Acta Physiol Scand 2000, 168, 687-690 Author index \guerre, S. Martin, C.] asellas, rp: See Moore, | ie \kivama, T Takauchi, Y. asellas, D., Bouriquet, N. & Artuso, A. Nitric oxide and \lexander, B.T. Granger, |.P preglomerular vascular lesions in Lyon spontaneously \lexandrova, S. Salman, H hypertensive rats, 133 \ndreasen, D. Friis, U.G. haouloff, F. see Martin, C.L. \ndrews, F.M. Sandin, A. heng, H.-F. see Harris, R.C. AnsjOn, R. Pagani, M. 1, S.Y. see Navar, L.G. \peria, A. Holtbiack, 1 lark, A.D.H. see Clark, M.G. \rima, S. Ke y agura, IK. lark, M.G., Rattigan, S., Clerk, L.H., Vincent, M.A., \rsac, L. see Linossier, M.-T. Clark, A.D.H., Youd, J.M. & Newman, ].M.B. Nutritive \rtuso, A. 5 asellas, D. and non-nutritive blood flow: rest and exercise, 519 \ruldhas, M.M. lerk, L.H. see Clark, M.G. \shirova, O offman, T.M. see Schnermann, J. \ukland, K. onley, K.E., Orgwav, G.A. & Richardson, R.S. Deci phering the mysteries of myoglobin in striated muscle, Bangsbo, J. Muscle ox 623 and during in onvery, M.K. & Hancox, J.C. Na -Ca Baylis, ( rent from rabbit isolated atrioventricular nodal and Beilin, B. , ventricular myocytes compared using action potenti Bell, P.D., Mashburn and ramp waveforms, 393 ro iberg. ie SCE Gid6o, G. salt-sensitive Bergman, M I Ye Wit, C. see Boltz, S.-S Bernstein, R.D. I Ye Wit, C. see Pohl, Bessler, H. I Yenis, ¢ Linossier, M.-T. Bianchi, G. Fe i Yibona, G.F. Differentiation of vasoactive renal Birdsey, G.M., Leiper, j.M. & Vallance, P thetic nerve fibres, 195 localization of dimethylarginine dimethyl I Yimmeler, S Fisslthaler, B. overexpressed in an endothelial cell [ Yjaldetti, M. se Salman, H. Blantz, R.C., Satriano, |., Gabbai, F. I Yormois, D. s Linossier, M.-T. effects of arginine metabolites, 2 I Yuclos, M. see Martin, C.L. Blix, A.S. Nordgarden, U. Boltz, S.-S., Pieperhoff, $., De Wit, C. & Pohl, U. | dvinsson, L. see Hou, M. increases in transmural pressure reduce NO-m« isner, G.M. Ce Felder, R.A dilations in isolated resistance arteries of the | llinger, \. Moore, L.¢ . 113 llsworth, M.L. The red blood cel Bouriquet, N Casellas, D what is the evidence?, 551 Boushel, R. & Piantadosi, C.A. Near-infrared spect ndo, Y. Kohagura, K. for monitoring muscle ox genation, 615 rlinge, D Hou, M. Braam, B., Turkstra, E. & Koomans, H.A. Concert tions of renal endothelial and macula densa NO elder, R.A., Eisner, G.M. & Jose, P.A. D; Dopamine in the maintenance of extracellular fluid volume receptor signalling defect in spontaneous hypertension, Briggs, J.P. s Schnermann, J. 245 Brismar, H. see Holtback, U. errandi, M. & Bianchi, G. Genetic mechanisms under Brown, G.( Nitric oxide as a competitive inhibit hy the regulation of urinary sodium excretion and oxygen consumption in the mitochondrial respit arterial blood pressure: the role of adducin, 187 chain, 667 isslthaler, B., Dimmeler, S., Hermann, ( , Busse, R. & Brown, R. see Persson, A.E.G. Fleming, I. Phosphorylation an d activation of the en Budzikowski, A.S. s¢ Goligorsky, M.S. dothelial nitric oxide synthase by fluid shear stress, 81 Busse, R. Fisslthaler, B latebo, T. see Melsom, M.N latmark, T. Catecholamine biosynthesis and physiological albert, J.A.L. Oxygen tension and content in th regulation in neuroendocrine cells, 1 ulation of limb blood flow, 465 leming, I. see Fisslthaler, B. arey, R.M., Jin, X.