PUBLICATIONS
[1] Trumbore, C. N. and Raghunandan, A. (2022). An Alzheimer’s Disease Mechanism Based on Early Pathology, Anatomy, Vascular-Induced Flow, and Migration of Maximum Flow Stress Energy Location with Increasing Vascular Disease. Journal of Alzheimer’s Disease, (in press).
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[2] Raghunandan A., Ladron-de-Guevara, A., Tithof, J., Mestre, H., Nedergaard M., Thomas, J.H., Kelley D.H. (2021). Bulk flow of cerebrospinal fluid in periarterial spaces is not an artifact of injection. eLife 10: e65958.
[3] ​McMackin, P. M., Griffin, S. R., Riley, F. P., Gulati, S., Debono, N.E., Raghunandan, A., Lopez, J. M., Hirsa, A. H., (2020). Simulated microgravity in the ring-sheared drop. npj Microgravity, 6 (2).
[4] Raghunandan, A., Hirsa, A. H., Underhill, P. T., & Lopez, J. M. (2018). Predicting shear rheology of condensed-phase monomolecular films at the air-water interface. Physical Review Letters, 121, 164502.
[5] Balaraj, V. S., Zeng, P. C., Sanford, S. P., McBride, S. A., Raghunandan, A., Lopez, J. M., & Hirsa, A. H. (2017). Surface shear viscosity as a macroscopic probe of amyloid fibril formation at a fluid interface. Soft Matter, 13(9), 1780-1787. (Cover article)
[6] Rasheed, F.*, Raghunandan, A.*, Hirsa, A. H., & Lopez, J. M. (2017). Oscillatory shear rheology measurements and Newtonian modeling of insoluble monolayers. Physical Review Fluids, 2(4), 044002. *Equal contribution
[7] Gulati, S., Raghunandan, A., Rasheed, F., McBride, S. A., & Hirsa, A. H. (2017). Ring-Sheared Drop (RSD): microgravity module for containerless flow studies. Microgravity Science and Technology, 29(1-2), 81-89.
[8] Raghunandan, A., Lopez, J. M., & Hirsa, A. H. (2015). Bulk flow driven by a viscous monolayer. Journal of Fluid Mechanics, 785, 283-300.