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Effects of resistance training on muscle fiber composition and endurance capacity
1. Aagaard P., Andersen J. L., Bennekou M., Larsson B., Olesen J. L.,
Crameri R., Magnusson S. P., Kjaer M., Effects of resistance trai-
ning on endurance capacity and muscle fiber composition in
young top-level cyclists, Scand. J. Med. Sci. Sports, 21. 2011,
298–307.
Andersen J. L., Aagaard P., Effects of strength training on
muscle fiber types and size; consequences for athletes training
for high-intensity sport, Scand. J. Med. Sci. Sports, 20, 2010,
32–38.
Baar K., Epigenetic control of skeletal muscle fibre type, Acta
Physiol., 199, 2010, 4, 477–487.
Bassel-Duby R., Olson E. N., Signaling pathways in skeletal
muscle remodeling, Ann. Rev. Biochem., 75, 2006, 19–37.
Beneke R., Leithäuser R. M., Ochentel O., Blood lactate diagno-
stics in exercise testing and training, Int. J. Sports Physiol.
Perform., 6, 2011, 1, 8–24.
Bickham D. C., Bentley D. J., Le Rossignol P. F., Cameron-Smith
D., The effects of short-term sprint training on MCT expression
in moderately endurance-trained runners, Eur. J. Appl. Physiol.,
96, 2006, 636–643.
Billat V. L., Sirvent P., Py G., Koralsztein J., Mercier J., The concept
of maximal lactate steady state: A bridge between biochemistry,
physiology and sport science, Sports Med., 2003, 33, 407–426.
Böning D., Maassen N., Milchsäure und Säure-Basen-
Gleichgewicht, Dtsch. Z. Sportmed., 2008, 59, 287–291.
Bosquet L., Léger L., Legros P., Blood lactate response to over-
training in male endurance athletes, Eur. J. Appl. Physiol., 84,
2001, 107–114.
Bottinelli R., Canepari M., Pellegrino M. A., Reggiani C., Force
velocity properties of human skeletal muscle fibres: myosin
heavy chain isoform and temperature dependence, J. Physiol.
(London), 495, 1996, 573–586.
Boutellier U., Die aerobe Schwelle, Schweiz. Z. Sportmed.
Sporttraumatol., 53, 4, 2005, 185.
Boutellier U., Die Milchsäure, Schweiz. Z. Sportmed.
Sporttraumatol., 54, 3, 2005, 109.
Braumann K. M., Tegtbur U., Busse M. W., Maassen N., Die
«Laktatsenke» – Eine Methode zur Ermittlung der individuellen
Dauerleistungsgrenze, Dtsch. Z. Sportmed., 1991, 42, 240–246.
Brooks G.A., Cell-cell and intracellular lactate shuttles, J.
Physiol. (London), 587, 2009, 5591–5600.
Brooks G. A., What does glycolysis make and why is it impor-
tant?, J. Appl. Physiol., 108, 2010, 1450–1451.
Brooks G. A., Brooks T. G., Brooks S., Laktat als metabolisches
Signal der Genexpression, Dtsch. Z. Sportmed., 59, 2008,
280–286.
Brooks G. A., Hashimoto T., Investigation of the lactate shuttle
in skeletal muscle mitochondria. J. Physiol. (London), 584, 2007,
705–706.
Burgomaster K. A., Howarth K. R., Phillips S. M., Rakobowchuk
M., Mac- Donald M. J., McGee S. L., Gibala M. J., Similar meta-
bolic adaptations during exercise after low volume sprint inter-
val and traditional endurance training in humans, J. Physiol.
(London), 586, 2008, 151–160.
Canepari M., Pellegrino M.A., D‘Antona G., Bottinelli R., Skeletal
muscle fibre diversity and the underlying mechanisms, Acta
Physiol., 2010, 199, 465–476.
Chemello F., Bean C., Cancellara P., Laveder P., Reggiani C.,
Lanfranchi G., Microgenomic analysis in skeletal muscle:
expression signatures of individual fast and slow myofibers,
PLos One 6, 2011, 2, e16807.
Cormie P., McGuigan M. R., Newton R. U., Developing maximal
neuromuscular power: Part 1- biological basis of maximal
power production, Sports Med., 41, 2010a, 17–38.
Cormie P., McGuigan M. R., Newton R. U., Developing maximal
neuromuscular power: Part 2 – training considerations for
improving maximal power production, Sports Med., 41, 2011b,
125–146.