-H., Wang, Z.-Q. & Siragy, H.M. N olkow, L.P. see Nordgarden, oxide: a physiological mediator of the type 2 (AT ortia, P. see Shen, W. angiotensin receptor, 65 riis, U.G., Jensen, B.L., Hansen, P.B., Andreasen, D. & ‘arlsson, O., Rosengren, B.-I. & Rippe, B. Effects Skott, O. Exocytosis and endocytosis in juxtaglomerular peritoneal hyaluronidase treatment on transperiti cells, 95 solute and fluid transport in the rat, 371 Fukunaga, T. see Kubo, K. \uthor index Gabbai, F. see Blantz, R.C. Ito, S. see Kohagura, K. Gay, J.-P. see Linossier, M.-T. Iwata, H. see Sugiura, H. Gebremedhin, D. see Harder, D.R. Geyssant, A. see Linossier, M.-T. Jacobsson, H. see Pagani, M. Gibala, M.J., Young, M.E. & Taegtmeyer, H. Anaplerosis Jayaraman, G. see Healy, D.P. ; of the citric acid cycle: role in energy metabolism of Jebcns, E. see Medbo, J.I. heart and skeletal muscle, 657 Jensen, B.L. see Friis, U.G. Gid6, G., Cronberg, T. & Wieloch, T. The effect of Jin, X.-H. see Carey, R.M. x — phenyl-tert-butyl nitrone (PBN) on free radical Jc msson, C. se Pagani, M. formation in transient focal ischaemia measured by J6quist, M. see Hansell, P. microdialysis and 3,4-dihydroxybenzoate formation, 277 Jose, P.A. see Felder, R.A. Gloe, ‘ Ya: Pohl, [ Joyner, M.J. & Halliwill, ].R. Neurogenic vasodilation in Goligorsky, M.S., Noiri, | Tsukahara, H., Budzikowski, human skeletal muscle: possible role in contraction \.S. & Li, H. A pivotal role of nitric oxide in endothelial induced hyperaemia, 481 cell dysfunction, 33 Gotz, K -H. see Kurtz, A. Kanehisa, H. see Kubo, K. Govindarajulu, P. see Sunil, N. Kaskel, F.J. see Moore, L.C. Granger, J.P. & \lexander, B.T. Abnormal pressure Kawakami, Y. see Kubo, K. natriuresis in hypertension: role of nitric oxide, 161 Kay, L. see Saks, V.A. Gross, S.S. see Lane, P. Kelly\ , Cot Blantz, R.( Gutierrez, \. a: Persson, A.E.G. Kindahl, H. see Soppela, P. Kohagura, K., Endo, Y., Ito, O., \rima, S., Omata, K. & Halliwill, J.R. see Joyner, M.J. Ito, S. Endogenous nitric oxide and epoxyeicosatrienoic Hamann, M. see Kurtz, A. acids modulate angiotensin II-induced constriction in Hancox, J.C. see Convery, M.K. the rabbit afferent arteriole, 107 Hanem, S. Medbo, J.I. Kone, B.C. Protein-protein interactions controlling nitric Hansell, P., Isaksson, B. &. JGquist, M. Renal dopamine oxide synthases and noradrenaline excretion during CNS-induced Kongas, O. see Saks, V.A. latriuresis in spontaneously hypertensive rats: influence Koomans, H.A. see Braam, B. of dietary sodium, 257 Kruse, M.S. see Holtbick, | Hansen, J., Sander, M. & Thomas, G.D. Metabolic mod Kubo, K., Kanehisa, H., Kawakami, Y. & Fukunaga, T. ulation of sympathetic vasoconstriction in exercising Elasticity of tendon structures of the lower limbs in skeletal muscle, 489 sprinters, 327 Hansen, P.B. see Friis, U.G. Kurkus, J. see Thorup, C. Harder, D.R., Roman, R.J. & Gebremedhin, D. Molecular Kurtz, A., Gotz, K -H., Hamann, M. & Sandner, P. Mode mechanisms controlling nutritive blood flow: role of of nitric oxide action on the renal vasculature, 41 cytochrome P450 enzymes, 543 Kiister, E. see Miihlbauer, B. Harris, R.C., Cheng, H.