| Solubility advantage of amorphous drugs and pharmaceutical cocrystals NJ Babu, A Nangia Crystal Growth & Design 11 (7), 2662-2679, 2011 | 1128 | 2011 |
| C− H⊙⊙⊙ F Interactions in the crystal structures of some fluorobenzenes VR Thalladi, HC Weiss, D Bläser, R Boese, A Nangia, GR Desiraju Journal of the American Chemical Society 120 (34), 8702-8710, 1998 | 833 | 1998 |
| Conformational polymorphism in organic crystals A Nangia Accounts of chemical research 41 (5), 595-604, 2008 | 592 | 2008 |
| Pharmaceutical cocrystals: walking the talk G Bolla, A Nangia Chemical communications 52 (54), 8342-8360, 2016 | 569 | 2016 |
| Tape and layer structures in cocrystals of some di-and tricarboxylic acids with 4, 4′-bipyridines and isonicotinamide. From binary to ternary cocrystals BR Bhogala, S Basavoju, A Nangia CrystEngComm 7 (90), 551-562, 2005 | 447 | 2005 |
| Molecular complexes of homologous alkanedicarboxylic acids with isonicotinamide: X-ray crystal structures, hydrogen bond synthons, and melting point alternation P Vishweshwar, A Nangia, VM Lynch Crystal growth & design 3 (5), 783-790, 2003 | 342 | 2003 |
| Crystal engineering of pharmaceutical cocrystals in the discovery and development of improved drugs G Bolla, B Sarma, AK Nangia Chemical reviews 122 (13), 11514-11603, 2022 | 331 | 2022 |
| Eutectics as improved pharmaceutical materials: design, properties and characterization S Cherukuvada, A Nangia Chemical Communications 50 (8), 906-923, 2014 | 301 | 2014 |
| New polymorphs of curcumin P Sanphui, NR Goud, UBR Khandavilli, S Bhanoth, A Nangia Chemical Communications 47 (17), 5013-5015, 2011 | 299 | 2011 |
| Cocrystals of 1, 3, 5-Cyclohexanetricarboxylic Acid with 4, 4 ‘-Bipyridine Homologues: Acid⊙⊙⊙ Pyridine Hydrogen Bonding in Neutral and Ionic Complexes BR Bhogala, A Nangia Crystal growth & design 3 (4), 547-554, 2003 | 292 | 2003 |
| Cubanecarboxylic Acids. Crystal Engineering Considerations and the Role of C− H⊙⊙⊙ O Hydrogen Bonds in Determining O− H⊙⊙⊙ O Networks SS Kuduva, DC Craig, A Nangia, GR Desiraju Journal of the American Chemical Society 121 (9), 1936-1944, 1999 | 290 | 1999 |
| Supramolecular synthons and pattern recognition A Nangia, GR Desiraju Design of Organic Solids, 57-95, 1998 | 290 | 1998 |
| Fast dissolving curcumin cocrystals P Sanphui, NR Goud, UBR Khandavilli, A Nangia Crystal Growth & Design 11 (9), 4135-4145, 2011 | 280 | 2011 |
| Crystal engineering of some 2, 4, 6-triaryloxy-1, 3, 5-triazines: octupolar nonlinear materials VR Thalladi, S Brasselet, HC Weiss, D Bläser, AK Katz, HL Carrell, ... Journal of the American Chemical Society 120 (11), 2563-2577, 1998 | 272 | 1998 |
| Recurrence of carboxylic acid− pyridine supramolecular synthon in the crystal structures of some pyrazinecarboxylic acids P Vishweshwar, A Nangia, VM Lynch The Journal of Organic Chemistry 67 (2), 556-565, 2002 | 256 | 2002 |
| Crystal engineering: an outlook for the future AK Nangia, GR Desiraju Angewandte Chemie International Edition 58 (13), 4100-4107, 2019 | 229 | 2019 |
| A Cambridge Structural Database analysis of the C–H⋯ Cl interaction: C–H⋯ Cl− and C–H⋯ Cl–M often behave as hydrogen bonds but C–H⋯ Cl–C is generally a van der Waals interaction PK Thallapally, A Nangia CrystEngComm 3 (27), 114-119, 2001 | 225 | 2001 |
| Crystal engineering with hydrogen bonds and halogen bonds BK Saha, A Nangia, M Jaskólski CrystEngComm 7 (58), 355-358, 2005 | 218 | 2005 |
| A green synthetic route to phenolics fabricated magnetite nanoparticles from coconut husk extract: Implications to treat metal contaminated water and heavy metal stress in … A Sebastian, A Nangia, MNV Prasad Journal of Cleaner Production 174, 355-366, 2018 | 205 | 2018 |
| Synthon competition and cooperation in molecular salts of hydroxybenzoic acids and aminopyridines B Sarma, NK Nath, BR Bhogala, A Nangia Crystal Growth and Design 9 (3), 1546-1557, 2009 | 204 | 2009 |
