氮杂冠醚化双Schiff碱配合物催化羧酸酯水解的研究

将4种氮杂冠醚取代的双Schiff碱钴(H)、锰(m)配合物作为仿水解酶模型催化羧酸酯(PNPP)水解.考察了Schiff碱配合物中氮杂冠醚取代的位置、氮杂冠醚的数目对其仿水解酶性能的影响;探讨了Schiff配合物催化PNPP水解的动力学和机理;提出了配合物催化PNPP水解的动力学模型.结果表明,在25℃条件下随着缓冲溶液pH值的增大,配合物催化PNPP水解速率提高;四种氮杂冠醚取代的双Schiff碱配合物在催化PNPP水解反应中表现出良好的催化活性;氮杂冠醚3-取代的Schiff碱配合物CoL2的催化活性高于5-取代的Schiff碱配合物CoL1,含有2个氮杂冠醚的配合物CoL3的催化活性高于含有1个氮杂冠醚的配合物CoL2.     

氮杂冠醚化单Schiff碱锰(III)配合物催化PNPP水解研究

将4种氮杂冠醚或吗啉取代的单Schiff碱锰(III)配合物作为仿水解酶模型催化α-吡啶甲酸对硝基苯酯(PNPP)水解。考察了单Schiff碱配体中取代基类型、氮杂冠醚取代的位置对其仿水解酶性能的影响;探讨了Schiff配合物催化PNPP水解的动力学和机理;提出了配合物催化PNPP水解的动力学模型。结果表明,在25℃条件下随着缓冲溶液pH值的增大,配合物催化PNPP水解速率提高,氮杂冠醚化单Schiff碱锰(III)配合物在催化PNPP水解反应中表现出良好的催化活性,Schiff碱配体结构显著影响配合物催化活性。     

不对称Salen-Mn(Ⅲ)配合物催化PNPP水解的动力学研究

用分光光度法研究了两种不对称Salen-Mn(Ⅲ)配合物催化α-吡啶甲酸对硝基苯酚酯(PNPP)的水解动力学.提出了相应的PNPP催化水解机理,讨论了底物浓度、体系的酸碱度、温度以及配合物结构对PNPP催化水解反应的影响.结果表明:此两种Schiff碱锰(Ⅲ)配合物在催化PNPP水解中均表现出较好的催化活性,PNPP水解速率随着底物浓度、体系pH值的增大而增大;在15～55℃温度范围内,未观察到催化剂失活现象;其中,带有苯并氮杂-15-冠-5侧基的不对称Salen-Mn(Ⅲ)配合物比带有吗啉基的另一配合物拥有更高的催化活性,这可能主要由这两种模拟水解酶之间较大的疏水微环境差异所引起.     

聚醚桥连二异羟肟酸双核配合物催化PNPP水解的反应动力学

 合成了4种聚醚桥连二异羟肟酸双核配合物,并将其用于催化α-吡啶甲酸对硝基苯酯(PNPP)水解反应,研究了聚醚桥连二异羟肟酸双核配合物催化PNPP水解反应的动力学和机理,提出了配合物催化PNPP水解的动力学模型. 结果表明, 在25 ℃条件下,随着缓冲溶液pH值的增大, 聚醚桥连二异羟肟酸双核配合物催化PNPP水解速率逐渐提高,表现出很高的催化活性. 根据阿累尼乌斯公式和不同温度下的表观一级常数,求出了水解反应的表观活化能.     

Schiff碱钴(Ⅱ)配合物催化PNPP水解研究

摘要：两种分别带吗啉侧基和氮杂冠醚侧基的Schiff碱钴(Ⅱ)配合物CoL¹ 和CoL²，作为模拟水解金属酶，用于羧酸酯（PNPP）的催化水解。通过对水解反应体系的特性吸收光谱的分析，表明在PNPP催化水解的反应过程中形成了由PNPP和Co(Ⅱ)配合物组成的关键中间体。在分析特性吸收光谱的基础上提出了PNPP的催化水解的机理，由此机理上建立了PNPP催化水解的动力学数学模型。在本文中讨论缓冲溶液酸度、配合物结构以及反应温度对配合物催化PNPP水解速率的影响。     

杂氮冠醚化Schiff碱钴(Ⅱ)配合物模拟磷酸二酯水解酶的研究

含杂氮冠醚的Schiff碱过渡金属配合物作为模拟水解酶被用于催化BNPP水解，讨论了两种杂氮冠醚化单Schiff碱钴(Ⅱ)配合物催化BNPP水解的动力学和机理，分析了反应体系的特征光谱变化。提出了配合物催化BNPP水解的动力学数学模型，结果表明，在反应过程中形成中间物种的假设是合理的；随着缓冲溶液pH的增大，两种配合物催化BNPP水解速率提高；两种配合物在催化BNPP水解中表现出好的催化活性。     

