Practical and convenient modifications of the A,C-secondary hydroxyl face of cyclodextrins

A practical and convenient method for the preparation of α-, β-, and γ-cyclodextrin derivatives, in which the secondary hydroxyl faces of A- and C-glucose units are regioselectively modified, has been developed. Reactions of α-, β-, and γ-cyclodextrins with 1,4-dibenzoylbenzene-3′,3″-disulfonyl imidazole in N,N-dimethylformamide in the presence of molecular sieves regioselectively afforded the corresponding cyclic 2^A,2^C-(1,4-dibenzoylbenzene-3′,3″-disulfonyl)-cyclodextrins. Subsequent treatment of the sulfonylated cyclodextrins with sodium hydroxide or aqueous ammonia afforded the corresponding 2^A,3^A:2^C,3^C-di-manno-epoxy-cyclodextrins or 3^A,3^C-diamino-3^A,3^C-dideoxy-(2^AS,2^CS,3^AS,3^CS)-cyclodextrins, respectively, which can serve as important intermediates for further functionalizations of the cyclodextrins.     

An efficient strategy for the modification of α-cyclodextrin: direct conversion of one or two adjacent 6-OHs to phthalimides

α-Cyclodextrin was reacted with phthalimide under modified Mitsunobu conditions to give the 6^A-deoxy-6^A-phthalimido-α-cyclodextrin in 41% yield. This reaction also worked well in the modification of two methylene carbons, giving the 6^A,6^B-, 6^A,6^C- and 6^A,6^D-diphthalimido-α-cyclodextrins in 22, 9.5 and 4.6% isolated yields, respectively. All the phthalimido species can be quantitatively converted to the corresponding amino cyclodextrins by hydrazinolysis.     

A CAS study on S‐loss and O‐loss dissociation mechanisms of the SO2+ ion in the C,D, and E states

In the present work, we mainly study dissociation of the C ²B₁, D²A₁, and E²B₂ states of the SO₂⁺ ion using the complete active‐space self‐consistent field (CASSCF) and multiconfiguration second‐order perturbation theory (CASPT2) methods. We first performed CASPT2 potential energy curve (PEC) calculations for S‐ and O‐loss dissociation from the X, A, B, C, D, and E primarily ionization states and many quartet states. For studying S‐loss predissociation of the C, D, and E states by the quartet states to the first, second, and third S‐loss dissociation limits, the CASSCF minimum energy crossing point (MECP) calculations for the doublet/quartet state pairs were performed, and then the CASPT2 energies and CASSCF spin‐orbit couplings were calculated at the MECPs. Our calculations predict eight S‐loss predissociation processes (via MECPs and transition states) for the C, D, and E states and the energetics for these processes are reported. This study indicates that the C and D states can adiabatically dissociate to the first O‐loss dissociation limit. Our calculations (PEC and MECP) predict a predissociation process for the E state to the first O‐loss limit. Our calculations also predict that the E²B₂ state could dissociate to the first S‐ and O‐loss limits via the A²B₂ ← E²B₂ transition. On the basis of the 13 predicted processes, we discussed the S‐ and O‐loss dissociation mechanisms of the C, D, and E states proposed in the previous experimental studies. © 2010 Wiley Periodicals, Inc. J Comput Chem, 2010     

Synthesis of symmetrically modified α-cyclodextrins: an efficient and easy method

Efficient and simple synthetic methods of designed specific synthons of cyclodextrins are fundamental for the further development of more sophisticated supramolecular devices. Here, a new two step synthesis was proposed for the obtention of the 6^A,6^C,6^E-triazido-6^A,6^C,6^E-trideoxy-6^B,6^D,6^F-tri-O-methylhexakis-(2,3-di-O-methyl)cyclomaltohexaose on a large scale.     

