Shreya Ghosh

511 total citations
21 papers, 399 citations indexed

About

Shreya Ghosh is a scholar working on Biophysics, Materials Chemistry and Molecular Biology. According to data from OpenAlex, Shreya Ghosh has authored 21 papers receiving a total of 399 indexed citations (citations by other indexed papers that have themselves been cited), including 14 papers in Biophysics, 9 papers in Materials Chemistry and 7 papers in Molecular Biology. Recurrent topics in Shreya Ghosh's work include Electron Spin Resonance Studies (14 papers), Lanthanide and Transition Metal Complexes (7 papers) and Metal complexes synthesis and properties (6 papers). Shreya Ghosh is often cited by papers focused on Electron Spin Resonance Studies (14 papers), Lanthanide and Transition Metal Complexes (7 papers) and Metal complexes synthesis and properties (6 papers). Shreya Ghosh collaborates with scholars based in United States, Israel and India. Shreya Ghosh's co-authors include Sunil Saxena, Matthew J. Lawless, Austin Gamble Jarvi, Sharon Ruthstein, Gordon S. Rule, Lada Gevorkyan‐Airapetov, Kevin Singewald, Timothy F. Cunningham, Junmei Wang and Ralph T. Weber and has published in prestigious journals such as Proceedings of the National Academy of Sciences, Nucleic Acids Research and Angewandte Chemie International Edition.

In The Last Decade

Shreya Ghosh

18 papers receiving 398 citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Shreya Ghosh United States 11 336 217 129 96 81 21 399
Timothy F. Cunningham United States 11 394 1.2× 274 1.3× 153 1.2× 70 0.7× 88 1.1× 13 451
René Tschaggelar Switzerland 11 377 1.1× 330 1.5× 105 0.8× 22 0.2× 67 0.8× 18 549
Laura Galazzo Switzerland 11 153 0.5× 104 0.5× 37 0.3× 41 0.4× 106 1.3× 19 298
Elwy H. Abdelkader Australia 15 260 0.8× 282 1.3× 90 0.7× 20 0.2× 235 2.9× 36 559
Mykhailo Azarkh Germany 11 268 0.8× 226 1.0× 95 0.7× 19 0.2× 162 2.0× 22 479
Dmitry Akhmetzyanov Germany 10 250 0.7× 243 1.1× 81 0.6× 21 0.2× 38 0.5× 16 361
R. Trokowski United States 10 95 0.3× 382 1.8× 119 0.9× 21 0.2× 30 0.4× 10 502
Luis Fábregas Ibáñez Switzerland 11 202 0.6× 123 0.6× 52 0.4× 11 0.1× 109 1.3× 13 310
Mark Tseytlin United States 11 232 0.7× 130 0.6× 29 0.2× 14 0.1× 32 0.4× 24 300
Thorsten Bahrenberg Israel 8 244 0.7× 227 1.0× 54 0.4× 7 0.1× 43 0.5× 11 312

Countries citing papers authored by Shreya Ghosh

Since Specialization
Citations

This map shows the geographic impact of Shreya Ghosh's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Shreya Ghosh with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Shreya Ghosh more than expected).

Fields of papers citing papers by Shreya Ghosh

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Shreya Ghosh. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Shreya Ghosh. The network helps show where Shreya Ghosh may publish in the future.