氮杂冠醚取代非对称双Schiff碱配合物催化氧化对二甲苯研究

将一系列苯并-10-氮杂-15-冠-5或吗啉基取代的不对称双Schiff碱配合物作为催化剂,在常压和120℃条件下用于催化氧化对二甲苯研究。探讨了Schiff配合物中心金属离子、Schiff碱配体中挂接的氮杂冠醚环、配体芳环上取代基等对催化氧化对二甲苯反应活性及其氧化产物选择性的影响。实验结果表明:配合物中氮杂冠醚的存在能显著缩短反应诱导期、提高催化活性和选择性;Schiff碱Mn(Ⅲ)配合物比Schiff碱Co(Ⅱ)和Schiff碱Cu(Ⅱ)具有更高的催化活性;氮杂冠醚Schiff碱Mn(Ⅲ)配合物催化氧化二甲苯的转化率和产物选择性分别达75%和90%。     

氮杂冠醚取代基对schiff碱锰(Ⅲ) 配合物催化苯乙烯环氧化反应的影响

合成并表征了苯并-10-氮杂-15-冠-5或吗啉基取代的单和双Schiff碱锰（Ⅲ）配合物MnL2^1Cl,MnL2^2Cl,Mnl^3Cl和MnL^4Cl．研究了它们作为仿P450模型化合物催化苯乙烯环氧化反应的性能,并考察了催化反应的动力学．结果表明,氮杂冠醚取代的Schifft碱锰（Ⅲ）配合物优于相应的吗啉基取代的Schiff碱锰（Ⅲ）配合物,且反应遵从Michaelis—Menten规律．这是由于具有特殊功能和空间构型的氮杂冠醚大环的引入。改善了催化中心周围的微环境,从而显著地提高了Schiff碱锰（Ⅲ）配合物的催化活性．     

氮杂冠醚取代单Schiff碱过渡金属配合物催化氧化对二甲苯研究

本文将苯并-10-氮杂-15-冠-5或吗啉基取代的单Schiff碱过渡配合物作为催化剂,在常压和120℃条件下,以空气为氧源,研究了对二甲苯催化氧化反应。实验探讨了Schiff碱配合物中心金属离子、Schiff碱配体中挂接的氮杂冠醚环、配体芳环上取代基和反应时间等对对二甲苯催化氧化反应的影响。实验结果表明:Schiff碱配合物中氮杂冠醚的存在能显著缩短反应诱导期,提高催化反应活性和产物选择性;Schiff碱Mn(III)配合物比Schiff碱Co(II)具有更高的催化反应活性;氮杂冠醚Schiff碱Mn(III)配合物对于二甲苯的催化氧化反应转化率大于60%,对甲苯甲酸产物的选择性均高于70%。     

大环钴(Ⅱ)配合物模拟水解酶催化羧酸酯水解的比较研究

在Brij35胶束溶液中,比较研究了四氮大环席夫碱(5,7,7,12,14,14-六甲基-1,4,8,11-四氮杂十四环-二烯,L)的钴(Ⅱ)配合物1催化对硝基苯酚吡啶甲酸酯(PNPP)及对硝基苯酚乙酸酯(PNPA)水解的动力学.结果表明:配合物1对PNPP及PNPA的催化作用具有酸碱催化的特征,催化活性物种为与金属离子结合的氢氧根离子CoL-OH-;配合物1催化PNPP水解的速度远远大于其催化PNPA水解的速度,在pH 7.40、30℃时,表观二级速率常数kc分别为0.997mol-1@L@s-1和1.12×10-3mol-1@L@s-1,这种反应速率的差异可归因于反应机理的不同;Brij35胶束对PNPP及PNPA的水解均有抑制作用.     

p‐Nitrophenyl Picolinate Cleavage by Unsymmetrical Bis‐Schiff Base Manganese(III) and Cobalt(II) Complexes with Aza‐Crown Ether or Morpholino Pendants

The unsymmetrical bis‐Schiff base manganese(III) and cobalt(II) complexes with either benzo‐10‐aza‐crown ether pendants (MnL¹Cl, MnL²Cl) or morpholino pendant (MnL³Cl, CoL³) have been employed as models for hydrolase by studying the kinetics of their hydrolysis reactions with p‐nitrophenyl picolinate (PNPP). A kinetic model of PNPP cleavage catalyzed by these complexes is proposed. The effects of complex structures and reaction temperature on the rate of PNPP hydrolysis have been examined. All four complexes exhibit high catalytic activity and the rate increases with pH under 25°C. The complexes of ligands containing a crown ether group exhibit higher catalytic activities than the non‐crown analogues. The catalytic activity of the complexes follows the order Mn(III)>Co(II) under the same ligands.     

