Global ETD Search

121	Halide-Assisted Synthesis of Cadmium Chalcogenide Nanoplatelets Meerbach, Christian, Wu, Cong, Erwin, Steven C., Dang, Zhiya, Prudnikau, Anatol, Lesnyak, Vladimir 01 April 2021 (has links) Atomically flat colloidal semiconductor CdSe nanoplatelets (NPLs) with precisely controlled thickness possess a range of unique optoelectronic properties. Here, we study the growth of CdSe, CdTe, and CdS NPLs with the aim of synthesizing thicker NPLs in order to extend their optical activity further into the lower energy/larger wavelength range. We employ cadmium halides, which lead to faster reaction kinetics as confirmed by control experiments with cadmium hydroxide as a Cd-precursor. Addition of halides in all cases led to the formation of thicker NPL species, as compared with the corresponding syntheses without these additives. Analysis of a recent theoretical model of the platelet growth mechanism confirms an earlier suggestion that reducing both the reaction enthalpy and the surface energy of CdSe, by replacing acetate ligands with chloride ions, should indeed lead to thicker NPLs as observed. We noticed a formation of Cd0-metal nanoparticles in the first stage of the synthesis by preparing the Cd-precursor, which is another key finding of our work. We assume that these particles can serve as an active cadmium source facilitating the growth of the NPLs. The resulting 6 ML CdSe NPLs exhibited bright photoluminescence with quantum yield of up to 50%, exceptionally narrow spectrum centered at 582 nm with full width at half-maximum of approx. 11 nm, and small Stokes shift of 2 nm. Moreover, we demonstrated the synthesis of heterostructured core/shell CdSe/CdS NPLs based on 6 ML CdSe platelets, which also exhibited bright fluorescence. This work shows the possibility to overcome energetic barrier limiting the size (thickness) control by using appropriate promoters of the growth of CdSe, CdTe, and CdS 2D structures. info:eu-repo/classification/ddc/540 ddc:540
122	Topological defect-induced magnetism in a nanographene Mishra, Shantanu, Beyer, Doreen, Berger, Reinhard, Liu, Junzhi, Gröning, Oliver, Urgel, José I., Müllen, Klaus, Ruffieux, Pascal, Feng, Xinliang, Fasel, Roman 13 January 2021 (has links) The on-surface reactions of 10-bromo-10'-(2,6-dimethylphenyl)-9,9'-bianthracene on Au(111) surface have been investigated by a combination of bond-resolved scanning tunneling microscopy, scanning tunneling spectroscopy, and tightbinding and mean-field Hubbard calculations. The reactions afford the synthesis of two open-shell nanographenes (1a and 1b) exhibiting different scenarios of all-carbon magnetism. 1a, an allbenzenoid nanographene with previously unreported triangulenelike termini, contains a high proportion of zigzag edges, which endows it with an exceedingly low frontier gap of 110 meV and edge-localized states. The dominant reaction product (1b) is a non-benzenoid nanographene consisting of a single pentagonal ring in a benzenoid framework. The presence of this nonbenzenoid topological defect, which alters the bond connectivity in the hexagonal lattice, results in a non-Kekulé nanographene with a spin S = ½, which is detected as a Kondo resonance. Our work provides evidence of all-carbon magnetism, and motivates the use of topological defects as structural elements toward engineering agnetism in carbon-based nanomaterials for spintronics. info:eu-repo/classification/ddc/540 ddc:540
123	Non–Destructive Imaging of Phytosulfokine Trafficking Using a Fiber–Optic Fluorescence Microscope Abakah, Bernard, Ntim, Thomas, Offei, Edward, Erb, Christopher, Morgan, Jessica, Liu, Dian, Jelenska, Joanna, Morrell-Falvey, Jennifer L., Greenberg, Jean, Standaert, Robert Frank 06 April 2022 (has links) Plants secrete peptide ligands and use receptor signaling to respond to stress and control development. Understanding the signaling mechanisms and associated molecular trafficking is key to improving plant health and productivity for food, fiber and energy applications. However, one of the challenges to elucidating communication pathways in plants is to study the trafficking of molecules and signals iteratively and non-destructively. This study focuses on using fiber-optic fluorescence microscopy to image live plants iteratively and non-destructively after delivering both labeled and unlabeled phytosulfokine (PSK) into the plant. PSK is a sulfated peptide hormone involved in the regulation of plant cell division and growth via specific receptors, PSKRs. It also plays a role in