Werner M. Nau scite author profile

The cover picture shows in the center an electron‐density map of the molecular container compound cucurbit[7]uril. The polarizability inside the cavity of this host can be explored through solvatochromic effects on the absorption spectra (bottom right) when probed by the inclusion of an azo chromophore guest (top left). This novel method allows insight into the inner phase of supermolecules. More details about this process is described by Marquiz and Nau on pp. 4387 ff.

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Applications of Cucurbiturils in Medicinal Chemistry and Chemical Biology

Das

2019

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The supramolecular chemistry of cucurbit[n]urils (CBn) has been rapidly developing to encompass diverse medicinal applications, including drug formulation and delivery, controlled drug release, and sensing for bioanalytical purposes. This is made possible by their unique recognition properties and very low cytotoxicity. In this review, we summarize the host-guest complexation of biologically important molecules with CBn, and highlight their implementation in medicinal chemistry and chemical biology.

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Nanomolar Binding of Steroids to Cucurbit[n]urils: Selectivity and Applications

et al. 2016

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Cucurbit[n]urils (CBn, n = 7, 8) serve as artificial receptors for steroids (21 tested), including the hormones testosterone and estradiol as well as steroidal drugs. Fluorescence displacement titrations and isothermal titration calorimetry (ITC) provided up to nanomolar binding affinities in aqueous solution for these hydrophobic target molecules, exceeding the values of known synthetic receptors. Remarkable binding selectivities, even for homologous steroid pairs, were investigated in detail by NMR, X-ray crystal diffraction, ITC, and quantum chemical calculations. Notably, the CBn•steroid complexes are stable in water and buffers, in artificial gastric acid, and even in blood serum. Numerous applications have been demonstrated, which range from the solubility enhancement of the steroids in the presence of the macrocycles (up to 100 times, for drug delivery) and the principal component analysis of the fluorescence responses of different CBn•reporter dye combinations (for differential sensing of steroids) to the real-time monitoring of chemical conversions of steroids as substrates (for enzyme assays).

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HYDROPHOBE Challenge: A Joint Experimental and Computational Study on the Host–Guest Binding of Hydrocarbons to Cucurbiturils, Allowing Explicit Evaluation of Guest Hydration Free-Energy Contributions

et al. 2017

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The host-guest complexation of hydrocarbons (22 guest molecules) with cucurbit[7]uril (CB7) was investigated in aqueous solution. Association constants were determined by using the indicator displacement strategy, which allows binding constant determinations also for poorly water-soluble (hydrophobic) guests. The binding constants (103–109 M−1) increased with the size of the hydrocarbon, pointing to the hydrophobic effect and dispersion interactions as driving forces. Besides potential applications for the sensing and separation of hydrocarbons, the measured affinities provide unique benchmark data for the binding of neutral guest molecules. Consequently, a computational blind challenge, the HYDROPHOBE challenge, was conducted in order to allow a comparison with state-of-the-art computational methods for predicting host-guest affinity constants. In total, 5 computational data sets were submitted, which allowed the comparison of experimental binding constants with those predicted by coupled-cluster theory (DLPNO-CCSD(T)), dispersion-corrected density functional theory (DFT), and explicit solvent molecular dynamics (MD) simulations parameterized with two different force field combinations from the AMBER simulation package. All submissions were capable of predicting the general binding trend, with a slightly better correlation for the MD compared to the quantum-chemical (QM) data sets (R2MD = 0.80 vs R2QM = 0.66, average values for the submitted data sets). On the other hand, QM calculations showed better predictions for the absolute values of the binding affinities as reflected by the mean signed errors (4.3 kcal mol−1 for MD vs 1.8 kcal mol−1 for QM). When searching for sources of uncertainty in predicting the host-guest affinities, the experimentally known hydration energies of the investigated hydrocarbons could be employed, which provided a distinct advantage of the HYDROPHOBE challenge. The comparison with the employed solvation models (explicit solvent for MD and COSMO-RS for QM) confirmed a good correlation for both methods, but revealed a rather constant offset of the COSMO data, by ca. +2 kcal mol−1, which was traced back to a required reference-state correction in the QM submissions (2.38 kcal mol−1). Introduction of the reference-state correction improved the predictive power of the QM methods, particularly for small hydrocarbons up to C5. The correlations of both QM and MD submissions also exposed specific outliers, which could be due to peculiarities of the investigated guests, for example, different degrees of conformational changes upon complexation, such as helical structures of the longer n-alkyl chains within the cavity. The latter was confirmed by 2D NMR experiments and both the MD as well as QM calculations.

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Ultrastable Rhodamine with Cucurbituril

Mohanty

Nau

2005

Angewandte Chemie

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Rhodamines are arguably the most important fluorescent dyes as shown by their classical and contemporary applications, [1][2][3][4][5][6][7][8] for example, in dye lasers, as quantum counters, as photosensitizers, for spectral calibration in fluorometers, in single-molecule detection, as imaging agents for biomolecules, for scanning confocal microscopy, in fluorescence correlation spectroscopy (FCS), and in high-throughput screening assays. The various applications are made possible through the combination of their water solubility, close-tounity quantum yields, high extinction coefficients, and very high photostability. Rhodamine 6G (Rh6G) is the most prominent derivative and has become a prototype for many reasons, [3,4] including its photostability: the first continuouswave dye laser, for example, was based on an aqueous solution of Rh6G containing 1.5 % triton X as surfactant.[9]

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Werner M. Nau

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Applications of Cucurbiturils in Medicinal Chemistry and Chemical Biology

Nanomolar Binding of Steroids to Cucurbit[n]urils: Selectivity and Applications

HYDROPHOBE Challenge: A Joint Experimental and Computational Study on the Host–Guest Binding of Hydrocarbons to Cucurbiturils, Allowing Explicit Evaluation of Guest Hydration Free-Energy Contributions

Ultrastable Rhodamine with Cucurbituril

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