Your search keyword '"Z. Szkutnik"' showing total 23 results

1. Characterization of age-dependent decline in spontaneous running performance in the heart failure Tgα

Author

J A, Zoladz, Z, Nieckarz, Z, Szkutnik, E, Pyza, S, Chlopicki, and J, Majerczak

Subjects

Heart Failure, Mice, Physical Conditioning, Animal, Animals, Heart, Mice, Transgenic

Abstract

In this study we characterize the impact of aging on the spontaneous running performance of the Tgα

Published

2021

2. Software filtering and online reconstruction in H1

Author

A. Campbell, R. Gerhards, J. Olsson, Z. Szkutnik, R. Prosi, P. Fuhrmann, and U. Kruner-Marquis

Subjects

Software, Data acquisition, Reduced instruction set computing, business.industry, Event (computing), Computer science, Detector, Filter (signal processing), HERA, business, Computer hardware, Event reconstruction

Abstract

In spring 1992, the H1 detector at the HERA electron proton collider at DESY came into operation. The high bunch crossing rate of 10 MHz and the total number of 270,000 electronic channels, are placing demanding requirements on the trigger, the data logging and event reconstruction. This note describes a software filtering, data logging and event reconstruction system for the H1 experiment. An event rate of typically 40 Hz (4 MB/s) is processed by a parallel array ("filter farm") of 34 MIPS R3000 RISC processors. Fast online event reconstruction and filtering algorithms reduce this rate to 5-8 Hz ( >

Published

2002

3. Change point in VCO2 during incremental exercise test: a new method for assessment of human exercise tolerance

Author

J A, Zoladz, Z, Szkutnik, J, Majerczak, and K, Duda

Subjects

Adult, Male, Exercise Test, Humans, Models, Theoretical, Exercise, Models, Biological

Abstract

The main purpose of this study was to present a new method to determine the level of power output (PO) at which VCO2 during incremental exercise test (IT) begins to rise non-linearly in relation to power output (PO) - the change point in VCO2 (CP-VCO2). Twenty-two healthy non-smoking men (mean +/- SD: age 22.0 +/- 0.9 years; body mass 74.5 +/- 7.5 kg; height 181 +/- 7 cm; VO2max 3.753 +/- 0.335 l min-1) performed an IT on a cycloergometer. The IT started at a PO of 30 W, followed by gradual increases of 30 W every 3 min. Antecubital venous blood samples were taken at the end of each step and analysed for plasma lactate concentration [La]pl, blood PO2, PCO2 [HCO3-]b and [H+]b. In the detection of the change-point VCO2 (CP-VCO2), a two-phase model was assumed for the 'third-minute-data' of each step of the test. In the first phase, a linear relationship between VCO2 and PO was assumed, whereas in the second, an additional increase in VCO2 was allowed, above the values expected from the linear model. The PO at which the first phase ends is called the change point in VCO2. The identification of the model consists of two steps: testing for the existence of the change point, and estimating its location. Both procedures are based on suitably normalized recursive residuals (see Zoladz et al. 1998a. Eur J Appl Physiol 78, 369-377). In the case of each of our subjects it was possible to detect the CP-VCO2 and the CP-VO2 as described in our model. The PO at the CP-VCO2 amounted to 134 +/- 42 W. The CP- VO2 was detected at 136 +/- 32 W, whereas the PO at the LT amounted to 128 +/- 30 W and corresponded to 49 +/- 11, 49 +/- 8 and 47 +/- 8.6% VO2max, respectively, for the CP-VCO2, CP-VO2 and the LT. The [La]pl at the CP-VCO2 (2.65 +/- 0.76 mmol L-1), at the CP-VO2 (2.53 +/- 0. 56 mmol L-1) and at the LT (2.25 +/- 0.49 mmol L-1) were already significantly higher (P0.01, Students t-test) than the value reached at rest (1.86 +/- 0.43 mmol L-1). Our study illustrates that the CP-VCO2 and the CP-VO2 occur at a very similar power output as the LT. We therefore postulate that the CP-VCO2 and the CP-VO2 be applied as an additional criterion to assess human exercise tolerance.