Studies on the Kinetics and Mechanism of Hydrolysis of p-nitrophenyl Picolinate (PNPP) by Unsymmetrical bis-Schiff Base Complexes with Aza-crown Ether or Morpholino Pendants

Two novel unsymmetrical bis-Schiff base manganese(III) and cobalt(II) complexes with benzo-10-aza-crown ether pendants (MnL¹Cl, CoL¹), and their analogoues with morpholino pendants (MnL²Cl, CoL²), have been synthesized and employed as models to mimic hydrolase in p-nitrophenyl picolinate (PNPP). The kinetics and the mechanism of PNPP hydrolysis catalyzed by these complexes were investigated. A kinetic mathematical model of PNPP cleavage catalyzed by these complexes was proposed. The effects of the complexes structure and reactive temperature on the rate of catalytic PNPP hydrolysis have been also examined. The results showed that the rate for the catalytic PNPP hydrolysis increased following the increase in pH of the buffer solution; four complexes exhibited high activity in the catalytic PNPP hydrolysis. Compared with the crown-free analogoues MnL²Cl and CoL², the crowned Schiff base complexes (MnL¹Cl, CoL¹) exhibit a higher catalytic activity; the pseudo-first-order-rate (k_obs) for the PNPP hydrolysis catalyzed by the complex MnL¹Cl containing benzo-10-aza-crown ether is 1.04 × 10³ that of spontaneous hydrolysis of PNPP at pH = 7.00, [S] = 2.0×10⁻⁴ mol dm⁻³.     

Studies on <Emphasis Type="Italic">p</Emphasis>-nitrophenyl picolinate cleavage by mono-Schiff base complexes with aza-crown ether or morpholino pendants

Abstract  Mono-Schiff base manganese(III) and cobalt(II) complexes with either benzo-10-aza-crown ether pendants (MnL¹ ₂ Cl, CoL¹ ₂) or morpholino pendants (MnL² ₂Cl, CoL² ₂) have been employed as models for hydrolase enzymes by studying the kinetics of their hydrolysis reactions with p-nitrophenyl picolinate (PNPP). A kinetic model of PNPP cleavage catalyzed by these complexes is proposed. The effects of complex structures and reaction temperature on the rate of catalytic PNPP hydrolysis have been also examined. The rate increases with pH of the buffer solution; all four complexes exhibited high activity in the catalytic PNPP hydrolysis. Compared with the crown-free analogues MnL² ₂Cl and CoL² ₂, the crowned Schiff base complexes (MnL¹ ₂Cl, CoL¹ ₂) exhibit higher catalytic activity. The pseudo-first-order-rate ( k _obs ) for the PNPP hydrolysis catalyzed by the complex MnL¹ ₂Cl containing benzo-10-aza-crown ether is 1.06 × 10³ times that of spontaneous hydrolysis of PNPP at pH = 7.00, 25 °C, [S] = 2.0 × 10⁻⁴ mol dm⁻³. Graphical Abstract   Studies on p-nitrophenyl picolinate cleavage by mono-Schiff base complexes with aza-crown ether or morpholino pendants Jian-zhang Li*, Fa-mei Feng, Bin Xu,Wei-dong Jiang Key Laboratory of Green and Technology, Department of Chemistry, Sichuan University of Science & Engineering, Zigong, Sichuan, 643000, P.R. China Sheng-ying Qin Department of Chemistry, Sichuan University, Chengdu, Sichuan, 610064, P.R. China Mono-Schiff base manganese(III) and cobalt(II) complexes with either benzo-10-aza-crown ether pendants (MnL¹ ₂Cl, CoL¹ ₂) or morpholino pendants (MnL² ₂Cl, CoL² ₂) have been employed as models for hydrolase enzymes by studying the kinetics of their hydrolysis reactions with PNPP. A kinetic model of PNPP cleavage catalyzed by these complexes is proposed. Compared with the crown-free analogy MnL² ₂Cl and CoL² ₂, the crowned Schiff base complexes (MnL¹ ₂Cl, CoL¹ ₂) exhibit higher catalytic activity.      

