The History, Present and Future of Allergen Standardization in the United States and Europe

The topic of standardization in relation to allergen products has been discussed by allergists, regulators, and manufacturers for a long time. In contrast to synthetic medicinal products, the natural origin of allergen products makes the necessary comparability difficult to achieve. This holds true for both aspects of standardization: Batch-to-batch consistency (or product-specific standardization) and comparability among products from different manufacturers (or cross-product comparability). In this review, we focus on how the United States and the European Union have tackled the topic of allergen product standardization in the past, covering the early joint standardization efforts in the 1970s and 1980s as well as the different paths taken by the two players thereafter until today. So far, these two paths have been based on rather classical immunological methods, including the corresponding benefits like simple feasability. New technologies such as mass spectrometry present an opportunity to redefine the field of allergen standardization in the future.

Biological Significance of Imidazole-based Analogues in New Drug Development

In the field of heterocyclic medicinal chemistry, especially five-membered ring structures containing a nitrogen atom, imidazole core is an imperative aromatic heterocycle which is usually present in naturally occurring products and synthetic bioactive molecules. The occurrence of imidazole moiety in therapeutic compounds may be beneficial in terms of improving water-soluble properties due to its two nitrogen atoms which leads to the creation of hydrogen bonds. The imidazole nucleus has also been recognized as an important isostere of triazole, pyrazole, thiazole, tetrazole, oxazole, amide etc. for the purpose of designing and development of various biologically active molecules. Moreover, imidazole core as an attractive binding site could interact with diverse cations and anions as well as biomolecules through different reactions in the human biological system thus displaying extensive biological activities. This effort thoroughly provides a wide-ranging assessment in current drug discovery and developments of imidazolebased analogues in the entire series of synthetic medicinal chemistry as antibacterial and antifungal, anticancer, anti-tubercular, analgesic and anti-inflammatory, anti-neuropathic, antihypertensive, anti-allergic, anti-parasitic, antiviral, antidepressant, anti-obesity and so on, altogether with their prospective approaches in diagnostic and pathological field. It is expected that the present review will be supportive on behalf of new opinions in the search for rational strategies of more efficacious and less toxic medicinal agents and drugs containing imidazole core.

Significance of 1,3,4-Oxadiazole Containing Compounds in New Drug Development

Background: Oxadiazole core displays various pharmacological properties among five membered nitrogen heterocyclic compounds specially 1,3,4-oxadiazole containing molecules have occupied a particular place in the field of synthetic medicinal chemistry as surrogates (bioisosteres) of carboxylic acids, carboxamides and esters. Moreover, they are having widespread kind of applications in numerous zones as polymers, as luminescence producing materials and as electron-transporting materials and corrosion inhibitors. Methods: This write up contains comprehensive and extensive literature survey on chemical reactivity and biological properties associated with 1,3,4-oxadiazole containing compounds. Results: This review summarises 1,3,4-oxadiazole moiety in numerous compounds with reported pharmacological activity such as antiviral, analgesic and anti-inflammatory, antitumor, antioxidant, insecticidal and anti-parasitic etc. Nevertheless, ring opening reactions of the 1,3,4-oxadiazole core have also made great attention, as they produce new analogues containing aliphatic nitrogen atom and to other ring system. Conclusion: In relation to occurrence of oxadiazoles in biologically active molecules, 1,3,4-oxadiazole core emerges as an structural subunit of countless significance and usefulness for the development of new drug aspirants applicable to the treatment of many diseases. It concludes that 1,3,4-oxadiazole core compounds are more efficacious and less toxic medicinal agents with respect to new opinions in the search for rational strategies.

Application-Oriented Marine Isomerases in Biocatalysis

The class EC 5.xx, a group of enzymes that interconvert optical, geometric, or positional isomers are interesting biocatalysts for the synthesis of pharmaceuticals and pharmaceutical intermediates. This class, named “isomerases,” can transform cheap biomolecules into expensive isomers with suitable stereochemistry useful in synthetic medicinal chemistry, and interesting cases of production of l-ribose, d-psicose, lactulose, and d-phenylalanine are known. However, in two published reports about potential biocatalysts of marine origin, isomerases are hardly mentioned. Therefore, it is of interest to deepen the knowledge of these biocatalysts from the marine environment with this specialized in-depth analysis conducted using a literature search without time limit constraints. In this review, the focus is dedicated mainly to example applications in biocatalysis that are not numerous confirming the general view previously reported. However, from this overall literature analysis, curiosity-driven scientific interest for marine isomerases seems to have been long-standing. However, the major fields in which application examples are framed are placed at the cutting edge of current biotechnological development. Since these enzymes can offer properties of industrial interest, this will act as a promoter for future studies of marine-originating isomerases in applied biocatalysis.

An Electroreductive Approach to Silyl Radical Chemistry via Strong Si–Cl Bond Activation

The construction of C(sp³)–Si bonds is important in synthetic, medicinal, and materials chemistry. In this context, reactions mediated by silyl radicals have become increasingly attractive but methods for accessing these intermediates remain limited. We present a new strategy for silyl radical generation via electroreduction of readily available chlorosilanes. At highly biased potentials, electrochemistry grants access to silyl radicals through energetically uphill reductive cleavage of strong Si–Cl bonds. This strategy proved to be general in various alkene silylation reactions including disilylation, hydrosilylation, and allylic silylation under simple and transition-metal-free conditions.

An Electroreductive Approach to Silyl Radical Chemistry via Strong Si–Cl Bond Activation

The construction of C(sp³)–Si bonds is important in synthetic, medicinal, and materials chemistry. In this context, reactions mediated by silyl radicals have become increasingly attractive but methods for accessing these intermediates remain limited. We present a new strategy for silyl radical generation via electroreduction of readily available chlorosilanes. At highly biased potentials, electrochemistry grants access to silyl radicals through energetically uphill reductive cleavage of strong Si–Cl bonds. This strategy proved to be general in various alkene silylation reactions including disilylation, hydrosilylation, and allylic silylation under simple and transition-metal-free conditions.

An Electroreductive Approach to Silyl Radical Chemistry via Strong Si–Cl Bond Activation

The construction of C(sp³)–Si bonds is important in synthetic, medicinal, and materials chemistry. In this context, reactions mediated by silyl radicals have become increasingly attractive but methods for accessing these intermediates remain limited. We present a new strategy for silyl radical generation via electroreduction of readily available chlorosilanes. At highly biased potentials, electrochemistry grants access to silyl radicals through energetically uphill reductive cleavage of strong Si–Cl bonds. This strategy proved to be general in various alkene silylation reactions including disilylation, hydrosilylation, and allylic silylation under simple and transition-metal-free conditions.

An Electroreductive Approach to Silyl Radical Chemistry via Strong Si–Cl Bond Activation

The construction of C(sp³)–Si bonds is important in synthetic, medicinal, and materials chemistry. In this context, reactions mediated by silyl radicals have become increasingly attractive but methods for accessing these intermediates remain limited. We present a new strategy for silyl radical generation via electroreduction of readily available chlorosilanes. At highly biased potentials, electrochemistry grants access to silyl radicals through energetically uphill reductive cleavage of strong Si–Cl bonds. This strategy proved to be general in various alkene silylation reactions including disilylation, hydrosilylation, and allylic silylation under simple and transition-metal-free conditions.