Published

1999

4. The tracking calorimeter and muon detectors of the H1 experiment at Hera

Author

L. N. Shtarkov, A. Panitch, G. Tappern, R. Nisius, Armen Vartapetian, P. S. Flower, R. Bernet, D. White, K. C. Hoeger, B. Morgan, H. Bergstein, S. D. Kolya, Th. Naumann, U. Bassler, J. Žáček, A. B. Lodge, P. Jovanovic, F. Linsel, J. P Dewulf, H. Novakova, K. Gabathuler, A. Buniatian, D. Wegener, W.J. Haynes, J. R. Smith, R. Herma, S. Schiek, H. Duhm, V. Milone, E. Gažo, J. Mock, Tim Greenshaw, A. Sirous, N.H. Cunliffe, F. Blouzon, Vincent Hedberg, G. Knies, A. Wegner, Paul Richard Newman, Grzegorz Nowak, Emmanuel Monnier, C. Jacobsson, L. R. West, S. Kermiche, Michael Schulz, J. M. Foster, P. Štefan, J-P. Meyer, W. von Schlippe, Leif J. Jönsson, E. Deffur, M. Lemler, T. Köhler, M. W. Krasny, Vladimir Andreev, J. Heatherington, H. Ziaeepour, E. Panaro, J. Kurzhöfer, T. Merz, M. Ibbotson, J. Duboc, B. Stella, D. Hammer, S. Kasarian, Leith Godfrey, P. Ribarics, V. Nagovizin, A. W. E. Dann, L. Laptin, S. Mani, R. Felst, J. Haack, G. Martin, S. Levonian, K. Stephens, H. P. Beck, J.M. Morton, P. Kostka, H. Greif, R. Eichler, I. O. Skillicorn, J.P. Lottin, H. Lohmander, Derek L. G. Hill, V. Efremenko, S. Eichenberger, H. B. Dreis, J. P. Kubenka, U. Gensch, J. H. Köhne, J. Huber, R. Kaschowitz, R. Bernier, D. Newton, K. Zuber, A. Lebedev, Stephen Burke, M. Eberle, J. Staeck, E. Peppel, D. Handschuh, M. Wagener, W. Hildesheim, J. Ferencei, Roland Horisberger, M. Colombo, M. Rietz, S. Aid, K. Flamm, D. Imbault, M. David, Murrough Landon, R.L. Chase, A. E. Wright, H. Krehbiel, A. Valkárová, A. Mavroidis, G. Kemmerling, V. Tchudakov, G. W. Noyes, G. Siegmon, A. Pieuchot, S. Mikocki, M. Seman, K. Rüter, S. Riess, F. Zomer, A. M. Goodall, H. T. Blume, F. Charles, R. Beyer, L. Del Buono, I. Sheviakov, E. Malinovski, M. Kuhlen, U. Dretzler, K. Hangarter, U. Kathage, E. Eisenhandler, D. Haidt, D. Breton, J. Moreels, J. Cvach, K. Thiele, C. Niebuhr, C. Gregory, S. Egli, P. Lanius, K. Gadow, A. Reboux, P. I. P. Kalmus, B. Laforge, Mikhail Danilov, D. Lewin, H. Steiner, Th. Wolff, R. Roosen, D. Kant, F. Moreau, J. Hladký, J. D. Dowell, Zhen Zhang, Y. Soloviev, H. Itterbeck, S. Peters, P. Van Mechelen, M. Charlet, M. Rudowicz, G. Heinzelmann, P E. Hatton, I. Abt, F. Ould-Saada, G. Buschhorn, H. I. Cronström, Z.Y. Feng, U. Lenhardt, U. Harder, V. Tchernyshov, H.-J. Küsel, P. Hill, Steve McMahon, Kerstin Borras, U. Krüger, J.F. Huppert, M. Kolander, Carl R. Brune, M. Barth, E. Gabathuler, J. David, J. Bán, F. Descamps, M. Fleischer, T. R. Ebert, A. Semenov, H. Shooshtari, A. Jacholkowska, J. Martyniak, S. Dagoret, C. A. Meyer, R. J. Thompson, Yves Sirois, H. U. Martyn, A. Busata, A. Fedotov, Günter Flügge, U. Seehausen, T. P. Yiou, U. Krüner-Marquis, M. Vecko, J. C. Biasci, I. W. Walker, I. R. Kenyon, T. Novák, D. Mercer, F. Sefkow, H. Spitzer, A. Gruber, H. Küster, G. Kantel, N. Lugetski, G. Bertrand-Coremans, M. C. Cousinou, K. Johannsen, M. Urban, V I. Shekelyan, R. Haydar, B. Fominykh, A. Leuschner, Christoph Grab, Nicolas Ellis, A. Rudge, P. Fuhrmann, J. Lipinski, C. Zeitnitz, E. Wünsch, K. Wacker, R. Steinberg, A. Nepeipivo, Christophe Royon, M. Korn, K. Ludwig, B. Liss, G. Falley, S. Masson, E. Barrelet, Dave Sankey, P. Burmeister, P. Dingus, F. Krivan, A. Usik, Ch. Ley, J. Feltesse, L. Criegee, G. Franke, A. De Roeck, F. Brasse, L. Goerlich, D. Gillespie, Richard E. Taylor, Michel Devel, B. Naroska, T. Jansen, Emmanuelle Perez, Winston Ko, G. Weber, Björn Lundberg, P. Hartz, V. Masbender, M. Kubantsev, J.F. Connolly, Max Klein, R. J. Ellison, L. Urban, U. Straumann, F. Dupont, C. Pascaud, G. D. Patel, H. Meyer, R. von Staa, S. Rusakov, L. Van Lancker, Dusan Bruncko, P. Nayman, W. Pimpl, Ch. Berger, F. Ferrarotto, H. Henschel, A. Gellrich, U. Berthon, F. Lamarche, T. Kurča, G. Rädel, J. Schütt, A. Drescher, N. Magnussen, Guenter Eckerlin, R. Vick, D.P. Johnson, M. Jaffre, J. E. Olsson, P. Jean, L. Gosset, H. Genzel, W. Fröchtenicht, S. A. Murray, W. Bartel, B. Koppitz, M. Hampel, B. Kuznik, J. Formánek, N. Sahlmann, E. Schuhmann, H. Brettel, P. A. Smirnov, K. Meier, C. Beigbeder, Ph. Huet, K. Tröger, C. Trenkel, G. Reinmuth, Wolfgang Scobel, D. Darvill, P. Biddulph, P. Binko, R. Ebbinghaus, J. Koch, L. Büngener, Ch. Pichler, D. Bederede, J. Martens, H. Laskus, M. Flieser, Kaori Maeshima, F. Kole, Martin Erdmann, Eckhart Fretwurst, J. Stier, J. V. Morris, D. A. Cragg, D. Newman-Coburn, Hermann Kolanoski, Jan Godlewski, M. A. Jabiol, G. Villet, S. Schleif, U. Obrock, J. Marks, F. Niebergall, V. Korbel, Pierre Marage, G. Schmidt, Y. Vazdik, D. Clarke, G. A. Beck, J. Garvey, F. W. Büsser, R B. Hopes, John A Coughlan, A. Coville, R. C. W. Henderson, U. Cornett, C. Vallée, Elzbieta Banas, Rosario Martín, P. Goritchev, A. Epifantsev, H. Quehl, A. M. Fomenko, U. Pein, K. Gamerdinger, Horst Oberlack, Vladimir Rusinov, L. Smolik, H. K. Nguyen, I. Herynek, P. Perrodo, Pavel Shatalov, W. Tribanek, J. Tutas, R. D. Appuhn, W. Braunschweig, M. Forbush, I. V. Gorelov, K. Müller, A. Schwind, R. Sell, S. Tapprogge, W.D. Dau, M. Vanderkelen, D. Lüers, J. D. Burger, Petr Zavada, P. Weissbach, E. Elsen, R. Prosi, Pavel Murin, V. Brisson, H. Grässler, Pavel Staroba, C. Arnault, B. Dulny, A. Courau, J. B. Dainton, C. Paulot, J. Spalek, I. Tichomirov, L.A. Womersley, Claire Bourdarios, R. Grässler, Ch. Coutures, W. Struczinski, Stephen Maxfield, J L. Mills, P. Verrecchia, P. Škvařil, C R. Hedgecock, D. Neyret, N. Huot, U. Siewert, R. L. Lander, H. Bärwolff, J. Stiewe, S. Palanque, A. Rostovtsev, Claus Kleinwort, J. Fent, M. Gennis, B W H. Edwards, V. Schröder, G. Van Beek, A. B. Clegg, Andrew Mehta, J. Riedlberger, H. H. Kaufmann, N. Gogitidze, M. Zimmer, C. Gruber, A. Patoux, M. Nyberg, J. Harjes, S. M. Robertson, A. Walther, W. Flauger, Jean-Francois Laporte, Laurent Favart, Z. Szkutnik, J. Turnau, M. Ruffer, G. Ernst, S. Orenstein, W. Zimmermann, B E. Wyborn, M. Steenbock, I. Giesgen, C. Dollfus, R. Bernard, P. Pailler, J. Ebert, B. Andrieu, A. Strowbridge, H. Hufnagel, Daniel Pitzl, K. Geske, J. Koll, Frank Raupach, K. Finke, S. Günther, S. K. Kotelnikov, L. Hajduk, N. Wulff, A. Perus, Ulrich Goerlach, P. Kasselmann, E. Evrard, Peter Loch, J. Gayler, C.D. Hilton, U. Buchner, G. Lindström, M. Turiot, A. Porrovecchio, B. Delcourt, U. Stösslein, M. Grewe, B. Montes, C. Leverenz, R. Marshall, Dirk Krücker, O. Hamon, V. Bidoli, P. Baranov, D.E. Baynham, V. Commichau, G. Cozzika, Peter Schleper, P. Röpnack, F. Eisele, A. Lindner, J. Janoth, Marc Besancon, A.S. Belousov, J.P. Phillips, Stefan Valkar, P. Truöl, F. Basti, H T. Phillips, Volker Blobel, C. Keuker, Hannes Jung, D. Schmidt, K. Rosenbauer, M. Haguenauer, Peter Schacht, G. C. Lopez, Rudolf Langkau, W. Schmitz, M. Savitski, E. Vogel, Gregorio Bernardi, V. Boudry, Anton Babaev, C. Thiebaux, A. Ducorps, J. Strachota, Jean Sacton, G. Thompson, A. Cyz, H. Riege, D. Düllmann, H. J. Behrend, J.C. Bizot, M. Goldberg, Peter Robmann, J. Šťastný, V. Riech, O. Dünger, M. Hapke, R. Gerhards, P. E. Reimer, Alan Campbell, E. M. Hanlon, J. Jeanjean, G. G. Winter, G. Grindhammer, P. Steffen, Jolanta Olszowska, D. Zarbock, H. P. Wellisch, T. Carli, K. Rauschnabel, Wolfgang Lange, E. Binder, E. Sanchez, D. Sole, S. Prell, I F. Fensome, S. Reinshagen, C. Kiesling, T. Kobler, R J. Day, K. Djiki, T. Külper, S. Karstensen, N. Schirm, M. Arpagaus, K. Rybicki, C. Schmidt, J. P. Sutton, W. Glasgow, Wolfram Erdmann, T. Ahmed, J. Meissner, D. Feeken, J.Y. Parey, S. Willard, H. Schmücker, M. Winde, J. P. Pharabod, L. Johnson, J.M. Baze, F. Martin, V. Lubimov, A. Hrisoho, Kerec, Hélène, Laboratoire de l'Accélérateur Linéaire (LAL), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Centre de Physique des Particules de Marseille (CPPM), Aix Marseille Université (AMU)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), H1, Laboratoire de l'Accélérateur Linéaire ( LAL ), Université Paris-Sud - Paris 11 ( UP11 ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Centre National de la Recherche Scientifique ( CNRS ), Centre de Physique des Particules de Marseille ( CPPM ), Centre National de la Recherche Scientifique ( CNRS ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Aix Marseille Université ( AMU ), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Elementary Particle Physics, and Vrije Universiteit Brussel

Subjects

Physics, Nuclear and High Energy Physics, Luminosity (scattering theory), Calorimeter (particle physics), [PHYS.HEXP] Physics [physics]/High Energy Physics - Experiment [hep-ex], Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, Detector, HERA, Tracking (particle physics), 7. Clean energy, 01 natural sciences, Nuclear physics, [ PHYS.HEXP ] Physics [physics]/High Energy Physics - Experiment [hep-ex], 0103 physical sciences, Calibration, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], High Energy Physics::Experiment, 010306 general physics, Instrumentation, Storage ring, Muon detector

Abstract

Technical aspects of the three major components of the H1 detector at the electron-proton storage ring HERA are described. This paper covers the detector status up to the end of 1994 when a major upgrading of some of its elements was undertaken. A description of the other elements of the detector and some performance figures from luminosity runs at HERA during 1993 and 1994 are given in a paper previously published in this journal.

