Your search keyword '"Rama Krishna Gamidi"' showing total 6 results

1. Visible‐Light‐Induced Radical Sulfonylative‐Cyclization Cascade of 1,6‐Enynol Derivatives with Sulfinic Acids: A Sustainable Approach for the Synthesis of 2,3‐Disubstituted Benzoheteroles.

Author

Haritha Kumari, Arram, Jagadesh Kumar, Jangam, Sharadha, Nunavath, Rama Krishna, Gamidi, and Jannapu Reddy, Raju

Subjects

SULFINIC acids, ROSE bengal, PHARMACEUTICAL chemistry, RADICALS (Chemistry), FUNCTIONAL groups, ANNULATION, RING formation (Chemistry)

Abstract

Benzoheteroles are promising structural scaffolds in the realm of medicinal chemistry, but sustainable synthesis of 2,3‐difunctionalized benzoheterole derivatives is still in high demand. Indeed, we have conceptually rationalized the intrinsic reactivity of propargylic‐enyne systems for the flexible construction of 2,3‐disubstituted benzoheteroles through radical sulfonylative‐cyclization cascade under organophotoredox catalysis. We hereby report an efficient visible‐light‐induced sulfonyl radical‐triggered cyclization of 1,6‐enynols with sulfinic acids under the dual catalytic influence of 4CzIPN and NiBr2⋅DME, which led to the formation of 2,3‐disubstituted benzoheteroles in good to high yields. Additionally, the Rose Bengal (RB)‐catalyzed radical sulfonylative‐cycloannulation of acetyl‐derived 1,6‐enynols with sulfinic acids under blue LED irradiation allowed to access 3‐(E‐styryl)‐derived benzofurans and benzothiophenes in moderate to good yields. The scope and limitations of the present strategies were successfully established using different classes of 1,6‐enynols and sulfinic acids bearing various sensitive functional groups, yielding the desired products in a highly stereoselective fashion. Plausible mechanistic pathways were also proposed based on the current experimental and control experiments. [ABSTRACT FROM AUTHOR]

Published

2024

2. Brønsted Acid-Promoted Cyclodimerization of α,β-Unsaturated γ-Ketoesters: Construction of Fused Pyrano-ketal-lactones and γ-Ylidene-butenolides

Author

Vinodkumar, Ramavath, primary, Nakate, Ashwini K., additional, Sharma, Himanshu, additional, Vanka, Kumar, additional, Rama Krishna, Gamidi, additional, and Kontham, Ravindar, additional

Published

2024

3. Metal-Free One-Pot Domino Synthesis of Oxazolidinethione Derivatives of Quaternary Amino Acids from α-Amino Esters and Aldehydes Using CS2

Author

Shinde, Dinesh R., primary, Rama Krishna, Gamidi, additional, and Marelli, Udaya Kiran, additional

Published

2024

4. Metal-Free One-Pot Domino Synthesis of Oxazolidinethione Derivatives of Quaternary Amino Acids from α‑Amino Esters and Aldehydes Using CS2.

Author

Shinde, Dinesh R., Rama Krishna, Gamidi, and Marelli, Udaya Kiran

Published

2024

5. Base controlled rongalite-mediated reductive aldol/cyclization and dimerization of isatylidene malononitriles/cyanoacetates.

Author

Chaudhari, Suryakant S., Nichinde, Chandrakant B., Patil, Baliram R., Girase, Amardipsing S., Rama Krishna, Gamidi, and Kinage, Anil K.

Published

2024

6. Prediction of Solid State Properties of Cocrystals Using Artificial Neural Network Modeling

Author

Rama Krishna, Gamidi, Ukrainczyk, Marko, Zeglinski, Jacek, and Rasmuson, Åke. C.

Abstract

Using Artificial Neural Networks (ANNs), four distinct models have been developed for the prediction of solid-state properties of cocrystals: melting point, lattice energy, and crystal density. The models use three input parameters for the pure model compound (MC) and three for the pure coformer. In addition, as an input parameter the model uses the pKadifference between the MC and the coformer, and a 1:1 MC–conformer binding energy as calculated by a force field method. Notably, the models require no data for the actual cocrystals. In total, 61 CCs (two-component molecular cocrystals) were used to construct the models, and melting temperatures and crystal densities were extracted from the literature for four MCs: caffeine, theophylline, nicotinamide, and isonicotinamide. The data set includes 14 caffeine cocrystals, 9 theophylline cocrystals, 9 nicotinamide cocrystals, and 29 isonicotinamide cocrystals. Model-I is trained using known cocrystal melting temperatures, lattice energies, and crystal densities, to predict all three solid-state properties simultaneously. The average relative deviation for the training set is 2.49%, 6.21%, and 1.88% for the melting temperature, lattice energy, and crystal density, respectively, and correspondingly 6.26%, 4.58%, and 0.99% for the valdation set. Model-II, model-III, and model-IV were built using the same input neurons as in model-I, for separate prediction of each respective output solid–state property. For these models the average relative deviation for the training sets becomes 1.93% for the melting temperature model-II, 1.29% for the lattice energy model-III, and 1.03% for the crystal density model-IV, and correspondingly 2.23%, 2.40%, and 1.77% for the respective validation sets.

Published

2024