Kari Rissanen scite author profile

Dodecaborate anions of the type B12X122− and B12X11Y2− (X=H, Cl, Br, I and Y=OH, SH, NH3+, NR3+) form strong (Ka up to 106 L mol−1, for B12Br122−) inclusion complexes with γ-cyclodextrin (γ-CD). The micromolar affinities reached are the highest known for this native CD. The complexation exhibits highly negative enthalpies (up to −25 kcal mol−1) and entropies (TΔS up to −18.4 kcal mol−1, both for B12I122−), which position these guests at the bottom end of the well-known enthalpy-entropy correlation for CDs. The high driving force can be traced back to a chaotropic effect, according to which chaotropic anions have an intrinsic affinity to hydrophobic cavities in aqueous solution. In line with this argument, salting-in effects revealed dodecaborates as superchaotropic dianions.

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Recognition and sensing of fluoride anion

Cametti

2009

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Fluoride anion recognition is attracting a mounting interest in the scientific community due to its duplicitous nature. It is a useful chemical for many industrial applications, and it has been used in human diet, but, recently it has been accused for several human pathologies. Here we describe the ample panorama of different approaches the chemists world-wide have employed to face the challenge of fluoride binding, and we outline some of the research which in our view can contribute to the development of this field, especially when fluoride binding has to be achieved in highly competitive protic solvents and water.

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An Unlockable–Relockable Iron Cage by Subcomponent Self‐Assembly

et al. 2008

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In irons bound: Linear diamine and formylpyridine subcomponents form a tetrahedral cage with iron(II) in water (see scheme). This cage traps hydrophobic guests with high specificity within a rigid cavity, isolating them from the aqueous environment. The cage may be broken, releasing the guest, upon the addition of a triamine. It may also be unlocked by adding acid, allowing the guest to be reversibly released until base is added, relocking it within.

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A Self‐Assembled M₈L₆ Cubic Cage that Selectively Encapsulates Large Aromatic Guests

et al. 2011

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Biological encapsulants such as ferritin, [1] lumazine synthase, [2] and viral capsids [3] achieve their selective separation and sequestration of substrates by providing: 1) a guest microenvironment isolated from the surroundings, 2) favorable interactions complementing a size and shape match with the encapsulated guests, and 3) sufficient flexibility to allow guests to be incorporated and released.[4] These biological hosts self-assemble from multiple copies of identical protein subunits, the symmetries and connection properties [5] of which dictate the hollow polyhedral structures of the encapsulant. In order to create abiological molecular systems that are capable of expressing functions of similar complexity to biological systems and to explore new applications of synthetic hosts, [6] there is a need to create synthetic capsules capable of tightly and selectively binding large substrates.Taking inspiration from natural systems [1][2][3] and from other previously reported metal-organic capsules, [7] we report the design and synthesis of a series of metallo-supramolecular cage molecules capable of selectively encapsulating large aromatic guests. The necessary features to achieve this function are: 1) small pore sizes to isolate guests from the environment, [8] 2) large cavity sizes to ensure sufficient volume for the guests of interest, 3) enough flexibility and lability to allow guests to enter and exit the host, and 4) regions of the cage walls rich in p-electron density to provide favorable interactions with targeted guests.[9] The selective encapsulation of large aromatic molecules is an attractive goal since their physicochemical properties are similar, which can render their separation difficult. The higher fullerenes represent particularly attractive targets because their potential applications [10] remain difficult to explore because of the challenges associated with their separation, despite recent advances. [11] Employing principles of geometric analysis, [5] we determined that combination of the C 4 -symmetric tetrakis-bidentate ligand shown in Figure 1 with the C 3 -symmetric iron(II) tris(pyridylimine) center would result in the formation of an O-symmetric cubic structure of general formula M 8 L 6 , in which the corners of the cube are defined by the metal centers and the faces by the ligands (Figure 1). This cage represents the first example of a new class of closed-face metallosupramolecular cubic hosts to be synthesized. In order to provide favorable binding sites for our target guests we incorporated porphyrin moieties, which have previously been demonstrated to interact with large aromatic molecules, [11a-c, 12] into our design. This design also provides for small pore sizes and the potential to create new chemical functionality through the introduction of different metal ions into the centers of the N 4 macrocycle and by substituting these metals axial ligands. We chose to employ labile iron(II) centers with pyridylimine ligands as chelating agents to allow for the formation of the liga...

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Kari Rissanen

Water Structure Recovery in Chaotropic Anion Recognition: High‐Affinity Binding of Dodecaborate Clusters to γ‐Cyclodextrin

Recognition and sensing of fluoride anion

An Unlockable–Relockable Iron Cage by Subcomponent Self‐Assembly

A Self‐Assembled M₈L₆ Cubic Cage that Selectively Encapsulates Large Aromatic Guests

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Kari Rissanen

Water Structure Recovery in Chaotropic Anion Recognition: High‐Affinity Binding of Dodecaborate Clusters to γ‐Cyclodextrin

Recognition and sensing of fluoride anion

An Unlockable–Relockable Iron Cage by Subcomponent Self‐Assembly

A Self‐Assembled M8L6 Cubic Cage that Selectively Encapsulates Large Aromatic Guests

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Resources

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A Self‐Assembled M₈L₆ Cubic Cage that Selectively Encapsulates Large Aromatic Guests