Visible-light-induced decarboxylative alkynylation of carboxylic acids in batch and continuous flow

Tailoring cellulose: from extraction and chemical modification to advanced industrial applications

Cellulose is a natural polymer with excellent physicochemical properties that can be extracted from various plant sources and has widespread applications across multiple industries. Due to its biodegradability, renewability, and mechanical strength, cellulose has gained significant attention in fields such as pharmaceuticals, food packaging, sensors, water treatment, and textiles. However, its inherent limitations, such as poor solubility, low electrical conductivity, and limited functionality, hinder its application in advanced technologies. To overcome these challenges, chemical modifications have been extensively explored to enhance its structural properties and broaden its utility in specialized applications. This review explores the modifications applied to cellulose with a focus on targeted advanced industries. Emphasis is placed on identifying the limitations of cellulose in each industry and highlighting the most recent techniques available for modifying its properties to meet specific requirements. Finally, this review discusses the challenges associated with cellulose processing and the high costs of extraction while providing insights into future research directions and potential advancements in cellulose-based technologies.

Light Induced Diastereoselective Ketoesterification To Access 6,5-Fused Tetrahydrobenzofuranones in Batch and Continuous Flow Conditions

Ketoesterification stands as a pivotal technique in organic synthesis, particularly due to its essential role in the construction of numerous natural products and bioactive compounds. In this study, we have successfully accomplished a visible-light-induced cyclization and diastereoselective direct ketoesterification of cyclohexadienones, facilitating access to cis 6,5-fused tetrahydrobenzofuranone derivatives. The utilization of TEMPO radical quenching experiments has provided insights, suggesting an ionic mechanism underlying this methodology. Additionally, the regioselective addition of 2-oxo-2-phenylacetate to the least hindered side in a cis-selective fashion makes this protocol more appealing toward natural product development. Incorporation of a continuous flow reaction into the batch protocol has notably bolstered the efficiency and reaction rate. Furthermore, the demonstration of gram-scale reactions in the flow setup and synthetic utility with NaOH underscore the scalability and practical applicability of this approach.