New cup-shaped α-cyclodextrin derivatives and a study of their catalytic properties in oxidation reactions

A series of new α-cyclodextrin derivatives with a substituted propylene bridge attached to the 6-O's of the A,D-glucose units are reported. The compounds were prepared from the known 6^A,6^D-di-O-(prop-2-methylidene-1,3-dienyl)-hexadeca-O-benzyl-α-cyclodextrin, which was transformed into 6^A,6^D-di-O-(prop-2-methyl-1,3-dienyl)-α-cyclodextrin, 6^A,6^D-di-O-(prop-2-formyl-2-hydroxy-1,3-dienyl)-α-cyclodextrin, 6^A,6^D-di-O-(prop-2-aminomethyl-2-hydroxy-1,3-dienyl)-α-cyclodextrin, 6^A,6^D-di-O-(prop-2-hydroxymethylidene-1,3-dienyl)-α-cyclodextrin, 6^A,6^D-di-O-(prop-2-formyl-1,3-dienyl)-α-cyclodextrin, 6^A,6^D-di-O-(prop-2-carboxy-1,3-dienyl)-α-cyclodextrin and 6^A,6^D-di-O-(prop-2-methoxycarbonyl-1,3-dienyl)-α-cyclodextrin. The new compounds were evaluated for their ability to affect amine and alcohol oxidations in the presence of hydrogen peroxide.     

Taming of the DIBAL Promoted Debenzylation of α-Cyclodextrin. Kinetics,Substituent Effects and Efficient Synthesis of Lings Tetrol**

The kinetics of the reaction of perbenzyl α-cyclodextrin was studied varying the concentration of DIBAL and substrate, and the temperature. The initial debenzylation was found to be 1^st order in substrate and follow the relationship 0.0675+0.179[DIBAL]² with respect to the concentration of DIBAL. The second and the third debenzylation which led to the 3^A,6^A,6^D-triol (Lings triol) were both found to be 1^st order in substrate concentration and zero order in DIBAL concentration. Longer reaction times with DIBAL in high concentration gave further debenzylation to comparatively complex mixtures containing the 2B,3^A,6^A,6^D-tetrol and the 3^A,6^A,6^C,6^D-tetrol. In contrast reaction at 0.1 M DIBAL gave the symmetrical 3^A,6^A,3D,6D-tetrol (Lings tetrol) in 60 % yield. The effect of chlorine or methyl substitution of the phenyl groups of perbenzyl α-cyclodextrin was also investigated. Per 4-chlorobenzyl slowed down the reaction with DIBAL, while 4-methylbenzyl increased the reaction rate, but still gave the corresponding 6 A-monool or 6^A,6^D-diol products. A Hammett reaction constant of −4.9 was found for the first debenzylation showing a high degree of positive charge in the transition state. The per(2,4-dichlorobenzyl)-α-cyclodextrin-derivative was completely resistant to DIBAL, however upon addition of trimethyl aluminium this derivative also reacted to give the 6^A,6^D-diol product.     

Preparation of complexes formed in the reaction between diironnanocarbonyl and tetraalkyl(phenyl)diphosphine disulfides,R2P(S)P(S)R2 (R=Et,n -Pr,n -Bu,Ph)

Fe₂(CO)₉ and R₂P(S)P(S)R₂ (R = Et, n-Pr, n-Bu, Ph) react to form two types of cluster complexes Fe₃(CO)₉(μ₃-S)₂ (1), Fe₂(CO)₆(μ-SPR₂)₂ (2A)–(2D), [2A, R = Et; 2B, R = n-Pr; 2C, R = n-Bu; 2D, R = Ph]. The complexes result from phosphorus–phosphorus bond scission; in the former sulfur abstraction has also occurred. The complexes have been characterized by elemental analyses, FT-IR and ³¹P-[¹H]-NMR spectroscopy and mass spectrometry.     

