borane Dotaz Zobrazit nápovědu
- MeSH
- finanční podpora výzkumu jako téma MeSH
- Publikační typ
- abstrakty MeSH
Surface of ultra-high-molecular-weight polyethylene (UHMWPE) was modified by chemical methods. Surface was firstly activated by Piranha solution and then grafted with selected amino-compounds (cysteamine, ethylenediamine or chitosan). The next step was grafting of some borane cluster compounds, highly fluorescent borane hydride cluster anti-B18H22 or its thiolated derivative 4,4'-(HS)2-anti-B18H20. Polymer foils were studied using various methods to characterize surface chemistry (X-ray photoelectron spectroscopy), roughness and morphology (atomic force microscopy, scanning electron microscopy), chemistry and polarity (electrokinetic analysis), wettability (goniometry) and photophysical properties (UV-Vis spectroscopy) before and after modification steps. Subsequently some kinds of antimicrobial tests were performed. Immobilization of anti-B18H22 in small quantities onto UHMWPE surface leads to materials with a luminescence. Samples grafted with borane clusters showed significant inhibition of growth for gram-positive bacteria (S. epidermidis). These approaches can be used for (i) luminophores on the base of polymers nanocomposites development and/or (ii) preparation of materials with antimicrobial effects.
Ring cleavage of cyclic ether substituents attached to a boron cage via an oxonium oxygen atom are amongst the most versatile methods for conjoining boron closo-cages with organic functional groups. Here we focus on much less tackled chemistry of the 11-vertex zwitterionic compound [10-(O-(CH2-CH2)2O)-nido-7,8-C2B9H11] (1), which is the only known representative of cyclic ether substitution at nido-cages, and explore the scope for the use of this zwitterion 1 in reactions with various types of nucleophiles including bifunctional ones. Most of the nitrogen, oxygen, halogen, and sulphur nucleophiles studied react via nucleophilic substitution at the C1 atom of the dioxane ring, followed by its cleavage that produces six atom chain between the cage and the respective organic moiety. We also report the differences in reactivity of this nido-cage system with the simplest oxygen nucleophile, i.e., OH-. With compound 1, reaction proceeds in two possible directions, either via typical ring cleavage, or by replacement of the whole dioxane ring with -OH at higher temperatures. Furthermore, an easy deprotonation of the hydrogen bridge in 1 was observed that proceeds even in diluted aqueous KOH. We believe this knowledge can be further applied in the design of functional molecules, materials, and drugs.
Icosahedral heteroboranes and especially metallacarboranes, which have recently been shown to act as potent HIV-1 protease inhibitors, are a unique class of chemical compounds with unusual properties, one of which is the formation of dihydrogen bonds with biomolecules. In this study, we investigate the effect of various metal vertices and exo-substitutions on several series of heteroboranes, including 11-vertex carborane cages [nido-7,8-C2B9Hn]n-13(n= 11,12,13), closo-1-SB11H11, closo-1-NB11H12, metal bis(dicarbollides)[3,3'-M (1,2-C2B9H11)2]n(M/n=Fe/2-, Co/1-, Ni/0) and fluoro (F), amino (NH2) and hydroxo (OH) derivatives of the metal bis(dicarbollides). Besides the properties of isolated systems (geometries, electronic properties and hydration), we study their interactions with a tetrapeptide, which models their biomolecular partner. Calculations have confirmed that the extra hydrogen in [nido-7,8-C2B9H12]- forms a bridge, which fluctuates between two stationary states. Using RESP-derived charges, it was ascertained that the negative charge of heteroboranes is located mainly on boron-bound hydrogens. An increase of the negative total charge (from 0 to -1 or -2) of heteroboranes yields an increase in the stabilisation energies of heteroborane[dot dot dot]peptide complexes and also a substantial increase in the hydration free energies of heteroboranes. Compared to the substitutions of metal vertices, the exo-substitutions of metallacarboranes cause a larger increase in stabilisation energies and a smaller increase in desolvation penalties. These two terms, stabilisation energies and desolvation penalties, contribute in opposite directions to the total heteroborane-biomolecule binding energy and must both be taken into account when designing new HIV-1 protease inhibitors.
n background electrolyte (BGE) with the optimal methanol concentration of 30% (v/v), the ion with -NCS group bonded to a cluster boron atom exhibits the strongest interaction with alpha-cyclodextrin and the highest separation selectivity. Interaction of ions with alkyl or thioalkyl group weakens with the increasing substituent size. The ion with phenyl group exhibits the weakest interaction. Bonding of a group to boron atom weakens the ion interaction with alpha-cyclodextrin. Second substituent further weakens the interaction with alpha-cyclodextrin. Separation efficiency is lower at the presence of alpha-cyclodextrin than at its absence. This separation efficiency loss, amounts up to 90%.
Chalcogen atoms are a class of substituents capable of generating inner and outer derivatives of boron clusters. It is well known that chalcogenated boron clusters can form strong σ-hole interactions when a chalcogen atom is a part of an icosahedron. This paper studies σ-hole interactions of dicarbaboranes with two exopolyhedral chalcogen atoms bonded to carbon vertices. Specifically, a computational investigation has been carried out on the co-crystal of (1,2-C2B10H10)2Se4•toluene and a single crystal of (1,2-C2B10H10)2Te4.
- MeSH
- borany chemie MeSH
- chalkogeny chemie MeSH
- krystalizace MeSH
- molekulární modely MeSH
- statická elektřina MeSH
- termodynamika MeSH
- Publikační typ
- časopisecké články MeSH
An aminoborane side product from the nicergoline manufacture process was identified by single-crystal X-ray diffraction. As boranes of pharmaceutical molecules are quite rare, the binding potential of the BH3 group was investigated and compared with similar compounds using Cambridge Structural Database (CSD). Surprisingly, the packing was stabilized by a dihydrogen bond, which triggered a false alert for too-short contact of hydrogen atoms in IUCR checkCIF. As the dihydrogen bond concept is not widely known, such an alert might mislead crystallographers to force -CH3 optimal geometry to -BH3 groups. The B-H distances equal to or less than 1.0 Å (17% of the CSD structures) are substantially biased when analyzing the structures of aminoborane complexes in CSD. To conduct proper searching, B-H bond length normalization should be applied in the CSD search.
