Abstract
The overall adverse effects of tissue hypoxia are determined by the degree of fall in oxygen delivery to tissue and the complex changes that occur both in the tissue and in the microcirculation that supplies the tissue. The latter can be considered an adaptation to hypoxia. In this chapter, we will consider the biochemistry and physiology of tissue hypoxia and adaptation mechanisms.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Acker H: The meaning of tissue PO2 and local blood flow for the chemoreceptive process of the carotid body. Fed Proc 39: 2641–2647, 1980.
Acker H, Pietruschka: Meaning of the type I cell for the chemorecptive process. An electrophysiological study on cultured type I cells of the carotid body. In: Acker H, Fidone S, Pallot D, Eyzaquirre C, Lubbers D, Torrence RW (eds) Chemoreceptions in the carotid body. New York: Springer-Verlag, 1977, pp 9–98.
Atkinson DE: Adenine nucleotides as stoichiometric coupling agents in metabolism and as regulatory modifiers. In: Vogel HJ (ed) Metabolic pathways. New York: Academic Press, 1971, pp 1–21.
Bachelard HS, Lewis LD, Monten U, Siesjö BK: Mechanisms activating glycolysis in the brain in arterial hypoxia. J Neurochem 22: 395–401, 1974.
Bushford CL, Barlow CH, Chance B, Haselgrove J: The oxidation-reduction state of cytochrome oxidase in freeze-trapped gerbil brains. FEBS Lett 113: 78–80, 1980.
Berglund L, Hamble E: Kinetic properties of pig pyruvate kinases type A from kidney and type M from muscle. Arch Biol Chem Biophys 195: 347–361, 1979.
Berne RM: The role of adenosine in the regulation of coronary blood flow. Circ Res 47:807– 313, 1980.
Berne RM, Foley DH, Watkinson WP, Miller WL, Winn HR, Rubio R: Role of adenosine as a mediator of metabolic vasodilation in the heart and brain: a brief overview and update. Physiological and regulatory functions of adenosine and adenine nucleotides. In: Baer HP, Drummond GI (eds) New York: Raven, 1979, pp 117–126.
Bloxham DP, Lardy HA: Phophofructokinase. In: Boyer PD (ed) The enzymes, 3rd edn, vol 8, part A. New York: Academic Press, 1973, pp 239–278.
Bourdeau-Martini J, Honig CR: Control of coronary intercapillary distance: effect of arterial PCO2 and pH. Microvasc Res 6: 286–296, 1973.
Bourdeau-Martini J, Odoroff CL, Honig CR: Dual effect of oxygen on magnitude and uniformity of coronary intercapillary distance. Am J Physiol 226: 800–810, 1974.
Burger RM, Lowenstein JM: 5 nucleotidase from smooth muscle of small intestine and from brain, inhibition by nucleotides. Biochemistry 14: 2362–2366, 1975.
Burt CT, Cohen SM, Barany M: Analysis of intact tissue with 31 P NMR. Annu Rev Biophys Bioenerg 8: 1–25, 1979.
Burt TC, Glonek T, Barany M: Analysis of phosphate metabolites, the intracellular pH, and the state of adenosine triphosphate in intact muscle by phosphorus nuclear magnetic resonance. J Biol Chem 251: 2584–2591, 1976.
Chance B: Molecular basis of O2 affinity for cytochrome oxidase. In: Jobsis FF (ed) Oxygen and physiological function. Dallas: Professional Information Library, 1976, pp 14–15.
Chance B: Pyridine nucleotide as an indicator of the oxygen requirements for energy-linked functions of mitochondria. Circ Res [Suppl1] 38: 131–138, 1976.
Chance B, Barlow C, Nakase Y, Takeda H, Mayevsky A, Fischetti R, Graham N, Sorge J: Heterogeneity of oxygen delivery in normoxic and hypoxic states: a fluorometer study. Am J Physiol 235: H809–H820, 1978.
Chance B, Haselgrove J, Barlow C: Redox gradients in oxygen delivery to tissue. Adv Physiol Sci 25: 13–17, 1981.
Chance B, Maitra PK: Determination of the intracellular phosphate potential of ascites cells by reversed electron transfer. In: Wright B (ed) Control mechanisms in respiration and Fermentation. Ronald Press, 1963, pp 307–332.