Hetero-bifunctionalization of the secondary face of β-cyclodextrin: selective 3-sulfonylation and subsequent 2,3-epoxidation of 3-azido-3-deoxy-altro-β-cyclodextrin

3^A-Azido-3^A-deoxy-altro-β-cyclodextrin, which has 20 different hydroxyl groups, was selectively sulfonylated by 1-naphthalenesulfonyl chloride at the 3^G-OH of the glucoside residue as well as the 2^A-OH of the altroside one. Alkali treatment of the 3^G-sulfonate gave successfully the 2^G,3^G-epoxyalloside with the 3^A-azido group being left unaffected. Both the 3^G-sulfonate and 2^G,3^G -alloepoxide species of 3^A-azido-3^A-deoxy-altro-β-cyclodextrin not only have two sugar units being modified differently, but also can serve as versatile starting materials for the syntheses of bifunctional cyclodextrins with diverse combination of different functionalities.     

Analysis of the molecular bands of D2H and H2D at 5600 Å

Spectral simulation was used to analyze the molecular rovibrational bands of D₂H and H₂D at 5600 Å. These bands were previously measured by the ion beam neutralization method. They were assigned to the electronic 3p²B₁ ? 2s²A₁ and vibrational (ν - ν″) = (0, 0, 0,-0, 0, 0) transitions. Least squares fits to the experimental line-positions were made to determine the asymmetric rotator constants A, B and C for the 2s²A₁ and 3p²B₁ ν = 0 states of D₂H and H₂D, hitherto unknown. Lorentz line-profiles were assumed for the D₂H and H₂D rotational lines, whose widths are mainly governed by the lifetimes of the lower states. The bands at 5600 Å were simulated and the 2s²A₁ state lifetimes were estimated to be σ ≥ 0.5 ± 0.2 ps for D₂H and σ ≥ 0.4 ± 0.2 ps for H₂D. Vibrational constants of D₃ and D₂H in the 2s²A₁ states are determined from the positions of the 0-0 and 0-1 vibrational bands given in respective experimental spectra previously measured. For the first time the vibrational constants ω₁ and ω₂ of the 2s²A₁ state of H₂D were estimated from the positions of the 0-0 and 0-1 band maxima. These vibrational constants are compared with the corresponding vibrational constants of their ions.     

Darstellung von μ-Schwefeldisulfoniumsalzen [(CH3)2S?Sx?S(CH3)2]2+2A− (x = 1–3, A− = AsF6−, SbF6−, SbCl6−). Über die Analogie im Reaktionsverhalten zwischen Sulfanen und Sulfoniumsalzen

Preparation of μ-Sulfurdisulfonium Salts [(CH₃)₂S? S_x? S(CH₃)₂]²⁺2A^? (x = 1–3, A^? = AsF₆^?, SbF₆^?, SbCl₆^?). On the Analogy of the Reactivity of Sulfanes and Sulfonium Salts The preparation of the μ-sulfurdisulfonium salts [(CH₃)₂S? S_x? S(CH₃)₂]²⁺(A^?)₂ with x = 1–3 and A^? = AsF₆^?, SbF₆^?, SbCl₆^? is reported. The salts are formed by reaction of (CH₃)₂SH⁺A^? and (CH₃)₂SSH⁺A^? with SCl₂ and S₂Cl₂, resp. They are characterized by vibrational spectroscopic measurements. [(CH₃)₂S? S₂? S(CH₃)₂]²⁺(SbF₆^?)₂ crystallizes in the space group C2/c with a = 1 884.5(7) pm, b = 1 302.8(5) pm, c = 1 477.2(5) pm, β = 98.62(3)° und Z = 8.     