Published

1997

5. The H1 detector at HERA

Author

I. Abt, T. Ahmed, S. Aid, V. Andreev, B. Andrieu, R.D. Appuhn, C. Arnault, M. Arpagaus, A. Babaev, H. Bärwolff, J. Bán, E. Banas, P. Baranov, E. Barrelet, W. Bartel, M. Barth, U. Bassler, F. Basti, D.E. Baynham, J.-M. Baze, G.A. Beck, H.P. Beck, D. Bederede, H.-J. Behrend, C. Beigbeder, A. Belousov, Ch. Berger, H. Bergstein, R. Bernard, G. Bernardi, R. Bernet, R. Bernier, U. Berthon, G. Bertrand-Coremans, M. Besançon, R. Beyer, J.-C. Biasci, P. Biddulph, V. Bidoli, E. Binder, P. Binko, J.-C. Bizot, V. Blobel, F. Blouzon, H. Blume, K. Borras, V. Boudry, C. Bourdarios, F. Brasse, W. Braunschweig, D. Breton, H. Brettel, V. Brisson, D. Bruncko, C. Brune, U. Buchner, L. Büngener, J. Bürger, F.W. Büsser, A. Buniatian, S. Burke, P. Burmeister, A. Busata, G. Buschhorn, A.J. Campbell, T. Carli, F. Charles, M. Charlet, R. Chase, D. Clarke, A.B. Clegg, M. Colombo, V. Commichau, J.F. Connolly, U. Cornett, J.A. Coughlan, A. Courau, M.-C. Cousinou, Ch. Coutures, A. Coville, G. Cozzika, D.A. Cragg, L. Criegee, H.I. Cronström, N.H. Cunliffe, J. Cvach, A. Cyz, S. Dagoret, J.B. Dainton, M. Danilov, A.W.E. Dann, D. Darvill, W.D. Dau, J. David, M. David, R.J. Day, E. Deffur, B. Delcourt, L. Del Buono, F. Descamps, M. Devel, J.P. Dewulf, A. De Roeck, P. Dingus, K. Djidi, C. Dollfus, J.D. Dowell, H.B. Dreis, A. Drescher, U. Dretzler, J. Duboc, A. Ducorps, D. Düllmann, O. Dünger, H. Duhm, B. Dulny, F. Dupont, R. Ebbinghaus, M. Eberle, J. Ebert, T.R. Ebert, G. Eckerlin, B.W.H. Edwards, V. Efremenko, S. Egli, S. Eichenberger, R. Eichler, F. Eisele, E. Eisenhandler, N.N. Ellis, R.J. Ellison, E. Elsen, A. Epifantsev, M. Erdmann, W. Erdmann, G. Ernst, E. Evrard, G. Falley, L. Favart, A. Fedotov, D. Feeken, R. Felst, J. Feltesse, Z.Y. Feng, I.F. Fensome, J. Fent, J. Ferencei, F. Ferrarotto, K. Finke, K. Flamm, W. Flauger, M. Fleischer, M. Flieser, P.S. Flower, G. Flügge, A. Fomenko, B. Fominykh, M. Forbush, J. Formánek, J.M. Foster, G. Franke, E. Fretwurst, W. Fröchtenicht, P. Fuhrmann, E. Gabathuler, K. Gabathuler, K. Gadow, K. Gamerdinger, J. Garvey, J. Gayler, E. Gažo, A. Gellrich, M. Gennis, U. Gensch, H. Genzel, R. Gerhards, K. Geske, I. Giesgen, D. Gillespie, W. Glasgow, L. Godfrey, J. Godlewski, U. Goerlach, L. Goerlich, N. Gogitidze, M. Goldberg, A.M. Goodall, I. Gorelov, P. Goritchev, L. Gosset, C. Grab, H. Grässler, R. Grässler, T. Greenshaw, C. Gregory, H. Greif, M. Grewe, G. Grindhammer, A. Gruber, C. Gruber, S. Günther, J. Haack, M. Haguenauer, D. Haidt, L. Hajduk, D. Hammer, O. Hamon, M. Hampel, D. Handschuh, K. Hangarter, E.M. Hanlon, M. Hapke, U. Harder, J. Harjes, P. Hartz, P.E. Hatton, R. Haydar, W.J. Haynes, J. Heatherington, V. Hedberg, C.R. Hedgecock, G. Heinzelmann, R.C.W. Henderson, H. Henschel, R. Herma, I. Herynek, W. Hildesheim, P. Hill, D.L. Hill, C.D. Hilton, J. Hladký, K.C. Hoeger, R.B. Hopes, R. Horisberger, A. Hrisoho, J. Huber, Ph. Huet, H. Hufnagel, N. Huot, J.-F. Huppert, M. Ibbotson, D. Imbault, H. Itterbeck, M.-A. Jabiol, A. Jacholkowska, C. Jacobsson, M. Jaffré, T. Jansen, P. Jean, J. Jeanjean, L. Jönsson, K. Johannsen, D.P. Johnson, L. Johnson, P. Jovanovic, H. Jung, P.I.P. Kalmus, D. Kant, G. Kantel, S. Karstensen, S. Kasarian, R. Kaschowitz, P. Kasselmann, U. Kathage, H.H. Kaufmann, G. Kemmerling, I.R. Kenyon, S. Kermiche, C. Keuker, C. Kiesling, M. Klein, C. Kleinwort, G. Knies, W. Ko, T. Kobler, J. Koch, T. Köhler, J. Köhne, M. Kolander, H. Kolanoski, F. Kole, J. Koll, S.D. Kolya, B. Koppitz, V. Korbel, M. Korn, P. Kostka, S.K. Kotelnikov, M.W. Krasny, H. Krehbiel, F. Krivan, D. Krücker, U. Krüger, U. Krüner-Marquis, M. Kubantsev, J.P. Kubenka, T. Külper, H.-J. Küsel, H. Küster, M. Kuhlen, T. Kurča, J. Kurzhöfer, B. Kuznik, B. Laforge, F. Lamarche, R. Lander, M.P.J. Landon, W. Lange, R. Langkau, P. Lanius, J.-F. Laporte, L. Laptin, H. Laskus, A. Lebedev, M. Lemler, U. Lenhardt, A. Leuschner, C. Leverenz, S. Levonian, D. Lewin, Ch. Ley, A. Lindner, G. Lindström, F. Linsel, J. Lipinski, B. Liss, P. Loch, A.B. Lodge, H. Lohmander, G.C. Lopez, J.-P. Lottin, V. Lubimov, K. Ludwig, D. Lüers, N. Lugetski, B. Lundberg, K. Maeshima, N. Magnussen, E. Malinovski, S. Mani, P. Marage, J. Marks, R. Marshall, J. Martens, F. Martin, G. Martin, R. Martin, H.-U. Martyn, J. Martyniak, V. Masbender, S. Masson, A. Mavroidis, S.J. Maxfield, S.J. McMahon, A. Mehta, K. Meier, J. Meissner, D. Mercer, T. Merz, C.A. Meyer, H. Meyer, J. Meyer, S. Mikocki, J.L. Mills, V. Milone, J. Möck, E. Monnier, B. Montés, F. Moreau, J. Moreels, B. Morgan, J.V. Morris, J.M. Morton, K. Müller, P. Murín, S.A. Murray, V. Nagovizin, B. Naroska, Th. Naumann, P. Nayman, A. Nepeipivo, P. Newman, D. Newman-Coburn, D. Newton, D. Neyret, H.K. Nguyen, F. Niebergall, C. Niebuhr, R. Nisius, T. Novák, H. Nováková, G. Nowak, G.W. Noyes, M. Nyberg, H. Oberlack, U. Obrock, J.E. Olsson, J. Olszowska, S. Orenstein, F. Ould-Saada, P. Pailler, S. Palanque, E. Panaro, A. Panitch, J.-Y. Parey, C. Pascaud, G.D. Patel, A. Patoux, C. Paulot, U. Pein, E. Peppel, E. Perez, P. Perrodo, A. Perus, S. Peters, J.-P. Pharabod, H.T. Phillips, J.P. Phillips, Ch. Pichler, A. Pieuchot, W. Pimpl, D. Pitzl, A. Porrovecchio, S. Prell, R. Prosi, H. Quehl, G. Rädel, F. Raupach, K. Rauschnabel, A. Reboux, P. Reimer, G. Reinmuth, S. Reinshagen, P. Ribarics, V. Riech, J. Riedlberger, H. Riege, S. Riess, M. Rietz, S.M. Robertson, P. Robmann, P. Röpnack, R. Roosen, K. Rosenbauer, A. Rostovtsev, C. Royon, A. Rudge, K. Rüter, M. Rudowicz, M. Ruffer, S. Rusakov, V. Rusinov, K. Rybicki, J. Sacton, N. Sahlmann, E. Sanchez, D.P.C. Sankey, M. Savitski, P. Schacht, S. Schiek, N. Schirm, S. Schleif, P. Schleper, W. von Schlippe, C. Schmidt, D. Schmidt, G. Schmidt, W. Schmitz, H. Schmücker, V. Schröder, J. Schütt, E. Schuhmann, M. Schulz, A. Schwind, W. Scobel, U. Seehausen, F. Sefkow, R. Sell, M. Seman, A. Semenov, P. Shatalov, V. Shekelyan, I. Sheviakov, H. Shooshtari, L.N. Shtarkov, G. Siegmon, U. Siewert, Y. Sirois, A. Sirous, I.O. Skillicorn, P. Škvařil, P. Smirnov, J.R. Smith, L. Smolik, D. Sole, Y. Soloviev, J. Špalek, H. Spitzer, R. von Staa, J. Staeck, P. Staroba, J. Šťastný, M. Steenbock, P. Štefan, P. Steffen, R. Steinberg, H. Steiner, B. Stella, K. Stephens, J. Stier, J. Stiewe, U. Stösslein, J. Strachota, U. Straumann, A. Strowbridge, W. Struczinski, J.P. Sutton, Z. Szkutnik, G. Tappern, S. Tapprogge, R.E. Taylor, V. Tchernyshov, V. Tchudakov, C. Thiebaux, K. Thiele, G. Thompson, R.J. Thompson, I. Tichomirov, C. Trenkel, W. Tribanek, K. Tröger, P. Truöl, M. Turiot, J. Turnau, J. Tutas, L. Urban, M. Urban, A. Usik, Š. Valkár, A. Valkárová, C. Vallée, G. Van Beek, M. Vanderkelen, L. Van Lancker, P. Van Mechelen, A. Vartapetian, Y. Vazdik, M. Vecko, P. Verrecchia, R. Vick, G. Villet, E. Vogel, K. Wacker, M. Wagener, I.W. Walker, A. Walther, G. Weber, D. Wegener, A. Wegner, P. Weissbach, H.P. Wellisch, L. West, D. White, S. Willard, M. Winde, G.-G. Winter, Th. Wolff, L.A. Womersley, A.E. Wright, E. Wünsch, N. Wulff, B.E. Wyborn, T.P. Yiou, J. Žáček, D. Zarbock, P. Závada, C. Zeitnitz, Z. Zhang, H. Ziaeepour, M. Zimmer, W. Zimmermann, F. Zomer, K. Zuber, Laboratoire de Physique Nucléaire et de Hautes Énergies ( LPNHE ), Université Pierre et Marie Curie - Paris 6 ( UPMC ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Université Paris Diderot - Paris 7 ( UPD7 ) -Centre National de la Recherche Scientifique ( CNRS ), Laboratoire de l'Accélérateur Linéaire ( LAL ), Université Paris-Sud - Paris 11 ( UP11 ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Centre National de la Recherche Scientifique ( CNRS ), Centre de Physique des Particules de Marseille ( CPPM ), Centre National de la Recherche Scientifique ( CNRS ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Aix Marseille Université ( AMU ), H1, Laboratoire de Physique Nucléaire et de Hautes Énergies (LPNHE), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de l'Accélérateur Linéaire (LAL), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Centre de Physique des Particules de Marseille (CPPM), Aix Marseille Université (AMU)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Pierre et Marie Curie - Paris 6 (UPMC), and Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)

