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Baird, A. , Braam, B. , & Layton, A. . (2015). Implications of Increased Renal Venous Pressure for Renal Hemodynamic and Reabsorptive Function Studied by a Mathematical Model of the Kidney. The FASEB Journal, 29, 808–19. The Federation of American Societies for Experimental Biology.
Layton, A. , & Minion, M. . (2007). Implications of the choice of predictors for semi-implicit Picard integral deferred correction methods. Communications in Applied Mathematics and Computational Science, 2, 1–34. Mathematical Sciences Publishers.
Layton, A. T. , & Minion, M. L. . (2005). Implications of the choice of quadrature nodes for Picard integral deferred corrections methods for ordinary differential equations. BIT, 45(2), 341–373.
Layton, A. T. , & Minion, M. L. . (2005). Implications of the choice of quadrature nodes for Picard integral deferred corrections methods for ordinary differential equations. BIT Numerical Mathematics, 45, 341–373. Springer-Verlag.
Ahmed, S. , Hu, R. , Leete, J. , & Layton, A. T. . (2019). Integrative Cardiovascular Physiology and Pathophysiology: Understanding sex differences in long-term blood pressure regulation: insights from experimental studies and computational modeling. American Journal of Physiology-Heart and Circulatory Physiology, 316, H1113. American Physiological Society.
Sadria, M. , & Layton, A. T. . (2021). Interactions among mTORC, AMPK and SIRT: a computational model for cell energy balance and metabolism. Cell Communication and Signaling, 19, 1–17. BioMed Central.
Sgouralis, I. , & Layton, A. T. . (2012). Interactions between Tubuloglomerular Feedback and the Myogenic Mechanism of the Afferent Arteriole. Federation of American Societies for Experimental Biology.
Layton, A. T. , & Wei, G. . (2012). Interface methods for biological and biomedical problems. John Wiley & Sons, Ltd Chichester, UK.
Layton, A. T. , & Wei, G. . (2012). Interface methods for biological and biomedical problems. International journal for numerical methods in biomedical engineering, 28, 289–290. John Wiley & Sons, Ltd Chichester, UK.
Sgouralis, I. , & Layton, A. . (2016). Internephron Coupling Increases the Efficiency of Dynamic Autoregulation. The FASEB Journal, 30, 739–6. The Federation of American Societies for Experimental Biology.
Sgouralis, I. , & Layton, A. . (2016). Internephron Coupling Increases the Efficiency of Dynamic Autoregulation. The FASEB Journal, 30, 739–6. The Federation of American Societies for Experimental Biology.
Layton, A. T. , Moore, L. C. , & Layton, H. E. . (2002). Internephron coupling may contribute to emergence of irregular oscillations mediated by tubuloglomerular feedback. In JOURNAL OF THE AMERICAN SOCIETY OF NEPHROLOGY (Vol. 13, p. 333A–333A). LIPPINCOTT WILLIAMS & WILKINS 530 WALNUT ST, PHILADELPHIA, PA 19106-3621 USA.
Burt, T. , Rouse, D. C. , Lee, K. , Wu, H. , Layton, A. T. , Hawk, T. C. , Weitzel, D. H. , et al. (2015). Intraarterial microdosing: a novel drug development approach, proof-of-concept PET study in rats. Journal of Nuclear Medicine, 56, 1793–1799. Society of Nuclear Medicine.
Burt, T. , Wu, H. , Layton, A. T. , Rouse, D. C. , Chin, B. B. , Hawk, T. C. , Weitzel, D. H. , et al. (2015). Intra-arterial microdosing (IAM), a novel drug development approach, proof of concept in rats. Clinical Therapeutics, 37, e40–e41. Elsevier.
Burt, T. , Wu, H. , Layton, A. T. , Rouse, D. C. , Chin, B. B. , Hawk, T. C. , Weitzel, D. H. , et al. (2015). Intra-Arterial Microdosing (IAM), a novel Drug development approach, proof of concept in Rats. Clinical Therapeutics, 37, e40–e41. Elsevier.
Burt, T. , Noveck, R. J. , MacLeod, D. B. , Layton, A. T. , Rowland, M. , & Lappin, G. . (2017). Intra-Target Microdosing (ITM): a novel drug development approach aimed at enabling safer and earlier translation of biological insights into human testing. Clinical and translational science, 10, 337. Wiley-Blackwell.
Burt, T. , Noveck, R. J. , MacLeod, D. B. , Layton, A. T. , Rowland, M. , & Lappin, G. . (2017). Intra-Target Microdosing (ITM): a novel drug development approach aimed at enabling safer and earlier translation of biological insights into human testing. Clinical and translational science, 10, 337. Wiley-Blackwell.
Layton, A. T. , & Edwards, A. . (2014). Introduction: Basics of Kidney Physiology. In Mathematical Modeling in Renal Physiology (pp. 1–5). Springer, Berlin, Heidelberg.
Layton, A. T. , & Edwards, A. . (2017). Introduction to Mathematical Modeling of Blood Flow Control in the Kidney. Women in Mathematical Biology, 63–73. Springer, Cham.
Layton, A. T. , & Edwards, A. . (2017). Introduction to Mathematical Modeling of Blood Flow Control in the Kidney. In Women in Mathematical Biology (pp. 63–73). Springer, Cham.

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