R. Krishnan scite author profile

It's a trap! DNA polyhedra formed through molecular self-assembly may function as nanocapsules for the targeted delivery of encapsulated entities. This functional aspect was demonstrated for the most complex DNA-based platonic solid: During the stepwise amalgamation of discrete polyhedra to form icosahedra, gold nanoparticles (GNPs) were encapsulated from solution (see illustration and TEM image of icosahedral cages containing GNPs).

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Interaction of poly (ethylene oxide)–poly (propylene oxide)–poly (ethylene oxide) triblock copolymer of molecular weight 2800 with sodium dodecylsulfate (SDS) micelles: some physicochemical studies

James

Vellaichami

Krishnan

et al. 2005

Chemical Physics

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Self-Assembling Characteristics of A New Nonionic Gemini Surfactant

2004

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A new class of unusual nonionic gemini surfactant, viz. the bis-amide p-phenylenediamine Boc-bis-glycamide, was synthesized for the first time in our laboratory. The bis-amide is insoluble in water. However, the evidence for micelle formation of this bis-amide in chloroform has been obtained from surface tension, Langmuir film balance, and UV−visible, IR, and fluorescence spectroscopy. The critical micelle concentration (cmc) of this bis-amide, obtained by these techniques, correlates well. Tensiometry gave the cmc value, surface activity, and Gibbs molecular surface area. Film studies on the bis-amide gemini gave limiting areas and collapse pressures. The results of film studies also suggest that the bis-amide forms a stable monolayer film even at low concentrations and the limiting areas obtained at high concentrations (above the cmc value) are in good agreement with the contact area estimated from the theoretically calculated Connolly surface treatments. Both theoretical and experimental results suggest that the bis-amide molecules at high concentrations (above the cmc value) prefer slightly tilted conformations rather than a fully extended conformation at the air/water interface. The aggregation numbers of the bis-amide have also been determined by using both steady-state and time-resolved fluorescence methods, and they are in good agreement with each other. The concentration dependence aggregation number for bis-amide micelles has also been observed, and the results suggest the formation of only small micelles, despite the potential to grow; this is similar to the case for many micellar geminis. Computer simulation techniques show that about 11 molecules of bis-amide can aggregate to form a cluster. The IR spectra of the bis-amide in pre- and postmicellar regions were analyzed; there is no significant change in the intensity of the intermolecular hydrogen-bonding pattern for the bis-amide in the monomeric and micellar states. However, the intensity of the solvent-exposed −N−H stretching band increased as a function of bis-amide concentration after the cmc value was obtained. The fluorescence intensity of ANS in chloroform increases on interaction with bis-amide micelles, suggesting that, even in apolar media, ANS binds to the bis-amide in a region of lower polarity than does the chloroform alone. The pyrene emission intensity ratio of the first vibronic band to the third band as a function of bis-amide concentration suggested the hydrophobic character of bis-amide micelles in chloroform. Since there is no trace amount of water present in the system and the aggregate formation of the bis-amide is in the presence of pure chloroform solvent only, the species may be considered an inverted micelle. Steady-state fluorescence results suggest that 66% of the total pyrene emission is accessible to quenching in bis-amide micelles in chloroform. On the basis of lifetime measurements, the bimolecular quenching rate constant of the pyrene by CPC quencher in bis-amide micelles was found to be (1.4 ± 0.3) × 107 M-1 s-1, w...

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Icosahedral DNA Nanocapsules by Modular Assembly

et al. 2009

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In der Falle: Durch molekulare Selbstorganisation erzeugte DNA‐Polyeder könnten als Nanokäfige für den gerichteten Transport von verkapselten Spezies dienen. Das Funktionsprinzip wurde für den komplexesten aller DNA‐basierten platonischen Festkörper gezeigt: Während der stufenweisen Amalgamierung diskreter Polyeder zu Ikosaedern wurden Gold‐Nanopartikel (GNPs) aus der Lösung eingekapselt (siehe Illustration und TEM‐Bild ikosaederischer Käfige mit verkapselten GNPs).

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The I‐Tetraplex Building Block: Rational Design and Controlled Fabrication of Robust 1D DNA Scaffolds through Non‐Watson–Crick Interactions

Ghodke¹,

Krishnan²,

Vignesh³

et al. 2007

Angewandte Chemie

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Alles verdrahtet: Robuste 1D‐Gerüste auf der Basis des i‐Tetraplex wurden erhalten, indem ein bidirektionales Wachstum an „verrutschten“ Tetraplexen ausgelöst wurde. Das Wachstum nutzt Nicht‐Watson‐Crick‐Basenpaare und führt zu Nanodrähten von mehr als 3 μm Länge. Diese Nanodrähte wurden mikroskopisch (AFM und TEM, siehe Bild), durch oberflächenverstärkte Raman‐Spektroskopie und Circulardichroismusspektroskopie charakterisiert.

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R. Krishnan

Icosahedral DNA Nanocapsules by Modular Assembly

Interaction of poly (ethylene oxide)–poly (propylene oxide)–poly (ethylene oxide) triblock copolymer of molecular weight 2800 with sodium dodecylsulfate (SDS) micelles: some physicochemical studies

Self-Assembling Characteristics of A New Nonionic Gemini Surfactant

Icosahedral DNA Nanocapsules by Modular Assembly

The I‐Tetraplex Building Block: Rational Design and Controlled Fabrication of Robust 1D DNA Scaffolds through Non‐Watson–Crick Interactions

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