-F., Wang, J.-L., Zhang, M.-Z. & Mckanna, J.A. Interactions of the renin-angiotensin acour, J.-R. Linossier, M.-7 system and neuronal nitric oxide synthase in regulation ane, P. & Gross, $.S. The autoinhibitory control element of cyclooxygenase-2 in the macula densa, 47 and calmodulin conspire to provide physiological mod Healy, D.P., Jayaraman, G. & Ashirova, O. Chemical ulation of endothelial and neuronal nitric oxide synthase hypoxia-induced increases in dopamine D,, receptor activity, 53 mRNA in renal epithelial cells are mediated by nitric aarsson, S.A. see Pagani, M. oxide, 233 eiper, J.M. see Birdsey, G.M. Heiskari, U. see Soppela, P. 4, H. see Goligorsky, M.S. Hellsten, Y. see Radegran, G. 4, L. see Schafer, J.A. Hermann, C. see Fisslthaler, B. ind, F. see Pagani, M. Hintze, T.H. see Shen, W. Anossier, M.-T., Dormois, D., Arsac, L., Denis, C., Gay, Holtback, U., Kruse, M.S., Brismar, H. & Aperia, A. J.-P., Geyssant, A. & Lacour, J.-R. Effect of Intrarenal dopamine coordinates the effect of hyperoxia on aerobic and anaerobic performances antinatriuretic and natriuretic factors, 215 and muscle metabolism during maximal cycling exercise, Hoppeler, H. & Weibel, E.R. Structural and functional 403 limits for oxygen supply to muscles, 445 ju, R: See Persson, \.] GS. Hou, M., Pantev, E., MGller, S., Erlinge, D. & Edvinsson, okhandwala, M.F. & Hussain, T. Defective renal dopa L. Angiotensin II type 1 receptors stimulate protein mine D,-like receptor signal transduction in obese synthesis in human cardiac fibroblasts via a Ca>*-sen hypertensive rats, 251 sitive PKC-dependent tyrosine kinase pathway, 301 Lucas-Teixeira, V., Serrao, M.P. & Soares-Da-Silva, P. Hussain, T. see Lokhandwala, M.F. Effect of salt intake on jejunal dopamine, Na’, K \TPase activity and electrolyte transport, 22 5 Ichihara, A. see Navar, L.G. Luippold, G. see Miihlbauer, B. Imig, J.D. see Navar, L.G. Inaba, R. see Sugiura, H. Manier, G. see Martin, C.L. Isaksson, B. see Hansell, P. Marshall, J.M. Adenosine and muscle vasodilation in acute Ito, O. see Kohagura, K. systemic hypoxia, 561 Author index Martin, ¢ J . Duclos, M... \guerre, hy Mormede, vasodilators in the development of hypertension: NO Manier, G. & Ch iouloff, F. ( orticotropi and and dopamine, 19 serotonergic responses to acute stress with/wit Persson, A.E.G. see Thorup, ¢ prior exercise training in different rat strains, 4 Persson, A.E.G., Gutierrez, A., Pittner, J., Ring, A., Ol Mashburn, N. see Bell, P.D lerstam, A., Brown, R., Liu, R. & Thorup, C. Renal NO Mattson, D.L. & Wu, F. Cont production and the development of hypertension, 169 and renal sodium excret by nitric oxid f Persson, P.B. see Stauss, H.M. the renal medulla, 14! Piantadosi, C.A. see Boushel, R. Mckanna, J.A. Pieperhoff, S. see Boltz, S.