环芳酰胺的合成及自组装行为

本文主要综述了近年来由三中心氢键和远程位阻效应促进的环芳酰胺合成,以及利用该类化合物进行自组装行为的研究进展. 在研究一步高效成环的基础上,对合成不同孔径刚性大环的方法进行了探讨. 改变大环周边侧链的性质可以调控这类大环分子的自组装行为. 最后对环芳酰胺的应用进行了简单介绍     

硝基芳环和硝基杂芳环中氢的替代亲核取代

氢的替代亲核取代反应(VNS)是与硝基芳环的亲电反应、亲核反应不同的一种新反应. 将VNS与硝基芳环的亲电反应、亲核反应做比较, 阐述了VNS的定义; 通过对竞比实验、速控步骤和动力学同位素效应的分析, 解释了VNS的反应机理; 分别从硝基芳环的结构、亲核试剂的类型和反应条件三方面讨论了影响VNS定位效应的因素; 介绍了VNS反应的应用, 尤其是VNS胺化反应在军事化学中的实际应用.     

含长链亚烷基桥的芳炔类共轭大环的合成

采用模板导向法高产率地合成了两个含长链亚烷基桥的芳炔类共轭大环. 通过四碘化合物与单保护双炔化合物的四重Hagiraha偶合反应构建了环化所需要的复杂前体. 通过相应的模板四炔衍生物的分子内Glaser 偶合反应环化得到大环. 大环的结构用NMR, GPC 及UV-Vis表征确证.     

氮叶立德高立体选择性地合成螺[环丙烷-1,4'-吡唑啉-5'-酮] 衍生物的研究

螺环丙基杂环化合物是一类具有重要药理、生理活性的化合物, 研究和发展这类化合物的新的立体选择性合成方法是当前有机合成领域的一个热点. 对1,4-二氮杂双环[2.2.2]辛环(DABCO)衍生的氮叶立德与3-甲基-1-苯基-4-芳亚甲基-5-吡唑啉酮合成螺环丙基吡唑啉酮的反应做了研究, 并与胂叶立德所参与的类似反应的结果做了比较, 发现仅得到单一反式结构产物, 但存在exo和endo两种构型, 其中前者为主要产物. 产物结构由IR, MS, 1H NMR, 13C NMR, 元素分析和X射线衍射鉴定. 还从反应机理角度对两种叶立德性质对反应的影响做了解释.     

海南粗榧新碱类似物芳环的反常氢化反应（英文）

报道了海南粗榧新碱类似物芳环的一种反常氢化反应，并提出了可能的反应机理。     

芳香胺参加的Mannich反应(Ⅱ)——用芳胺盐酸盐合成β-芳胺基酮

室温时芳香胺盐酸盐与甲醛、烷基芳基酮在HCl(气)-C₂H₅OH溶液中可以直接发生Mannich反应,生成β-芳胺基芳酮。这是继文献[1]之后,通过Mannich反应直接合成β-芳胺基芳酮的一个新方法。产率与文献[1]相近或略高。脂肪酮如丙酮、丁酮、甲基异丙基甲酮、甲基异丁基甲酮;环酮如环己酮、环庚酮,同样能发生上述反应。用HNMR谱测定了不对称酮与芳胺及甲醛进行Mannich反应所得到的β-芳胺基脂酮的结构。这一事实说明在室温及酸性条件下,可以用芳胺一步直接合成β-芳胺基酮,其反应机理仍符合一般公认的Mannich反应机理。     

分子内氢键促进的大环合成:动力学和热力学控制途径

氢键诱导的线性芳酰胺寡聚体骨架可以采取折叠、螺旋、直线或"之"字型构象.这一结构预组织特征可以被应用于促进大环的合成.在芳酰胺骨架的两端引入适当反应基团,骨架的预组装构象可以诱导它们形成不同的空间取向和距离.当成环反应涉及到不可逆共价键、碳-金属键或配位键的形成时,前体的结构预组织构象可以促进目标大环形成的产率.当成环反应涉及亚胺及腙等可逆共价键时,在反应达到热力学平衡后,可以高产率或定量地形成大环.     

通过Michael加成反应和氧化环化反应合成多取代缺电子环丁烷

从简单易得的原料出发实现了多取代缺电子环丁烷的合成.该合成方法的关键反应是Michael加成反应和氧化环化反应.得到了目标产物的单晶结构,并且提出了可能的氧化环化反应机理.     