Reactivity of Schiff Base Manganese(III) Complexes with Different Pendants toward the Hydrolysis of p‐Nitrophenyl Picolinate

This paper describes the catalytic performance of two manganese(III) complexes with mono‐Schiff base ligands as artificial hydrolases towards the hydrolysis of p‐nitrophenyl picolinate (PNPP). Observations reveal that the one complex (MnL₂²Cl) containing morpholine pendants exhibits 1.2–1.7 fold kinetic advantage over the other one (MnL₂¹Cl) containing benzoaza‐15‐crown‐5 group. Especially, optimum molecule structures using a Gaussian 03 software confirm that MnL₂²Cl indeed possesses a relatively open linked site for the approaching of PNPP, resulting in higher efficiency due to a convenient association between substrate (PNPP) and MnL₂²Cl. In addition, the steric hindrance of two pendants, i.e., benzoaza‐15‐crown‐5 and morpholine, may be a main influencing factor for tuning catalytic activities of the synthesized Mn(III) catalysts. Both Mn(III) catalysts used here were found to have fine tolerance to the operated temperature and pH. Related kinetic and thermodynamic analyses were also given to demonstrate their structure‐activity relationships (SAR) of both catalysts used.     

Cobalt(II) Schiff Base Complexes Bearing Aza Crown Ether Pendants as Synthetic Hydrolase Catalyzing PNPP Hydrolysis

Two Co^II complexes with aza crown ether substituted salicylaldimine Schiff base, CoL¹ ₂ and CoL² ₂, have been synthesized and employed as models to mimic hydrolase in catalytic hydrolysis of a carboxylic ester. The specific change of u.v.–vis. absorption spectra of the hydrolytic reactive systems has been observed, which indicates that key intermediates are formed by PNPP and Co^II complexes. The kinetics and the mechanism of PNPP hydrolysis have been investigated. The kinetic mathematical model for PNPP cleavage catalyzed by the Co^II complexes has been proposed. The results show that, compared with the crown-free analogous CoL³ ₂, the bis(aza crown ether)s Co^II complexes CoL¹ ₂ and CoL² ₂ exhibit high activity in the PNPP catalytic hydrolysis; the rate of the PNPP hydrolysis catalyzed by the complexes increases with the increase of pH of the buffer solution; the pseudo-first-order rate constants (k _ob) of PNPP hydrolysis catalyzed by the complexes is 1000 times more than that of spontaneous hydrolysis of PNPP.     

Studies on PNPP Hydrolysis Catalyzed by Schiff Base Cobalt（Ⅱ） Complexes

Two cobalt（Ⅱ） complexes of the Schiff base with morpholino or aza-crown ether pendants, CoL^1 and CoL^2, as mimic hydrolytic metalloenzyme, were used in catalytic hydrolysis of carboxylic ester （PNPP）. The analysis of specific absorption spectra of the hydrolytic reaction systems indicates that key intermediates, made up of PNPP and Co（Ⅱ） complexes, have been formed in reaction processes of the PNPP catalytic hydrolysis. The mechanism of PNPP catalytic hydrolysis has been proposed based on the analytic result of specific absorption spectrum. A kinetic mathematical model, applied to the calculation of the kinetic parameter of PNPP catalytic hydrolysis, has been established based on the mechanism proposed. The acid effect of buffer solution, structural effect of the complexes, and effect of temperature on the rate of PNPP hydrolysis catalyzed by the complexes have been also discussed.     

Cobalt（Ⅱ） Salen Complex with Two Aza-crown Pendants and Its Analogues as Synthetic Oxygen Carriers

Salen with two aza‐crown ether pendants H₂L¹ and its analogues H₂L^2‐H₂L⁴ were successfully synthesized starting from benzo‐10‐aza‐15crown‐5 (BN15C5) or morpholine. Their structures were characterized by IR, MS, ¹H NMR and elemental analysis, and were confirmed by X‐ray diffraction analysis of H₂L¹. Moreover, the saturated oxygen uptake of their cobalt(II) complexes CoL^1‐CoL⁴ in diethyleneglycol dimethyl ether was determined at different temperature. The oxygenation contants (K_O2 ) and thermodynamic parameters (ΔH° and ΔS°) were calculated. The modulation of O₂‐binding capabilities by pendant substituents were investigated as compared with the parent Schiff base complex CoL⁵ (CoSalen). The results indicate that the dioxygen affinities of CoL have been much more enhanced by aza‐crown pendants than that by morpholino pendants, and the O₂‐binding capabilities of CoL¹ and CoL² with aza‐crown pendants would also be enhanced by adding alkali metal cations.     

