抗原变异可使得多种致病微生物易于逃避宿主免疫应答。表达在感染红细胞表面的恶性疟原虫红细胞表面蛋白1（PfPMP1）与感染红细胞、内皮细胞、树突状细胞以及胎盘的单个或多个受体作用，在黏附及免疫逃避中起关键的作用。每个单倍体基因组var基因家族编码约60种成员，通过启动转录不同的var基因变异体为抗原变异提供了分子基础。

疟原虫var基因转换速率变化导致抗原变异[英]／Paul H, Robert P, Christodoulou Z, et al//Proc Natl Acad Sci U S A

Iron Catalysis in Organic Synthesis

Flow chemistry involves the use of channels or tubing to conduct a reaction in a continuous stream rather than in a flask Flow equipment provides chemists with unique control over reaction parameters enhancing reactivity or in some cases enabling new reactions This relatively young technology has received a remarkable amount of attention in the past decade with many reports on what can be done in flow Until recently, however, the question, “Should we do this in flow?” has merely been an afterthought This review introduces readers to the basic principles and fundamentals of flow chemistry and critically discusses recent flow chemistry accounts

The Hitchhiker's Guide to Flow Chemistry

In the past few years, continuous-flow reactors with channel dimensions in the micro- or millimeter region have found widespread application in organic synthesis. The characteristic properties of these reactors are their exceptionally fast heat and mass transfer. In microstructured devices of this type, virtually instantaneous mixing can be achieved for all but the fastest reactions. Similarly, the accumulation of heat, formation of hot spots, and dangers of thermal runaways can be prevented. As a result of the small reactor volumes, the overall safety of the process is significantly improved, even when harsh reaction conditions are used. Thus, microreactor technology offers a unique way to perform ultrafast, exothermic reactions, and allows the execution of reactions which proceed via highly unstable or even explosive intermediates. This Review discusses recent literature examples of continuous-flow organic synthesis where hazardous reactions or extreme process windows have been employed, with a focus on applications of relevance to the preparation of pharmaceuticals.

Continuous‐Flow Technology—A Tool for the Safe Manufacturing of Active Pharmaceutical Ingredients

Continuous-flow photochemistry in microreactors receives a lot of attention from researchers in academia and industry as this technology provides reduced reaction times, higher selectivities, straightforward scalability, and the possibility to safely use hazardous intermediates and gaseous reactants. In this review, an up-to-date overview is given of photochemical transformations in continuous-flow reactors, including applications in organic synthesis, material science, and water treatment. In addition, the advantages of continuous-flow photochemistry are pointed out and a thorough comparison with batch processing is presented.

Applications of Continuous-Flow Photochemistry in Organic Synthesis, Material Science, and Water Treatment

Colloidal inorganic nanocrystals stand out as an important class of advanced nanomaterials owing to the flexibility with which their physical-chemical properties can be controlled through size, shape, and compositional engineering in the synthesis stage and the versatility with which they can be implemented into technological applications in fields as diverse as optoelectronics, energy conversion/production, catalysis, and biomedicine. The use of microwave irradiation as a non-classical energy source has become increasingly popular in the preparation of nanocrystals (which generally involves complex and time-consuming processing of molecular precursors in the presence of solvents, ligands and/or surfactants at elevated temperatures). Similar to its now widespread use in organic chemistry, the efficiency of "microwave flash heating" in dramatically reducing overall processing times is one of the main advantages associated with this technique. This Review illustrates microwave-assisted methods that have been developed to synthesize colloidal inorganic nanocrystals and critically evaluates the specific roles that microwave irradiation may play in the formation of these nanomaterials.

Microwave-assisted synthesis of colloidal inorganic nanocrystals.

