Publications
Tubular Fluid Oscillations Mediated by Tubuloglomerular Feedback in a Short Loop of Henle. Federation of American Societies for Experimental Biology.
. (2012). Tubular fluid flow and distal NaCl delivery mediated by tubuloglomerular feedback in the rat kidney. Journal of mathematical biology, 68, 1023–1049. Springer Berlin Heidelberg.
. (2014). Transport efficiency and workload distribution in a mathematical model of the thick ascending limb. American Journal of Physiology-Renal Physiology, 304, F653–F664. American Physiological Society Bethesda, MD.
. (2013). Transport across tubular epithelia. Mathematical Modeling in Renal Physiology, 155–183. Springer Berlin Heidelberg.
. (2014). Transfer function analysis of dynamic blood flow control in the rat kidney. Bulletin of mathematical biology, 78, 923–960. Springer US.
. (2016). Tracking the Distribution of a Solute Bolus in the Rat Kidney. In Women in Mathematical Biology: Research Collaboration Workshop, NIMBioS, Knoxville, June 2015 (pp. 115–136). Springer International Publishing.
. (2017). Towards a web resource for quantitative renal physiology. In Proceedings of the Physiological Society (Vol. 565, p. 98P).
. (2005). Three-dimensional reconstructions of rat renal inner medulla suggest two anatomically separated countercurrent mechanisms for urine concentration. Federation of American Societies for Experimental Biology.
. (2008). Theoretical assessment of the Ca 2+ oscillations in the afferent arteriole smooth muscle cell of the rat kidney. International Journal of Biomathematics, 11, 1850043. World Scientific Publishing Company.
. (2018). Theoretical assessment of renal autoregulatory mechanisms. American Journal of Physiology-Renal Physiology, 306, F1357–F1371. American Physiological Society Bethesda, MD.
. (2014). Targeted delivery of solutes and oxygen in the renal medulla: role of microvessel architecture. American Journal of Physiology-Renal Physiology, 307, F649–F655. American Physiological Society Bethesda, MD.
. (2014). Sweet success? SGLT2 inhibitors and diabetes. American Journal of Physiology-Renal Physiology, 314, F1034–F1035. American Physiological Society Bethesda, MD.
. (2018). Structural organization of the renal medulla has a significant impact on oxygen distribution (890.11). The FASEB Journal, 28, 890–11. The Federation of American Societies for Experimental Biology.
. (2014). Special Issue on Fluid Motion Driven by Immersed Structures Preface. COMMUNICATIONS IN COMPUTATIONAL PHYSICS, 12, I–III. GLOBAL SCIENCE PRESS ROOM 3208, CENTRAL PLAZA, 18 HARBOUR RD, WANCHAI, HONG ….
. (2012). Solutions to Problem Sets. Mathematical Modeling in Renal Physiology, 185–218. Springer Berlin Heidelberg.
. (2014). Solute transport and oxygen consumption along the nephrons: effects of Na+ transport inhibitors. American Journal of Physiology-Renal Physiology, 311, F1217–F1229. American Physiological Society Bethesda, MD.
. (2016). Solute and water transport along an inner medullary collecting duct undergoing peristaltic contractions. American Journal of Physiology-Renal Physiology, 317, F735–F742. American Physiological Society Bethesda, MD.
. (2019). Simulating biofluid-structure interactions with an immersed boundary framework–a review. Biological Fluid Dynamics: Modeling, Computations, and Applications, 628, 1. American Mathematical Soc.
. (2014). Signal transduction in a compliant thick ascending limb. American Journal of Physiology-Renal Physiology, 302, F1188–F1202. American Physiological Society Bethesda, MD.
. (2012). Signal transduction in a compliant short loop of Henle. International journal for numerical methods in biomedical engineering, 28, 369–383. John Wiley & Sons, Ltd Chichester, UK.
. (2012).