PappenheimerJ.R.Passage of molecules through capillary walls.Physiol Rev1953; 33: 387–423.
2.
GrotteG.Passage of dextran molecules across the blood-lymph barrier.Acta ChirScand1956; 211(Suppl): 1–84.
3.
RenkinE.M.Relation of capillary morphology to trans port of fluid and large molecules: A reviewActa Physiol Scand1979; 463(Suppl): 81–91.
4.
RippeB., HaraldssonB.Transport of macromolecules across microvascular walls: The two pores theory.Physiol Rev1994; 74: 163–219.
5.
RippeB., StelinG.Simulations of peritoneal solute transport during CAPD. Application of two-pore for malism.Kidney Int1989; 35: 1234–44.
6.
KarnovskyM.J.The ultrastructural basis of capillary permeability studied with peroxidase as a tracer.J Cell Bio11967; 35: 213–36.
7.
RippeB., HaraldssonB.How are macromolecules trans ported across the capillary wall?NIPS1987; 2: 135–8.
8.
FoxJ., GaleyF., WaylandH.Action of histamine on the mesenteric microvasculature.Microvasc Res1980; 19: 108–26.
9.
RippeB., StelinG., HaraldssonB.Computer simulations of peritoneal fluid transport in CAPD.Kidney Int1991; 40: 315–25.
10.
RippeB.A three pore model of peritoneal transport.Perit Dial Int1993; 13(Suppl 2): S35–8.
11.
NolphK.D., HanoJ.E., TeschanP.E.Peritoneal sodium transport during hypertonic peritoneal dialysis.Ann Intern Med1969; 70: 931–41.
12.
NolphK.D., TwardowskiZ.J., PopovichR.P., RubinJ.Equilibration of peritoneal dialysis solutions during long-dwell exchanges.J Lab Clin Med1979; 93: 246–56.
13.
HeimbürgerO, WaniewskiJ., WerynskiA., TranaeusA., LindholmB.Peritoneal transport in CAPD patients with permanent loss of ultrafiltration capacity.Kidney Int1990; 38: 495–506.
14.
MonquilM.C., ImholzA.L.T., StruijkD.G., KredietR.T.Does impaired transcellular water transport contribute to net ultrafiltration failure during CAPD?Perit Dial Int1995; 15: 42–8.
15.
PrestonG.M., CarrollT.P., GugginoW.B., AgreP.Appearance of water channels in Xenopus oocytes expressing red cell CHIP28 protein.Science1992; 256: 385–7.
16.
DempsterJ.A., Van HoekA.N., Van OsC.H.The quest for water channels.NIPS1992; 7: 172–6.
17.
AgreP., SasakiS., ChrispeelsM.J.Aquaporins: A family of waterchannel proteins.Am J Physiol1993; 265: F461.
18.
AgreP., PrestonG.M., SmithB.L.Aquaporin-CHIP: The archetypal molecular water channel.Am J Physiol1993; 265: F463–76.
19.
AgreP., SabooriA.M., AsimosA., SmithB.L.Purification and partial characterization of the Mr 30,000 intrinsic protein associated with the erythrocyte Rh(D) ant igen.J Biol Chem1987; 262: 17497–593.
20.
NielsenS., SmithB.L., ChristensenEl, AgreP.Distribution of the aquaporin CHIP in secretory and resorptive epithelia and capillary endothelia.Proc Natl Acad Sci U S A1993; 90: 7275–9.
21.
DeenP.M.T., DempsterJ.A., WieringaB., Van OsC.H.Isolation of a cDNA for rat CHIP28 water channel: High mRNA expression in kidney cortex and inner medulla.Biochem Biophys Res Commun1992; 188: 1267–73.
22.
KnepperM.A., RectorJrF.C.Urinary concentration and dilution. In: BrennerB.M., RectorF.C.Jr eds. The kidney (4th ed) Philadelphia: Saunders, 1991: 445–82.
23.
FushimiK., UchidaS., HaraY., HirataY., MarumoF., SasakiS.Cloning and expression of apical membrane water channel of rat kidney collecting tubule.Nature New Bio11993; 361: 549–52.
24.
SmithB.L., AgreP.Erythrocyte Mr 28,000 transmembrane protein exists as a multi-subunit oligomer of similar to channel proteins.J Biol Chem1991; 266: 6407–15.
25.
Van HoekA.N., LuthjensL.H., HomM.L., De JongM.D., DempsterJ.A., Van OsC.H.A30 kDa functional size for the erythrocyte water channel determined in situ by radiation inactivation.J Biol Chem1991; 266: 16633–5.
