochemical properties are found to be dependent on the geometries of the copper(I) complexes. One of the geometric properties that are important for both photochemical and photophysical properties is coordination number. Coordination numbers have been observed to be dependent on both ligand size and recrystallization conditions. The complexes geometric structure, as well as the electronic effects of the coordination ligands, is shown both computationally as well as experimentally to affect the emission energies. Two-coordinate complexes are seen to have only weak emission at liquid nitrogen temperature (77 K), while at room temperature (298 K) the two-coordinate complexes are not observed to be luminescent. Three-coordinate complexes are observed to be luminescent at liquid nitrogen temperature as well as at room temperature. The three-coordinate complexes have a Y-shaped ground (S0) state that distorts towards a T-shape upon photoexcitation to the lowest lying phosphorescent state (T1). The geometric distortion is tunable by size of the coordinating ligand. Luminescence is controllable by limiting the amount of non-radiative emission. One manner by which non-radiative emission is controlled is the amount of geometric distortion that occurs as the complex undergoes photoexcitation. Bulky ligands allow for less distortion than smaller ligands, leading to higher emission energies (blue shifted energies) with higher quantum efficiency. Tuning emission and increasing quantum efficiencies can be used to create highly efficient, white emitting materials for use in white OLEDS.

Copper(I) complexes

OLED

luminescence

photochemistry

photophysics

Synthesis and bio-applications of luminescent iridium (III) and ruthenium (II) bipyridine complexes

