Catalytic Methods for the Production of Sugar Esters

Nowadays, Sugar esters (SEs) have become the focus of researchers due to their biocompatibility and extensive industrial applications as surfactants. This trend provides new methods and opportunities for the development of green synthetic chemistry. Taking the above into consideration, a critical review presented in this work emphasized the efficiency of catalyzing the synthesis of SEs with minimal hazardous by-products. These catalytic media have been employed with various impacts involving chemical, biological, and other catalytic materials. Chemical methods have been reported to show limitations in terms of preparation and bio-compatibility. To solve these shortcomings, therefore, other technologies have been adopted; ionic liquids (eutectic solvents), chemo-enzymatic systems and chemo-enzymatic systems on a catalytic surface. The use of chemo-enzymatic systems on catalytic surfaces has proved to be suitable in solving biocompatibility and stability problems and correspondingly increasing the yield of esters formed. Therefore, finding an improved catalytic surface, and the sustainable optimal reaction conditions for enzymes will be vital to improving sugar ester conversion. This study highlights the different catalytic advances employed in the esterification of SEs.

Significance of Green Synthetic Chemistry from a Pharmaceutical Perspective

Background: Conventional practices of synthesis, manufacturing, and processing have led to severe adverse consequences for living beings and the environment. Objectives: Although medications cannot be replaced, the methods of synthesizing, manufacturing, and processing them can be changed and/or replaced. This paper explains the significance of green chemistry practices in the pharmaceutical industry. It emphasizes that we must replace conventional drug synthesis, processing, and manufacturing techniques with greener ones that are cost-effective, sustainable, environment-friendly, and profitable. Discussion: This paper comprises five sections. Section 1 is an introduction to green chemistry and its correlation with the pharmaceutical industry. Section 2 discusses the metrics necessary to measure the greenness of a process. Section 3 is about solvents used in the pharmaceutical industry, hazards, safety status, and environmental effects, including the ozone depletion potential. Section 4 explains catalytic amidation reactions because amides are one of the most commonly occurring functional groups with pharmacological activity. Section 5 discusses successful cases of converting conventional synthesis of active pharmaceutical ingredients and/or their intermediates to greener, sustainable alternatives. Conclusion: A balance is necessary between profits, processes, consumers, and the environment to ensure the survival of all stakeholders and decrease the environmental burden of pharmaceuticals. Incentives such as green chemistry awards should be endorsed and encouraged, in addition to making green chemistry part of tertiary education. In addition, changes to rules and regulations for drug approval in the context of green chemistry principles are necessary in order to preserve our planet for future generations.

Virtually going green: The role of quantum computational chemistry in reducing pollution and toxicity in chemistry

Continuing advances in computational chemistry has permitted quantum mechanical calculation to assist in research in green chemistry and to contribute to the greening of chemical practice. Presented here are recent examples illustrating the contribution of computational quantum chemistry to green chemistry, including the possibility of using computation as a green alternative to experiments, but also illustrating contributions to greener catalysis and the search for greener solvents. Examples of applications of computation to ambitious projects for green synthetic chemistry using carbon dioxide are also presented.

Organocatalysis: Key Trends in Green Synthetic Chemistry, Challenges, Scope towards Heterogenization, and Importance from Research and Industrial Point of View

This paper purports to review catalysis, particularly the organocatalysis and its origin, key trends, challenges, examples, scope, and importance. The definition of organocatalyst corresponds to a low molecular weight organic molecule which in stoichiometric amounts catalyzes a chemical reaction. In this review, the use of the term heterogenized organocatalyst will be exclusively confined to a catalytic system containing an organic molecule immobilized onto some sort of support material and is responsible for accelerating a chemical reaction. Firstly, a brief description of the field is provided putting it in a green and sustainable perspective of chemistry. Next, research findings on the use of organocatalysts on various inorganic supports including nano(porous)materials, nanoparticles, silica, and zeolite/zeolitic materials are scrutinized in brief. Then future scope, research directions, and academic and industrial applications will be outlined. A succinct account will summarize some of the research and developments in the field. This review tries to bring many outstanding researches together and shows the vitality of the organocatalysis through several aspects.