Crewther B., Keogh J., Cronin J., Cook C., Possible stimuli for
strength and power adaptation: acute hormonal responses,
Sports Med., 36, 2006, 215–238.
Donovan C. M., Pagliassotti M. J., Quantitative assessment of
pathways for lactate disposal in skeletal muscle fiber types.
Med. Sci. Sports Exerc., 32, 2000, 772–777.
Duchateau J., Enoka R. M., Human motor unit recordings:
Origins and insight into the integrated motor system, Brain
Res., 2011, 1409, 42–61.
Ehlert T., Simon P., Genetik und Epigenetik der körperlichen
Leistungsfähigkeit, Dtsch. Z. Sportmed. 62, 2011, 86–91.
Faude O., Kindermann W., Meyer T., Lactate threshold concepts:
How valid are they?, Sports Med., 39, 2009, 469–490.
Fluck M., Molekularbiologische Grundlagen der Konditionierung
von muskulärem Leistungsvermögen und Fitness, Schweiz. Z.
Sportmed. Sporttraumatol., 54, 2, 2006, 43–49.
Formenti F., Constantin-Teodosiu D., Emmanuel Y., Cheeseman
J., Dorrington K. L., Edwards L.M., Humphreys S. M., Lappin T. R.
J., McMullin M. F., McNamara C.J., Mills W., Murphy J.A.,
O’Connor D. F., Percy M. J., Ratcliffe P.J., Smith T.G., Treacy M.,
Frayn K. N., Greenhaff P.L., Karpe F., Clarke K. Robbins P.A.,
Regulation of human metabolism by hypoxia-inducible factor,
Proc. Natl. Acad. Sci., 107, 2010, 12722–12727.
Gibala M., 2009): Molecular responses to high-intensity interval
exercise, Appl. Physiol. Nutr. Metab., 34, 428–432.
Gladden L. B., Lactate metabolism: a new paradigm for the
third millennium, J. Physiol., (London) 558, 2004, 5–30.
Gladden L. B., Is there an intracellular lactate shuttle in ske-
letal muscle?, J. Physiol., (London), 582, 2007, 899.
Gladden L. B., A «lactatic» perspective on metabolism, Med. Sci.
Sports Exerc., 40, 2008, 477–485.
Green H. J., Duhamel T. A., Holloway G. P., Moule J. W., Ranney
D. W., Tupling A. R., Ouyang J., Rapid upregulation of GLUT-4
and MCT-4 expression during 16 h of heavy intermittent cycle
exercise, Am. J. Physiol. Regul. Integr. Comp. Physiol., 294, 2008,
2008, R594–R600.
Guzun R., Saks V., Application of the principles of systems bio-
logy and Wiener‘s cybernetics for analysis of regulation of
energy fluxes in muscle cells in vivo, Int. J. Mol. Sci., 11, 2010,
982–1019.
Hafstad A. D., Boardman N. T., Lund J., Hagve M., Khalid A. M.,
Wisløff U., Larsen T.S., Aasum E., High intensity interval training
alters substrate utilization and reduces oxygen consumption in
the heart, J. Appl. Physiol., 111, 2011, 1235–1241.
Halestrap A. P., Price N. T., The proton-linked monocarboxylate
transporter (MCT) family: structure, function and regulation,
Biochem. J., 343, 1999, 281–299.
Harridge S. D. R., Plasticity of human skeletal muscle: gene
expression to in vivo function, Exp. Physiol., 92, 2007, 783–797.
Hashimoto T., Brooks G. A., Mitochondrial lactate oxidation
complex and an adaptive role for lactate production, Med. Sci.
Sports Exerc., 40, 2008, 486–494.
Heck H., Beneke R., 30 Jahre Laktatschwellen – was bleibt zu
tun?, Dtsch. Z. Sportmed., 59, 2008, 297–302.
Hennemann E., Somjen G., Carpenter D. O., Functional signifi-
cance of cell size in spinal motoneurones., J. Neurophysiol., 28,
1965, 560–580.
Hickson R. C., Interference of strength development by simulta-
neously **training for strength and endurance, Eur. J. Appl.
Physiol., 45, 1980, 255–263.
Hohmann A., Rutten A., Wissenschaftliche Trainingsberatung –
Ein interdisziplinäres Konzept. Sportwissenschaft, 25, 1995,
137–157.
Hoffman E. P., Escolar D., Translating mighty mice into neuro-
muscular therapeutics: Is bigger muscle better?, Am. J. Pathol.,
168, 2006, 1775–1778.