Chance B, Oshnio N, Sugano T, Mayevsky A: Basic principles of tissue oxygen determination from mitochondrial signals. In: Bicher HI, Bruley DF (eds) Oxygen transport to tissue-I. New York: Plenum, 1974, pp 277–292.
Chance B, Quistorff B: Study of tissue oxygen gradients by single and multiple indicators. In: Silver IA, Erecinska M, Bicher HI (eds) Oxygen transport to tissue-III. New York: Plenum, 1978, pp 331–338.
Chance B, Saronio C, Leigh JS: Functional intermediates in the reaction of membrane-bound cytochrome oxidase with oxygen. J Biol Chem 250: 9226–9237, 1975.
Chance B, Schoener B, Oshino R, Itshak F, Nakase Y: Oxidation-reduction ratio studies of mitochondria in freeze-trapped samples. J Biol Chem 254: 4764–4771, 1979.
Chance B, Williams GR: The respiratory chain and oxidative phosphorylation. Adv Enzymol 17: 65–134, 1956.
Clark BJ, Coburn RF: Mean myoglobin PO2 during exercise and at maximal oxygen uptake. J Appl Physiol 39: 135–144, 1975.
Cobbold A, Folkow B, Kjellmer I, Mellander S: Nervous and local cherqical control of precapillary sphincters in skeletal muscle as measured by changes in filtration coefficient. Acta Physiol Scand 57: 180–192, 1963.
Coburn RF, Forman HJ: Carbon monoxide hypoxia. In: Handbook of respiration. Bethesda: American Physiological Society, (in press) 1982.
Coburn RF, Grubb B, Aronson RD: Effect of cyanide on oxygen tension-dependent mechanical tension in rabbit aorta. Circ Res 44: 368 – 378, 1979.
Coburn RF, Mayers LB: Myoglobin O2 tension determined from measurement of carboxy- myoglobin in skeletal muscle. Am J Physiol 220: 66–74, 1971.
Coburn RF, Pendleton M: Effects of norepinephrine on oxygenation of resting skeletal muscle. Am J Physiol 5: H307–313, 1979.
Coburn RF, Ploegmakers, Gondrie P, Abboud R: Myocardial myoglobin oxygen tension. Am J Physiol 224: 870–876, 1973.
Crisp DM, Pogson CI: Glycolytic and gluconeogenic enzyme activities in parenchymal and nonparenchymal cells from mouse liver. Biochem J 126: 1009–1023, 1972.
Davis JM: Synaptosomal tyrosine hydroxylation. Affinity for oxygen. J Neurochem 28:1043 -1050, 1977.
Davis JM, Carlson A: The effect of hypoxia on monoamine synthesis levels and metabolism in rat brain. J Neurochem 21: 783–790, 1973.
Dawson MJ, Gadian DG, Wilkie DR: Mechanical relaxation rate and metabolism studied in fatiguing muscle by phosphorus nuclear magnetic resonance. J Physiol 299: 464–484, 1980.
De Haan EJ, Croot GSP, Scholte HR, Tager JM, Wit-Peeters EM: Biochemistry of muscle mitchondria. In: Bourne GH (ed) The structure and function of muscle, 2nd edn, vol 3. New York: Academic Press, 1973, pp 417–469.
Diwan JJ, Lehrer PH: Effects on mitochondrial K flux of pH, K concentration, and N-ethyl maleimide. Membr Biochem 1: 43–60, 1978.
Dóra F, Chance B, Kovach AGB, Silver IA: Carbon monoxide-induced localized toxic anoxia in the brain cortex. J Appl Physiol 41: 480–488, 1976.
Duhm M: Effects of high altitude (arterial PO2) and displacements of the O2 dissociation curve of blood on peripheral oxygen extraction and PO2. In: Brendel W, Zink RA (eds) High altitude physiology and medicine. Topics in environmental physiology and medicine. Heidelberg: Springer, 1980.
Duran WN, Renkin EM: Oxygen consumption and blood flow in resting mammalian skeletal miscle. Am J Physiol 226: 173–177, 1974.