Wang, Haitao

24 August 2020

This thesis is based on the past three years of research work including synthesis, characterization of three series of iridium(III) complexes and one series of ruthenium(II) complexes, and their comparative bio-applications of DNA-binding, cell morphology, cytotoxicity, mitochondrial membrane potential, cellular uptake and distribution. Chapter 1 introduces the background and recent studies of transition-metal complexes as biosensors and anti-tumor medicines. Their structure related properties of cytotoxicities, cellular uptake and distributions were also discussed. In chapter 2, five iridium(III) complexes Ir4: [Ir(4-mpp)2DPPZ]+, Ir7: [Ir(4-mpp)2BDPPZ]+, Ir8: [Ir(4-mpp)2MDPPZ]+, Ir115: [Ir(pp)2DBDPPZ]+ and Ir139: [Ir(dpapp)2DBDPPZ]+ were synthesized and characterized. The crystals of complex Ir139 were successfully cultured and analyzed by X-ray crystallography. The HOMO and LUMO energy gaps of complexes Ir4, Ir7 and Ir8 were obtained. The smaller the energy gap is the larger the Stokes shift will be. The DNA binding properties of Ir4, Ir7 and Ir8 were studied to acquire their binding constants and quenching constants. All the five complexes were cultured with hepatocellular carcinoma cell (hep-G2) in different concentrations for cell morphologies and MTT assays. The IC50 values were calculated and the structure-activity relationship (SAR) was discussed. Properties of Ir115 and Ir139 for photodynamic therapy under the visible light were studied, and moderate light-enhanced cytotoxicities were discovered. The live and dead cell assay and mitochondrial transmembrane potential (ΔΨM) testing were performed and a similar cytotoxicity order to IC50 values was obtained. Some interesting interactions between complex and calcein or propidium iodide (PI) dye were observed and discussed. Cellular uptake and distribution assay showed that the fluorescence of iridium complex was closely related to its toxicity. The obvious cellular uptake at 4 ℃ indicated that all the complexes could transfer into cell through a passive transport mode of facilitated diffusion without the consumption of ATP. The greatest change in uptake intensity of Ir115 implied that the ATP could assist the transport of Ir115 at 37.5 ℃. The efficiency of uptake and distribution of complexes in paraformaldehyde (PFA) fixed cells was found to be strictly related to their size and the hydrophobicity. The rigidity of dipyrido[3,2-a:2',3'-c]phenazine based bipyridine ligands in this chapter contributed to the main cytotoxcities of those iridium complexes. Most of the iridium complexes in chapter 2 have similar structures to their classic ruthenium analogues while their activities have largely improved due to the higher cellular uptake and more biocompatibility. Chapter 3 presented five iridium complexes with rotatable 1H-imidazo [4,5-f] [1,10] (phenanthroline) based bipyridine ligands, which are Ir79: [Ir(pp)2MTPIP]+, Ir80: [Ir(pp)2EIPP]+, Ir116: [Ir(piq)2APIP]+, Ir119: [Ir(piq)2PPIP]+ and Ir134: [Ir(iqdpba)2PPIP]+. Cell morphology and proliferation assay, MTT assay indicated that most of them were not quite toxic for hep-G2 cell lines except for Ir116 which contained an amino group and was assumed to be very active to the carboxyl group in the protein residues in cells. Under the irradiation of visible light, Ir80 and the Ir119 were found to be quite photo-toxic with the light IC50 value of 8.08 μM and 6.14 μM respectively. They could become the potential candidates for the promising drugs of photo-dynamic therapy. The cytotoxicities of those five complexes were further investigated by the live and dead assay using calcein AM (acetoxymethyl) and propidium iodide (PI) double stain method. JC-1 aggregates observation and analysis in the mitochondrial transmembrane potential (ΔΨM) testing proved the lower cytotoxicities of those five complexes than those in chapter 2. Fluorescence and cytotoxicity relationship (FCR) was also uncovered in chapter 3 in which the stronger macromolecular binding to complex could lead to its higher fluorescence intensity. Without the metabolic activity and the assistance of ATP at low temperature of 4 ℃, little Ir80 and Ir134 were found in cells, and the moderate uptake for Ir79 and higher volume of Ir116 and Ir119 were detected. A novel strategy of cold-shock enhanced cellular uptake pathway was discovered in Ir119 and its cold-shock caused cytotoxicity would be further evaluated. The volumes of uptake for those complexes in paraformaldehyde fixed cells were all very low due to their higher hydrophilicity and lower structural rigidity than those in chapter 2. Chapter 4 reported the investigation of six iridium complexes of Ir105: [Ir(4-mpp)2CDYP]+, Ir107: [Ir(piq)2CDYP]+, Ir108: [Ir(3-mpp)2CDYP]+, Ir123: [Ir(4-mpp)2CDYMB]+, Ir125: [Ir(piq)2CDYMB]+ and Ir133: [Ir(dpapp)2CDYMB]+ with rotatable 5H-cyclopenta[2,1-b:3,4-b']dipyridin Schiff-base ligands. Most of them were rather toxic to hep-G2 cell lines from the MTT assay, cell morphology and proliferation assay due to the Schiff-base N^N ligands. Those rotatable Schiff-base ligands seemed to have more cytotoxicity than the flexible 1H-imidazo[4, 5-f] [1, 10](phenanthroline) ligands in chapter 3. The planar and rigid structure of piq C^N ligands in Ir107 and Ir125 were supposed to contribute to the highest cytotoxicity in chapter 4. The dead (red PI) to live (green calcein) cell area ratios and the ΔΨM assay were in accordance with the cytotoxocity sequence in MTT assay. Most of the complexes in chapter 4 demonstrated characteristics of