regulating how plants are able to tolerate stress conditions. The microscope provides two-color (FITC/TRITC) optics and provides high-resolution (3–5 µm) epifluorescence micrographs via a 1-m coherent imaging fiber and a GRIN objective lens. To obtain high-quality images, the fiber was mounted either to a conventional upright microscope body equipped with a leaf compressor, or to a leaf clip with 5-axis positioning (X–Y–Z plus pitch and yaw) mounted on an extensible arm. PSK and TAMRA-labelled PSK were delivered into the roots of various Arabidopsis thaliana genotypes (wt; receptor-deficient: pskr1/pskr2; and tagged receptor overproducing: PSKR1‑GFP), and their movement in roots and leaves was tracked with the fiber-optic fluorescence microscope. Peptide trafficking was successfully observed in live plants non- destructively, confirming that PSK is mobile in both wt and receptor-deficient plants. Preliminary results suggest that the level of receptor PSKR1 may change in response to PSK, and that levels of PSKR1, PSKR2 or both may impact the trafficking of PSK. Understanding how PSK is trafficked in plants will offer insights into how we can improve plants health and productivity. Phytosulfokine Plant Signaling Molecular Trafficking Non-Destructive Imaging Fiber-Optic Microscopy Molecular Recognition Stress Response Amino Acids Chemical Synthesis Ligands Organic Chemistry Fluorescence Microscopy
124	Amine-Boranes: Synthesis and Applications Henry J Hamann (10730742) 30 April 2021 (has links) Reported herein is a brief summary of the history, properties, and applications of amine-boranes. The past methods devised for their preparation are described and the routes used to produce the compounds used in the work presented here are detailed. Building on prior synthetic approaches to amine-boranes, a new carbon dioxide mediated synthesis is presented. Proceeding through a monoacyloxyborane intermediate, the borane complexes of ammonia, primary, secondary, tertiary, and heteroaromatic amine are provided in 53-99% yields. Utilizing the amine-boranes obtained from the methods described, two divergent methods for direct amidation are introduced. The first uses amine-boranes as dual-purpose reagents, where the carboxylic acid is first activated by the borane moiety to form a triacyloxyborane-amine complex. This allows the delivery of the coordinated amine to form the amide products. A series of primary, secondary, and tertiary amides were prepared in 55-99% yields using this protocol, which displays a broad functional group tolerance. Extended from this dual-purpose methodology, a catalytic amidation is described. Utilizing ammonia-borane as a substoichiometric (10%) catalyst, a series of secondary and tertiary amide are prepared directly from carboxylic acids and amines in 59-99% yields, including amines containing typically borane reactive functionalities including alcohols, thiols, and alkenes. Amine-boranes are additionally used in two borylation methodologies. By reaction with <i>n</i>-butyl lithium, the amine-boranes are converted to the corresponding lithium aminoborohydrides, which upon reaction with a terminal alkyne provides the alkynyl borane-amine complexes in 65-98% yields. This process is compatible with both alkenes and internal alkynes, as well as a range of aprotic functionalities. A new strategy for aminoborane synthesis is also described and applied to the borylation of haloarenes. Activation of a series of amine-boranes with iodine produces the iodinated amine-borane, which undergoes dehydrohalogenation with an appropriate base to produce either monomeric or dimeric aminoboranes. Several aminoboranes were synthesized exclusively as the monomeric species, which due to their greater reactivity, were used directly in the synthesis of a series of aryl boronates in 65-99% yields. Organic Chemistry Organic Chemical Synthesis Catalysis and Mechanisms of Reactions amine-boranes Aminoboranes amidation borylation synthesis methodology metal amidoboranes triacyloxyborane-amine ammonia-borane aminoborohydrides boronate esters
