Jonathan Pfeuffer-Rooschüz scite author profile

Deep cavitands, concave molecular containers, represent an important supramolecular host class that has been explored for a variety of applications ranging from sensing, switching, purification and adsorption to catalysis. A major limitation in the field has been the cavitand volume that is restricted by the size of the structural platform utilized (diameter approx. 7 Å). We here report the synthesis of a novel, unprecedentedly large structural platform, named acridane[4]arene (diameter approx. 14 Å), suitable for the construction of cavitands with volumes of up to 814 Å 3 . These megalocavitands serve as size-selective hosts for fullerenes with mM to sub-μM binding affinity for C 60 and C 70 . Furthermore, the selective binding of fullerene C 70 in the presence of C 60 was demonstrated.

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Xanthene[n]arenes: Exceptionally Large, Bowl-Shaped Macrocyclic Building Blocks Suitable for Self-Assembly

Pfeuffer-Rooschüz

Schmid

Prescimone

et al. 2021

JACS Au

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A new class of macrocycles denoted as “xanthene[n]arenes” was synthesized. In contrast to most other macrocycles, they feature a conformationally restricted bowl shape due to the attached alkyl groups at the linking methylene units. This facilitates the synthesis of cavitands and the self-assembly to molecular capsules via noncovalent interactions. The derivatization potential of the novel macrocycles was demonstrated on the xanthene[3]arene scaffold. Besides a deep cavitand and an oxygen-embedded zigzag hydrocarbon belt[12]arene, a modified macrocycle was synthesized that self-assembles into a hydrogen-bonded tetrameric capsule, demonstrating the potential of xanthene[n]arenes as a new set of macrocyclic building blocks.

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Interaction of Cm(III) with human serum albumin studied by time-resolved laser fluorescence spectroscopy and NMR

Adam

Keskitalo

et al. 2019

Journal of Inorganic Biochemistry

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A B S T R A C TThe complexation of Cm(III) with human serum albumin (HSA) was investigated using time-resolved laser fluorescence spectroscopy (TRLFS). The Cm(III) HSA species is dominating the speciation between pH 7.0 and 9.3. The first coordination sphere is composed by three to four H 2 O molecules and five to six coordinating ligands from the protein. For the complex formation at pH 8.0 a conditional stability constant of logK = 6.16 ± 0.50 was determined. Furthermore, information on the Cm(III) HSA binding site were obtained. With increasing Cu(II) concentration the Cm(III) HSA complexation is suppressed whereas the addition of Zn(II) has no effect. This points to the complexation of Cm(III) at the N-terminal binding site (NTS) which is the primary Cu(II) binding site. NMR experiments with Cu(II), Eu(III) and Am(III) HSA show a decrease of the peak assigned to the His C2 proton of His 3, which is part of the NTS, with increasing metal ion concentration. This confirms the complexation of Eu(III) and Am(III) at the Cu(II) binding site NTS. The results presented in this study contribute to a better understanding of relevant biochemical reactions of incorporated actinides.

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Megalo‐Kavitanden: Synthese von Acridan[4]arenen und Bildung großer, tiefer Kavitanden für die selektive C₇₀‐Aufnahme

Pfeuffer-Rooschüz¹,

Heim²,

Prescimone³

et al. 2022

Angewandte Chemie

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Tiefe Kavitanden, konkave molekulare Behälter, stellen eine wichtige supramolekulare Wirtsklasse dar, die für eine Vielzahl von Anwendungen erforscht wurde, die von der Sensorik, Schaltung, Reinigung und Adsorption bis hin zur Katalyse reichen. Eine wesentliche Einschränkung auf diesem Gebiet ist das Kavitandenvolumen, das durch die Größe der verwendeten Strukturplattform (Durchmesser ca. 7 Å) begrenzt ist. Wir berichten hier über die Synthese einer neuartigen, beispiellos großen Strukturplattform namens Acridan[4]aren (Durchmesser ca. 14 Å), die sich für die Konstruktion von Kavitanden mit einem Volumen von bis zu 814 Å3 eignet. Diese Megalo‐Kavitanden dienen als größenselektive Wirte für Fullerene mit einer Bindungsaffinität von mM bis sub‐μM für C60 und C70. Darüber hinaus wurde die selektive Bindung von Fulleren C70 in Gegenwart von C60 nachgewiesen.

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Xanthene[n]arenes: Exceptionally Large, Bowl-shaped Macrocyclic Building Blocks Suitable for Self-Assembly

Pfeuffer-Rooschüz¹,

Prescimone²,

Tiefenbacher

2021

Preprint

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<div>A new class of macrocycles denoted as “xanthene[n]arenes” was synthesized. In contrast to most other macrocycles, they feature a rigid bowl-shape, required for the synthesis of cavitands and for the self-assembly to molecular capsules via non-covalent interactions. The derivatization potential of the novel macrocycles was demonstrated on the xanthene[3]arene scaffold. Beside a deep cavitand, a modified macrocycle was synthesized that self-assembles into a hydrogen-bonded tetrameric capsule. Both supramolecular systems display host-guest binding properties, demonstrating the potential of xanthene[n]arenes as a new set of macrocyclic building blocks.</div>

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