Co-authorship network of co-authors of Shreya Ghosh

This figure shows the co-authorship network connecting the top 25 collaborators of Shreya Ghosh. A scholar is included among the top collaborators of Shreya Ghosh based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Shreya Ghosh. Shreya Ghosh is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Tugarinov, Vitali, et al.. (2025). Modeling Protein Aggregation Kinetics from NMR Data. Journal of Molecular Biology. 437(23). 169269–169269.
2.
Kumari, Arram Haritha, et al.. (2025). Metal‐Free Four‐Component Strategy to Access Thioether‐Derived Imidazo[1,2‐a]pyridines and Imidazo[2,1‐b]thiazoles. European Journal of Organic Chemistry. 28(29).
3.
Ghosh, Shreya, et al.. (2024). De novo designed aliphatic and aromatic peptides assemble into amyloid-like cytotoxic supramolecular nanofibrils. RSC Advances. 14(7). 4382–4388. 1 indexed citations
4.
Ghosh, Shreya, Vitali Tugarinov, & G. Marius Clore. (2024). Quantitative NMR analysis of the mechanism and kinetics of chaperone Hsp104 action on amyloid β-42 aggregation and fibril formation. Biophysical Journal. 123(3). 168a–168a.
5.
Ghosh, Shreya, Vitali Tugarinov, & G. Marius Clore. (2023). Quantitative NMR analysis of the mechanism and kinetics of chaperone Hsp104 action on amyloid-β42 aggregation and fibril formation. Proceedings of the National Academy of Sciences. 120(21). e2305823120–e2305823120. 6 indexed citations
6.
Hofmann, Lukas, et al.. (2022). Cu(ii)-based DNA labeling identifies the structural link between transcriptional activation and termination in a metalloregulator. Chemical Science. 13(6). 1693–1697. 23 indexed citations
7.
Ghosh, Shreya, et al.. (2021). Nanoscale spin detection of copper ions using double electron-electron resonance at room temperature. Physical review. B.. 104(22). 3 indexed citations
8.
Jarvi, Austin Gamble, et al.. (2021). Going the dHis-tance: Site-Directed Cu2+ Labeling of Proteins and Nucleic Acids. Accounts of Chemical Research. 54(6). 1481–1491. 36 indexed citations
9.
Ghosh, Shreya, et al.. (2020). Orientation and dynamics of Cu2+based DNA labels from force field parameterized MD elucidates the relationship between EPR distance constraints and DNA backbone distances. Physical Chemistry Chemical Physics. 22(46). 26707–26719. 12 indexed citations
10.
11.
Ghosh, Shreya, Matthew J. Lawless, Kevin Singewald, et al.. (2020). Cu2+-based distance measurements by pulsed EPR provide distance constraints for DNA backbone conformations in solution. Nucleic Acids Research. 48(9). e49–e49. 27 indexed citations
12.
13.
Wagner, Eugene P., et al.. (2019). An Undergraduate Experiment To Explore Cu(II) Coordination Environment in Multihistidine Compounds through Electron Spin Resonance Spectroscopy. Journal of Chemical Education. 96(8). 1752–1759. 13 indexed citations
14.
Ghosh, Shreya, Velia Garcia, Kevin Singewald, Steven M. Damo, & Sunil Saxena. (2018). Cu(II) EPR Reveals Two Distinct Binding Sites and Oligomerization of Innate Immune Protein Calgranulin C. Applied Magnetic Resonance. 49(11). 1299–1311. 4 indexed citations
15.
Ghosh, Shreya, et al.. (2018). EPR Spectroscopy Detects Various Active State Conformations of the Transcriptional Regulator CueR. Angewandte Chemie. 131(10). 3085–3088. 9 indexed citations
16.
Ghosh, Shreya, Sunil Saxena, & Gunnar Jeschke. (2018). Rotamer Modelling of Cu(II) Spin Labels Based on the Double-Histidine Motif. Applied Magnetic Resonance. 49(11). 1281–1298. 22 indexed citations
17.
Jarvi, Austin Gamble, Kalina Ranguelova, Shreya Ghosh, Ralph T. Weber, & Sunil Saxena. (2018). On the Use of Q-Band Double Electron–Electron Resonance To Resolve the Relative Orientations of Two Double Histidine-Bound Cu2+ Ions in a Protein. The Journal of Physical Chemistry B. 122(47). 10669–10677. 43 indexed citations
18.
Ghosh, Shreya, et al.. (2018). EPR Spectroscopy Detects Various Active State Conformations of the Transcriptional Regulator CueR. Angewandte Chemie International Edition. 58(10). 3053–3056. 57 indexed citations
19.
Ghosh, Shreya, Matthew J. Lawless, Gordon S. Rule, & Sunil Saxena. (2017). The Cu2+-nitrilotriacetic acid complex improves loading of α-helical double histidine site for precise distance measurements by pulsed ESR. Journal of Magnetic Resonance. 286. 163–171. 59 indexed citations
20.
Lawless, Matthew J., et al.. (2017). On the use of the Cu2+–iminodiacetic acid complex for double histidine based distance measurements by pulsed ESR. Physical Chemistry Chemical Physics. 19(31). 20959–20967. 45 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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