Hoppeler H., Baum O., Mueller M., Lurman G., I meccanismi
molecolari della capacità di adattamento della muscolatuta
scheletrica, SdS-Scuola dello Sport, 2013, 32, 98, 25-33.
Issurin V. B., New horizons for the methodology and physio-
logy of training periodization, Sports Med., 40, 2010, 189–
206.
Kellmann M., Preventing overtraining in athletes in high-inten-
sity sports and stress/recovery monitoring, Scand. J. Med. Sci.
Sports, 20, 2010, 95–102.
Kindermann W., Anaerobe Schwelle. Dtsch. Z. Sportmed., 55,
2004, 161–162.
Kinsey S. T., Hardy K. M., Locke B. R., The long and winding
road: influences of intracellular metabolite diffusion on cellular
organization and metabolism in skeletal muscle, J. Exp. Biol.,
210, 2007, 3505–3512.
Koulmann N., Bigard A., Interaction between signalling
pathways involved in skeletal muscle responses to endurance
exercise, Pflugers Arch., 452, 2006, 125–139.
Laursen P. B., Training for intense exercise performance: High
intensity or high-volume training?, Scand. J. Med. Sci. Sports,
20, 2010, 1–10.
Laursen P. B., Jenkins D. G., The scientific basis for high-inten-
sity interval training: Optimising training programmes and
maximising performance in highly trained endurance athletes,
Sports Med., 32, 2002, 53–73.
Little J. P., Safdar A., Wilkin G. P., Tarnopolsky M. A., Gibala M.
J., A practical model of low-volume high-intensity interval trai-
ning induces mitochondrial biogenesis in human skeletal
muscle: potential mechanisms. J. Physiol., (London), 2010, 588,
1011–1022.
Little J. P., Safdar A., Bishop D., Tarnopolsky M. A., Gibala M. J.,
An acute bout of high-intensity interval training increases the
nuclear abundance of PGC-1 and activates mitochondrial bio-
genesis in human skeletal muscle, Am. J. Physiol. Regul. Integr.
Comp. Physiol., 2011, 300, 6, R1303–R1310.
Maassen N., Schneider G., Die kapilläre Laktatkonzentration als
Mass fur die Belastungsreaktion, Dtsch. Z. Sportmed., 62, 2011,
92–97.
Matheny R. W., Nindl B. C., Adamo M. L., Minireview:
Mechanogrowth factor: a putative product of IGF-I gene
expression involved in tissue repair and regeneration, Endocri-
nology, 151, 2010, 865–875.
Olesen J., Kiilerich K., Pilegaard H., PGC-1alpha-mediated
adaptations in skeletal muscle, Pflugers Arch., 460, 2010,
153–162.
Passarella S., de Bari L., Valenti D., Pizzuto R., Paventi G., Atlante
A., Mitochondria and L-lactate metabolism, FEBS Lett., 582,
2008, 3569-3576.
Péronnet F., Lactate as an end-product and fuel, Dtsch. Z.
Sportmed., 61, 2010, 112–116.
Philp A., Macdonald A. L., Watt P. W., Lactate – a signal coordi-
nating cell and systemic function, J. Exp. Biol., 208, 2005,
4561–4575.
Reilly T., Woodbridge V., Effects of moderate dietary manipula-
tions on swim performance and on blood lactate – swimming
velocity curves, Int. J. Sports Med., 20, 1999, 93–97.
Röckl K. S. C., Witczak C. A., Goodyear L. J., Signaling mechani-
sms in skeletal muscle: Acute responses and chronic adapta-
tions to exercise, IUBMB Life, 60, 2008, 145–153.
Sahlin K., Fernström M. , Svensson M., Tonkonogi M., No evi-
dence of an intracellular lactate shuttle in rat skeletal muscle. J.
Physiol. (London), 541, 2002, 569–574.
Schaible E., Boehringer A., Callau D., Niess A. M., Simon P.,
Exercise and menstrual cycle dependent expression of a trunca-
ted alternative splice variant of HIF1 in leukocytes, Exerc.
Immunol. Rev., 15, 2009, 145–156.
Schiaffino S., Fibre types in skeletal muscle: a personal account,
Acta Physiol., 199, 2010, 451–463.
Schurr A., Lactate: the ultimate cerebral oxidative energy sub-
strate?, J. Cereb. Blood Flow Metab., 26, 2006, 142–152.