Subjects

Physics, Nuclear and High Energy Physics, Particle physics, Luminosity (scattering theory), Calorimeter (particle physics), Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, Detector, HERA, 01 natural sciences, law.invention, Nuclear physics, Upgrade, Data acquisition, law, [ PHYS.HEXP ] Physics [physics]/High Energy Physics - Experiment [hep-ex], 0103 physical sciences, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], High Energy Physics::Experiment, 010306 general physics, Collider, Instrumentation, Storage ring

Abstract

General aspects of the H1 detector at the electron-proton storage ring HERA as well as technical descriptions of the magnet, luminosity system, trigger, slow-control, data acquisition and off-line data handling are given. The three major components of the detector, the tracking, calorimeter and muon detectors, will be described in a forthcoming article. The present paper describes the detector that was used from 1992 to the end of 1994. After this a major upgrade of some components was undertaken. Some performance figures from luminosity runs at HERA during 1993 and 1994 are given.

Published

1997

6. Exercise Training Decreases Nitrite Concentration in the Heart and Locomotory Muscles of Rats Without Changing the Muscle Nitrate Content.

Author

Majerczak J, Drzymala-Celichowska H, Grandys M, Kij A, Kus K, Celichowski J, Krysciak K, Molik WA BSc, Szkutnik Z, and Zoladz JA

Subjects

Rats, Animals, Nitrites, Nitric Oxide metabolism, Nitrogen Dioxide metabolism, Muscle, Skeletal metabolism, Exercise, Nitrite Reductases metabolism, Nitrates metabolism, Physical Conditioning, Animal

Abstract

Background: Skeletal muscles are postulated to be a potent regulator of systemic nitric oxide homeostasis. In this study, we aimed to evaluate the impact of physical training on the heart and skeletal muscle nitric oxide bioavailability (judged on the basis of intramuscular nitrite and nitrate) in rats., Methods and Results: Rats were trained on a treadmill for 8 weeks, performing mainly endurance running sessions with some sprinting runs. Muscle nitrite (NO 2 - ) and nitrate (NO 3 - ) concentrations were measured using a high-performance liquid chromatography-based method, while amino acids, pyruvate, lactate, and reduced and oxidized glutathione were determined using a liquid chromatography coupled with tandem mass spectrometry technique. The content of muscle nitrite reductases (electron transport chain proteins, myoglobin, and xanthine oxidase) was assessed by western immunoblotting. We found that 8 weeks of endurance training decreased basal NO 2 - in the locomotory muscles and in the heart, without changes in the basal NO 3 - . In the slow-twitch oxidative soleus muscle, the decrease in NO 2 - was already present after the first week of training, and the content of nitrite reductases remained unchanged throughout the entire period of training, except for the electron transport chain protein content, which increased no sooner than after 8 weeks of training., Conclusions: Muscle NO 2 - level, opposed to NO 3 - , decreases in the time course of training. This effect is rapid and already visible in the slow-oxidative soleus after the first week of training. The underlying mechanisms of training-induced muscle NO 2 - decrease may involve an increase in the oxidative stress, as well as metabolite changes related to an increased muscle anaerobic glycolytic activity contributing to (1) direct chemical reduction of NO 2 - or (2) activation of muscle nitrite reductases.

Published

2024

7. Body mass and V'O 2 at rest affect gross efficiency during moderate-intensity cycling in untrained young healthy men: correlations with V'O 2MAX .

Author

Zoladz JA, Zapart-Bukowska J, Grandys M, Szkutnik Z, Grassi B, and Majerczak J

Subjects

Adult, Humans, Male, Young Adult, Oxygen Consumption physiology, Body Size, Bicycling physiology

Abstract

Seventeen young healthy physically active males (age 23 ±3 years; body mass (BM) 72.5 ±7.9 kg; height 178 ±4 cm, (mean ±SD)), not specifically trained in cycling, participated in this study. The subjects performed two cycling incremental tests at the pedalling rate of 60 rev x min -1 . The first test, with the power output (PO) increases of 30 W every 3 min, was to determine the maximal oxygen uptake (V'O 2max ) and the power output (PO) at V'O 2max , while the second test (series of 6 minutes bouts of increasing intensity) was to determine energy expenditure (EE (V'O 2 )), gross efficiency (GE (V'O 2 /PO)) and delta efficiency (DE(ΔV'O 2 /DPO)) during sub-lactate threshold (LT) PO. V'O 2max was 3.79 ±0.40 L x min -1 and the PO at V'O 2max was 288 ±27 W. In order to calculate GE and DE the V'O 2 was expressed in W, by standard calculations. GE measured at 30 W, 60 W, 90 W and 120 W was 11.6 ±1.4%, 17.0 ±1.4%, 19.6 ±1.2% and 21.4 ±1.1%, respectively. DE was 29.8 ±1.9%. The subjects' BM (range 59-87 kg) was positively correlated with V'O 2 at rest (p<0.01) and with the intercept of the linear V'O 2 vs. PO relationship (p<0.01), whereas no correlation was found between BM and the slope of V'O 2 vs. PO. No correlation was found between BM and DE, whereas GE was negatively correlated with BM (p<0.01). GE was also negatively correlated with V'O 2max and the PO at V'O 2max (p<0.01). We conclude that: V'O 2 at rest affects GE during moderate-intensity cycling and GE negatively corelates with V'O 2max and the PO at V'O 2max in young healthy men.

Published

2023

8. Nitrite Concentration in the Striated Muscles Is Reversely Related to Myoglobin and Mitochondrial Proteins Content in Rats.

Author

Majerczak J, Kij A, Drzymala-Celichowska H, Kus K, Karasinski J, Nieckarz Z, Grandys M, Celichowski J, Szkutnik Z, Hendgen-Cotta UB, and Zoladz JA

Subjects

Animals, Hypoxia metabolism, Mitochondrial Proteins metabolism, Muscle, Skeletal metabolism, Nitric Oxide metabolism, Nitrogen Dioxide pharmacology, Rats, Myoglobin metabolism, Nitrites metabolism

Abstract

Skeletal muscles are an important reservoir of nitric oxide (NO • ) stored in the form of nitrite [NO 2 - ] and nitrate [NO 3 - ] (NO x ). Nitrite, which can be reduced to NO • under hypoxic and acidotic conditions, is considered a physiologically relevant, direct source of bioactive NO • . The aim of the present study was to determine the basal levels of NO x in striated muscles (including rat heart and locomotory muscles) with varied contents of tissue nitrite reductases, such as myoglobin and mitochondrial electron transport chain proteins (ETC-proteins). Muscle NO x was determined using a high-performance liquid chromatography-based method. Muscle proteins were evaluated using western-immunoblotting. We found that oxidative muscles with a higher content of ETC-proteins and myoglobin (such as the heart and slow-twitch locomotory muscles) have lower [NO 2 - ] compared to fast-twitch muscles with a lower content of those proteins. The muscle type had no observed effect on the [NO 3 - ]. Our results demonstrated that fast-twitch muscles possess greater potential to generate NO • via nitrite reduction than slow-twitch muscles and the heart. This property might be of special importance for fast skeletal muscles during strenuous exercise and/or hypoxia since it might support muscle blood flow via additional NO • provision (acidic/hypoxic vasodilation) and delay muscle fatigue.