Erecinska M, Stubbs M, Miyata Y, Ditre CM, Wilson DF: Regulation of cellular metabolism by intracellular phosphate. Biochem Biophys Acta 462: 20–35, 1977.
Ernster L, Kuylensterna B: Outer membrane of mitochondria. In: Racker E (ed) Membrane of mitochondria and chloroplasts. New York: Van Nostrand Reinhold, 1970, pp 172–212.
Eyzaguirre C, Fidone SJ: Transduction mechanism in carotid body; glomus cells, putative neurotransmitters and nerve endings. Am J Physiol 239 [Cell Physiol 8]: C135–C152, 1980.
Eyzaguirre C, Fitzgerald RS, Lahiri S, Zapata P: Arterial chemoreceptors. In: Handbook of respiration. Bethesda: American Physiological Society press, (in press) 1982.
Fay FS: Guinea pig ductus arteriosus. I. Cellular and metabolic basis for oxygen sensitivity. Am J Physiol 221: 470–479, 1971.
Fay FS, Nair P, Whalen WJ: Mechanism of oxygen induced contraction of ductus arteriosus. In: Reivich M, Coburn RF, Lahiri S, Chance B (eds) Tissue hypoxia and ischemia. New York: Plenum, 1977, pp 123–134.
Fay FS, Jobsis FF: Guinea pig ductus arteriosus. III. Light absorption changes during response to O2. Am J Physiol 223: 588–595, 1972.
Fini C, Minelli A, Floridi A, Ipata PL: Effect of nucleoside di- and triphosphates and MgCC2 on the activity of 5’ nucleotidase from bull seminal plasma. Experientia 31: 399–401, 1975.
Fisher DB, Kaufman S: The inhibition of phenylalanine and tyrosine hydroxlases by high oxygen levels. J Neurochem 19: 1359–3165, 1972.
Fitch CD, Chevli R, Jellinek M: Phosp ho creatine does not inhibit rabbit muscle phosphofru- ctokinase or pyruvate kinase. J Biol Chem 254: 11357–11359, 1979.
Franke H, Barlow CH, Chance B: Fluorescence of pyridine nucleotide and flavoproteins as an indicator of substrate oxidation and oxygen demand of the isolated perfused rat kidney. J Biochem 12: 269–275, 1980.
Gadian DG, Hoult DI, Radda GK, Seeley PJ, Chance B, Barlow C: Phosphorus nuclear magnetic resonance studies on normoxic and ischemic cardiac tissue. Proc Natl Acad Sci USA 73: 4446–4448, 1976.
Gayeski TEJ, Honig CR: Myoglobin saturation and calculated PO2 in single cells of resting gracilis muscles. Adv Exp Med Biol 94: 77–94, 1977.
Ginsburg MD, Orela L, Wrobel-Kuhl K, Reivich M: Mitochondrial metabolism following bilateral cerebral ischemia in the gerbil. Ann Neurol 1: 519–527, 1977.
Gonzalez CY, Kwok Y, Gibb J, Fidone S: Effects of hypoxia on tyrosine hydroxylase activity in rat carotid body. J Neurochem 33: 713–719, 1979.
Granger HJ, Goodman AH, Granger DN: Role of resistance and exchange vessels in local microvascular control of skeletal muscle oxygenation in the dog. Circ Res 38: 379–385, 1976.
Hellstrand P, Johansson B, Norberg K: Mechanical electrical and biochemical effects of hypoxia and substrate removal on spontaneously active vascular smooth muscle. Acta Physiol Scand 100: 69–83, 1977.
Hempel FG, Jobsis FF, La Manna JL, Rosenthal MR, Saltzman HA: Oxidation of cerebral cytochrome aa3 by oxygen plus carbon dioxide at hyperbaric pressures. J Appl Physiol (Respir Environ Exerc Physiol) 43: 873–879, 1977.
Henderson J: Regulation of adenosine metabolism. In: Bauer HP, Drummond GI (eds) Physiological and regulatory functions of adenosine and adenine nucleotides. New York: Raven, 1979, pp 315–322.
Henquell L, Honig CR: Capillary spacing around coronary venules suggests that diffusion distance is controlled by local tissue PO2. Microvasc Res 15: 363–366, 1978.