-S Medbo, J.1., Han land, H. & Jel ye Piiper, |. Perfusion, diffusion, and their hetrogeneities \rterio-venous differences of blood acid-bas« imiting blood-tissue O> transfer mu} scle, 603 and plasma sodium caused by intense bicycling, Pittman, R.N. Oxygen supIptl y to contracting skeletal Melsom, M.N., Flatebo, icolaysen,G . N muscle at the microcirculatory level: diffusion vs efft tect ot matchingo f | convention, 593 perfusion and ventilation in awake sheep, 3( Pittner, |. see Persson, A.E.G. Mirbod, S.M. s I Schnermann, J. Moller, S. Hou, ohl, U. Boltz Moore, L.C., Thorup, C., inger, A.., ne Pohl, U., De Wit, C. & Gloe, T. Lar; Casellas, D |. Advanced glycosylat control of blood flow: rol end-products and dependent va atior dilation, 505 ifferent art Mormede, Morsing, P. rup, exercise-induced human Mr IWKa, ta 4 575 ] Rasmussen, | I receptors in the rat kidney: r n physiolog Rasmussen, U.F. & Rasmussen, H.N. Human skeleta pathophysiolog ) mt mitochondrial capacity, 473 Murrant, C.l : rk, M.G. hardson, R.S. Conley, K.I contraction, 531 ng, A. Persson, A.E.G Nadeau, J. Naftz, B Harder, D.R. dependent hypertensior 9 ysengren, B.-I. ( irisson, Newman, ].M Nicola Ss Kongas, O., Vendel Nieminen phx sphe creantin Nilsson, din, n hondrial respi Nishida, Sugiura, ilman, H., Bergman Nishimura, M., Takahashi, oshimura, M. R Beilin, B. & Dya nitric ] a 7 wr ] ; ‘ hers ten _ | nh . 7 tic activ. ity Noddel Nori, | Nordgarden, th1 e d}i ra ecti1o n intravertebral vein ing simulated Hansen, \ndrews, Ochoa, M nervous excitati Ollerstam, A Ollerstam, A Omata, K Orgway, G.A. Paccione, ]. see Moore, Pagani, M., Ansj6n, R., Lind, F., Uusijarvi, J., S nine and vasopressin-dependent Jonsson, C., Salmaso, D., Jacobsson, H. & Lars S Schmidt, R.]. Xiao, S. Effects of acute hyp|o baric hyp| oxia on reg:i ona Schnermann, J., Travnor, T., Pohl, H., ° blood flow distribution: a Single Photon Emiss Coftman, T.M. & Briggs, ].P. Vasoconstrictor r Computed Tomography study in humans, 3 in thromboxane receptor knockout mice Pantev, E. see Hou, M. mneerr ular feedback and ureteral obstruction, Persson, A.E.G. Introduction to the Fourth Act SeC gal, S.S. Integration of blood it flfl ow contro Physiologica Scandinavica International Symp« nuscle: kev role of feed arteries, 511 ] 690 \uthor index Serrao, M.P. see Lucas-Teixeira, V. Thorup, C., Kurkus, J., Morsing, P., Ollerstam, A. & Shen, W., Xu, X., Ochoa, M., Zhao, G., Bernstein, R.D., Persson, A.E.G. Impaired effect by NO synthase Forfia, P. & Hintze, T.H. Endogenous nitric oxide in the inhibition on tubuloglomerular feedback in rats after control of skeletal muscle oxygen extraction during chronic renal denervation, 89 exercise, 675 Traynor, T. see Schnermann, J. Shennan, D.B. & Thomson, J. Further evidence for the Tsukahara, H. see Goligorsky, M.S. existence of a volume-activated taurine efflux pathway in Turkstra, E. see Braam, B. rat mammary tissue independent from volume-sensitive CI channels, 295 Unlap, M.T. see Bell, P.D. Siragy, H.M. see Carey, R.M. Uusijarvi,J . see Pagani, M. Skott, O. see Friis, U.G. Soares-Da-Silva, P. see Lucas-Teixeira, V. Vallance, P. see Birdsey, G.M. Soppela, P., Heiskari, U., Nieminen, M., Salminen, I., Van Hall, G. Lactate as a fuel for mitochondrial respira Sankari, S$. & Kindahl, H. The effects of a prolonged tion, 643 undernutrition on serum lipids and fatty acid composi Vendelin, M. see Saks, V.A. tion of reindeer calves during winter and spring, 337 Vincent, M.A. see Clark, M.G. Srinivasan, N. see Sunil, N. Stauss, H.M., Naftz, B., Mrowka, R. & Persson, P.B. Blood Wagner, P.D. Diffusive resistance to O> transport in pressure control in eNOS knock-out mice: comparison muscle, 609 with other species under NO blockade, 155 Walloe, L. see Nordgarden, U. Sugiura, H. see Sugiura, H. Wang, J.