Crystal and molecular structure of bis(N,N-dipropyl-N′-diphenoxythiophosphoryl-thioureato) nickel(II) [(C6H5O)2P(S)NC(S)N(C3H7)2]2Ni

The Ni complex [C₆H₅O₂P(S)N(C₃H₇₂]₂Ni is monoclinic, space group P2₁/n with a = 8.890(3), b = 21.692(5), c = 11.670(4) Å, β = 108.35(5)°, V = 2136(1) ų, F(000) = 916, M_r = 534.01, Z = 2, D_m = 1.318, D_x = 1.358 Mg m^?3, graphite monochromatized MoKα ^? radiation, π = 0.7107 Å, μ = 0.76 mm^?1, T = 293 K. The structure was solved by a heavy atom method and refined to R = 0.044 for 3095 independent reflexions. The Ni atom lies in the centre of symmetry and is coordinated by four S atoms of the two molecules of the ligand in a planar arrangement. Ni? S bond lengths are 2.205 and 2.226 Å resp., the angles S? Ni? S are 97.65 and 82.35° resp.     

Potential energy surfaces for OsH2

Summary We compute the potential energy surfaces of 12 electronic states of OsH₂ (four quintet, four triplet, and four singlet) arising from⁵ D ground state of the Os atom as well as triplet and singlet excited states using the complete active space multiconfiguration self-consistent field (CAS-MCSCF) followed by multireference configuration interaction (MRCI) and relativistic CI (RCI) calculation which include up to 430,000 configurations. We find that the⁵ D ground state of Os atom does not insert into H₂ while the excited³ F state of Os does. The³ B ₁ ground state of OsH₂ (there are two other nearly degenerate states) in the absence of spin-orbit coupling was found to be 22 kcal/mol more stable than Os(⁵ D)+H₂. The spin-orbit mixing of³ B ₁,³ B ₂,³ A ₂, and¹ A ₁ states was so strong that it induces significant change in bond angles (up to 10°) for OsH₂.Dedicated to Prof. Klaus RuedenbergCamille and Henry Dreyfus Teacher-Scholar     

Synthesis of large chelate rings with diphosphites built on a cyclodextrin scaffold. Unexpected formation of 1,2-phenylene-capped α-cyclodextrins

Two primary face difunctionalised α-cyclodextrins (α-CDs) bearing AC and AD-positioned triarylphosphite ligands have been synthesised and their ability to form large chelate rings has been evaluated. 6^A,6^D-Bis-O-{2-〚(diphenoxyphosphino)oxy〛phenyl}-2^A,2^B,2^C,2^D,2^E,2^F,3^A,3^B,3^C,3^D,3^E,3^F,6^B,6^C,6^E,6^F-hexadeca-O-methyl-α-cyclodextrin (L1) was prepared in three steps in 59% overall yield: (i) treatment of 6^A,6^D-di-O-(methylsulfonyl)-2^A,2^B,2^C,2^D,2^E,2^F,3^A,3^B,3^C,3^D,3^E,3^F,6^B,6^C,6^E,6^F-hexadeca-O-methyl-α-cyclodextrin (1a) with sodium 2-(benzyloxy)phenolate, affording a mixture of the corresponding bisaryloxy substitution product 2a; (ii) cleavage of the benzyl groups of 2a with formation of bisphenol 6a; (iii) reaction of 2a with chlorodiphenylphosphite to afford L1. Diphosphite L2 was obtained in a similar manner using the AC dimesylate 1b (yield: 54%). In step (i) of each synthesis, the unexpected formation of a catecholato-capped CD was observed as a result of benzyl loss under the used arylation conditions. The AD-bridged product was characterised by a single crystal X-ray diffraction study. In the solid state, the CD torus adopts the usual circular shape while four glucose rings, although not distorted, are considerably tilted towards the cavity axis. Both ligands, L1 and L2, when reacted with the cationic complexes AgBF₄ or 〚Rh(norbornadiene)(THF)₂〛X (X = BF₄, PF₆), produced selectively chelate complexes having up to 29-membered metallomacrocycles in high yields. Rhodium systems based on either L1 or L2 catalyse effectively the hyfroformylation of 1-octene (TOF up to 1200 mol mol^–1 of Rh h^–1). Hydrogenation of dimethyl itaconate with a Rh(I)/L2 complex produced dimethyl (R)-(+)-methylsuccinate with an EE as high as 83.6%.     