one kind of programmed cell death (PCD), namely apoptosis and the typical features of another cell death mode of oncosis including cellular dwelling and cytoplasm vacuolation have been discovered from Hep-G2 cell lines in the incubation with Ir107. The JC-1 aggregates have disappeared when the two most toxic complexes Ir107 and Ir125 were cultured with the cells at 5 μmol/L, indicating the ΔΨM lost repidly under the damage of iridium complexes. All the complexes were distributed in the cellular nuclei when the incubation time reached 120 minutes at the concentration of 20 and 40 μmol/L. The positive correlation in the fluorescence and cytotoxicity relationship (FCR) were also discovered in chapter 4. The luminescence intensity sequence of the complexes from the cellular uptake and distribution has almost the same order as the previous toxicity results. The two most toxic complexes of Ir107 and Ir125 were found to have the two highest fluorescent intensities inside cells at 4 ℃. Most complexes in this chapter could easily distribute in the fixed cellular nuclei except for Ir125 and Ir133 owing to their large and hydrophobic structures. Generally, the uptake of complexes in paraformaldehyde fixed cells was higher than the live cells at 4 ℃ according to their passive transport mode. Although the simple Schiff base ligands of CDYP and CDYMB in this chapter were rotatable and flexible similar to the 1H-imidazo[4, 5-f][1, 10](phenanthroline) based bipyridine ligands in chapter 3, the cytotoxicities of complexes were much higher than those in chapter 3. The former chapters implied that effective uptake of complexes in nuclei were the results of the cytotoxicities which damaged the integrity of nuclear envelope and leaked into the nucleoplasm. We assumed that there could be another explanation in chapter 4 that the complexes transferred into the nuclei through the nuclear pore on the nuclear envelope and accumulated in the nucleolus, and therefore, triggered the apoptosis of cells. This kind of evidence was discovered for the two most toxic complexes Ir107 and Ir125 that could enter into cellular nuclei when the cell looked quite healthy. There would be another possiblilty that the Schiff base could interrupt the function of intracellular hydrolase enzymes. Chapter 5 compared the properties of five ruthenium(II) complexes of Ru2: [Ru(bpy)2DBDPPZ]2+, Ru7: [Ru(bpy)2MTPIP]2+, Ru8: [Ru(bpy)2EIPP]2+, Ru15: [Ru(phen)2BPDC]2+ and Ru24: [Ru(phen)2CDYMB]2+ with the ligand DBDPPZ from chapter 2, MTPIP and EIPP from chapter 3, CDYMB from chapter 4 and BPDC with two carboxyl groups. Those two positively charged ruthenium complexes indicated very low cytotoxicities from the cell morphology assay and MTT assay. No typical features of cellular apoptosis such as round and shrank cells were observed. However, the light IC50 value of Ru8 was excitingly obtained to be 2.33 μM upon the irradiation of 465 nm which was found to be one of the most promising drugs for photodynamic therapy (PDT) in his thesis. Charge and property relationship (CPR) was discovered to be the most decisive factor in the cytotoxicities of iridium and ruthenium complexes in this thesis which was also supported by a few of the independent literature papers mentioning high cytotoxicity of one positively charged ruthenium complex or low toxicity of two positively charged iridium complex. The DBDPPZ and CDYMB ligands in the ruthenium complexes Ru2 and Ru24 did not add into their cytotoxicity but those ligands greatly enhanced the toxicities of iridium complexes. The calculation of both area and number ratios of dead to live cells stained by the PI and calcein dyes indicated the lowest dark cytotoxicity among the ruthenium complexes could be Ru8 while the Ru24 and Ru7 were more toxic than others. Active JC-1 aggregates were maintained in the cell mitochondria and did not greatly diminish with the increasing concentration of ruthenium complexes. The two positive charges were found to play the important role in the poor cellular uptake of all the ruthenium complexes and the large size of phen ligand further prevented the uptake of Ru24 and reduced its toxicity. The Ru2, Ru7 and Ru8 were found to distribute in fixed cells with much higher luminescence intensities than their corresponding iridium complexes of Ir115, Ir79 and Ir80 with the same N^N ligand respectively which were assigned to be the two positive charges in those ruthenium complexes. The facilitated diffusion was found to be the main passive transport for the five ruthenium complexes in HepG2 cells at 4 ℃ when the ATP functions were considered to be largely inhibited. The low temperature cellular uptake has the similar trend of the cytotoxicities of the five complexes, indicating the structures of complexes were decisive in the process of facilitated diffusion. The enormous difference of cellular uptake and distribution in the fixes cells remind us the normal protocol before the cell-image pictures of fluorescence inverse microscopes (FIM) or confocal laser scanning microscope (CLSM) should be cancelled or very cautiously handled when the luminescent metal complexes were applied. In chapter 6, the further structure-activity relationship (SAR) was discussed based on the different C^N, N^N ligands and metal cores from the previous chapters. The overall research scheme, results and significance were summarized. Highlights were listed and future research plan was also proposed. At last, Chapter 7 described briefly the experiment protocols and supplementary information for the former chapters.