Published

2022

9. Characterization of age-dependent decline in spontaneous running performance in the heart failure Tgα q *44 mice.

Author

Zoladz JA, Nieckarz Z, Szkutnik Z, Pyza E, Chlopicki S, and Majerczak J

Subjects

Animals, Heart, Mice, Mice, Transgenic, Heart Failure, Physical Conditioning, Animal

Abstract

In this study we characterize the impact of aging on the spontaneous running performance of the Tgα q *44 mice (transgenic murine model of chronic heart failure) as compared to the wild-type FVB mice. In 166 mice we have recorded the following parameters of their physical activities in the running wheels: the total distance covered during the experiment (D sum ), the maximal distance covered in single-effort (D max ), mean time spent on running per 24 h (T mean ), mean running speed (ν mean ), the maximum instantaneous speed of run (ν max ) and the number of efforts (i.e. the number of running events undertaken by the mice) during 54 days, in four age groups ~4, ~10, ~12 and ≥12.5 months of age. The level of spontaneous running performance of the FVB mice remained essentially unchanged, but a strong impact of aging in the Tgα q *44 mice on their running performance was found. Namely, the D sum , D max , T mean and ν mean in the Tgα q *44 mice at the age of ≥12.5 months decreased by ~50%, when compared to its level corresponding level at the age of ~4 months, with far lesser effect of aging on their V max . Surprisingly, the number of attempts to perform running by the Tgαq*44 mice at the age of 4 - 12 months remained essentially unchanged. This suggests that the exercise intolerance of the aging heart failure (HF) mice seems to be more dependent on deterioration of heart and muscles function linked to HF than on a possible ageing-related impairment of the 'willngness' to initiate running, generated by the central nervous system.

Published

2021

10. Age-Dependent Impairment in Endothelial Function and Arterial Stiffness in Former High Class Male Athletes Is No Different to That in Men With No History of Physical Training.

Author

Majerczak J, Grandys M, Frołow M, Szkutnik Z, Zakrzewska A, Niżankowski R, Duda K, Chlopicki S, and Zoladz JA

Subjects

Adolescent, Adult, Age Factors, Aged, Case-Control Studies, Endurance Training, Humans, Male, Middle Aged, Pulse Wave Analysis, Young Adult, Aging physiology, Athletes, Endothelium, Vascular physiopathology, Vascular Stiffness physiology, Vasodilation physiology

Abstract

Background Physical activity is generally considered to exert positive effects on the cardiovascular system in humans. However, surprisingly little is known about the delayed effect of professional physical training performed at a young age on endothelial function and arterial stiffness in aging athletes. The present study aimed to assess the impact of long-lasting professional physical training (endurance and sprint) performed at a young age on the endothelial function and arterial stiffness reported in older age in relation to glycocalyx injury, prostacyclin and nitric oxide production, inflammation, basal blood lipid profile, and glucose homeostasis. Methods and Results This study involved 94 male subjects with varied training backgrounds, including young athletes (mean age ∼25 years), older former high class athletes (mean age ∼60 years), and aged-matched untrained control groups. Aging increased arterial stiffness, as reflected by an enhancement in pulse wave velocity, augmentation index, and stiffness index ( P <10 -4 ), as well as decreased endothelial function, as judged by the attenuation of flow-mediated vasodilation (FMD) in the brachial artery ( P =0.03). Surprisingly, no effect of the training performed at a young age on endothelial function and arterial stiffness was observed in the former athletes. Moreover, no effect of training performed at a young age ( P >0.05) on blood lipid profile, markers of inflammation, and glycocalyx shedding were observed in the former athletes. Conclusions Our study clearly shows that aging, but not physical training history, represents the main contributing factor responsible for decline in endothelial function and increase in arterial stiffness in former athletes.

Published

2019

11. Adaptation of motor unit contractile properties in rat medial gastrocnemius to treadmill endurance training: Relationship to muscle mitochondrial biogenesis.

Author

Kryściak K, Majerczak J, Kryściak J, Łochyński D, Kaczmarek D, Drzymała-Celichowska H, Krutki P, Gawedzka A, Guzik M, Korostynski M, Szkutnik Z, Pyza E, Jarmuszkiewicz W, Zoladz JA, and Celichowski J

Subjects

Animals, DNA, Mitochondrial metabolism, Electron Transport Chain Complex Proteins metabolism, Exercise Test, GTP Phosphohydrolases metabolism, Gene Expression Regulation, Male, Membrane Proteins metabolism, Mitochondrial Proteins metabolism, Muscle Fatigue physiology, Organelle Biogenesis, Peroxisome Proliferator-Activated Receptor Gamma Coactivator 1-alpha metabolism, Physical Conditioning, Animal physiology, RNA, Messenger metabolism, Random Allocation, Rats, Wistar, Adaptation, Physiological physiology, Mitochondria metabolism, Muscle Contraction physiology, Muscle, Skeletal metabolism, Physical Endurance physiology, Running physiology

Abstract

This study aimed at investigating the effects of 2, 4 and 8 weeks of endurance training on the contractile properties of slow (S), fast fatigue resistant (FR) and fast fatigable (FF) motor units (MUs) in rat medial gastrocnemius (MG) in relation to the changes in muscle mitochondrial biogenesis. The properties of functionally isolated MUs were examined in vivo. Mitochondrial biogenesis was judged based on the changes in mitochondrial DNA copy number (mtDNA), the content of the electron transport chain (ETC) proteins and PGC-1α in the MG. Moreover, the markers of mitochondria remodeling mitofusins (Mfn1, Mfn2) and dynamin-like protein (Opa1) were studied using qPCR. A proportion of FR MUs increased from 37.9% to 50.8% and a proportion of FF units decreased from 44.7% to 26.6% after 8 weeks of training. The increased fatigue resistance, shortened twitch duration, and increased ability to potentiate force were found as early as after 2 weeks of endurance training, predominantly in FR MUs. Moreover, just after 2 weeks of the training an enhancement of the mitochondrial network remodeling was present as judged by an increase in expression of Mfn1, Opa1 and an increase in PGC-1α in the slow part of MG. Interestingly, no signs of intensification of mitochondrial biogenesis assessed by ETC proteins content and mtDNA in slow and fast parts of gastrocnemius were found at this stage of the training. Nevertheless, after 8 weeks of training an increase in the ETC protein content was observed, but mainly in the slow part of gastrocnemius. Concluding, the functional changes in MUs' contractile properties leading to the enhancement of muscle performance accompanied by an activation of signalling that controls the muscle mitochondrial network reorganisation and mitochondrial biogenesis belong to an early muscle adaptive responses that precede an increase in mitochondrial ETC protein content.

Published

2018

12. Effect of temperature on fatty acid metabolism in skeletal muscle mitochondria of untrained and endurance-trained rats.

Author

Zoladz JA, Koziel A, Broniarek I, Woyda-Ploszczyca AM, Ogrodna K, Majerczak J, Celichowski J, Szkutnik Z, and Jarmuszkiewicz W

Subjects

Animals, Male, Oxidation-Reduction, Rats, Rats, Wistar, Fatty Acids metabolism, Mitochondria, Muscle metabolism, Muscle, Skeletal metabolism, Physical Conditioning, Animal, Temperature

Abstract

We studied the effects of various assay temperatures, representing hypothermia (25°C), normothermia (35°C), and hyperthermia (42°C), on the oxidation of lipid-derived fuels in rat skeletal muscle mitochondria of untrained and endurance-trained rats. Adult 4-month-old male Wistar rats were assigned to a training group (rats trained on a treadmill for 8 weeks) or a sedentary control group. In skeletal muscle mitochondria of both control and trained rats, an increase in the assay temperature from 25°C to 42°C was accompanied by a consistent increase in the oxidation of palmitoylcarnitine and glycerol-3-phosphate. Moreover, endurance training increased mitochondrial capacity to oxidize the lipid-derived fuels at all studied temperatures. The endurance training-induced increase in mitochondrial capacity to oxidize fatty acids was accompanied by an enhancement of mitochondrial biogenesis, as shown by the elevated expression levels of Nrf2, PGC1α, and mitochondrial marker and by the elevated expression levels of mitochondrial proteins involved in fatty acid metabolism, such as fatty acid transporter CD36, carnitine palmitoyltransferase 1A (CPT1A), and acyl-CoA dehydrogenase (ACADS). We conclude that hyperthermia enhances but hypothermia attenuates the rate of the oxidation of fatty acids and glycerol-3-phosphate in rat skeletal muscle mitochondria isolated from both untrained and trained rats. Moreover, our results indicate that endurance training up-regulates mitochondrial biogenesis markers, lipid-sustained oxidative capacity, and CD36 and CPT1A proteins involved in fatty acid transport, possibly via PGC1α and Nrf2 signaling pathways.