A facile sulfonylation method enabling direct syntheses of per(2-O-sulfonyl)-β-cyclodextrins

Cs₂CO₃ was found to efficiently catalyze the reaction of β-cyclodextrin and N-tosylimidazole. Stirring β-cyclodextrin and N-tosylimidazole in 1/1.2 molar ratio in DMF in the presence of catalytic amount of Cs₂CO₃ at rt for 1.5 h afforded 2^A-mono(O-tosyl)-β-cyclodextrin in 32% yield. The 2^A,2^B-, 2^A,2^C- and 2^A,2^D-ditosylates were isolated in ca. 6-7% yields, respectively, when β-cyclodextrin and N-tosylimidazole were used in 1/2.5 molar ratio. The charge of excess (10 equiv) of N-tosylimidazole ensured a one-step direct (protection-free) synthesis of the per(2-O-tosyl)-β-cyclodextrin in 5% isolated yield. N-(m-Nitrobenzenesulfonyl)imidazole even allowed a much faster access to the corresponding persulfonate in only 1 h reaction.     

Mechanism of 2-O→3-O silyl migration in cyclomaltohexaose (α-cyclodextrin)

To gain insight into the mechanism of the well-known 2-O→3-O silyl migration of 2-O-silylated cyclomaltooligosaccharides (cyclodextrins) under basic conditions, we have undertaken studies of the reaction of 2^A-O-TBDMSi-6^A-deoxy-6^A-S-phenyl-α-cyclodextrin with MeI and NaH. Under these conditions, the TBDMSi group on the C-2 oxygen was found to migrate onto the C-3 oxygen in the glucose residue in which the C-2 oxygen is located, and not onto the C-3 oxygen in the adjacent glucose residue.     

Tetra-hydrides of the third-row transition elements: spin–orbit coupling effects on geometrical deformation in WH4 and OsH4

The dissociation energies of MH₄ (M =  La, Hf–Hg) were computed using full optimized reaction space (FORS) multi-configuration self-consistent field (MCSCF) and second-order multi-reference Møller–Plesset perturbation methods with the SBKJC basis sets augmented by a set of polarization functions (SBKJC(f,p)). It was shown that of the molecules examined, only four tetra-hydrides HfH₄, TaH₄, WH₄, and OsH₄ with T_d symmetry are lower in energy than the corresponding dissociation limits. For WH₄ and OsH₄, the potential energy surfaces from the D_4h to the T_d structure were explored from both theoretical calculations and symmetry arguments based on the pseudo-Jahn- Teller effect. As for WH₄, it is found that the ground state could be ³E_g, ³A_2g, or ³B_2g at the D_4h structure. The present calculations suggest that the ground state is ³E_g, and that this state is stabilized by the e_u deformation into a C_2v structure (³B₁) and then sequentially to the most stable T_d structure (³A₂). If the molecular system is promoted to the lowest ³B_2g state, the D_4h structure can directly deform into the most stable T_d structure along the b_2u vibrational mode. For OsH₄, the ground state (⁵B_1g) at the D_4h structure deforms into a D_2d structure and the resulting ⁵B₂ state strongly interacts with the lowest ³E and ¹A₁ states due to the spin-orbit couplings (SOCs). As a result, it was shown that the relativistic potential energy of the lowest spin-mixed state (ground state) monotonically decreases along the D_2d deformation path from the D_4h to the T_d structure.     

