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A. Ruggiu, R. Cancedda (2015)
Bone mechanobiology, gravity and tissue engineering: effects and insightsJournal of Tissue Engineering and Regenerative Medicine, 9
P. Witten, L. Gil-Martens, B. Hall, A. Huysseune, A. Obach (2005)
Compressed vertebrae in Atlantic salmon Salmo salar: evidence for metaplastic chondrogenesis as a skeletogenic response late in ontogeny.Diseases of aquatic organisms, 64 3
T. Wada, T. Nakashima, Nishina Hiroshi, J. Penninger (2006)
RANKL-RANK signaling in osteoclastogenesis and bone disease.Trends in molecular medicine, 12 1
G. Thillart, V. Ginneken, F. Körner, R. Heijmans, R. Linden, A. Gluvers (2004)
Endurance swimming of European eelJournal of Fish Biology, 65
Gorman (2010)
10Scoliosis, 5
Gray (1933a)
391Journal of Experimental Biology, 10
K. F. Gorman, G. R. Handrigan, G. Jin, R. Wallis, F. Breden (2010)
Structural and micro‐anatomical changes in vertebrae associated with idiopathic‐type spinal curvature in the curveback guppy model, 5
K. Kitamura, N. Suzuki, Yusuke Sato, T. Nemoto, M. Ikegame, N. Shimizu, T. Kondo, Yukihiro Furusawa, S. Wada, A. Hattori (2010)
Osteoblast activity in the goldfish scale responds sensitively to mechanical stress.Comparative biochemistry and physiology. Part A, Molecular & integrative physiology, 156 3
K. Gorman, G. Handrigan, G-C Jin, R. Wallis, F. Breden
Open Access Research
BY Gray (1933)
STUDIES IN ANIMAL LOCOMOTION II. THE RELATIONSHIP BETWEEN WAVES OF MUSCULAR CONTRACTION AND THE PROPULSIVE MECHANISM OF THE EELThe Journal of Experimental Biology, 10
R. V. Beecham, C. D. Minchew, S. D. F. To, G. R. Parsons (2014)
Design and calibration of a tilting tunnel respirometer to study non‐horizontal swimming in fishes, 4
J. Renn, C. Winkler, M. Schartl, R. Fischer, R. Goerlich (2006)
Zebrafish and medaka as models for bone research including implications regarding space-related issuesProtoplasma, 229
P. Witten, A. Obach, A. Huysseune, G. Baeverfjord (2006)
Vertebrae fusion in Atlantic salmon (Salmo salar) : Development, aggravation and pathways of containmentAquaculture, 258
Blazka (1960)
553Physiologia Bohemoslovenica, 9
C. Hammer (1995)
FATIGUE AND EXERCISE TESTS WITH FISHComparative Biochemistry and Physiology Part A: Physiology, 112
M. Owen, B. Eynon, S. Woodgate, S. Davies, S. Fox (2012)
Increased water current induces micro-architectural changes to the vertebral bone of juvenile rainbow trout (Oncorhynchus mykiss)Aquaculture, 344
B. K. Hall (2015)
Bones and cartilage
G. Totland, P. Fjelldal, H. Kryvi, Guro Løkka, A. Wargelius, A. Sagstad, T. Hansen, S. Grotmol (2011)
Sustained swimming increases the mineral content and osteocyte density of salmon vertebral boneJournal of Anatomy, 219
M. Doblaré, J. Garcı́a, M. Gómez (2004)
Modelling bone tissue fracture and healing: a review ☆Engineering Fracture Mechanics, 71
Hall (2007)
13
S. Nagatomi, H. A. Singer, R Bizios (2011)
Mechanobiology handbook
L. Lanyon (1987)
Functional strain in bone tissue as an objective, and controlling stimulus for adaptive bone remodelling.Journal of biomechanics, 20 11-12
F. W. H. Beamish (1978)
Fish Physiology
E. Burger, J. Klein-Nulend (1999)
MECHANOTRANSDUCTION IN BONE : ROLE OF THE LACUNOCANALICULAR NETWORKThe FASEB Journal, 13
BY Gray (1933)
Studies in Animal Locomotion: I. The Movement of Fish with Special Reference to the EelThe Journal of Experimental Biology, 10
Beecham (2014)
22Science and Technology of Food Industry, 4
M. Moss (1961)
Osteogenesis of acellular teleost fish boneAmerican Journal of Anatomy, 108
Tierney (2011)
e2572Journal of Visualized Experiments: JoVE, 51
K. Gorman, F. Breden (2007)
Teleosts as models for human vertebral stability and deformity.Comparative biochemistry and physiology. Toxicology & pharmacology : CBP, 145 1
A. Fiaz, K. Léon-Kloosterziel, G. Gort, S. Schulte-Merker, J. Leeuwen, S. Kranenbarg (2012)
Swim-Training Changes the Spatio-Temporal Dynamics of Skeletogenesis in Zebrafish Larvae (Danio rerio)PLoS ONE, 7
B. Bagatto, B. Pelster, W. Burggren (2001)
Growth and metabolism of larval zebrafish: effects of swim training.The Journal of experimental biology, 204 Pt 24
J. Aceto, R. Nourizadeh-Lillabadi, R. Marée, N. Dardenne, Nathalie Jeanray, L. Wehenkel, P. Aleström, J. Loon, M. Muller (2015)