-L. see Harris, R.C. Sugiura, H., Sugiura, H., Nishida, H., Inaba, R., Mirbod, Wang, Z.-Q. see Carey, R.M. S.M. & Iwata, H. Immunomodulation by 8-week W eibel, E.R. See Hoppeler, H. voluntary exercise in mice, 413 Welsh, W J. see X ilcox, CS. Sumen, G. see Pagani, M. Wieloch, E SCE Gid6é, G. Sun, D. see Schafer, J.A. Wilcox, C.S. & Welsh, W.J. Interaction between nitric Sunil, N., Srinivasan, N., Aruldhas, M.M. & Govindarajulu, oxide and oxygen radicals in regulation of tubuloglo- P. Impact of oestradiol and progesterone on the glyco- merular feedback, 119 saminoglycans and their depolymerizing enzymes of the Wu, F. see Mattson, D.L. rat mammary gland, 385 Xiao, S., Schmidt, R.J. & Baylis, C. Plasma from ESRD Taegtmeyer, H. see Gibala, MJ. patients inhibits nitric oxide synthase activity in cultured Takahashi, H. see Nishimura, M. human and bovine endothelial cells, 175 Takauchi, Y., Yamazaki, T. & Akiyama, T. Tyramine- Xu, X. see Shen, W. induced endogenous noradrenaline efflux from én situ cardiac sympathetic nerve ending in cats, 287 Yamazaki, T. see Takauchi, Y. Tenstad, O. see Roald, A.B. Yoshimura, M. see Nishimura, M. Thomas, D.W. see Schnermann, J. Youd, J.M. see Clark, M.G. Thomas, G.D. see Hansen, J. Young, M.E. see Gibala, MJ. Thomson, J. see Shennan, D.B. Thorup, C. see Moore, L.C. Zhang, M.-Z. see Harris, R.C. Thorup, C. see Persson, A.E.G. Zhao, G. see Shen, W. 2000 Scandinavian Physiological Society Acta Physiol Scand 2000, 168, 69 Subject index Adre noceptors, 21 : ( AMP, 95, 245 7-OH-DPAT, 219 apillaries, 445, 593 \cetylcholine, 101, 113, 675 apillary, 531 \cid-base balance, 311 irbohydrates, 445 ACTH, 421 Cardiovascular physiology, 465 \dducin locus, 187 arrier-mediated outward transport, 287 \denosine, 561 atecholamine, 1 Adenosine 5’ triphosphate, 551 atechol-O-methyltransferase, 215 \drenaline, 1 wveolae, 33, 73 Afferent arteriole, 107, 119 wveolin, 27 \fferent arterioles, 133 ell proliferation, 21 \geing, 133 erebral blood flow, 543 \gmatine, 21 hondroitinase, 385 \lpha adrenoceptors, 489 itrulline formation, 139 \mino acid metabolism, 657 learance, 371 \mplification of nutrient delivery, 519 ompartmentation, 635 (Anatomy, 271 ompliance, 327 \ngiogenesis, 33 onnective tissue adipocytes, 519 Angiotensin I, 107, ; onnective tissue flow, 519 \ngiotensin, 65 Cortical collecting duct, 245 \ngiotension, 125 orticosterone, 421 \nimal model, 187 yclooxygenase, 47 ANP (atrial natriuretic peptide), 215 ytochrome P450, 543 \ntidiuresis, 351 \rcuate and interlobular arteries, 133 D1 like receptors, 215 \rginine, 21 Dj, receptor, 233 \rterial blood pressure, 155 D, receptor, 239 \rterial pressure, 161 DAHL, 219 Arterioles, 209, 593 