Lanthanoid Activated Phosphors with 5d-4f Visible Luminescence for Lighting Applications: Development and Characterization Based on Control of Electronic Structure and Ligand Field / 照明応用5d-4f 可視発光を有するランタノイド賦活蛍光体－電子構造および配位子場制御に基づく開発と特性評価－

Asami, Kazuki

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(人間・環境学) / 甲第21849号 / 人博第878号 / 新制||人||210(附属図書館) / 2018||人博||878(吉田南総合図書館) / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)教授 田部 勢津久, 教授 内本 喜晴, 教授 加藤 立久, 教授 吉田 寿雄 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DGAM

Lanthanide

Luminescence

Garnet

Phosphor

Electronic Structure

361

Synthesis and bio-applications of luminescent iridium (III) and rutherium (II) bipyridine complexes

Wang, Haitao

24 August 2020

This thesis is based on the past three years of research work including synthesis, characterization of three series of iridium(III) complexes and one series of ruthenium(II) complexes, and their comparative bio-applications of DNA-binding, cell morphology, cytotoxicity, mitochondrial membrane potential, cellular uptake and distribution. Chapter 1 introduces the background and recent studies of transition-metal complexes as biosensors and anti-tumor medicines. Their structure related properties of cytotoxicities, cellular uptake and distributions were also discussed. In chapter 2, five iridium(III) complexes Ir4: [Ir(4-mpp)2DPPZ]+, Ir7: [Ir(4-mpp)2BDPPZ]+, Ir8: [Ir(4-mpp)2MDPPZ]+, Ir115: [Ir(pp)2DBDPPZ]+ and Ir139: [Ir(dpapp)2DBDPPZ]+ were synthesized and characterized. The crystals of complex Ir139 were successfully cultured and analyzed by X-ray crystallography. The HOMO and LUMO energy gaps of complexes Ir4, Ir7 and Ir8 were obtained. The smaller the energy gap is the larger the Stokes shift will be. The DNA binding properties of Ir4, Ir7 and Ir8 were studied to acquire their binding constants and quenching constants. All the five complexes were cultured with hepatocellular carcinoma cell (hep-G2) in different concentrations for cell morphologies and MTT assays. The IC50 values were calculated and the structure-activity relationship (SAR) was discussed. Properties of Ir115 and Ir139 for photodynamic therapy under the visible light were studied, and moderate light-enhanced cytotoxicities were discovered. The live and dead cell assay and mitochondrial transmembrane potential (ΔΨM) testing were performed and a similar cytotoxicity order to IC50 values was obtained. Some interesting interactions between complex and calcein or propidium iodide (PI) dye were observed and discussed. Cellular uptake and distribution assay showed that the fluorescence of iridium complex was closely related to its toxicity. The obvious cellular uptake at 4 ℃ indicated that all the complexes could transfer into cell through a passive transport mode of facilitated diffusion without the consumption of ATP. The greatest change in uptake intensity of Ir115 implied that the ATP could assist the transport of Ir115 at 37.5 ℃. The efficiency of uptake and distribution of complexes in paraformaldehyde (PFA) fixed cells was found to be strictly related to their size and the hydrophobicity. The rigidity of dipyrido[3,​2-​a:2',​3'-​c]phenazine based bipyridine ligands in this chapter contributed to the main cytotoxcities of those iridium complexes. Most of the iridium complexes in chapter 2 have similar structures to their classic ruthenium analogues while their activities have largely improved due to the higher cellular uptake and more biocompatibility. Chapter 3 presented five iridium complexes with rotatable 1H-imidazo [4,5-f] [1,10] (phenanthroline) based bipyridine ligands, which are Ir79: [Ir(pp)2MTPIP]+, Ir80: [Ir(pp)2EIPP]+, Ir116: [Ir(piq)2APIP]+, Ir119: [Ir(piq)2PPIP]+ and Ir134: [Ir(iqdpba)2PPIP]+. Cell morphology and proliferation assay, MTT assay indicated that most of them were not quite toxic for hep-G2 cell lines except for Ir116 which contained an amino group and was assumed to be very active to the carboxyl group in the protein residues in cells. Under the irradiation of visible light, Ir80 and the Ir119 were found to be quite photo-toxic with the light IC50 value of 8.08 μM and 6.14 μM respectively. They could become the potential candidates for the promising drugs of photo-dynamic therapy. The cytotoxicities of those five complexes were further investigated by the live and dead assay using calcein AM (acetoxymethyl) and propidium iodide (PI) double stain method. JC-1 aggregates observation and analysis in the mitochondrial transmembrane potential (ΔΨM) testing proved the lower cytotoxicities of those five complexes than those in chapter 2. Fluorescence and cytotoxicity relationship (FCR) was also uncovered in chapter 3 in which the stronger macromolecular binding to complex could lead to its higher fluorescence intensity. Without the metabolic activity and the assistance of ATP at low temperature of 4 ℃, little Ir80 and Ir134 were found in cells, and the moderate uptake for Ir79 and higher volume of Ir116 and Ir119 were detected. A novel strategy of cold-shock enhanced cellular uptake pathway was discovered in Ir119 and its cold-shock caused cytotoxicity would be further evaluated. The volumes of uptake for those complexes in paraformaldehyde fixed cells were all very low due to their higher hydrophilicity and lower structural rigidity than those in chapter 2. Chapter 4 reported the investigation of six iridium complexes of Ir105: [Ir(4-mpp)2CDYP]+, Ir107: [Ir(piq)2CDYP]+, Ir108: [Ir(3-mpp)2CDYP]+, Ir123: [Ir(4-mpp)2CDYMB]+, Ir125: [Ir(piq)2CDYMB]+ and Ir133: [Ir(dpapp)2CDYMB]+ with rotatable 5H-cyclopenta[2,1-b:3,4-b']dipyridin Schiff-base ligands. Most of them were rather toxic to hep-G2 cell lines from the MTT assay, cell morphology and proliferation assay due to the Schiff-base N^N ligands. Those rotatable Schiff-base ligands seemed to have more cytotoxicity than the flexible 1H-imidazo[4, 5-f] [1, 10](phenanthroline) ligands in