125	APLIKACE NANOMATERIÁLŮ PRO VÝVOJ PÁJEK BEZ OLOVA / THE APPLICATION OF NANOMATERIALS FOR LEAD FREE SOLDERS DEVELOPMENT Pešina, Zbyněk January 2012 (has links) The present dissertation is motivated by the search for alternatives of lead-free soldering by nanoparticles of metals and their alloys. The research focuses on the possibility of replacing lead-free solders by nanoparticles. This issue is currently being addressed by the use of lead-free solders but their properties are not entirely equivalent to properties of lead-tin based alloys. The theoretical part of the dissertation first summarizes up-to date knowledge on the development of lead-free alloys currently used for soldering in the electronics. The work compares these lead-free solder candidates with previously used Pb-Sn alloys. The second section of the theoretical part is devoted to nanotechnology that offers possible solutions of problems associated with the use of lead-free solders. The text contains a description of the properties of nanocrystalline materials in comparison with those of compact alloys having the same chemical composition. The possibility of preparation of nanoparticles and potential problems associated with small particle sizes are also presented. Introduction of the experimental part focuses on the preparation of nanoparticles of pure metals and alloys by chemical and physical ways as well as on an instrumentation for characterisation and analysis. Attention is focused on the silver in nanoparticle form that exhibits the low temperature sintering effect, which is thermally activated by decomposition of oxide envelope covering the Ag nanoparticles. This factor is critical for low-temperature sintering and thus also for possible future applications. The thermal effects of the low sintering process were studied by methods of thermal analysis. The preparation of the Cu / Ag nano / Cu joints was carried out in-situ in inert atmosphere and under the action of atmospheric oxygen. In both cases varying conditions of thermal treatment were used. The cross sections of the prepared joints were then used for the metallographic analysis of the local mechanical properties of the resulting silver layer, for the chemical composition evaluation of the resulting layers of the joint, and for the microstructure study. Strength characteristics are represented by testing shear strength of individual joints.
126	Chemical tools to investigate inositol pyrophosphate protein interactions Furkert, David 24 July 2023 (has links) Die Inositol-Pyrophosphate (PP-InsPs) sind eine ubiquitäre Gruppe hochphosphorylierter eukaryotischer Signalmoleküle. Sie werden mit einer Vielzahl zentraler zellulärer Prozesse in Verbindung gebracht, doch fehlt oft ein detailliertes Verständnis der einzelnen Signalereignisse, was zum Teil auf einen Mangel an chemischen Werkzeugen zurückzuführen ist. Diese Arbeit beschreibt die chemische Synthese, Validierung und Anwendung von PP-InsP-Affinitätsreagenzien zur Identifizierung von Proteinbindungspartnern von Inositolhexakisphosphat (InsP6) und 5-Diphosphoinositol-Pentakisphosphat (5PP-InsP5), zwei wichtigen eukaryotischen Metaboliten. Die Affinitätsreagenzien wurden entwickelt, um InsP6 und ein metabolisch stabiles 5PP-InsP5-Analogon auf drei verschiedene Arten darzustellen. Die Anwendung dieser triplexierten Reagenzien auf Säugetier-Lysate lieferte einen ersten umfassenden Datensatz in HCT116- und HEK293T-Zellen. Die Interaktome wurden mittels quantitativer Proteomik annotiert und enthüllten Hunderte von potenziellen Proteinbindungspartnern. Die quantitative Analyse der InsP6- und 5PP-InsP5-bindenden Proteine zeigte Beispiele für hochspezifische Protein-Ligand-Interaktionen auf. Biochemische Untersuchungen ergaben, dass Inositol-5-Phosphatasen, PRPS1 und spezifische Phosphatidyl-Inositolphosphat-Kinasen potenziell unentdeckte Zielproteine von PP-InsPs sind. Darüber hinaus wurde durch die Entwicklung einer neuen Strategie der Myo-Inositol-Desymmetrisierung erstmals die Synthese eines Affinitätsreagens auf der Basis von 1,5-Bisdiphosphoinositol-Tetrakisphosphat (1,5(PP)2-InsP4) beschrieben. Die Affinitätsreagenzien und die proteomischen Datensätze stellen für die Gemeinschaft leistungsstarke Ressourcen dar, um künftige Untersuchungen zu den vielfältigen Signalmodalitäten von Inositolpyrophosphaten einzuleiten. / Inositol pyrophosphates (PP-InsPs) are a ubiquitous group of highly phosphorylated eukaryotic messengers. They have been linked to a panoply of central cellular processes, but a detailed understanding of the discrete signaling events is often missing, which can partially be attributed to a lack of chemical tools. This thesis describes the chemical synthesis, validation and application of PP-InsP affinity reagents to identify protein binding partners of inositol hexakisphosphate (InsP6) and 5-diphosphoinositol pentakisphosphate (5PP-InsP5), two important eukaryotic metabolites. The affinity reagents were developed to display InsP6 and a