Copolymeric cyclodextrin polysiloxane stationary phases prepared from 6A,6C- and 6A,6D-dialkenyl-substituted β-cyclodextrin

The syntheses of four new β-cyclodextrin-hexasiloxane copolymers from heptakis(2,3-di-O-methyl)-β-cyclodextrin (2) by multi-step processes are described. 6^A,6^C-Di-O-[p,p'-methylenebis(benzenesulfonyl)]hetakis(2,3-di-O-methyl)β-cyclodextrin (3) , which was prepared by the reaction of 2 with p,p'-methylenebis-(benzenesulfonyl chloride), is a key intermediate for the preparation of permethylated 6^A,6^C-bisalkenyl-β-cyclodextrins 5, 6 , and 9. Permethylated 6^A,6^C-bissulfonate ester 4 , which was obtained from 3 by a methylation reaction under mild conditions, was reacted with sodium allyloxide or sodium ω-undecenyloxide to produce permethylated 6^A,6^C-bisallyl- (or bis-ω-undecenyl)-β-cyclodextrin 5 or 6 or was hydrolyzed with 2% sodium amalgam in methanol to yield diol 7. Compound 7 was oxidized with periodinane, followed by Wittig's reaction with methyltriphenylphosphonium iodide to give permethylated 6^A,6^C-dideoxy-6^A,6^C-dimethylene-β-cyclodextrin (9). Treatment of 2 with p,p'-methylenebis(benzenesulfonyl chloride) or p,p'-biphenyldisulfonyl chloride gave bissulfonate esters 10 or 11 , respectively. Both of them were treated with sodium p-allyloxy-phenoxide in DMF, followed by methylation, to form permethylated 6^A,6^D-di-O-(p-allyloxyphenyl)-β-cyclo-dextrin (16). Bisalkenes 5, 6, 9 and 16 were copolymerized with α,ω-dioctyldecamethylhexasiloxane by a hydrosilylation process to give the cyclodextrin-containing copolymers 17–20.     

Electron paramagnetic resonance parameters of V2+ ions in both Cd2+ sites of CsCdCl3 crystal

From the perturbation formulas based on a two-spin-orbit-parameter model, the electron paramagnetic resonance (EPR) zero-field splitting (D), g-factors (g_//, g_⊥) and hyperfine structure constants (A_//, A_⊥) for V²⁺ in Cd²⁺(I) and Cd²⁺(II) sites of CsCdCl₃ crystal at room and liquid nitrogen temperatures are calculated. From the calculations, the signs of zero-field splittings and hyperfine structure constants are determined and so all of the EPR parameters are explained reasonably on the basis of the structure data of lattice.     

Quantum-chemical study of ytterbium fluorides and of complex F<Subscript>2</Subscript>YbF<Subscript>2</Subscript>CeF<Subscript>2</Subscript>

The structural parameters of the (²Σ⁺//C_∞v)-YbF, (¹A₁//C_2v)-YbF2, (²A₂^′//D_3h)-YbF₃, (¹Ag//D_2h)-YbF₂Yb, (¹Ag//C_2h)-FYbF₂YbF, (¹A₁//C_2v)-FYbF₂YbF, (¹A₁//C_2v)-YbF₂YbF₂, (³B_3u//D_2h)-F₂YbF₂YbF₂, (²A′//C_s)-FYbF₂YbF₂, and (³B₂//С_2v)-F₂YbF₂CeF₂ molecules have been determined. Disproportionation of ytterbium monofluoride (2YbF → YbF₂ + Yb + 0.46 eV) is less exothermic than dimerization (2YbF → YbF₂Yb + 2.10 eV). The bond energy of the ytterbium difluoride molecules in the trans dimer (2.93 eV) exceeds those in the cis dimer (2.86 eV) and the coaxial dimer (1.66 eV). Ytterbium trifluoride dimerizes exothermically (2.95 eV) without spin pairing. The dipole and quadrupole moments of the molecules as well as the charges and spin populations of the atoms and the valence electron configurations of the lanthanides have been calculated.     

Collisional ionization of fast K atoms by H2S and D2S

The process K + H₂S/D₂S → HS^?/DS^? + K⁺+ H/D has been investigated for K impact energies from near threshold to ≈100 eV. Positive and negative ion energy spectra have been obtained in the forward direction. The threshold for HS^? or DS^?production corresponds to the HS^?/DS^?+ H/D limit of the ²A₁ H₂S^?/D₂S^? state at 1.55 eV.