Hossman KA, Keilhues P: Reversibility of ischemic brain damage. Arch Neurol 29: 375–384, 1975.
Itoh R, Usami C, Nishino T, Tsushima K: Kinetic properties of cytosol 5’ nucleotidase from chicken liver. Biochem Biophys Acta 526: 154–162, 1978.
Jobsis FF: What is a molecular oxygen sensor? What is a transduction process? In: Reivich M, Coburn R, Lahiri S, Chance B (eds) Hypoxia and ischemia. New York: Plenum, 1977, pp 3–18.
Jobsis FF, Keizer JH, La Manna JC, Rosenthal M: Reflective spectrophotometry of cytochrome aa3 in vivo. J Appl Physiol (Respir Environ Exerc Physiol) 43: 858–872, 1977.
Johannsson H, Siesjo BK: Cerebral blood flow and oxygen consumption in the rat in hypoxic hypoxia. Acta Physiol Scand 93: 269–276, 1975.
Jones DP, Mason HS: Gradients of O2 concentration in hepatocytes. J BiolChem 253:4874 -4880,1978.
Kety SS: Determinants of tissue oxygen tension. Fed Proc 16: 666–670, 1953.
Kleinert HD, Scales JL, Weiss HR: Effects of carbon monoxide or low oxygen gas mixture inhalation cn regional oxygenation, blood flow, and small vessel blood content of the rabbit heart. Pfluegers Arch Eur J Physiol 383: 105–111, 1980.
Kessler M, Hoper J, Lubbers DW, Ti S: Local factors affecting regulation of microflow, O2 uptake and energy metabolism. Adv Physiol Sci 25: 155–162, 1981.
Kontos HA, Wei EP, Raper AJ, Rosenblum WI, Navari RM, Patterson JLJr: Role of tissue hypoxia in local regulation of cerebral microcirculation. Am J Physiol 234: H582–H591, 1978.
Krogh A: The anatomy and physiology of capillaries. New York: Hafner, 1959.
Kovach AGB, Dora E: Redox state and vascular volume changes in the cat brain cortex during CBF autoregulation. Adv Physiol Sci 25: 145–154, 1981.
Krebs HA: The Pasteur effect and the relations between respiration and fermentation. Essays Biochem 8: 1–34, 1972.
Lahiri S, Mulligan E, Nishino T, Mokashi A, Davies RO: Relative responses of aortic body and carotid body chemoreceptors to carboxyhemoglobinemia. J Appl Physiol 50: 580–586, 1981.
LaNone KF, Bryla J, Bassett DJP: Energy-driven aspartate efflux from heart and liver mitochondria. J Biol Chem 249: 7514–7521, 1974.
Land JM, Booth RFG, Berger R, Clark JB: Development of mitochondrial energy metabolism in rat brain. Biochem J 164: 339–348, 1977.
Lardy HA, Tonsky PW, Johnson D: Antibiotics as tools for metabolic studies. IV. Comparative effectiveness of oligomycin A, B, and C and ratomycin as inhibitors of phosphoryl transfer reactions in mitochondria. Biochemistry 4: 552–560, 1965.
Lipmann F: Metabolic generation and utilization of phosphate bond energy. Adv Enzymol 1: 99–162, 1941.
Martini J, Honig CR: Direct measurement of intercapillary distance in beating rat heart in situ under various conditions of O2 supply. Microvasc Res 1: 244–256, 1969.
McLaughlin AC, Takeda H, Chance B: Rapid ATP assays in perfused mouse liver by 31P NMR. Proc Natl Sci USA 76: 5445–5449, 1979.
Mela L: Mechanism and physiological significance of calcium transport across mammalian mitochondrial membranes. Curr Top Memb Trans 9: 321–366, 1979.
Mela L, Goodwin CW, Miller LD: In vivo control of mitochondrial concentrations and activity by oxygen. Am J Physiol 231: 1811–1816, 1976.
Mela L, Goodwin CW, Miller LD: Correlation of mitochondrial cytochrome concentration and activity to oxygen availability in the newborn. Biochem Biophys Res Commun 64: 384–390, 1975.
Mela L: Mitochondrial function in cerebral ischemia and hypoxia. Comparison of inhibitory and adaptive responses. Neurol Res 1: 51–63, 1979.
