Synthesis of a Tyr-octreotate conjugated closo-carborane [HC2B10H10]: a potential compound for boron neutron capture therapy

A novel Tyr³-octreotate conjugated closo-carborane as a potential compound for boron neutron capture therapy was obtained via Fmoc solid phase peptide synthesis. The boron cluster [C₂B₁₀H₁₁] was introduced through the reaction of 6,9-bis(acetonitrile)decaborane and 5-hexynoic acid yielding a new closo-carborane conjugated carboxylic acid which was coupled subsequently with solid phase conjugated Tyr³-octreotate. The final boron-containing peptide was purified by preparative reverse phase HPLC and structural identity was proved applying MALDI-TOF mass spectrometry.     

9-Allyl-1,7-dicarbadodecaborane as a dienophile in aza Diels-Alder reactions of 1,2,4-triazines: synthesis of pyridines bearing a carborane cage

The synthesis of pyridine and bipyridine derivatives of m-carborane via aza Diels-Alder reaction of 1,2,4-triazines with 9-allyl m-carborane and their structural characterization and photophysical properties are described. The products 3- and 4-(m-carborane-9-ylmethyl)-2,2′-bipyridines form Zn(II) complexes on reaction with ZnCl₂, which increases significantly their fluorescence intensity.     

The nido‐Cage⋅⋅⋅π Bond: A Non‐covalent Interaction between Boron Clusters and Aromatic Rings and Its Applications

Non‐covalent interactions involving multicenter multielectron skeletons such as boron clusters are rare. Now, a non‐covalent interaction, the nido‐cage???π bond, is discovered based on the boron cluster C₂B₉H₁₂^? and an aromatic π system. The X‐ray diffraction studies indicate that the nido‐cage???π bonding presents parallel‐displaced or T‐shaped geometries. The contacting distance between cage and π ring varies with the type and the substituent of the aromatic ring. Theoretical calculations reveal that this nido‐cage???π bond shares a similar nature to the conventional anion???π or π???π bonds found in classical aromatic ring systems. This nido‐cage???π interaction induces variable photophysical properties such as aggregation‐induced emission and aggregation‐caused quenching in one molecule. This work offers an overall understanding towards the boron cluster‐based non‐covalent bond and opens a door to investigate its properties.     

Synthesis of boron-containing derivatives of pyropheophorbide <Emphasis Type="ItalicUnderline">a</Emphasis> and investigation of their photophysical and biological properties

Proceeding from pyropheophorbide a and 9-hydroxymethyl-m-carborane, 1-hydroxymethyl-o-carborane, and 3-amino-o-carborane new carboranylchlorins were prepared, and their photophysical and biological properties were investigated.     

Some aspects for sintering of β-rhombohedral boron

The investigation of sintering conditions for magnesiothermic amorphous boron (Mg_mB_n) powder is presented. The results of chemical and X-ray analyses of magnesiothermic boron (Mg_mB_n) indicate that it consists of amorphous boron MgB₁₂ and a lesser amount of β-rhombohedral boron. The Mg_mB_n-sintering process is determined by the conditions of amorphous boron transformation into β-boron (crystallization), such as the process of decomposition of MgB₁₂ followed by formation of the “new” centers of active elementary boron. As a result of the experimental investigations of this process the following three stages—thermal decompositions, crystallization and Mg_mB_n sintering—were combined into one sintering process with the sintered bodies as a result of it.     

Synthesis of B-organo-substituted 1,2-, 1,7-, and 1,12-dicarbaclosododecarboranes(12)

A convenient new method is proposed for the synthesis of 9-organo-substituted o- and m-carboranes and 2-organo-substituted p-carborane by the substitution of iodine in 9-iodine-o-, 9-iodine-m-, and 2-iodine-p-carboranes by an organic group from an organomagnesium compound in the presence of catalytic amounts of phosphine complexes of palladium. For the first time the halogen in boron halogen carboranes has been substituted by an organic group.     

Energy transfer from aggregation-induced emissive o-carborane

π-Conjugated systems connected to o-carborane undergo enhancement of luminescence from boron dipyrromethene (BODIPY) dyes via encapsulation and energy transfer in aqueous media. The inhibition of H-aggregation formation in aqueous media effectively regains the emission from luminophores.     

NMR study of 1-aryl-1,2-dicarba-closo-dodecaboranes: intramolecular C-H?O hydrogen bonding in solution

Dicarba-closo-dodecaborane(12) (carborane) has recently received much attention as a building block for supramolecular assemblies and bioactive compounds. Among carborane isomers, 1,2-dicarba-closo-dodecaborane(12) (o-carborane) has unique chemical properties, including the ability of the o-carborane C-H hydrogens to form hydrogen bonds. To evaluate intramolecular hydrogen bond formation between the o-carborane C-H hydrogen and various hydrogen bond acceptors in solution, we have designed and synthesized 1-aryl-o-carboranes 2. Intramolecular hydrogen bonding ability was evaluated by means of ¹H NMR measurement of the o-carborane C-H hydrogen signal of 2. The 1-(2-methoxyphenyl)-o-carborane derivative 2m appeared to form an intramolecular hydrogen bond between o-carborane C-H hydrogen and the oxygen atom acting as a hydrogen bonding acceptor. In this study, we present evidence for hydrogen bond formation in solution between the o-carborane C-H and hydrogen bond acceptors positioned with appropriate geometry.     