metabolically stable 5PP-InsP5 analog in three different ways. Application of these triplexed reagents to mammalian lysates provided a first comprehensive data set in HCT116 and HEK293T cells. The interactomes were annotated using quantitative proteomics and uncovered hundreds of potential protein binding partners. Quantitative analysis of InsP6 versus 5PP-InsP5 binding proteins highlighted examples of highly specific protein-ligand interactions. Biochemical studies primed inositol 5-phosphatases, PRPS1 and specific phosphatidyl inositol phosphate kinases as potentially undiscovered targets of PP-InsPs. Moreover, by developing a novel strategy of myo-inositol desymmetrization, the synthesis of an affinity reagent based on 1,5-bisdiphosphoinositol tetrakisphosphate (1,5(PP)2-InsP4) was described for the first time. The affinity reagents and the proteomic data sets constitute powerful resources for the community, to help launching future investigations into the multiple signaling modalities of inositol pyrophosphates. Inositol pyrophosphate Chemische Biologie Chemische Synthese inositol polyphosphate inositol pyrophosphate Chemical Biology Chemical synthesis inositol polyphosphate 547 Organische Chemie ddc:547
127	Redox Active Ligands To Facilitate Reactivity From Redox Restricted Metals Matthew C Hewitt (11197530) 29 July 2021 (has links) The synthesis of metal-redox active ligand complexes is described, along with reactivity studies aimed at facilitating novel C-N bond forming reactions. A copper bis(iminosemiquinone) structure is characterized, analyzed and its reduction series are characterized and the reactivity of the Cu(II) bis(amidophenolate) analog is investigated with tosyl azide. The identification of the major reaction product and its characterization is detailed, with reaction sensitivities and heavily distorted x-ray diffraction single crystal structure generating a complex data set. The characterization of the isolated product is ongoing, with EPR studies aimed at identifying the radical nature of the complex. Unusual solvent effects and solubility issues have been noted with these initial EPR studies and more data is necessary before analysis can be properly attempted. An ytterbium bis(amidophenolate) complex was synthesized and its reactivity studied with aryl azides. Initial reactivities generate the first documented lanthanide tetrazenes in-lieu of the targeted ytterbium imido. Reactivities and characterization of these complexes support a stable, heavily ionic tetrazene-metal complex with no observed redox nature, UV light sensitivities, or imido azide-tetrazene equilibrium observed in various tetrazene transition metal complexes. Synthesis of a sterically blocked ytterbium imido was attempted, utilizing DMAP. Initial isolation was achieved with characterization and reactivity studies supporting the imido nature of the complex. The weak coordinating of the DMAP provided instability that proved in opposition to crystallization, however, so the imido could not be confirmed. Initial reactions using alternative steric hinderance from triphenylphosphine oxide and pyridine N-oxide prove promising to increasing the stability of the presumed ytterbium imido. Organic synthesis was performed generating a potential antibacterial agent. The synthesis of cyclopropenes was initiated as antagonists for ETR proteins in fruits and plants. The intermediates proved highly sensitive to harsh chemical conditions, which was overcome utilizing a tin-mediated Barbier allylation. The cyclopropene alcohol synthon was synthesized, though protecting group optimization is necessary. f-Block Chemistry Transition Metal Chemistry Organic Chemical Synthesis Organometallic Chemistry amidophenolate complexes Copper Complexes Redox active ligands Ytterbium Complexes agrochemical adjuvants nitrene transfer reaction Copper Hydride Reductions