Mills E, Jöbsis FF: Mitochondrial respiratory chain of carotid body and chemoreceptor response to changes in oxygen tension. J Neurophysiol 35: 405–428, 1972.
Mulligan E, Lahiri S, Storey BT: Carotid body O2 chemoreception and mitochondrial oxidative phosphorylation. J Appl Physiol (Respir Environ Exerc Physiol) 51: 438–446, 1981.
Myers WW, Honig CR: Number and distribution of capillaries as determinants of myocardial oxygen tension. Am J Physiol 207: 653–660, 1964.
Nayler WG, Poole-Wilson PA, Williams A: Hypoxia and calcium. J MolCell Cardiol 11:683– 706, 1979.
Needleman P, Key SL, Isakson PC, Kulkarni PS: Relationship between oxygen tension, coronary vasodilation and prostaglandin biosynthesis in the isolated rabbit heart. Prostaglandins 9: 123–134, 1975.
Newby AC: Role of adenosine deaminase, ecto-(5″ nucleotidase) and ecto- (non-specific phosphatase) in cyanide-induced adenosine monophosphate catabolism in rat polymorphonuclear leucocytes. Biochem J 186: 907–918, 1980.
Newby-Schmidt B, Roberts RJ, Bhatnager RK: Regional effects of carbon monoxide and hypoxia on catecholamines in the rat brain. Neurotoxicology 1: 533–540, 1980.
Nischiki K, Erecinska M, Wilson DF: Effect of amytal on metabolism of perfused rat heart: relationship between glycolysis and oxidative phosphorylation. Am J Physiol 237:C221- C230, 1979.
Nishiki K, Erecinska M, Wilson DF: Energy relationships between cytosolic metabolism and mitochondrial respiration in rat heart. Am J Physiol 234: C73–C81, 1978.
Nishiki K, Erecinska M, Wilson DF, Cooper S: Evaluation of oxidative phosphorylation in hearts from euthyroid, hypothyroid, and hyperthyroid rats. Am J Physiol 235:C212- C219, 1978.
Norberg K, Siesjo BK: Cerebral metabolism in hypoxia. I. Pattern of activation of glycolysis: a re-evaluation. Brain Res 86: 31–44, 1975.
Nordstron CH, Rehncrona S, Siesjo BK: Reconstitution of cerebral energy state after complete and incomplete ischemica of 30 min. duration. Acta Physiol Scand 97: 270–272, 1976.
95.0ntko JA: Genesis of liver mitochondria in the neonatal rat. Life Sci 5: 817–825, 1966.
Oshino N, Jamieson D, Chance B: The properties of hydrogen peroxide production under hyperbaric and hypoxia conditions of perfused rat liver. Biochem J 146: 53–60, 1975.
Oshino N, Sugano T, Oshino R, Chance B: The redox behavior of mitochondrial cytochrome oxidase during aerobioanaerobic transition and its relation to ATP hydrolysis. Biochim Biophys Acta 14: 201–214, 1974.
Park CD, Mela R, Wharton R, Reilly J, Fishbein P, Aberdeen E: Cardiac mitochondrial activity in acute and chronic cyanosis. J Surg Res 14: 139–146, 1973.
Pilkis SJ, El-Maghrabi MR, Pilkis J, Claus TH, Cumming DA: Fructose 2, 6-biphosphate. A new activator of phosphofructokinase. J Biol Chem 256: 3171–3174, 1981.
Pilkis SJ, El-Maghrabi MR, Pilkis J, Claus T: Inhibition of fructose 1, 6-biphosphatase by fructose 2, 6-biphosphate. J BiolChem 256: 3619–3622, 1981.
Pittman RN, Quinn JV: A physicochemical model of adenosine’s role in hypoxic relaxation of isolated vascular smooth muscle. Microvasc Res 17: S37, 1979.
Podgorski GT, Longmuir IS, Knopp JA, Benson DM: Use of an encapsulated fluorescent probe to measure intracellular PO2. J Cell Physiol 107: 329–333, 1981.
Poel WE: Effect of anoxic anoxia on myoglobin concentration in striated muscle. Am J Physiol 156: 44–51, 1949.