环三磷腈类阻燃剂的合成及应用研究进展

简要介绍了制备环三磷腈类阻燃剂所需起始原料六氯环三磷腈的合成方法、合成及取代反应机理;介绍了环三磷腈阻燃剂的阻燃机理;着重阐述了近20年间反应型的羟基/氨基环三磷腈、环氧基环三磷腈、含不饱和双键的环三磷腈、羧基环三磷腈阻燃剂,以及添加型烷氧基环三磷腈、芳氧基环三磷腈的合成及阻燃应用,同时综述了其应用材料的热稳定性能和阻燃性能,并对其发展趋势作了总结和展望。     

中环大环化合物合成研究进展

中环(8～11元环)与大环(12元环及以上)是药物和天然产物中非常重要的结构并广泛应用于药物合成、有机化学以及其他领域.科研工作者一直致力于开发更加简单、绿色、高效的合成中环大环的方法.归纳并总结近五年来最新的通过扩环和环化反应方法合成中环大环化合物的研究现状和进展,并对其未来的发展方向进行了总结和展望.     

One-pot synthesis of hybrid macrocyclic pentamers with variable functionalizations around the periphery

Rather than four- or six-residue macrocylces, one-pot macrocyclization allows for the highly selective formation of five-residue macrocycles rigidified by intramolecular hydrogen bonds. Variable functionalizations around the pentameric periphery were achieved by reacting monomers with higher oligomers bearing different exterior side chains. The formation of these hybrid pentamers suggests a chain-growth mechanism for the one-pot macrocyclization where the successive addition of monomers onto higher oligomers is faster than those between two monomers or two higher oligomers.     

POCl3-mediated H-bonding-directed one-pot synthesis of macrocyclic pentamers, strained hexamers and highly strained heptamers

Previously we have shown that POCl3-mediated H-bonding-directed one-pot macrocyclization allows for the highly selective preparation of five-residue macrocycles as the predominant product with low yields of hexamers and an undetectable occurrence of both tetramers and heptamers.Replacing the interiorly arrayed methyl groups with ethyl groups in these 4-7 residue macrocycles alters the relative stability order among them.Specifically,ethoxy-substituted six-residue macrocycle,rather than pentamer,turns out to be computationally the most stable,suggesting that ethoxy-containing hexamer possibly can be formed as the major product under suitable conditions.We have investigated this possibility by varying reaction temperatures and concentrations,invariably affording pentamer as the major macrocycle with strained circular hexamers and highly strained circular heptamers produced in substantial amounts.This discrepancy can be reasonably explained on the basis of bimolecular reactions between two oligomers higher than monomers via kinetic simulations.In this scenario,the acyclic pentamer is kinetically "trapped" to undergo an intramolecular cyclization to yield circular pentamer,rather than to produce acyclic hexamer.As a result,acyclic hexamer precursor is generated largely from sterically demanding bimolecular reactions between a dimer and a tetramer,or between two trimers that are kinetically slower than the pentamer-producing chain-growth reactions.We additionally found that one-pot macrocyclization proceeds to the largest extent at 40 ℃,an intriguing finding that highlights the low reactivities of acid chloride and amine groups in these H-bond-enforced acyclic oligomeric intermediates.     

BOP-mediated one-pot synthesis of C5-symmetric macrocyclic pyridone pentamers

We report here, for the first time, the BOP-mediated one-pot macrocyclization that is facilitated and guided by internally placed intramolecular H-bonds to allow for the highly selective formation of five-residue cation-binding macrocycles.     

Synthesis of cycloparaphenylene under spatial nanoconfinement

Suzuki coupling reactions between symmetrical monomers were conducted in various mesoporous silica nanoreactors grafted with palladium catalysts, enabling the selective formation of [12]cycloparaphenylene precursor with separate yield up to 25% in one-pot reactions, much higher than that in homogeneous reaction. The spatial nanoconfinement of the nanoreactors promotes the macrocyclization while limits the concomitant linear oligomer formation, offering more possibilities for the synthesis of macrocycles from symmetrical monomers in one-pot reaction.     

One‐Pot Multimolecular Macrocyclization for the Expedient Synthesis of Macrocyclic Aromatic Pentamers by a Chain Growth Mechanism

POCl₃‐mediated one‐pot macrocyclization allows the highly selective formation of five‐residue macrocycles that are rigidified by internally placed intramolecular hydrogen bonds. Mechanistic investigation by using tailored competition experiments and kinetic simulation provides a comprehensive model, supporting a chain‐growth mechanism underlying the one‐pot formation of aromatic pentamers, whereby the successive addition of a bifunctional monomer unit onto either another monomer or the growing oligomeric backbone is faster than other types of bimolecular condensations involving oligomers longer than monomers. DFT calculations at the B3LYP/6‐31G* level reveal the five‐residue pentamer to be the most stable with respect to alternative four‐, six‐, and seven‐residue macrocycles. These novel mechanistic insights may become useful in analyzing other macrocyclization, oligomerization, and ploymerization reactions.     