128	Transition-metal catalyzed cyclization reactions Pedro De Andrade Horn (14094015) 11 November 2022 (has links) <p> </p> <p>A historically important reaction, the Ueno-Stork reaction promotes, through the use of toxic organotin species, the cyclization of a haloacetal onto an alkene generating bicyclic acetals. This reaction has been used over the years in several total syntheses of biologically relevant natural products, especially the prostaglandin class of natural products. Herein, will be described the development of a novel nickel-catalyzed Ueno-Stork cyclization reaction, which no toxic organotin and radical promoters are used, and instead a greener, operationally friendly, and non-toxic earth abundant nickel catalyst is applied. Optimization studies, substrate scope, scalability, relative stereochemistry of the bicyclic acetals, as well as derivatization of the products were studied. Furthermore, the newly developed reaction was applied on the total synthesis of tricyclic-PGDM Methyl ester, a prostaglandin D2 metabolite of important clinical relevance that currently suffers from material supply issues.</p> <p>Cyclopropanol ring opening reactions have different reactivity modes. Either a metal homoenolate species or a b-keto radical species can be formed after ring opening depending on the reaction conditions applied. More specifically, hydroxycyclopropanols have been studied to access several important motifs present in an array of natural products and medicinally important molecules. The Dai group has used this strategy to access several motifs through intramolecular trapping of the homoenolate species with and without the presence of carbon monoxide to generate oxaspirolactones, THF/THP-fused bicyclic lactones, and disubstituted THF/THP heterocycles. Herein, it will be discussed the application of similar concepts to access new classes of heterocycles 4-ketovalerolactones and 3-furanones. The optimization of two reaction conditions to selectively synthesize each product starting from the same starting material was studied. Furthermore, the substrate scope, scale-up, and derivatization studies of each motif will be disclosed. </p> Transition metal chemistry Natural products and bioactive compounds Organic chemical synthesis PROSTAGLANDIN SYNTHESIS Nickel catalyst Palladium Catalysts copper catalyst CYCLIZATIONS
129	DEVELOPMENT OF CHEMICAL PROBES TO CBX CHROMODOMAIN USING DNA-ENCODED LIBRARIES AND COVALENT CONJUGATION WITH MANNICH ELECTROPHILES Sijie Wang (13141959) 26 July 2022 (has links) <p>Polycomb repressive complex 1 (PRC1) is critical for mediating gene expression during development. Five chromobox (CBX) homolog proteins, CBX2,4,6,7,8, are incorporated into PRC1 complexes, where they mediate targeting to trimethylated lysine 27 of histone H3 (H3K27me3) via the N-terminal chromodomain (ChD). Individual CBX paralogs have been implicated as drug targets in cancer; however, high similarity in sequence and structure among the CBX ChDs provide a major obstacle in developing selective CBX ChD inhibitors. Here a selection of small, focused, DNA-encoded libraries (DELs) against multiple homologous ChDs was reported to identify modifications to a parental ligand that confer both selectivity and potency for the ChD of CBX8. This on-DNA, medicinal chemistry approach enabled the development of SW2_110A, a selective, cell-permeable inhibitor of the CBX8 ChD. SW2_110A binds CBX8 ChD with a Kd of 800 nM, with minimal 5-fold selectivity for CBX8 ChD over all other CBX paralogs in vitro. SW2_110A specifically inhibits the association of CBX8 with chromatin in cells and inhibits the proliferation of THP1 leukemia cells driven by the MLL-AF9 translocation. In THP1 cells, SW2_110A treatment significantly decreases expression of MLL-AF9 target genes, including HOXA9, validating the previously established role for CBX8 in MLL-AF9 transcriptional activation, and defining the ChD as necessary for this function. The success of SW2_110A provides great promise for the development of highly selective and cell permeable probes for the full CBX family. In addition, the approach taken provides a proof-of-principle demonstration of how DELs can be used iteratively for optimization of both ligand potency and selectivity.</p> <p>CBX2 is upregulated in a variety of cancers, particularly in advanced prostate cancers. Using CBX2 inhibitors to understand and target CBX2 in prostate cancer is highly desirable. Here, selections of focused DNA encoded libraries (DELs) were performed for the discovery of a selective CBX2 chromodomain probe, SW2_152F. SW2_152F binds to CBX2 ChD with a Kd of 80 nM and displays 24-1000-fold selectivity for CBX2 ChD over other CBX paralogs <em>in vitro</em>. SW2_152F is cell permeable, selectively inhibits CBX2 chromatin binding in cells, and blocks neuroendocrine differentiation of prostate cancer cell lines in response to androgen deprivation.