Published

2017

13. Mechanisms of Attenuation of Pulmonary V'O2 Slow Component in Humans after Prolonged Endurance Training.

Author

Zoladz JA, Majerczak J, Grassi B, Szkutnik Z, Korostyński M, Gołda S, Grandys M, Jarmuszkiewicz W, Kilarski W, Karasinski J, and Korzeniewski B

Subjects

Blotting, Western, Computer Simulation, Exercise physiology, Exercise Test, Gene Expression, Heart Rate physiology, Humans, Lactates blood, Lung metabolism, Male, Models, Biological, Muscle Proteins metabolism, Oxidative Phosphorylation, Oxygen Consumption genetics, Physical Endurance genetics, Quadriceps Muscle metabolism, Reverse Transcriptase Polymerase Chain Reaction, Running physiology, Sarcoplasmic Reticulum Calcium-Transporting ATPases metabolism, Vascular Endothelial Growth Factor A genetics, Young Adult, Lung physiology, Oxygen Consumption physiology, Physical Endurance physiology, Quadriceps Muscle physiology

Abstract

In this study we have examined the effect of prolonged endurance training program on the pulmonary oxygen uptake (V'O2) kinetics during heavy-intensity cycling-exercise and its impact on maximal cycling and running performance. Twelve healthy, physically active men (mean±SD: age 22.33±1.44 years, V'O2peak 3198±458 mL ∙ min-1) performed an endurance training composed mainly of moderate-intensity cycling, lasting 20 weeks. Training resulted in a decrease (by ~5%, P = 0.027) in V'O2 during prior low-intensity exercise (20 W) and in shortening of τp of the V'O2 on-kinetics (30.1±5.9 s vs. 25.4±1.5 s, P = 0.007) during subsequent heavy-intensity cycling. This was accompanied by a decrease of the slow component of V'O2 on-kinetics by 49% (P = 0.001) and a decrease in the end-exercise V'O2 by ~5% (P = 0.005). An increase (P = 0.02) in the vascular endothelial growth factor receptor 2 mRNA level and a tendency (P = 0.06) to higher capillary-to-fiber ratio in the vastus lateralis muscle were found after training (n = 11). No significant effect of training on the V'O2peak was found (P = 0.12). However, the power output reached at the lactate threshold increased by 19% (P = 0.01). The power output obtained at the V'O2peak increased by 14% (P = 0.003) and the time of 1,500-m performance decreased by 5% (P = 0.001). Computer modeling of the skeletal muscle bioenergetic system suggests that the training-induced decrease in the slow component of V'O2 on-kinetics found in the present study is mainly caused by two factors: an intensification of the each-step activation (ESA) of oxidative phosphorylation (OXPHOS) complexes after training and decrease in the ''additional" ATP usage rising gradually during heavy-intensity exercise.

Published

2016

14. Mechanisms responsible for the acceleration of pulmonary V̇O2 on-kinetics in humans after prolonged endurance training.

Author

Zoladz JA, Grassi B, Majerczak J, Szkutnik Z, Korostyński M, Grandys M, Jarmuszkiewicz W, and Korzeniewski B

Subjects

Computer Simulation, DNA, Mitochondrial metabolism, Energy Metabolism, Gene Expression Regulation physiology, Humans, Lactic Acid blood, Male, Mitochondrial Proteins genetics, Mitochondrial Proteins metabolism, Models, Biological, Muscle, Skeletal metabolism, Myosin Heavy Chains chemistry, Myosin Heavy Chains metabolism, Oxygen Consumption physiology, Young Adult, Exercise physiology, Lung metabolism, Oxygen metabolism, Physical Endurance physiology

Abstract

The effect of prolonged endurance training on the pulmonary V̇O2 on- and off-kinetics in humans, in relation to muscle mitochondria biogenesis, is investigated. Eleven untrained physically active men (means±SD: age 22.4±1.5 years, V̇O2peak 3,187±479 ml/min) performed endurance cycling training (4 sessions per week) lasting 20 wk. Training shortened τp of the pulmonary V̇O2 on-kinetics during moderate-intensity cycling by ∼19% from 28.3±5.2 to 23.0±4.0 s (P=0.005). τp of the pulmonary V̇O2 off-kinetics decreased by ∼11% from 33.7±7.2 to 30.0±6.6 (P=0.02). Training increased (in vastus lateralis muscle) mitochondrial DNA copy number in relation to nuclear DNA (mtDNA/nDNA) (+53%) (P=0.014), maximal citrate synthase (CS) activity (+38%), and CS protein content (+38%) (P=0.004), whereas maximal cytochrome c oxidase (COX) activity after training tended to be only slightly (+5%) elevated (P=0.08). By applying to the experimental data, our computer model of oxidative phosphorylation (OXPHOS) and using metabolic control analysis, we argue that COX activity is a much better measure of OXPHOS intensity than CS activity. According to the model, in the present study a training-induced increase in OXPHOS activity accounted for about 0-10% of the decrease in τp of muscle and pulmonary V̇O2 for the on-transient, whereas the remaining 90-100% is caused by an increase in each-step parallel activation of OXPHOS., (Copyright © 2014 the American Physiological Society.)

Published

2014

15. Training-induced acceleration of O(2) uptake on-kinetics precedes muscle mitochondrial biogenesis in humans.

Author

Zoladz JA, Grassi B, Majerczak J, Szkutnik Z, Korostyński M, Karasiński J, Kilarski W, and Korzeniewski B

Subjects

Adult, Electron Transport Complex IV metabolism, Humans, Kinetics, Male, Muscle, Skeletal metabolism, Young Adult, Acceleration, Exercise physiology, Mitochondria, Muscle metabolism, Mitochondrial Turnover physiology, Oxygen metabolism, Oxygen Consumption physiology, Physical Endurance physiology

Abstract

The effects of 5 weeks of moderate-intensity endurance training on pulmonary oxygen uptake kinetics (V(O(2)) on-kinetics) were studied in 15 healthy men (mean ± SD: age 22.7 ± 1.8 years, body weight 76.4 ± 8.9 kg and maximal V(O(2)) 46.0 ± 3.7 ml kg(-1) min(-1)). Training caused a significant acceleration (P = 0.003) of V(O(2)) on-kinetics during moderate-intensity cycling (time constant of the 'primary' component 30.0 ± 6.6 versus 22.8 ± 5.6 s before and after training, respectively) and a significant decrease (P = 0.04) in the amplitude of the primary component (837 ± 351 versus 801 ± 330 ml min(-1)). No changes in myosin heavy chain distribution, muscle fibre capillarization, level of peroxisome proliferator-activated receptor γ coactivator 1α and other markers of mitochondrial biogenesis (mitochondrial DNA copy number, cytochrome c and cytochrome oxidase subunit I contents) in the vastus lateralis were found after training. A significant downregulation in the content of the sarcoplasmic reticulum ATPase 2 (SERCA2; P = 0.03) and a tendency towards a decrease in SERCA1 (P = 0.055) was found after training. The decrease in SERCA1 was positively correlated (P = 0.05) with the training-induced decrease in the gain of the V(O(2)) on-kinetics (ΔV(O(2)) at steady state/Δpower output). In the early stage of training, the acceleration in V(O(2)) on-kinetics during moderate-intensity cycling can occur without enhanced mitochondrial biogenesis or changes in muscle myosin heavy chain distribution and in muscle fibre capillarization. The training-induced decrease of the O(2) cost of cycling could be caused by the downregulation of SERCA pumps.

Published

2013

16. Isometric strength training lowers the O2 cost of cycling during moderate-intensity exercise.

Author

Zoladz JA, Szkutnik Z, Majerczak J, Grandys M, Duda K, and Grassi B

Subjects

Adult, Bicycling, Humans, Male, Exercise physiology, Isometric Contraction, Muscle Strength, Oxygen Consumption

Abstract

The effect of maximal voluntary isometric strength training of knee extensor muscles on pulmonary V'O(2) on-kinetics, the O(2) cost of cycling and peak oxygen uptake (V'O(2peak)) in humans was studied. Seven healthy males (mean ± SD, age 22.3 ± 2.0 years, body weight 75.0 ± 9.2 kg, V'O(2peak) 49.5 ± 3.8 ml kg(-1) min(-1)) performed maximal isometric strength training lasting 7 weeks (4 sessions per week). Force during maximal voluntary contraction (MVC) increased by 15 % (P < 0.001) after 1 week of training, and by 19 % (P < 0.001) after 7 weeks of training. This increase in MVC was accompanied by no significant changes in the time constant of the V'O(2) on-kinetics during 6 min of moderate and heavy cycling intensities. Strength training resulted in a significant decrease (by ~7 %; P < 0.02) in the amplitude of the fundamental component of the V'O(2) on-kinetics, and therefore in a lower O(2) cost of cycling during moderate cycling intensity. The amplitude of the slow component of V'O(2) on-kinetics during heavy cycling intensity did not change with training. Training had no effect on the V'O(2peak), whereas the maximal power output reached at V'O(2peak) was slightly but significantly increased (P < 0.05). Isometric strength training rapidly (i.e., after 1 week) decreases the O(2) cost of cycling during moderate-intensity exercise, whereas it does not affect the amplitude of the slow component of the V'O(2) on-kinetics during heavy-intensity exercise. Isometric strength training can have beneficial effects on performance during endurance events.

