Chapter 7 References Sands JM, Blount MA and Klein JD. Regulation of Renal Urea Transport by Vasopressin. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3116377/ In this invited piece, Sands and colleagues explain that although urea is permeable across membranes, this is slow, thus urea transporters in the kidney, under control of vasopressin, are needed to facilitate transport and create the medullary gradient.  Text book using 20% of extracellular compartment being in the intravascular compartment. https://courses.lumenlearning.com/ap2/chapter/body-fluids-and-fluid-compartments-no-content/ another one: https://med.libretexts.org/Bookshelves/Anatomy_and_Physiology/Book%3A_Anatomy_and_Physiology_(Boundless)/25%3A_Body_Fluids_and_Acid-Base_Balance/25.2%3A_Body_Fluids/25.2B%3A_Fluid_Compartments The chapter I wrote where I went through the math in figure 7-3. It was a major revelation to me: https://docs.google.com/document/d/17BM1xihvlztuQlU8GVNhEDoPLzr6GounHYZAtVUkLvw/edit?usp=sharing Association Between ICU-Acquired Hypernatremia and In-Hospital Mortality https://journals.lww.com/ccejournal/fulltext/2020/12000/association_between_icu_acquired_hypernatremia_and.26.aspx Rate of Correction of Hypernatremia and Health Outcomes in Critically Ill Patients https://pubmed.ncbi.nlm.nih.gov/30948456/ Edelman IS, Leibman J, O’Meara MP and Birkenfeld LW. Interrelations between serum sodium concentration, serum osmolarity and total exchangeable sodium, total exchangeable potassium and total body water. JCI 1958. This classic paper calculates the total body exchangeable sodium and potassium and establishes the relationship between these. Understanding this painstacking work helps understand the effect of supplementing potassium in the setting of hyponatremia.  https://dm5migu4zj3pb.cloudfront.net/manuscripts/103000/103712/cache/103712.1-20201218131357-covered-e0fd13ba177f913fd3156f593ead4cfd.pdf Edelman is the Root of Almost All Good in Nephrology https://www.renalfellow.org/2014/11/20/edelman-is-root-of-almost-all-good-in/ Jens Titze and his team published a pair of articles that shocked those interested in salt and water in JCI in 2017.  High Salt intake reprioritizes osmolyte and energy metabolism for body fluid conservation https://www.jci.org/articles/view/88532 Increased salt consumption induces body water conservation and decreases fluid intake https://www.jci.org/articles/view/88530 in this exciting exploration of the basic assumptions that we hold true regarding salt and water (and staring Russian cosmonauts and an incredible controlled simulation of salt and water intake), Titze shows that high sodium intake does not simply drive water consumption (as we usually teach) but instead leads to a complex hormonal and metabolic response (even with diurnal variation!) and results in body water conservation and decreased water consumption.  And accompanying editorial from Mark Zeidel: salt and water, not so simple. https://www.jci.org/articles/view/94004 In addition, Titze and others have done interesting work on sodium deposition in tissues where it may also be a source for systemic inflammation.https://pubmed.ncbi.nlm.nih.gov/28154199/ Jens Titze talking about salt, water, thirsting a TEDx talk. https://www.youtube.com/watch?v=jQQPBmnIuCY A discussion/debate of the overfill vs. underfill theory of edema in the nephrotic syndrome (hint- overfill theory triumphs) would be incomplete without a reference to congenital analbuminemia. This reference from Frontiers in Genetics explores the diagnosis, phenotype and molecular genetics and reveal that patients tend to have only mild edema but severe hyperlipidemia. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6478806/ The finding that proteinuria can directly lead to sodium retention based on a study when puromycin aminoglycoside induced proteinuria of one kidney lead to sodium retention by that kidney which was localized to the distal nephron. https://www.ncbi.nlm.nih.gov/pmc/