Chiral samarium iodo and terbutylate derivatives as catalysts for MPV ketone reductions

Samarium iodo and terbutylate derivatives coordinated by various chiral ligands have been prepared and used in situ as new catalysts for MPV reductions of aromatic ketones. The most active catalyst is samarium terbutylate binaphtolate albeit with moderate enantioselectivity.     

A novel unexpected luminescent quarternary coordination polymer {Sm3(C8H4O4)4(C12N2H8)2(NO3)}n with three high asymmetrical central Sm fragments by hydrothermal assembly

A novel chain-like luminescent samarium coordination polymer {Sm₃(C₈H₄O₄)₄(C₁₂N₂H₈)₂(NO₃)}_n (C₈H₄O₄ = phthalate, C₁₂N₂H₈ = 1,10-phenanthroline) has been assembled by hydrothermal process. The title complex crystallizes in the monoclinic system, space group P2(1)/c, with lattice parameters a = 22.56(3) Å, b = 11.155(15) Å, c = 20.32(3) Å, β = 96.70(2)°, V = 5078(12) ų, F(000) = 2964, GOF = 0.857, R₁ = 0.0358, wR₂ = 0.0597, Z = 4. Samarium ions exhibit different coordination modes from each other and lead to the unexpected high asymmetrical structure. To our knowledge, it is the first example of lanthanide coordination polymers comprising the three asymmetrical central Sm³⁺ fragments. The photophysical properties have been studied with excitation and emission spectra.     

钐在小鼠肝脏细胞中的动态观察

本实验给小鼠一次静脉注射氯化钐(70mg/kg体重)后15min至48h中的不同间期,应用电镜与X射线微区分析术对钐在肝脏枯否细胞与肝细胞中的运转进行了动态追踪。于15min 至2 h,两种细胞均以胞吞方式摄入含钐微粒,在胞质中形成吞噬体。在吞噬体中,微粒群处于由稀疏至密集的浓缩过程。小吞噬体亦互相融合。这种胞吞作用于枯否细胞极为活跃。于4—24 h,很多枯否细胞胞质充满吞噬体,细胞已经或趋于变性、崩解。肝细胞内的吞噬体则汇集于胆小管周围。于胆小管腔中可见到高电子密度微粒群,表明体内钐可经胆汁途径排出。于48 h,两种肝脏细胞巾仍见钐吞噬体沉积。     

Chemical and biological evaluation of 153Sm and 166Ho complexes of 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetrakis(methylphosphonic acid monoethylester) (H4 dotp OEt)

The novel methylphosphonic acid monoethylester (H₄dotp^OEt) has been synthesized and characterized and their complexes with Sm(III) and Ho(III) ions were studied. Dissociation constants of the ligand are lower than those of H₄dota. The stability constants of the Ln(III)-H₄dotp^OEt complexes are surprisingly much lower that those of H₄dota (H₄dota = 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid) probably due to a lower coordination ability of the phosphonate monoester groups. Acid-assisted decomplexation studies have shown that both complexes are less kinetically inert than the H₄dota complexes, but still much more inert than complexes of open-chain ligands. Nevertheless, the synthesis of ¹⁵³Sm and ¹⁶⁶Ho complexes with this ligand led to stable complexes both in vitro and in vivo. A very low binding of these complexes to hydroxyapatite (HA) and calcified tissues was observed confirming the assumption that a fully ionized phosphonate group(s) is necessary for a strong bone affinity. Both complexes show similar behaviour in vivo and, in general, follow the biodistribution trend of the H₄dota complexes with the same metals.     

Accumulation and distribution of samarium-153 in rat brain after intraperitoneal injection

It is well known that rare earth elements (REEs) have come into extensive use in a number of fields. As a result, REEs are becoming closely related to human's daily life. However, until now, the distributions of REEs in the brain are not yet very clear. In this study, Sprague-Dawley male rats were intraperitoneally injected with 0.25 mL of ¹⁵³SmCl₃ solution (containing 10 μg Sm). The brain were perfused with saline to minimize the blood influence. The radioactivities of ¹⁵³Sm in the five brain regions (hypothalamus, cerebellum, hippocampus, corpus striatum, and cerebral cortex) were counted. The results suggested that Sm did enter into the brain. Although only about 0.0003% of the given dose was accumulated in the brain, Sm seemed to be remain in the brain for a long time. The highest amounts and lowest concentrations of ¹⁵³Sm were found in the cerebral cortex, and the highest concentrations of ¹⁵³Sm were found in the hypothalamus.     

Synthesis of a C-linked hyaluronic acid disaccharide mimetic

The synthesis of a C-disaccharide that is designed as a mimetic for the repeating unit disaccharide of hyaluronic acid is described. The target compound was obtained via the SmI2-promoted coupling reaction of the sulfone, 2-acetamido-4,6-O-benzylidene-3-O-tert-butyldimethylsilyl-1,2-dideoxy-1-pyridinylsulfonyl-beta-D-glucopyranose (6), and the aldehyde, p-methoxyphenyl 2,3-di-O-benzyl-4-deoxy-4-C-formyl-6-O-p-methoxybenzyl-beta-D-glucopyranoside (14).     

SYNTHESIS OF COMPLEX NUCLEOSIDE ANTIBIOTICS

Herbicidin B and fully protected tunicaminyluracil, which were undecose nucleoside antibiotics, were synthesized using a samarium diiodide (SmI₂) mediated aldol reaction with the use of α-phenylthioketone as an enolate. The characteristics of the SmI₂-mediated aldol reaction are that the enolate can be regioselectively generated and the aldol reaction proceeds under near neutral condition. This reaction is proved to be a powerful reaction for the synthesis of complex nucleoside antibiotics. The synthesis of caprazol, the core structure of caprazamycins, was conducted by the strategy including β-selective ribosylation without using a neighboring group participation and the construction of a diazepanone by a modified reductive amination. Our synthetic route would provide a range of key analogues with partial structures to define the pharmacophore, which can be a lead for the development of more effective anti-bacterial agents.     