Published

2012

17. Endurance training decreases the non-linearity in the oxygen uptake-power output relationship in humans.

Author

Majerczak J, Korostynski M, Nieckarz Z, Szkutnik Z, Duda K, and Zoladz JA

Subjects

Ammonia blood, Biopsy, DNA, Mitochondrial metabolism, Humans, Ion Channels metabolism, Lactates metabolism, Male, Mitochondria, Muscle metabolism, Mitochondrial Proteins metabolism, Muscle, Skeletal pathology, Myosin Heavy Chains metabolism, Sarcoplasmic Reticulum Calcium-Transporting ATPases metabolism, Uncoupling Protein 3, Young Adult, Exercise physiology, Exercise Test, Muscle Strength physiology, Muscle, Skeletal metabolism, Oxygen Consumption physiology, Physical Endurance physiology

Abstract

In this study, we hypothesized that 5 weeks of cycling endurance training can decrease the magnitude of the non-proportional increase in oxygen uptake (V(O(2))) to power output relationship (V(O(2)) 'excess') at exercise intensities exceeding the lactate threshold (LT). Ten untrained, physically active men performed a bout of incremental cycling exercise until exhaustion before and after training. The mitochondrial DNA copy number, myosin heavy chain composition and content of uncoupling protein 3 and sarcoplasmic reticulum Ca(2+)-ATPases (SERCAs) were analysed in muscle biopsies taken from vastus lateralis before and after training. The training resulted in an enhancement of the power-generating capabilities at maximal oxygen uptake (V(O(2)max)) by ∼7% (P = 0.002) despite there being no changes in V(O(2)max) (P = 0.49). This effect was due to a considerable reduction in the magnitude of the V(O(2)) 'excess' (P < 0.05) above the LT. A decrease in plasma ammonia concentration was found during exercise after training (P < 0.05). A downregulation of SERCA2 in vastus lateralis (P = 0.006) was observed after training. No changes in myosin heavy chain composition, selected electron transport chain proteins, uncoupling protein 3 or the mitochondrial DNA copy number (P > 0.05) were found after training. We conclude that the training-induced increase in power-generating capabilities at V(O(2)max) was due to attenuation of the V(O(2)) 'excess' above the LT. This adaptive response seems to be related to the improvement of muscle metabolic stability, as judged by a lowering of plasma ammonia concentration. The enhancement of muscle metabolic stability after training could be caused by a decrease in ATP usage at a given power output owing to downregulation of SERCA2 pumps.

Published

2012

18. Effect of pedaling rates and myosin heavy chain composition in the vastus lateralis muscle on the power generating capability during incremental cycling in humans.

Author

Majerczak J, Szkutnik Z, Duda K, Komorowska M, Kolodziejski L, Karasinski J, and Zoladz JA

Subjects

Adult, Ammonia blood, Bicarbonates blood, Humans, Hydrogen-Ion Concentration, Lactic Acid blood, Male, Oxygen Consumption, Pulmonary Gas Exchange, Time Factors, Young Adult, Bicycling, Exercise, Muscle Contraction, Muscle Fatigue, Muscle Strength, Myosin Heavy Chains metabolism, Quadriceps Muscle metabolism

Abstract

In this study, we have determined power output reached at maximal oxygen uptake during incremental cycling exercise (P(I, max)) performed at low and at high pedaling rates in nineteen untrained men with various myosin heavy chain composition (MyHC) in the vastus lateralis muscle. On separate days, subjects performed two incremental exercise tests until exhaustion at 60 rev min(-1) and at 120 rev min(-1). In the studied group of subjects P(I, max) reached during cycling at 60 rev min(-1) was significantly higher (p=0.0001) than that at 120 rev min(-1) (287+/-29 vs. 215+/-42 W, respectively for 60 and 120 rev min(-1)). For further comparisons, two groups of subjects (n=6, each) were selected according to MyHC composition in the vastus lateralis muscle: group H with higher MyHC II content (56.8+/-2.79 %) and group L with lower MyHC II content in this muscle (28.6+/-5.8 %). P(I, max) reached during cycling performed at 60 rev min(-1) in group H was significantly lower than in group L (p=0.03). However, during cycling at 120 rev min(-1), there was no significant difference in P(I, max) reached by both groups of subjects (p=0.38). Moreover, oxygen uptake (VO(2)), blood hydrogen ion [H(+)], plasma lactate [La(-)] and ammonia [NH(3)] concentrations determined at the four highest power outputs completed during the incremental cycling performed at 60 as well as 120 rev min(-1), in the group H were significantly higher than in group L. We have concluded that during an incremental exercise performed at low pedaling rates the subjects with lower content of MyHC II in the vastus lateralis muscle possess greater power generating capabilities than the subjects with higher content of MyHC II. Surprisingly, at high pedaling rate, power generating capabilities in the subjects with higher MyHC II content in the vastus lateralis muscle did not differ from those found in the subjects with lower content of MyHC II in this muscle, despite higher blood [H(+)], [La(-)] and [NH(3)] concentrations. This indicates that at high pedaling rates the subjects with higher percentage of MyHC II in the vastus lateralis muscle perform relatively better than the subjects with lower percentage of MyHC II in this muscle.

Published

2008

19. Non-linear relationship between oxygen uptake and power output in the Astrand nomogram-old data revisited.

Author

Zoladz JA, Szkutnik Z, Majerczak J, Duda K, and Pedersen PK

Subjects

Female, Humans, Male, Exercise, Heart Rate, Oxygen Consumption physiology

Abstract

For the last decade there have been considerable discussion concerning the linearity / non-linearity of the oxygen uptake (V(O2)) - power output (W) relationship with strong experimental evidence of non-linearity provided mainly by breath-by-breath measurements. In this study, we attempted to answer the question whether the V(O2) - W relationship in the Astrand nomogram, as presented in the Textbook of Work Physiology, P.-O. Astrand et al. (2003), page 281, based on the Douglas bag method, is indeed linear, as stated by the authors before, or if a change point in V(O2), described by Zoladz et al. (1998) Eur J Appl Physiol 78: 369-377, can possibly be detected in those data. The V(O2) - W data were taken from the Astrand nomogram referenced above and from the Table 9.5 on page 282 in the same reference and tested for the presence of the change point in V(O2), using our two-phase model (see the reference above). In the first phase, a linear V(O2) - W relationship was assumed, whereas in the second one (above the so-called change point) an additional increase in V(O2) above the values expected from the linear model was allowed. It was found that in the data taken from the Astrand nomogram (data for men), as well as in the data taken from the Table 9.5, statistically significant change points in V(O2) were present at the power output of 150 W. The documentation of the presence of a change point in the V(O2) - W relationship in the Astrand data provides further evidence for the existence of a non-linearity in the V(O2) - W relationship in incremental exercise tests of humans, also in V(O2) data based upon the Douglas bag method.

Published

2007

20. High content of MYHC II in vastus lateralis is accompanied by higher VO2/power output ratio during moderate intensity cycling performed both at low and at high pedalling rates.

Author

Majerczak J, Szkutnik Z, Karasinski J, Duda K, Kolodziejski L, and Zoladz JA

Subjects

Adult, Electrophoresis, Polyacrylamide Gel, Exercise Test methods, Humans, Lactic Acid blood, Male, Muscle Contraction physiology, Physical Endurance physiology, Protein Isoforms metabolism, Quadriceps Muscle physiology, Time Factors, Bicycling physiology, Myosin Heavy Chains metabolism, Oxygen Consumption physiology, Physical Exertion physiology, Quadriceps Muscle chemistry

Abstract

The aim of this study was to examine the relationship between the content of various types of myosin heavy chain isoforms (MyHC) in the vastus lateralis muscle and pulmonary oxygen uptake during moderate power output incremental exercise, performed at low and at high pedalling rates. Twenty one male subjects (mean +/- SD) aged 24.1 +/- 2.8 years; body mass 72.9 +/- 7.2 kg; height 179.1 +/- 4.8 cm; BMI 22.69 +/- 1.89 kg.m(-2); VO2max 50.6 +/- 5.3 ml.kg.min(-1), participated in this study. On separate days, they performed two incremental exercise tests at 60 rev.min(-1) and at 120 rev.min(-1), until exhaustion. Gas exchange variables were measured continuously breath by breath. Blood samples were taken for measurements of plasma lactate concentration prior to the exercise test and at the end of each step of the incremental exercise. Muscle biopsies were taken from the vastus lateralis muscle, using Bergström needle, and they were analysed for the content of MyHC I and MyHC II using SDS--PAGE and two groups (n=7, each) were selected: group H with the highest content of MyHC II (60.7 % +/- 10.5 %) and group L with the lowest content of MyHC II (27.6 % +/- 6.1 %). We have found that during incremental exercise at the power output between 30-120 W, performed at 60 rev.min(-1), oxygen uptake in the group H was significantly greater than in the group L (ANCOVA, p=0.003, upward shift of the intercept in VO2/power output relationship). During cycling at the same power output but at 120 rev.min(-1), the oxygen uptake was also higher in the group H, when compared to the group L (i.e. upward shift of the intercept in VO2/power output relationship, ANCOVA, p=0.002). Moreover, the increase in pedalling rate from 60 to 120 rev.min(-1) was accompanied by a significantly higher increase of oxygen cost of cycling and by a significantly higher plasma lactate concentration in subjects from group H. We concluded that the muscle mechanical efficiency, expressed by the VO2/PO ratio, during cycling in the range of power outputs 30-120 W, performed at 60 as well as 120 rev.min(-1), is significantly lower in the individuals with the highest content of MyHC II, when compared to the individuals with the lowest content of MyHC II in the vastus lateralis.