chapter 3. The planar and rigid structure of piq C^N ligands in Ir107 and Ir125 were supposed to contribute to the highest cytotoxicity in chapter 4. The dead (red PI) to live (green calcein) cell area ratios and the ΔΨM assay were in accordance with the cytotoxocity sequence in MTT assay. Most of the complexes in chapter 4 demonstrated characteristics of one kind of programmed cell death (PCD), namely apoptosis and the typical features of another cell death mode of oncosis including cellular dwelling and cytoplasm vacuolation have been discovered from Hep-G2 cell lines in the incubation with Ir107. The JC-1 aggregates have disappeared when the two most toxic complexes Ir107 and Ir125 were cultured with the cells at 5 μmol/L, indicating the ΔΨM lost repidly under the damage of iridium complexes. All the complexes were distributed in the cellular nuclei when the incubation time reached 120 minutes at the concentration of 20 and 40 μmol/L. The positive correlation in the fluorescence and cytotoxicity relationship (FCR) were also discovered in chapter 4. The luminescence intensity sequence of the complexes from the cellular uptake and distribution has almost the same order as the previous toxicity results. The two most toxic complexes of Ir107 and Ir125 were found to have the two highest fluorescent intensities inside cells at 4 ℃. Most complexes in this chapter could easily distribute in the fixed cellular nuclei except for Ir125 and Ir133 owing to their large and hydrophobic structures. Generally, the uptake of complexes in paraformaldehyde fixed cells was higher than the live cells at 4 ℃ according to their passive transport mode. Although the simple Schiff base ligands of CDYP and CDYMB in this chapter were rotatable and flexible similar to the 1H-imidazo[4, 5-f][1, 10](phenanthroline) based bipyridine ligands in chapter 3, the cytotoxicities of complexes were much higher than those in chapter 3. The former chapters implied that effective uptake of complexes in nuclei were the results of the cytotoxicities which damaged the integrity of nuclear envelope and leaked into the nucleoplasm. We assumed that there could be another explanation in chapter 4 that the complexes transferred into the nuclei through the nuclear pore on the nuclear envelope and accumulated in the nucleolus, and therefore, triggered the apoptosis of cells. This kind of evidence was discovered for the two most toxic complexes Ir107 and Ir125 that could enter into cellular nuclei when the cell looked quite healthy. There would be another possiblilty that the Schiff base could interrupt the function of intracellular hydrolase enzymes. Chapter 5 compared the properties of five ruthenium(II) complexes of Ru2: [Ru(bpy)2DBDPPZ]2+, Ru7: [Ru(bpy)2MTPIP]2+, Ru8: [Ru(bpy)2EIPP]2+, Ru15: [Ru(phen)2BPDC]2+ and Ru24: [Ru(phen)2CDYMB]2+ with the ligand DBDPPZ from chapter 2, MTPIP and EIPP from chapter 3, CDYMB from chapter 4 and BPDC with two carboxyl groups. Those two positively charged ruthenium complexes indicated very low cytotoxicities from the cell morphology assay and MTT assay. No typical features of cellular apoptosis such as round and shrank cells were observed. However, the light IC50 value of Ru8 was excitingly obtained to be 2.33 μM upon the irradiation of 465 nm which was found to be one of the most promising drugs for photodynamic therapy (PDT) in his thesis. Charge and property relationship (CPR) was discovered to be the most decisive factor in the cytotoxicities of iridium and ruthenium complexes in this thesis which was also supported by a few of the independent literature papers mentioning high cytotoxicity of one positively charged ruthenium complex or low toxicity of two positively charged iridium complex. The DBDPPZ and CDYMB ligands in the ruthenium complexes Ru2 and Ru24 did not add into their cytotoxicity but those ligands greatly enhanced the toxicities of iridium complexes. The calculation of both area and number ratios of dead to live cells stained by the PI and calcein dyes indicated the lowest dark cytotoxicity among the ruthenium complexes could be Ru8 while the Ru24 and Ru7 were more toxic than others. Active JC-1 aggregates were maintained in the cell mitochondria and did not greatly diminish with the increasing concentration of ruthenium complexes. The two positive charges were found to play the important role in the poor cellular uptake of all the ruthenium complexes and the large size of phen ligand further prevented the uptake of Ru24 and reduced its toxicity. The Ru2, Ru7 and Ru8 were found to distribute in fixed cells with much higher luminescence intensities than their corresponding iridium complexes of Ir115, Ir79 and Ir80 with the same N^N ligand respectively which were assigned to be the two positive charges in those ruthenium complexes. The facilitated diffusion was found to be the main passive transport for the five ruthenium complexes in HepG2 cells at 4 ℃ when the ATP functions were considered to be largely inhibited. The low temperature cellular uptake has the similar trend of the cytotoxicities of the five complexes, indicating the structures of complexes were decisive in the process of facilitated diffusion. The enormous difference of cellular uptake and distribution in the fixes cells remind us the normal protocol before the cell-image pictures of fluorescence inverse microscopes (FIM) or confocal laser scanning microscope (CLSM) should be cancelled or very cautiously handled when the luminescent metal complexes were applied. In chapter 6, the further structure-activity relationship (SAR) was discussed based on the different C^N, N^N ligands and metal cores from the previous chapters. The overall research scheme, results and significance were summarized. Highlights were listed and future research plan was also proposed. At last, Chapter 7 described briefly the experiment protocols and supplementary information for the former chapters.