Silica Sulfuric Acid and Silica Chloride as Efficient Reagents for Organic Reactions

A few-component network of biologically relevant, organic reactions displays bistability and oscillations, without an enzymatic catalyst. Dissipative chemical reaction networks are systems that operate away from equilibrium and exhibit features such as continuous regeneration of components and autonomous regulation. The biological cell is one such out-of-equilibrium chemical network. Until now it has not been possible to recreate this type of dynamic behavior using simple organic molecules relevant to prebiotic Earth. Now, George Whitesides and colleagues demonstrate a few-component system of interacting organic species that, combined into a reaction network, displays autocatalytic and oscillatory features. All of the organic components are relatively simple and do not require enzymatic catalysis to react. Networks of organic chemical reactions are important in life and probably played a central part in its origin1,2,3. Network dynamics regulate cell division4,5,6, circadian rhythms7, nerve impulses8 and chemotaxis9, and guide the development of organisms10. Although out-of-equilibrium networks of chemical reactions have the potential to display emergent network dynamics11 such as spontaneous pattern formation, bistability and periodic oscillations12,13,14, the principles that enable networks of organic reactions to develop complex behaviours are incompletely understood. Here we describe a network of biologically relevant organic reactions (amide formation, thiolate–thioester exchange, thiolate–disulfide interchange and conjugate addition) that displays bistability and oscillations in the concentrations of organic thiols and amides. Oscillations arise from the interaction between three subcomponents of the network: an autocatalytic cycle that generates thiols and amides from thioesters and dialkyl disulfides; a trigger that controls autocatalytic growth; and inhibitory processes that remove activating thiol species that are produced during the autocatalytic cycle. In contrast to previous studies that have demonstrated oscillations and bistability using highly evolved biomolecules (enzymes15 and DNA16,17) or inorganic molecules of questionable biochemical relevance (for example, those used in Belousov–Zhabotinskii-type reactions)18,19, the organic molecules we use are relevant to metabolism and similar to those that might have existed on the early Earth. By using small organic molecules to build a network of organic reactions with autocatalytic, bistable and oscillatory behaviour, we identify principles that explain the ways in which dynamic networks relevant to life could have developed. Modifications of this network will clarify the influence of molecular structure on the dynamics of reaction networks, and may enable the design of biomimetic networks and of synthetic self-regulating and evolving chemical systems.

/pdf/autocatalytic-bistable-oscillatory-networks-of-biologically-1jopjfxbpy.pdf

Autocatalytic, bistable, oscillatory networks of biologically relevant organic reactions

Efficient synthesis of mono- and disubstituted 2,3-dihydroquinazolin-4(1H)-ones using KAl(SO4)2·12H2O as a reusable catalyst in water and ethanol

Functionalized anilines are industrially important intermediates in the preparation of pharmaceuticals, agrochemicals, dyes, and pigments. The most commonly used method for the synthesis of anilines is the reduction of aromatic nitro compounds. [1] While traditional non-catalytic reduction processes (that is using Fe/HCl) generate large amounts of undesirable waste; catalytic hydrogenation using heterogeneous transition-metal catalysts is a well-established technique and often the method of choice for the reduction of nitroarenes to anilines. [2, 3] However, selectivity problems in the presence of other common functional groups can occur, [4] often requiring the use of carefully selected and expensive precious metal catalysts (for example, Pd, Pt, or Ru). [3] Therefore, significant efforts have been made to develop more efficient and sustainable methods to achieve the selective reduction of nitroarenes to anilines. Apart from the use of hydrogen, several other stoichiometric reducing agents such as ammonium salts, [5] silanes, [6] boranes, [7] sodium borohydride, [8] formic acid, [9] and hydrazine, [10] have been used in combination with a number of different metal catalysts. [5–10] Hydrazine, specifically the less hazardous hydrazine hydrate (N2H4·H2O), is a particularly good reagent because it generates only N2 as a side product and is comparatively safe to handle. In the past few years, interest in the use of iron-based catalysts in organic synthesis has increased dramatically. [11] Iron is an abundant, eco-friendly, relatively nontoxic, and inexpensive element, and thus the development of catalysts based on this metal is highly desirable. Several Fe-catalyzed procedures for the hydrazine-mediated reduction of nitroarenes have been reported. [10a–g] In the general context of

Mostafa Baghbanzadeh

Papers

Microwave-assisted synthesis of colloidal inorganic nanocrystals.

Silica Sulfuric Acid and Silica Chloride as Efficient Reagents for Organic Reactions

Autocatalytic, bistable, oscillatory networks of biologically relevant organic reactions

Efficient synthesis of mono- and disubstituted 2,3-dihydroquinazolin-4(1H)-ones using KAl(SO4)2·12H2O as a reusable catalyst in water and ethanol

In Situ Generated Iron Oxide Nanocrystals as Efficient and Selective Catalysts for the Reduction of Nitroarenes using a Continuous Flow Method