Controlling the Dual-Emission Character of Aryl-Modified o-Carboranes by Intramolecular CH⋅⋅⋅O Interaction Sites

It is still challenging to realize a dual-emission system, in which two luminescent bands simultaneously appear by photoexcitation, in solid with organic dyes due to the difficulty in regulation of electronic properties in the excited state and concentration quenching. o-Carborane is known to be a versatile platform for constructing solid-state emitters since the sphere boron cluster is favorable for suppressing intermolecular interactions and subsequently concentration quenching. Here, we show solid-state dual-emissive o-carborane derivatives. We prepared 4 types of o-carborane derivatives and found dual-emission behaviors both in solution and solid states. By regulating the rotation at the o-carborane unit with the intramolecular C_cageH⋅⋅⋅O interaction, the dual-emission intensity ratios were changed. Finally, it was demonstrated that the overall photoluminescence spectra can be estimated using the binding energy of intramolecular interactions.     

Vibrational study of strong CH · middot; X hydrogen bonds in solid complexes of boron decachlorocarboranes

Solid complexes of boron decachloro-o-carborane and boron decachloro-m-carborane (B₁₀Cl₁₀C₂H₂) with some oxygen and nitrogen bases have been investigated by infrared and Raman spectroscopy. Complexes containing CH · · O hydrogen bonds are characterized by a relative CH stretching frequency shift up to 12% and a halfwidth of the νCH band up to 220 cm^?1. CH · · N hydrogen bonds, with trimethylamine for example, are stronger with a relative shift of about 18% and $\text{ν}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of about 500 cm^?1. Triethylamine complexes, however, form a NH⁺ · · C^? proton transfer hydrogen bond while pyridine can give either CH · · N or C^? · · ⁺HN hydrogen-bonded adducts depending on the solvent and temperature. The CH · · N?c^? · · ⁺HN equilibrium appears to be shifted towards ion-pair formation at considerably smaller enthalpy values compared to the OH · · N?O^? · · ⁺HN system. CH and NH stretching frequencies are correlated with the acidity of the donor and the basicity of acceptor molecules.     

Regioselective synthesis of triiodo-o-carboranes and tetraiodo-o-carborane

3,6-Diiodo-o-carborane 3, 3,6,9-triiodo-o-carborane 5, 3,9,12-triiodo-o-carborane 6 and 3,6,9,12-tetraiodo-o-carborane 7, which are suitable building blocks for supramolecular assemblies and carboracycles, were regioselectively synthesized by means of electrophilic iodination and introduction of iodine atoms via reconstruction of the o-carborane cage.     

Formation of p-carborane(12) from mo-carborane(12) via the cobalt complex [(o-C2B10H12)2CoIII]-

Oxidation of the cobalt complex obtained from o-C₂B₁₀H₁₂^2- and CoCl₂ in anhydrous tetrahydrofuran (THF) leads to a mixture of o-, p- and m-carborane(12) isomers whose ratio depends on the temperature (within the range 25–150°) and the length of heating. Similar mixtures of isomers have been obtained from the oxidation of p-C₂B₁₀H₁₂^2- and m-C₂B₁₀H₁₂^2- respectively and CoCl₂ in anhydrous THF.It is suggested that the presence of the cobalt atom in the complex reduces the activation energy required for the isomerization which is not observed with uncomplexed C₂B₁₀H₁₂^2- anions even at temperatures as high as 150°.A mechanism is proposed to explain the function of the cobalt atom in this process.     

New synthetic method of 1,2-diaryl-1,2-dicarba-closo-dodecaboranes employing aromatic nucleophilic substitution (SNAr) reaction

Aromatic nucleophilic substitution (S_NAr) reaction of 1-phenyl-o-carborane with 4-nitrofluorobenzene in the presence of NaH or KO^tBu proceeded smoothly to give 1-(4-nitrophenyl)-2-phenyl-o-carborane; similar reaction affords various 1,2-diaryl-o-carboranes, which are useful precursors for macromolecular construction and drug design.     

D2-m-carborane siloxanes. V. Structure–property relationships

D₂-m-decacarborane dimethylsiloxane has unusual thermal stability and resistance towards reversion, however, this material exhibits a crystalline phase, T_m at 68°C. To obtain an elastomeric material, this crystallinity is disrupted by replacing 30 to 50% of the m-carborane with p-carborane moieties or by the incorporation of phenyl moieties on the polymer backbone. The latter approach is preferred since improved thermo-oxidative stability accompanies this modification. Correlation of the glass transition temperature and thermo-oxidative stability with the polymer structure are presented.     