Quistorff B, Chance B: Two and three dimensional analysis on brain oxygen delivery. In: Jobsis FF (ed) Oxygen and physiological function. Dallas: Professional Information Library, 1976, pp 100–110.
Rehncrona S, Mela L, Chance B: Cerebral energy state, mitochondrial function, and redox state measurements in transient ischemia. Fed Proc 38: 2489–2492, 1979.
Rehncrona S, Mela L, Siesjo BK: Recovery of brain mitochondrial function in the rat after complete and incomplete cerebral ischemia. Stroke 10: 437–446, 1979.
Renkin EM, Rosell S: The influence of sympathetic adrenergic vasoconstrictor nerves on transport of diffusible solute from blood to tissues in skeletal muscle. Acta Physiol Scand 54: 223–240, 1962.
Riggs TE, Shafer AW, Guenther CA: Acute changes in oxyhemoglobin affinity: effect on oxygen transport and utilization. J Clin Invest 52:2660- 2663, 1973.
Roulet MJ, Coburn RF: Oxygen-induced contraction in the guinea pig neonatal ductus arteriosus. Circ Res 49: 897–1002, 1981.
Rubio R, Belardinelli L, Thompson CI, Berne RM: Cardiac adenosine: electrophysiological effects, possible significance in cell function and mechanisms controlling its release. In: Bauer HP, Drummond GI (eds) Physiological and regulatory functions of adenosine and adenine nucleotides. New York: Raven, 1979, pp 167–182.
Rubio R, Berne RM: Release of adenosine by the normal myocardium in dogs and its relationship to the regulation of coronary resistance. Circ Res 225: 407–415, 1969.
Rubio R, Berne RM, Dobson JG Jr: Sites of adenosine production in cardiac and skeletal muscle. Am J Physiol 225: 938–958, 1973.
Rubio R, Wiedmeier VT, Berne RM: Relationship between coronary flow and adenosine production and release. J Mol Cell Cardiol 6: 561–566, 1974.
Scarpa A, Brinley FJ: In situ measurements of free cytosolic magnesium ions. Fed Proc 40: 2626–2652, 1981.
Schrader J, Schutz W: Sites of adenosine production in the hypoxic heart. Fed Proc 38: 1037, 1979.
Schultz JS, Goddard JD, Suchdeo SR: Facilitated transport via carrier-mediated diffusion in membranes. Part I. Mechanistic aspects, experimental systems and characteristic regimes. A I Chi J 20: 417–445, 1974.
Shepherd AP: Intestinal O2 consumption and 86Rb extraction during arterial hypoxia. Am J Physiol 234: E248–E251, 1978.
Sies H: Peroxisomal enzymes and oxygen metabolism in liver. In: Reivich M. Coburn R, Lahiri S, Chance B (eds) Tissue hypoxia and ischemia. New York: Plenum, 1977, pp 51–66.
Sies H: Oxygen gradients during hypoxic steady states in liver. Urate oxidase and cytochrome oxidase as intracellular O2 indicators. Hoppe Seylers Z Physiol Chem 358:1O21-1032, 1977.
Sies H: Cytochrome oxidase and urate oxidase as intracellular O2 indicators in studies of O2 gradients during hypoxia in liver. In: Silver IA, Erecinska M, Bicher HI (eds) Oxygen transport to tissue -III. New York: Plenum, 1978, pp 561–566.
Siesjo BK: Brain energy metabolism. New York: John Wiley and Sons, 1978.
Siliprandi N, Rugolo M, Siliprandi D, Toninello A, Zoccarato F: Interaction between calcium and phosphate eyeing in rat liver mitochondria and related cation movements. In: Quagliariello E (ed) Function and molecular aspects of biomembrane transport. Amsterdam: Elsevier/ North Holland, 1979, pp 147–155.
Siliprandi N, Rugolo M, Siliprandi D, Toninello A, Zoccarato F: Induction of Mg2+ efflux and Ca2+ cycling in rat liver mitochondria by inorganic phosphate and oxidizing agents. In: Lee CP, Schatz G, Ernster L, Membrane bioenergetics. Reading MA: Addison-Wesley, 1979, pp 533–545.