Dermal microvascular endothelial cells, 175 \ssociation study, 187 Desmopressin, 351 \symmetric dimethylarginine (ADMA), 175 Diabetes mellitus, 101 \T, and AT> receptors, 301 Diabetic nephropathy, 101 A\T>, 65 Dilatation, 561 \TP synthesis, 473 Dimethylarginine dimethylaminohydrolase, 7 Atrioventricular nodal myocyte, 3 DNA polymorphism, 187 \tropine, 437 Dopamine D,; receptor, 219 Autoinhibitory domain, 53 Dopamine receptor subtypes, 239 \utoregulation, 125, 505 Dopamine receptors, 245 \V node, 393 Dopamine, 1, 215, 225, 233, 245, 251, 257 Doppler ultrasound flowmetry, 271 Basal ganglia, 377 Bethanechol, 437 fficiency of ATP utilization, 473 Biosynthesis, | Jectrophysiology, 95 Blood distribution, 271 ‘ndocytosis, 95 Blood flow regulation, 551 ndogenous nitric oxide synthase inhibitors, 175 > Blood flow velocity, | ‘ndothelial cells, 73 Blood flow, 457, 531, 575, 603, 615 ‘ndothelium, 27, 107 Blood pressure, 113 , 181 eNOS, 33 Blood, 311 .pitope tagging, 73 Body size scaling, 623 poxyeicosatrienoic acids, 107 Bovine aortic endothelial cells, 175 quine, 437 Bradykinin, 27, 65 rythrocyte, 551 Brain, 277 xercise hyperaemia, 575 xercise training, 421 Calcium exchanger, 209 ‘xercise, 311, 413, 445, 465, 481, 489, 603, 643 Calcium, 53 xhaustion, 403 Calmodulin, 27, 53 -xtracellular fluid volume, 125 cAMP production, 2232 9 -xtradural intravertebral vein, 271 2000 S 692 Subject index Facilitated diffusion, 623 Macrophage function, 413 Fatty acids, 337 Macrophages, 431 Flow-dependent dilation, 505 Macula densa, 89, 119 Focal ischaemia, 277 Magnetic resonance spectroscopy, 623 Free radicals, 277 Mammary gland, 385 Functional hypermia, 543 Mammary, 295 MAPKK, 301 G protein-related kinase, 245 Mathematical modeling, 635 Genetics, 187 Mean transit time, 457 GER, 139 Medial gastrocnemius, 327 Glomerular capillary endothelial cell, 175 Medullary thick ascending limb of Henle, 245 Glomerular filtration, 21 Mesangial cells, 209 Glutamate, 543 Metabolic control, 473 Glycogenolysis, 403 Metabolic regulation, 657 Glycosaminoglycans, 385 Methylarginines, 73 Cx ylo4, 73 Methyl-para-tyrosine, 287 Microcirculation, 505, 531, Haemodialysis, 181 Microdialysis, 287 Human cardiac fibroblasts, 301 Micropuncture, 201 Human genetics, 1 Microsphere embolism, 519 Human, 18 Mitochondria, 445, 635, 667 Humans, 481 Modelling, 603 Hyaluronan, 371 Morphology, 95 Hyaluronidase, 385 Motor cortex, 37 Hyperoxia, 403 Mouse, 413 Hypertension, 27 3, 139, 149, 155, 169, 187, 209, 215, Muscle capillary flow, 519 64 Wt RE So deesic) Peet8e Muscle contraction, 531 Hypobaric hypoxia, Muscle oxygenation, 615 Hypotension, 181 Muscle, 311 Hypothermia, 431 Myocardium, 657 Hypoxia, 233, 465, 561, Myocytes, 635 Myogenic, 505 Immobilization, 421 Myoglobin knockout mouse, 623 Immunohistochemistry, 2 Immunomodulatory effects, 413 Na! .