</p> <p>Targeted covalent inhibitors (TCIs) are rationally designed inhibitors that bind to a target protein and specifically label a non-conserved amino acid on proteins by means of reactive moieties (warheads). TCIs typically function by two steps, in which inhibitors first non-covalently bind to the target protein and then covalent bond formation occurs between the inhibitor- warhead and a proximal nucleophile on protein. Covalent inhibitors or drugs have prolonged target engagement and enhanced pharmacokinetic potency in vivo, compared to non-covalent molecules. Strategies to develop effective warheads of TCIs have been reported for labeling different nucleophilic amino acid residues, of which cysteine and lysine are the most established for covalent labeling. Tyrosine is recently becoming an attractive nucleophile for TCIs as an alternative choice, yet currently developed warheads that label tyrosine do so with modest specificity over other side chains. Here, I report the development of novel Mannich electrophiles and use those electrophiles as covalent warheads on an inhibitor to specifically target tyrosine in protein labeling. To my knowledge, this is first demonstration of the use of Mannich electrophiles in covalent inhibitors. Specifically, I leveraged a previously developed CBX8 chromodomain inhibitor to specifically label a non-conserved tyrosine within CBX8 using cyclic imine derivatives as warheads. This ligand-directed, specific tyrosine conjugation on CBX8 but not on CBX2, significantly improves both the potency and selectivity of inhibition. Biochemical, proteomic, and cellular validation further showed the cyclic imine covalent inhibitors can increase both potency and selectivity to the target protein CBX8 in cells, serving as a robust chemical probe for target function evaluation and modulation. This new type of tyrosine labeling warhead is a useful addition to the toolbox of medicinal chemists for covalent inhibitor development.</p> <p>The following chapters are modified from following publications, with permissions from Sijie Wang, Emily C.Dykhuizen, and Casey J. Krusemark. </p> <p>Wang, S., Denton, K. E., Hobbs, K. F., Weaver, T., McFarlane, J. M., Connelly, K. E., Gignac, M.C., Milosevich, N., Hof, F., Paci, I., Musselman, C. A., Dykhuizen, E.C., Krusemark, C. J. Optimization of Ligands Using Focused DNA-Encoded Libraries To Develop a Selective, Cell-Permeable CBX8 Chromodomain Inhibitor. <em>ACS Chem Biol. </em>2020, 15, 112-131</p> <p>Wang, S., Alpsoy, A., Sood, S., Ordonez-Rubiano, S. C., Dhiman, A., Sun, Y., Krusemark, C. J., Dykhuizen, E. C. A Potent, Selective CBX2 Chromodomain Ligand and its Cellular Activity During Prostate Cancer Neuroendocrine Differentiation. <em>ChemBioChem.</em> 2021, 22, 2335-2344</p> <p>Wang, S., Ordonez-Rubiano, S. C., Dhiman, A., Jiao G., Strohmier B. P., Krusemark, C. J., Dykhuizen, E. C. Polycomb Group proteins in cancer: multifaceted functions and strategies for modulation Modulators. <em>NAR Cancer</em>. 2021, 3, zcab039</p> Cancer cell biology Organic chemical synthesis DNA Encoded Library cbx chromodomains Cancer Biology Covalent inhibitor
130	Design, Synthesis and Evaluation of Novel Biarylpyrimidines ¿ a New Class of Ligand for Unusual Nucleic Acid Structures. Wheelhouse, Richard T., Jenkins, Terence C., Jennings, Sharon A., Pletsas, Dimitrios January 2006 (has links) No / Biarylpyrimidines are characterized as selective ligands for higher-order nucleic acid structures. A concise and efficient synthesis has been devised incorporating Suzuki biaryl cross-coupling of dihalopyrimidines. Two ligand series are described based on the parent thioether 4,6-bis[4-[[2-(dimethylamino)ethyl]mercapto]-phenyl]pyrimidine (la) and amide 4,6-bis(4[(2-(dimethylamino)ethyl)carboxamido]phenyl)pyrimidine (2a) compounds. In UV thermal denaturation studies with the poly(dA)·[poly(dT)]2 triplex structure, thioethers showed stabilization of the triplex form (¿Tm ¿ 20 °C). In contrast, amides showed duplex stabilization (¿Tm ¿ 15 °C) and either negligible stabilization or specific destabilization (¿Tm = -5 °C) of the triplex structure. Full spectra of nucleic acid binding preferences were determined by competition dialysis. The strongest interacting thioether bound preferentially to the poly(dA)·[poly(dT)]2 triplex, Kapp = 1.6 x 105 M-1 (40 x Kapp for CT DNA duplex). In contrast, the strongest binding amide selected the (T2G20T2)4 quadruplex structure, Kapp = 0.31 x 105 M-1 (6.5 x Kapp for CT DNA duplex). Sequence specificity Secondary structure Carboxamide Molecular structure Nucleotide sequence Telomere Benzamide derivatives Organic sulfide Triple helical structure Thymine nucleotide Adenine nucleotide Duplex Stability Nucleic acid Ligand Chemical synthesis

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