PNPP Hydrolysis Catalyzed by Manganese(III) Complexes with Crowned Salicylaldimine Schiff Base Ligand

Four manganese(III) complexes (MnL¹Cl, MnL²Cl, MnL⁴₂Cl, MnL⁵₂Cl) with a crowned salicylaldimine Schiff base ligand have been synthesized and employed as models to mimic hydrolase in the hydrolysis of p-nitrophenyl picolinate (PNPP). The kinetics and mechanism of catalytic PNPP hydrolysis have been investigated. The kinetic mathematical model of PNPP cleavage catalyzed by these complexes has been proposed. The effects of the ligand structure and crown ether ring in complexes, and the reactive temperature on the rate of catalytic PNPP hydrolysis have been also examined. The results show that compared with the crown-free analogous MnL³Cl and MnL⁶₂Cl, the crowned Schiff base manganese(III) complexes, MnL¹Cl, MnL²Cl, MnL⁴₂Cl and MnL⁵₂Cl, exhibit more high catalytic activity, which follow the order: MnL¹Cl >MnL²Cl >MnL⁴₂Cl >MnL⁵₂Cl >MnL³Cl >MnL⁶₂Cl; the pseudo-first-order-rate (k_obs) for the PNPP hydrolysis catalyzed by the complex MnL¹Cl containing three crown ether rings is highest among six complexes and is 1.81 times that of MnL³Cl, 1.49 × 10³ times that of spontaneous hydrolysis of PNPP, respectively, at pH = 7.00, [S] = 2.0 × 10⁻⁴ mol dm⁻³.     

PNPP Cleavage Catalyzed by Schiff Base Mn(III) Complexes Containing Polyether Side Chains in CTAB Micellar Solutions

Two Schiff base Mn(III) complexes containing polyether side chain were synthesized and characterized. The catalytic hydrolysis of p‐nitrophenyl picolinate (PNPP) by the two complexes in the buffered CTAB micellar solution in the pH range of 6.60–8.20 was investigated kinetically in this study. The influences of acidity, temperature, and structure of complex on the catalytic cleavage of PNPP were also studied. The mechanism of PNPP hydrolysis catalyzed by Schiff base manganese(III) complexes in CTAB micellar solution was proposed. The relative kinetic and thermodynamic parameters were determined. Comparied with the pseudo‐first‐order rate constant (k ₀) of PNPP spontaneous hydrolysis in water, the pseudo‐first‐order rate constants (k _obsd) of PNPP catalytic hydrolysis are 1.93×10³ fold for MnL¹ ₂Cl and 1.06×10³ fold for MnL² ₂Cl in CTAB micellar solution at pH=7.00, T=25°C, and [S]=2.0×10^?4mol · dm^?3, respectively. Furthermore, comparing the k _obsd of PNPP catalytic hydrolysis by metallomicelles with that of PNPP hydrolysis catalyzed only by metal complexes or CTAB micelle at the above‐mentioned condition, metallomicelles of MnL₂(L=L¹, L²) Cl/CTAB exhibit notable catalytic activities for promoting PNPP hydrolysis, and MnL¹ ₂Cl/CTAB system is superior in promoting cleavage of PNPP relative to MnL² ₂Cl/CTAB system under the same experimental conditions. The results indicate that the rate of PNPP catalytic cleavage is influenced by the structures of the two complexes, the acidity of reaction systems, and the solubilization of PNPP in CTAB micelles.     

Studies on p-Nitrophenyl Picolinate Cleavage by Unsymmetrical Bis-Schiff Base Manganese(III) and Cobalt(II) Complexes in CTAB Surfactant Micellar Solution

The unsymmetrical bis-Schiff base manganese(III) and cobalt(II) complexes with either benzo-10-aza-crown ether pendants (MnL¹Cl, MnL²Cl) or morpholino pendant (MnL³Cl, CoL³) have been employed as models for hydrolase by studying the kinetics of their hydrolysis reactions with p-nitrophenyl picolinate (PNPP) in the buffered CTAB micellar solution. A kinetic model of PNPP cleavage catalyzed by these complexes is proposed. The effects of complex structures and reaction temperature on the rate of PNPP hydrolysis have been examined. All four complexes exhibit higher catalytic activity in the buffered CTAB micellar solution and the rate increases with pH of the buffered CTAB micellar solution under 25°C. The complexes containing a crown ether group exhibit higher catalytic activities than the free-crown analogues. The catalytic activity of manganese(III) complex is superiority over cobalt(II) complex in catalyzing hydrolysis of PNPP under the same ligand.