Enzymatic Macrocyclization of 1,2,3‐Triazole Peptide Mimetics

The macrocyclization of linear peptides is very often accompanied by significant improvements in their stability and biological activity. Many strategies are available for their chemical macrocyclization, however, enzyme‐mediated methods remain of great interest in terms of synthetic utility. To date, known macrocyclization enzymes have been shown to be active on both peptide and protein substrates. Here we show that the macrocyclization enzyme of the cyanobactin family, PatGmac, is capable of macrocyclizing substrates with one, two, or three 1,4‐substituted 1,2,3‐triazole moieties. The introduction of non‐peptidic scaffolds into macrocycles is highly desirable in tuning the activity and physical properties of peptidic macrocycles. We have isolated and fully characterized nine non‐natural triazole‐containing cyclic peptides, a further ten molecules are also synthesized. PatGmac has now been shown to be an effective and versatile tool for the ring closure by peptide bond formation.     

Synthesis of New Multibenzo Oxygen–Sulfur Donor Macrocycles Containing Lactams at Room Temperature

Some new oxygen–sulfur, multibenzo macrocyclic ligands containing amide groups have been prepared using the macrocyclization process with the reaction of 2,2′-thiobis-[4-methyl(2-aminophenoxy)phenyl ether] as a symmetrical diamine with appropriate dicarboxylicacid dichlorides in moderate yields. This macrocyclization led to the formation of di- and tetramide macrocycles. These reactions were routinely carried out at ambient temperature in CH₂Cl₂ as solvent in high dilution without template effect conditions. It is found that sulfur the atom affects the rigidity of the macrocycles and diastereotopicity of nuclei in the ring of these series of macrocyclic compounds.     

Rapid construction of shape-persistent H-bonded macrocycles via one-pot H-bonding-assisted macrocyclization

The study of macrocycles has crossed many traditional disciplines such as chemistry, physics, biology, medicine and engineering with many research areas concentrating on specific and selective molecular recognition, self-organisation and its already demonstrated and other promising applications. Compared to traditional strategies to synthesize macrocycles with widely ranging structures using such as templated cyclization or dynamic covalent bond formation, one-pot H-bonding-assisted macrocyclization has been shown to provide a simple, fast and cost-efficient method to synthesize shape-persistent H-bonded macrocycles of varying types containing an internal cavity of as large as 2.9 nm in diameter. This review will summarize the recent works on such “greener” syntheses of H-bonded macrocycles that help to create a whole new dimension of research and to offer a new bottom-up strategy for constructing functional architectures and materials.     

Multicomponent assembly of boron-based dendritic nanostructures

A new synthetic strategy for the construction of boron-based macrocycles and dendrimers is described. Condensation of aryl- and alkylboronic acids with 3,4-dihydroxypyridine is shown to give pentameric macrocycles in which five boronate esters are connected by dative B-N bonds. Three macrocycles have been characterized crystallographically. The boron atoms of these assemblies represent chiral centers, and the assembly process is highly diastereoselective. Attachment of amino or aldehyde groups in the meta position of the arylboronic acid building blocks does not interfere with macrocyclization. This allows performing multicomponent assembly reactions between functionalized boronic acids, dihydroxypyridine ligands, and amines or aldehydes, respectively. Reaction of 3,5-diformylphenylboronic acid, 3,4-dihydroxypyridine, and a primary amine R-NH2 (R=Ph, Bn) gives dendritic nanostructures having a pentameric macrocyclic core and 10 amine-derived R groups in their periphery. Combination of 3,5-diformylphenylboronic acid with 2,3-dihydroxypyridine and the dendron 3,5-(benzyloxy)benzylamine, on the other hand, results in formation of a dendrimer with a tetrameric macrocyclic core and eight dendrons in its periphery.     

CuAAC macrocyclization: high intramolecular selectivity through the use of copper-tris(triazole) ligand complexes

A range of multivalent heteroaryl ligands, copper sources, and solvent systems have been investigated for use in CuAAC-mediated macrocyclization reactions. These studies have revealed the key factors governing selectivity for macrocyclization versus dimerization and identified a simple but specific set of reaction conditions capable of efficiently generating a diverse series of drug-like macrocycles at modest dilution in up to 95% yield.