Published

2006

21. Preexercise metabolic alkalosis induced via bicarbonate ingestion accelerates Vo2 kinetics at the onset of a high-power-output exercise in humans.

Author

Zoladz JA, Szkutnik Z, Duda K, Majerczak J, and Korzeniewski B

Subjects

Administration, Oral, Adult, Computer Simulation, Dose-Response Relationship, Drug, Exercise Test, Humans, Kinetics, Male, Metabolic Clearance Rate, Alkalosis chemically induced, Alkalosis physiopathology, Models, Biological, Oxygen metabolism, Oxygen Consumption drug effects, Physical Endurance, Sodium Bicarbonate administration & dosage

Abstract

The present study investigated the effect of preexercise metabolic alkalosis on the primary component of oxygen uptake (Vo(2)) kinetics, characterized by tau(1). Seven healthy physically active nonsmoking men, aged 22.4 +/- 1.8 (mean +/- SD) yr, maximum Vo(2) (Vo(2 max)) 50.4 +/- 4 ml.min(-1).kg(-1), performed two bouts of cycling, corresponding to 40 and 87% of Vo(2 max), lasting 6 min each, separated by a 20-min pause, once as a control study and a few days later at approximately 90 min after ingestion of 3 mmol/kg body wt of NaHCO(3). Blood samples for measurements of bicarbonate concentration and hydrogen ion concentration were taken from antecubital vein via catheter. Pulmonary Vo(2) was measured continuously breath by breath. The values of tau(1) were calculated by using six various approaches published in the literature. Preexercise level of bicarbonate concentration after ingestion of NaHCO(3) was significantly elevated (P < 0.01) compared with the control study (28.96 +/- 2.11 vs. 24.84 +/- 1.18 mmol/l; P < 0.01), and [H(+)] was significantly (P < 0.01) reduced (42.79 +/- 3.38 nmol/l vs. 46.44 +/- 3.51 nmol/l). This shift (P < 0.01) was also present during both bouts of exercise. During cycling at 40% of Vo(2 max), no significant effect of the preexercise alkalosis on the magnitude of tau(1) was found. However, during cycling at 87% of Vo(2 max), the tau(1) calculated by all six approaches was significantly (P < 0.05) reduced, compared with the control study. The tau(1) calculated as in Borrani et al. (Borrani F, Candau R, Millet GY, Perrey S, Fuchsloscher J, and Rouillon JD. J Appl Physiol 90: 2212-2220, 2001) was reduced on average by 7.9 +/- 2.6 s, which was significantly different from zero with both the Student's t-test (P = 0.011) and the Wilcoxon's signed-ranks test (P = 0.014).

Published

2005

22. Change point in VCO2 during incremental exercise test: a new method for assessment of human exercise tolerance.

Author

Zoladz JA, Szkutnik Z, Majerczak J, and Duda K

Subjects

Adult, Humans, Male, Models, Biological, Models, Theoretical, Exercise, Exercise Test methods

Abstract

The main purpose of this study was to present a new method to determine the level of power output (PO) at which VCO2 during incremental exercise test (IT) begins to rise non-linearly in relation to power output (PO) - the change point in VCO2 (CP-VCO2). Twenty-two healthy non-smoking men (mean +/- SD: age 22.0 +/- 0.9 years; body mass 74.5 +/- 7.5 kg; height 181 +/- 7 cm; VO2max 3.753 +/- 0.335 l min-1) performed an IT on a cycloergometer. The IT started at a PO of 30 W, followed by gradual increases of 30 W every 3 min. Antecubital venous blood samples were taken at the end of each step and analysed for plasma lactate concentration [La]pl, blood PO2, PCO2 [HCO3-]b and [H+]b. In the detection of the change-point VCO2 (CP-VCO2), a two-phase model was assumed for the 'third-minute-data' of each step of the test. In the first phase, a linear relationship between VCO2 and PO was assumed, whereas in the second, an additional increase in VCO2 was allowed, above the values expected from the linear model. The PO at which the first phase ends is called the change point in VCO2. The identification of the model consists of two steps: testing for the existence of the change point, and estimating its location. Both procedures are based on suitably normalized recursive residuals (see Zoladz et al. 1998a. Eur J Appl Physiol 78, 369-377). In the case of each of our subjects it was possible to detect the CP-VCO2 and the CP-VO2 as described in our model. The PO at the CP-VCO2 amounted to 134 +/- 42 W. The CP- VO2 was detected at 136 +/- 32 W, whereas the PO at the LT amounted to 128 +/- 30 W and corresponded to 49 +/- 11, 49 +/- 8 and 47 +/- 8.6% VO2max, respectively, for the CP-VCO2, CP-VO2 and the LT. The [La]pl at the CP-VCO2 (2.65 +/- 0.76 mmol L-1), at the CP-VO2 (2.53 +/- 0. 56 mmol L-1) and at the LT (2.25 +/- 0.49 mmol L-1) were already significantly higher (P < 0.01, Students t-test) than the value reached at rest (1.86 +/- 0.43 mmol L-1). Our study illustrates that the CP-VCO2 and the CP-VO2 occur at a very similar power output as the LT. We therefore postulate that the CP-VCO2 and the CP-VO2 be applied as an additional criterion to assess human exercise tolerance.

Published

1999

23. Detection of the change point in oxygen uptake during an incremental exercise test using recursive residuals: relationship to the plasma lactate accumulation and blood acid base balance.

Author

Zoladz JA, Szkutnik Z, Majerczak J, and Duda K

Subjects

Adult, Humans, Male, Acid-Base Equilibrium physiology, Lactic Acid blood, Oxygen Consumption physiology, Physical Exertion physiology

Abstract

The purpose of this study was to develop a method to determine the power output at which oxygen uptake (VO2) during an incremental exercise test begins to rise non-linearly. A group of 26 healthy non-smoking men [mean age 22.1 (SD 1.4) years, body mass 73.6 (SD 7.4) kg, height 179.4 (SD 7.5) cm, maximal oxygen uptake (VO2max) 3.726 (SD 0.363) l x min(-1)], experienced in laboratory tests, were the subjects in this study. They performed an incremental exercise test on a cycle ergometer at a pedalling rate of 70 rev x min(-1). The test started at a power output of 30 W, followed by increases amounting to 30 W every 3 min. At 5 min prior to the first exercise intensity, at the end of each stage of exercise protocol, blood samples (1 ml each) were taken from an antecubital vein. The samples were analysed for plasma lactate concentration [La]pl, partial pressure of O2 and CO2 and hydrogen ion concentration [H+]b. The lactate threshold (LT) in this study was defined as the highest power output above which [La-]pl showed a sustained increase of more than 0.5 mmol x l(-1) x step(-1). The VO2 was measured breath-by-breath. In the analysis of the change point (CP) of VO2 during the incremental exercise test, a two-phase model was assumed for the 3rd-min-data of each step of the test: Xi = at(i) + b + epsilon(i) for i = 1,2, ..., T, and E(Xi) > at(i) + b for i = T + 1, ..., n, where X1, ..., Xn are independent and epsilon(i) approximately N(0, sigma2). In the first phase, a linear relationship between VO2 and power output was assumed, whereas in the second phase an additional increase in VO2 above the values expected from the linear model was allowed. The power output at which the first phase ended was called the change point in oxygen uptake (CP-VO2). The identification of the model consisted of two steps: testing for the existence of CP and estimating its location. Both procedures were based on suitably normalised recursive residuals. We showed that in 25 out of 26 subjects it was possible to determine the CP-VO2 as described in our model. The power output at CP-VO2 amounted to 136.8 (SD 31.3) W. It was only 11 W -- non significantly -- higher than the power output corresponding to LT. The VO2 at CP-VO2 amounted to 1.828 (SD 0.356) l x min(-1) was [48.9 (SD 7.9)% VO2max]. The [La-]pl at CP-VO2, amounting to 2.57 (SD 0.69) mmol x l(-1) was significantly elevated (P < 0.01) above the resting level [1.85 (SD 0.46) mmol x l(-1)], however the [H+]b at CP-VO2 amounting to 45.1 (SD 3.0) nmol x l(-1), was not significantly different from the values at rest which amounted to 44.14 (SD 2.79) nmol x l(-1). An increase of power output of 30 W above CP-VO2 was accompanied by a significant increase in [H+]b above the resting level (P = 0.03).

Published

1998