Sillau AH, Banchero N: Effect of hypoxia on the capillarity of guinea pig skeletal muscle. Proc Soc Exp Biol Med 160: 368–373, 1979.
Simon LM, Robin ED, Phillips JR, Acevedo J, Axline SG, Theodore J: Enzymatic basis for bioenergetic differences of alveolar versus peritoneal macrophages and enzyme regulation by molecular O2. J Clin Invest 50: 443–448, 1977.
Simon M, Robin ED, Raffin R, Theodore J, Douglass WHJ: Bioenergetic pattern of isolated type II pneumocytes in air and during hypoxia. J Clin Invest 61: 1232–1239, 1978.
Slater EC: Application of inhibitors and uncouplers for a study of oxidative phosphorylation. Methods Enzymol 10: 48–57, 1967.
Smith HE, Paige E: Ultrastructural changes in rabbit heart mitochondria during the perinatal period. Neonatal transition to aerobic metabolism. Dev Biol 57: 109–117, 1977.
Somlyo AP, Somlyo AV: Effects and subcellular distribution of magnesium in smooth and striated muscle. Fed Proc 40: 2667–2671, 1981.
Srere AJ, Brister NW, Anthony A: Microsphere measurement of myocardial capillary bed in hypoxic rats. Experientia 36: 842–843, 1980.
Stainsly WN, Otis AB: Blood flow, blood oxygen tension and O2 transport in skeletal muscle. Am J Physiol 206: 858–866, 1964.
Stalcup AS, Lipset JS, Woan JM, Leuenberger P, Mellins RB: Inhibition of angiotensin converting enzyme activity in cultured cells by hypoxia. J Clin Invest 63: 966–976, 1980.
Stanley KK, Edwards MR, Lubzio J: Subcellular distribution and movement of 5’ nucleotidase in rat cells. Biochem J 186: 59–69, 1980.
Starlinger H, Lubbers DW: Oxygen consumption of the isolated carotid body tissue (cat). Pfluegers Arch 366: 61–66, 1976.
Steenbergen C, Deleeuw G, Barlow C, Chance B, Williamson JR: Heterogeneity of the hypoxic state in perfused rat heart. Circ Res 41: 606–615, 1977.
Storey BT, Kayne FJ: Energy metabolism of spermatoza. V. The Emb den-Meyer ho f pathway of glycolysis: activities of pathway enzymes in hypotonically treated rabbit epididymal spermatozoa. Fertil Steril 26: 1257–1265, 1975.
Stuart BH, Chance B: NADH brain surface scanning and 3-D computer display. Brain Res 76: 473–479, 1974.
138.Suchdeo SR, Goddard JD, Schultz JS: An analysis of the competitive diffusion of O2 and CO through hemoglobin solutions. Adv Exp Med Biol 37: 951–961, 1973.
139.Sugano T, Oshino N, Chance B: Mitochondrial functions under hypoxic conditions. The steady states of cytochrome c reduction and of energy metabolism. Biochim Biophys Acta 347: 340–358, 1974.
Sullivan JM, AlpersJB: In vitro regulation of rat heart 5’ nucleotidase by adenine nucleotides and magnesium. J Biol Chem 246: 3057–3063, 1971.
Szadon P, Bairey N, Oparil S: Effect of acute hypoxia on pulmonary conversion of angiotensin I to angiotensin II in dogs. Circ Res 46: 221–226, 1980.
Tamura M, Oshino N, Chance B, Silver IA: Optical measurements of intracellular oxygen concentration of rat heart in vitro. Arch Biochem Biophys 191: 8–22, 1978.
Tamura M, Oshino N, Chance B: The myoglobin probed optical studies of myocardial energy metabolism. In: Silver IA, Erecinska M, Bicher HI (eds) Oxygen transport to tissue -III. New York: Plenum, 1978, pp 561–566.
Thews G: Implications to physiology and pathology of oxygen diffusion at the capillary level. In: Schade JP, McMenemey WH (eds) Selective vulnerability of the brain in hypoxia. Oxford: Blackwell, 1963, pp 27–35.
Thews G: The theory of oxygen transport and its application to gaseous exchange in the lung. In: Lubbers DW, Luft EC, Thews G, Witzleb E (eds) Oxygen transport in blood and tissue. Stuttgart: Georg Thieme, 1968, pp 1–20.