Luminescence of Mn"+ in glasses : a spectroscopic probe for the study of thermal phase separation

Ménassa, Pierre-Elie.

January 1983

No description available.

Luminescence spectroscopy.

Glass -- Spectra.

Spectrum analysis.

Analytical Potential Of Polymerized Liposomes Bound To Lanthanide Ions For Qualitative And Quantitative Analysis Of Proteins

Santos, Marina

01 January 2006

One of the intriguing features of biological systems is the prevalence of highly selective and often very strong interactions among different cellular components. Such interactions play a variety of organizational, mechanical, and physiological roles at the cellular and organism levels. Antigen-antibody complexes are representative examples of highly selective and potent interactions involving proteins. The marked specificity of protein-antibody complexes have led to a wide range of applications in cellular and molecular biology related research. They have become an integral research tool in the present genomic and proteomic era. Unfortunately, the production of selective tools based on antigen-antibody interactions requires cumbersome protocols. The long term goal of this project explores the possibility of manipulating liposomes to serve as the chemical receptors ("artificial antibodies") against selected proteins. Cellular lipids (e.g., lipid rafts) are known to facilitate highly selective binding of proteins on cell membranes. The binding of proteins to cell membranes can be envisaged to be modulated via interactions between polar (charged) and non-polar head groups of lipids and the complementary amino acid residues of proteins. Their interaction is facilitated by a combination of van der Waals, electrostatic, hydrogen bonding and hydrophobic forces. A further interesting aspect of the above interaction is the "fluidity" of the membrane resident lipids, which can migrate from other regions to further enhance the complementary interactions of proteins on the initially "docked" membrane surface. With these features in mind, the end goal of this project is expected to deliver lipid-based chemical receptors "synthetically" designed against proteins to function as "artificial antibodies". Protein sensing will be accomplished with lipid receptors assembled in templated polymerized liposomes. The research presented here specifically focus on the analytical aspects of protein sensing via polymerized liposome vesicles. Lanthanide ions (Eu(III) and Tb(III)) are incorporated into polymerized liposome with the expectation to "report" quantitative and qualitative information on the interacting protein. Our proposition is to extract quantitative and qualitative information from the luminescence intensity and the luminescence lifetime of the lanthanide ion, respectively. A thorough investigation is presented regarding the analytical potential of these two parameters for protein sensing. Two chemometic approaches - namely partial least squares (PLS-1) and artificial neural networks (ANN) - are compared towards quantitative and qualitative analysis of proteins in binary mixtures.

luminescence

lanthanide ions

liposome

protein

chemometrics

Chemistry

Étude de l'oligomérisation du récepteur des oestrogènes et son interaction avec le peptide GRIP-1 à l'aide du BRET

Melançon, Geneviève

January 2001

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Coactiveur

Fluorescence

Luminescence

Oestradiol

Antioestrogènes

Dégradation

Agrégation