1. Bryan, L., S. Awasthi, Y. Li, P.N. Nirmalraj, S. Balog, J. Yang and M. Mayer, 2022. Site-specific C-terminal fluorescent labeling of Tau protein. bioRxiv, 10.1101/2022.06.07.495075.
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2. Ying, C., E. Karakaci, E. Bermudez-Urena, A. Ianiro and C. Foster, 2021. Watching single unmodified enzymes at work. Biol. Phys., 10.48550/arXiv.2107.06407.
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3. Awasthi, S., P. Sriboonpeng, C. Ying, J. Houghtaling and I. Shorubalko et al., 2020. Polymer coatings to minimize protein adsorption in solid‐state nanopores. Small Methods, Vol. 4. 10.1002/smtd.202000177.
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4. Awasthi, S., R. Preethy and N.T. Saraswathi, 2019. Nordihydroguaiaretic acid prevents glycation induced structural alterations and aggregation of albumin. Int. J. Biol. Macromol., 122: 479-484.
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5. Ying, C., J. Houghtaling, O.M. Eggenberger, A. Guha and P. Nirmalraj et al., 2018. Formation of single nanopores with diameters of 20–50 nm in silicon nitride membranes using laser-assisted controlled breakdown. ACS Nano, 12: 11458-11470.
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6. Awasthi, S., K. Sankaranarayanan and N.T. Saraswathi, 2016. Advanced glycation end products induce differential structural modifications and fibrillation of albumin. Spectrochimica Acta Part A: Mol. Biomol. Spectrosc., 163: 60-67.
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7. Awasthi, S., A. Ravi and N.T. Saraswathi, 2016. Troxerutin imparts preservative effects on albumin by preventing Maillard reaction-mediated early and advanced glycation modification. J. Biomol. Struct. Dyn., (In Press). 10.1080/07391102.2016.1229218.
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8. Awasthi, S. and N.T. Saraswathi, 2016. Vanillin restrains non-enzymatic glycation and aggregation of albumin by chemical chaperone like function. Int. J. Biol. Macromol., 87: 1-6.
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9. Awasthi, S. and N.T. Saraswathi, 2016. Sinigrin, a major glucosinolate from cruciferous vegetables restrains non-enzymatic glycation of albumin. Int. J. Biol. Macromol., 83: 410-415.
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10. Awasthi, S. and N.T. Saraswathi, 2016. Non-enzymatic glycation mediated structure-function changes in proteins: Case of serum albumin. RSC Adv., 6: 90739-90753.
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11. Awasthi, S. and N.T. Saraswathi, 2016. Elucidating the molecular interaction of sinigrin, a potent anticancer glucosinolate from cruciferous vegetables with bovine serum albumin: Effect of methylglyoxal modification. J. Biomol. Struct. Dyn., 34: 2224-2232.
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12. Awasthi, S. and N.T. Saraswathi, 2016. Carbonyl scavenging and chemical chaperon like function of essential amino acids attenuates non-enzymatic glycation of albumin. RSC Adv., 6: 24557-24564.
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13. Awasthi, S., S.K. Gayathiri, R. Ramya, R. Duraichelvan, A. Dhason and N.T. Saraswathi, 2015. Advanced glycation-modified human serum albumin evokes alterations in membrane and eryptosis in erythrocytes. Applied Biochem. Biotechnol., 177: 1013-1024.
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14. Awasthi, S., N.A. Murugan and N.T. Saraswathi, 2015. Advanced glycation end products modulate structure and drug binding properties of albumin. Mol. Pharmaceut., 12: 3312-3322.
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15. Awasthi, S. and N.T. Saraswathi, 2015. Silybin, a flavonolignan from milk thistle seeds, restrains the early and advanced glycation end product modification of albumin. RSC Adv., 5: 87660-87666.
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16. Awasthi, S. and N.T. Saraswathi, 2015. Crystal structure of Alanine-Copper(II) complex to understand the mechanism of salt induced prebiotic oligomerization of amino acids. Crystal Res. Technol., 50: 304-311.
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17. Sibi, G., S. Awasthi, K. Dhananjaya, H. Mallesha and K.R. Ravikumar, 2012. Comparative studies of Plumeria species for their phytochemical and antifungal properties against Citrus sinensis pathogens. Int. J. Agric. Res., 7: 324-331.
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18. Dhananjaya, K., G. Sibi, H. Mallesha, K.R. Ravikumar and S. Awasthi, 2012. In silico studies of daidzein and genistein with human estrogen receptor α. Asian Pacific J. Trop. Biomed., 2: S1747-S1753.
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