Thomas MF, Penney DG: Hematologic responses to carbon monoxide and altitude: a comparative study. J Appl Physiol (Respir Environ Exercise Physiol) 43: 364–369, 1977.
Van Den Berghe G, Van Pottelsberghe C, Hers H: A kinetic study of the soluble 5’-nucleotidase of rat liver. Biochem J 162: 611–616, 1977.
Van Shaftingen E, Jett M, Hue J, Hers HG: Control of liver 6-phosphofructokinase by fructose 2, 6-biphosphate and effectors. Proc Natl Acad Sci USA 78: 3483–3486, 1981.
Van Schaftingen E, Hers HG: Phosphofructokinase 2. The enzyme that forms fructase 2, 6-biphosphate from fructose 6-phosphate and ATP. Biochem Res Commun 101: 1078–1084, 1981.
Warshaw JB: Cellular energy metabolism during fetal development. IV Fatty acid activation, acyl transfer and fatty acid oxidation during development of the chick and the rat. Dev Biol 28: 537–544, 1972.
Weibel ER: Oxygen demand and the size of respiratory structures in mammals. In: Wood SC, Lenfant C (eds) Evolution of respiratory processes. A comparative approach. New York: Marcel Dekker, 1979, pp 289–340.
Whalen WJ, Nair P: Some factors affecting tissue PO2 in the carotid body. J Appl Physiol 39: 562–566, 1975.
Whalen WJ, Buerk D, Thuning C, Kanoy BE Jr, Duran WN: Tissue PO2, VO2, venous PO2 and perfusion pressure in resting dog gracilis muscle perfused at constant flow. Adv Exp Med Biol 75: 639–653, 1977.
White RR, Mela L, Bacalzo LV, Olofsson K, Miller LD: Hepatic ultrastructure in endotoxemia, hemorrhage, and hypoxia: emphasis on mitochondrial changes. Surgery 73: 524–534, 1973.
Wilks SS, Tomashefski JF, Clark RT Jr: Physiological effects of chronic exposure monoxide. J Appl Physiol 14: 305–310, 1959.
Williamson JR, Safer B, La None KF, Smith CM, Walatys E: Mitochondrial-cytosolic interactions in cardiac tissue: role of the malate-aspartate cycle in the removal of glycolytic NADH from the cytosol. In: Davies DD (ed) Proc Soc Exp Biol Symp no. 27. Cambridge: Cambridge University Press, 1973, pp 241–281.
Wilson DF, Owen C, Mela L, Wiener L: Control of mitochondrial respiration by the phosphate potential. Biochem Biophys Res Commun 53: 326–334.
Wittenberg BA, Wittenberg JB: Role of myoglobin in the oxygen supply to red skeletal muscle. J BiolChem 240: 9038–9043, 1975.
Wittenberg JB: Myoglobin facilitated diffusion: a role of myoglobin in O2 entry into muscle. Physiol Rev 50: 559–636, 1970.
Wood JD, Watson WJ, Decker AJ: The effect of hypoxia on brain gamma aminobutyric acid levels. J Neurochem 15: 603–608, 1968.
Wyman J: Facilitated diffusion and the possible role of myoglobin as a transport mechanism. J Biol Chem 241: 115–121, 1966.
Zoccarato F, Rugolo M, Siliprandi D, Siliprandi N: Correlated effluxes of adenine nucleotides, Mg2+ and Ca2+ induced in rat-liver mitochondria induced by external Ca2+ and phosphate. Eur J Biochem 114: 195–199, 1981.
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 1982 Springer Science+Business Media Dordrecht
About this chapter
Cite this chapter
Coburn, R.F., Storey, B.T. (1982). Tissue hypoxia. In: Prakash, O. (eds) Applied Physiology in Clinical Respiratory Care. Developments in Critical Care Medicine and Anaesthesiology, vol 1. Springer, Dordrecht. https://doi.org/10.1007/978-94-009-7567-5_29
Download citation
DOI: https://doi.org/10.1007/978-94-009-7567-5_29
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-009-7569-9
Online ISBN: 978-94-009-7567-5
eBook Packages: Springer Book Archive