-275:) Sh, 225 Inia-Cca, 393 Na’ ,H’ exchange, 311 Insulin, 437 Na /K' ATPase, 245 Interleukin-2 (IL-2), 413 Natriuresis, 215 Interstitium, 371 Near infrared, 615 Intracellular calcium, 113 Nephrogenesis, 47 Intracellular localization, 73 Nerves, 195 Isolated mitochondria, 473 Nitrate and nitrite, 175 Isotopes, 643 Nitrate, 181 Nitric oxide synthase, 119, 125, 139 Jeyunum, 225 Nitric oxide, 21, 27, 53, 65, 73, 89, 107, 149, 155, 169, 181, Juxtaglomerular apparatus, 95 233, 505, 667 Nitroxide, 119 K"-ATPase, 215 NO,, 175 Kidney failure, 175 Noradrenaline, 1, 257 Kidney, 27, 101, 195, 219, 251, 257 Knockout mice, 201 O>» diffusing capacity, 603 O» consumption, 603, 675 actate dehydrogenase, 643 QO, diffusion, 623 actate shuttle, 643 O> supply, 603 actate, 311 ( )besity, 251 aset-Doppler flowmetry, 149 Oestradiol, 385 -DOPA, 1, 225 Ornithine decarboxylase polyamines, 21 ewis rats, 421 Oxidation, 643 Apids, 337, 445 Oxidative phosphorylation, 623 L-NAME, 101, 361 Oxidative stress, 119 Localization, 219 Oxygen delivery, 457, 551 Low-renin hypertension, 239 Oxygen extraction, 457 2000 Scandinavian Physiological Society Subject inde. Oxygen transport, 593 Single Photon Emission Computed Tomography, 37 Oxygen uptake, 473 Skeletal muscle blood flow, 489, 675 Oxygen, 667 Skeletal muscle contraction, 489 Skeletal muscle oxygenation, 489 Pargyline, 287 Skeletal muscle, 445, 531, 561, 643 PBN, 277 S-nitroso-acetylpenicillamine, 119 PDZ domain, 27 Sodium excretion, 161, 219 Performance, 327 Sodium pump, 251 Peritoneal dialysis, 371 Sodium transport, 187 Permeability-surface area product, 371 Sodium, 209, 257, 311 Phagocytosis, 431 Sodium/hydrogen exchanger, 245 PKC, 301 Sodium-calcium exchange, 393 Plasma, 175, 311 Splenocyte proliferation, 413 Post-translational regulation, Sprint, 327, 403 Potassium, 311 Streptozotocin, 101 Power spectral anal Symmorphosis, 445 Progesterone, 385 rt) mpathetic nervous system, 489 Prostaglandins, 47 Sympathomimetic amine, 287 Protein kinase C, 239 Proximal tubule, 245 Taurine, 295 Pulmonary circulation, 361 Teasing, 437 Pyruvate carboxylation, 657 Tempol, 119 Pyruvate dehy« }l rogenase, 45 Petrahydrobiopterin, Pyruvate, 643 Thromboxane, 201 lranscriptional regulation, 1 Quadriceps muscle, 473 Transgenic animals, 1 Tricarboxylic acid cycle intermediates, 657 Rat, 219, 277 Tubuloglomerular feedback, 89, 125, 169, 201 Reactive oxygen species, 119 Tyrosine kinase, 301 Receptor, 65 Redox state, 403 Itrasonography, 327 Regional cerebral blood flow, 377 ndernutrition, 337 Reindeer, 337 reteral obstruction, 201 Renal autoregulation, 101 Renal blood flow, 351 Renal function, 125 ascular conductance, 575 Renal haemodynamic ascular endothelin-1, 13 Renal ischaemia, 233 Vascular injury, 133 Renal medulla, 14° ascular remodelling, 133 Renal nerves, 89 ascular resistance, 351, 575 Renal physiology, 169 asoconstriction, 201, 465 Renal sympathetic, 195 "ast dilation, 465, 481 Renin, 47, 95 ¥ asomotuon, 33 Reserpine, 287 ‘astus lateralis, 327 Respiration, 635, 667 Ventilation, 361 Respiratory rates, 473 Ventilation-perfusion ratio, 361 Resting muscle metabolism, 519 Ventricular myocyte, 393 RT-PCR, 301 Venules, 593 Ruminants, 337 Vessel culture, 113 Running, 675 VOomax,s 445 Volume-activated transport, 295 Salt (or Na’) reabsorption, 239 Salt intake, 225 Walking, 675 Serotonin, 421 Water permeability introduction, + 39 SHR, 219, 257, 421 Western analysis of NOS levels, 11 40) Signal transduction, 33, 245 WKY, 257