Seiler K. S., Kjerland G.Ø., Quantifying training intensity distri-
bution in elite endurance athletes: is there evidence for an
«optimal» distribution?, Scand. J. Med. Sci. Sports, 16, 2006,
49–56.
Slivka D. R., Hailes W. S., Cuddy J. S., Ruby B. C., Effects of 21
days of intensified training on markers of overtraining, J.
Strength Cond. Res., 24, 2010, 2604–2612.
Smith G. I., Patterson B. W., Mittendorfer B., Human muscle
protein turnover – why is it so variable?, J. Appl. Physiol., 110,
2011, 480–491.
Spurway N., Wackerhage H., Genetics and molecular biology of
muscle adaption. Advances in sport and exercise science series,
1a
edizione, Elsevier Churchill Livingstone, Edimburgo, 2006.
Tegtbur U., Busse M. W., Kubis H. P., Körperliches Training und
zelluläre Anpassung des Muskels, Unfallchirurg., 112, 2009,
365–372.
Toigo M., Trainingsrelevante Determinanten der molekularen
und zellulären Skelettmuskeladaptation: Teil 1: Einleitung und
Längenadaptation, Schweiz. Z. Sportmed. Sporttraumatol., 54,
2006a, 101–107.
Toigo M., Trainingsrelevante Determinanten der molekularen
und zellulären Skelettmuskeladaptation: Teil 2: Adaptation von
Querschnitt und Fasertypusmodulen, Schweiz. Z. Sportmed.
Sporttraumatol., 54, 2006b, 121–132.
Toigo M., Boutellier U., New fundamental resistance exercise
determinants of molecular and cellular muscle adaptations, Eur.
J. Appl. Physiol., 97, 2006, 643–663.
Tschopp M., Held T., Villinger B., Marti B., Qualitätsstandards in
der Ausdauerleistungsdiagnostik: Ein gemeinsames Projekt von
SGSM und Swiss Olympic, Schweiz. Z. Sportmed.
Sporttraumatol., 49, 2001, 57–66.
Urhausen A., Gabriel H. H., Weiler B., Kindermann W.,
Ergometric and psychological findings during overtraining: a
long-term follow-up study in endurance athletes, Int. J. Sports
Med., 19, 1998, 114–120.
van Hall G., Lactate kinetics in human tissues at rest and during
exercise, Acta Physiol., 199, 2010, 499–508.
van Wessel T., de Haan A., van der Laarse W. J., Jaspers R. T.,
The muscle fiber type-fiber size paradox: hypertrophy or
oxidative metabolism?, Eur. J. Appl. Physiol., 110, 2010,
665–694.
Wahl P., Bloch W., Mester J., Moderne Betrachtungsweisen des
Laktats: Laktat ein uberschätztes und zugleich unterschätztes
Molekul, Schweiz. Z. Sportmed. Sporttraumatol., 57, 2009,
100–107.
Wahl P., Hägele M., Zinner C., Bloch W., Mester J., High Intensity
Training (HIT) fur die Verbesserung der Ausdauerleistungsfähig-
keit im Leistungssport, Schweiz. Z. Sportmed. Sporttraumatol.,
58, 2010a, 125–133.
Wahl P., Hägele M., Zinner C., Bloch W., Mester J., 2010b): High
Intensity Training (HIT) fur die Verbesserung der Ausdauerlei-
stungsfähigkeit von Normalpersonen und im Präventions- &
Rehabilitationsbereich, Wien Med. Wochenschr., 160, 2010b,
627–636.
Wahl P., Zinner C., Achtzehn S., Bloch W., Mester J., Effect of
high- and low-intensity exercise and metabolic acidosis on
levels of GH, IGF-I, IGFBP-3 and cortisol, IGF Res., 20, 2010c,
380–385.
Wahl P., Zinner C., Achtzehn S., Behringer M., Bloch W., Mester
J., Effects of acid-base balance and high or low intensity exer-
cise on VEGF and bFGF, Eur. J. Appl. Physiol., 111, 2011,
1405–1413.
Wenger R. H., Stiehl D. P., Camenisch G., Integration of oxygen
signaling at the consensus, 306, 2005, Sci STKE. 18, re12.
Westerblad H., Bruton J. D., Katz A., Skeletal muscle: Energy
metabolism, fiber types, fatigue and adaptability, Exp. Cell Res.,
316, 2010, 3093–3099.
Zammit P. S., All muscle satellite cells are equal, but are some
more equal than others?, J. Cell Sci., 2008, 121, 2975–2982.
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