Syntheses, properties, and structural characteristics of several new [tetrakis(1-pyrazolyl)borato]samarium(III) complexes: comparative study of the B(pyrazolyl)4 and BH(pyrazolyl)3 ligation

Although reactions of samarium(III) chloride, SmCl₃ · 6H₂O, with potassium hydrotris(1-pyrazolyl)borate K[BH(pz)₃] (pz = 1-pyrazolyl) in a molar ratio of (1/1) in THF afford [SmCl{BH(pz)₃}₂(Hpz)], similar reactions with K[B(pz)₄] gave rise to separation of anhydrous H[B(pz)₄]. The homoleptic eight-coordinate complex [Sm{B(pz)₄}₃] obtained from SmCl₃ · 6H₂O and threefold moles of K[B(pz)₄] was allowed to react with twofold moles of K[BH(pz)₃] to give a mixture of three major species [Sm{B(pz)₄}_n{BH(pz)₃}_(3 − n)] (n = 2, 1, 0), whereas similar reactions of [Sm{BH(pz)₃}₃] with K[B(pz)₄] did not proceed at all. The acetylacetonato (acac) complex [Sm{B(pz)₄}₂(acac)], derived from the triflate “Sm{B(pz)₄}₂(OTf)”, was treated with twofold moles of K[BH(pz)₃] and showed its quantitative conversion to [Sm{BH(pz)₃}₂(acac)]. However, analogous reaction of [Sm{BH(pz)₃}₂(acac)] with K[B(pz)₄] did not proceed. Accordingly, samarium(III) ion was determined to prefer coordination of BH(pz)₃ ligand to that of B(pz)₄, indicating less σ-donating electronic character of the latter. The complexes [Sm{B(pz)₄}₂(L-L)] (L-L = β-ketoenolato) in toluene-d₈ exhibited ¹H NMR spectroscopic equivalence of all four pyrazolyl groups at high temperatures, and are regarded as a new class of B(pz)₄ complexes, showing fast intramolecular exchange of their coordinated and uncoordinated pyrazolyl groups. Four compounds were crystallographically characterized.     

Synthese Regiospecifique d'Un Dinucleoside Ponte: (O6 Desoxyguanosnyl)-1(N4-desoxycytidyl)-2 Ethane

Abstract

Appropriate protected deoxyguanosine and deoxyuridine derivatives, respectively activated at 0⁶ and. 0⁴ positions by the 3-nitro 1,2,4-triazol 1-yl group, were reacted with ethylene gtycol, ethylenediamine or ethanolamine to give monoalkylated nucleosides or cross-linked dimers or cross-linked dinucleosides.     

Preparation and Use of Samarium Diiodide (SmI2) in Organic Synthesis: The Mechanistic Role of HMPA and Ni(II) Salts in the Samarium Barbier Reaction

Although initially considered an esoteric reagent, SmI₂ has become a common tool for synthetic organic chemists. SmI₂ is generated through the addition of molecular iodine to samarium metal in THF.^1,2-3 It is a mild and selective single electron reductant and its versatility is a result of its ability to initiate a wide range of reductions including C-C bond-forming and cascade or sequential reactions. SmI₂ can reduce a variety of functional groups including sulfoxides and sulfones, phosphine oxides, epoxides, alkyl and aryl halides, carbonyls, and conjugated double bonds.^2-12 One of the fascinating features of SmI-₂-mediated reactions is the ability to manipulate the outcome of reactions through the selective use of cosolvents or additives. In most instances, additives are essential in controlling the rate of reduction and the chemo- or stereoselectivity of reactions.^13-14 Additives commonly utilized to fine tune the reactivity of SmI₂ can be classified into three major groups: (1) Lewis bases (HMPA, other electron-donor ligands, chelating ethers, etc.), (2) proton sources (alcohols, water etc.), and (3) inorganic additives (Ni(acac)₂, FeCl₃, etc).³Understanding the mechanism of SmI₂ reactions and the role of the additives enables utilization of the full potential of the reagent in organic synthesis. The Sm-Barbier reaction is chosen to illustrate the synthetic importance and mechanistic role of two common additives: HMPA and Ni(II) in this reaction. The Sm-Barbier reaction is similar to the traditional Grignard reaction with the only difference being that the alkyl halide, carbonyl, and Sm reductant are mixed simultaneously in one pot.^1,15 Examples of Sm-mediated Barbier reactions with a range of coupling partners have been reported,^1,3,7,10,12 and have been utilized in key steps of the synthesis of large natural products.^16,17 Previous studies on the effect of additives on SmI₂ reactions have shown that HMPA enhances the reduction potential of SmI₂ by coordinating to the samarium metal center, producing a more powerful,^13-14,18 sterically encumbered reductant^19-21 and in some cases playing an integral role in post electron-transfer steps facilitating subsequent bond-forming events.²² In the Sm-Barbier reaction, HMPA has been shown to additionally activate the alkyl halide by forming a complex in a pre-equilibrium step.²³Ni(II) salts are a catalytic additive used frequently in Sm-mediated transformations.^24-27 Though critical for success, the mechanistic role of Ni(II) was not known in these reactions. Recently it has been shown that SmI₂ reduces Ni(II) to Ni(0), and the reaction is then carried out through organometallic Ni(0) chemistry.²⁸These mechanistic studies highlight that although the same Barbier product is obtained, the use of different additives in the SmI₂ reaction drastically alters the mechanistic pathway of the reaction. The protocol for running these SmI₂-initiated reactions is described.