New B-substituted derivatives of m-carborane, p-carborane, and cobalt bis(1,2-dicarbollide) anion

The Pd-catalyzed cross-coupling reactions of B-I bond in m- and p-carboranes and cobalt bis(1,2-dicarbollide) anion with organomagnesium and organozinc compounds were studied. Carboranyl derivatives of furan, thiophene, indole, pyridine and quinoline were synthesized. 2-Pyridylethynyl and 3-quinolylethynyl derivatives of p-carborane were prepared by Pd-catalyzed cross-coupling reactions using corresponding alkynes or their magnesium derivatives.     

Solid-state supramolecular array through cooperative π-π interactions of 1-(2-methoxyphenyl)-o-carborane

Dicarba-closo-dodecaborane (carborane) has received much attention as a building block for supramolecular assemblies and bioactive compounds. Among the carborane isomers, 1,2-dicarba-closo-dodecaborane (o-carborane) has unique chemical properties, including the ability of the o-carborane C-H hydrogens to form H-bonds. We have designed and synthesized 1-(2-methoxyphenyl)-o-carborane 1a to study its ability to form an intramolecular H-bond between the o-carborane C-H hydrogen and various H-bond acceptors both in solution and in the solid state. Intramolecular H-bonding ability in solution was evaluated by means of ¹H NMR spectroscopic measurements of the C-H hydrogen signal. The signal of the C-H hydrogen of 1a showed a remarkable downfield shift in CDCl₃ and various other solvents, i.e., the shift was almost solvent-independent. We suggest that 1a forms an intramolecular H-bond in these solvents. Crystal structure analysis of 1a showed a C-H?O distance of 2.05 Å and a nearly planar torsion angle C(2)-C(1)-C(7)-C(8) of 6.5°, indicating intramolecular C-H?O H-bond formation in the solid state. The crystal packing of 1a indicates that a supramolecular array is stabilized by cooperative π-π stacking interactions among the methoxyphenyl groups and by hydrophobic interactions of the o-carborane cages. DFT calculations indicate that the strength of the intramolecular H-bond of 1a is about 3.53 kcal/mol. These observations indicate the potential value of o-carborane in supramolecular chemistry and materials chemistry; it should be possible to design novel materials by utilizing both the H-bonding ability of the o-carborane C-H hydrogen and the high hydrophobicity of the o-carborane cage.     

Synthesis of azomethines based on 4-formylphenyl m-carboranyl-C-methanoate

A preparative method for the synthesis of m-carborane azomethines via the condensation of mcarborane-C-4-formylphenyl methanoate with aliphatic, cycloaliphatic, and aromatic amines was developed.     

Chiral organotin complexes stabilized by C,N-chelating oxazolinyl-o-carboranes

A series of chiral organotin halides containing 2-(4-R)-oxazolinyl-o-carboranes (R = i-propyl 1, t-butyl 2; Cab^Oxa) was prepared from o-carborane with a chiral oxazoline auxiliary. X-ray structural analysis of the representative chiral organotin halide, [2-(4-i-propyl)-oxazolinyl-o-carboranyl]SnMe₂Br (4), revealed the formation of a stable penta-coordinated tin center due to a N → Sn interaction. Similar O → Sn assisted intramolecular penta-coordinated tin complexes (9 and 10) were prepared from methoxy-o-carborane ligands, MeOCH(Z)-o-carborane (Z = H 7, Ph 8; Cab^OMe), respectively, and a rigid o-carboranyl backbone provided the basic skeleton for the facile formation of organotin complexes.     

Reactions of lithium derivatives of o- and m-carboranes with 5,6-benzocoumarin and 5,6-benzo-3-ethoxycarbonylcoumarin

Reactions of lithium derivatives o- and m-carborane with 5,6-benzocoumarin and 5,6-benzo-3-ethoxycarbonylcoumarin have been studied.     

Crystal structure of tetragonal boron related to α-AlB12

Single crystals of the so-called β-tetragonal (or tetragonal II or III) boron modification have been obtained from boron deposits prepared by hydrogen reduction of BBr₃ on tantalum filaments at 1200°C. Chemical analysis of the samples shows that this phase can be regarded as a true modification of pure elemental boron in contrast to α-tetragonal phases which require small amounts of foreign atoms to stabilize their boron framework.The lattice parameters (a = 10.14(1)Å; c = 14.17(1)Å) were obtained and refined from single crystal data. The unit cell contains four chemical units, B₂₁ · 2B₁₂ · B_2.5 resulting in d_c = 2.34 g cm^?3 (d_m = 2.36(2) g cm^?3). The systematic extinctions are compatible with space group P4₁ or P4₃.The structure was determined from 1009 independent reflexions using a model derived from the recently solved structure of α - AlB₁₂ (a = 10.161Å; c = 14.283Å; space group P4₁2₁2 or P4₃2₁2). The final R value (unweighted data) is 9.6%.Basically, the structure of this tetragonal form of boron consists of the same three-dimensional boron skeleton, built upon simple and twinned icosahedra, as that of α-AlB₁₂. However, the defective twinned icosahedral B₁₉ units in α-AlB₁₂ are now completed (B₂₁ units) in the related tetragonal boron. A number of interstitial sites, located at positions different from those occupied by aluminum in α-AlB₁₂, are totally or partially filled by boron atoms and very probably increase the stability of the boron framework.