Zebrafish Bone and General Physiology Are Differently Affected by Hormones or Changes in GravityPLoS ONE, 10
V. Tucker (1970)
Energetic cost of locomotion in animals.Comparative biochemistry and physiology, 34 4
E. Burger, J. Klein-Nulend, Arie Plas, P. Nijweide (1995)
Function of osteocytes in bone--their role in mechanotransduction.The Journal of nutrition, 125 7 Suppl
Beamish (1978)
101
J. Brett (1964)
The Respiratory Metabolism and Swimming Performance of Young Sockeye SalmonWsq: Women's Studies Quarterly, 21
J. Kieffer (2010)
Perspective--Exercise in fish: 50+years and going strong.Comparative biochemistry and physiology. Part A, Molecular & integrative physiology, 156 2
E. Ytteborg, J. Torgersen, G. Baeverfjord, H. Takle (2010)
Morphological and molecular characterization of developing vertebral fusions using a teleost modelBMC Physiology, 10
D. Jones (1982)
Anaerobic exercise in teleost fishCanadian Journal of Zoology, 60
Laizé (2014)
29Drug Discovery Today: Disease Models, 13
M. Deschamps, A. Kacem, R. Ventura, G. Courty, P. Haffray, F. Meunier, J. Sire (2008)
Assessment of "discreet" vertebral abnormalities, bone mineralization and bone compactness in farmed rainbow troutAquaculture, 279
K. Holk, Gunnar Lykkeboe (1998)
The impact of endurance training on arterial plasma K+ levels and swimming performance of rainbow troutThe Journal of experimental biology, 201 (Pt 9)
M. Chatani, A. Mantoku, Kazuhiro Takeyama, Dawud Abduweli, Yasutaka Sugamori, K. Aoki, K. Ohya, Hiromi Suzuki, S. Uchida, T. Sakimura, Y. Kono, Fumiaki Tanigaki, Masaki Shirakawa, Y. Takano, A. Kudo (2015)
Microgravity promotes osteoclast activity in medaka fish reared at the international space stationScientific Reports, 5
K. Gorman, F. Breden (2009)
Idiopathic-type scoliosis is not exclusive to bipedalism.Medical hypotheses, 72 3
A. Palstra, J. Planas (2011)
Fish under exerciseFish Physiology and Biochemistry, 37
Gorman (2007)
28Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology, 145
A. Apschner, S. Schulte-Merker, P. Witten (2011)
Not all bones are created equal - using zebrafish and other teleost species in osteogenesis research.Methods in cell biology, 105
Burger (1999)
S101The FASEB Journal, 13
M. Harris, M. Harris, Katrin Henke, Katrin Henke, M. Hawkins, M. Hawkins, P. Witten (2014)
Fish is Fish: the use of experimental model species to reveal causes of skeletal diversity in evolution and disease.Zeitschrift fur angewandte Ichthyologie = Journal of applied ichthyology, 30 4
Gray (1933b)
386Journal of Experimental Biology, 10
D. Allen, B. Harrison, A. Maass, Matthew Bell, W. Byrnes, L. Leinwand (2001)
Cardiac and skeletal muscle adaptations to voluntary wheel running in the mouse.Journal of applied physiology, 90 5
M. Chatani, H. Morimoto, Kazuhiro Takeyama, A. Mantoku, Naoki Tanigawa, Koji Kubota, Hiromi Suzuki, S. Uchida, Fumiaki Tanigaki, Masaki Shirakawa, O. Gusev, V. Sychev, Y. Takano, T. Itoh, A. Kudo (2016)
Acute transcriptional up-regulation specific to osteoblasts/osteoclasts in medaka fish immediately after exposure to microgravityScientific Reports, 6
Harrie Weinans, P. Prendergast (1996)
Tissue adaptation as a dynamical process far from equilibrium.Bone, 19 2
Kota Ogawa, T. Miura (2013)
Aphid polyphenisms: trans-generational developmental regulation through viviparityFrontiers in Physiology, 5
S. Ferrari, E. Seeman, G. Strewler (2005)
Clinical and basic research papers - November 2005 selectionsbonekey Reports, 2
A. Fiaz, K. Leon, J. Leeuwen, S. Kranenbarg (2014)
Exploring the effect of exercise on the transcriptome of zebrafish larvae (Danio rerio)Journal of Applied Ichthyology, 30
Frida Solstorm, D. Solstorm, F. Oppedal, P. Fjelldal (2016)
The vertebral column and exercise in Atlantic salmon — Regional effectsAquaculture, 461
M. Forwood, C. Turner (1995)
Skeletal adaptations to mechanical usage: results from tibial loading studies in rats.Bone, 17 4 Suppl
Bagatto (2001)
4335Journal of Experimental Biology, 204
L. Lanyon (2005)
Osteocytes, strain detection, bone modeling and remodelingCalcified Tissue International, 53
M. L. K. Tate, J. R. Adamson, A. E. Tami, T. W. Bauer (2004)
The osteocyte, 36
G. Kogianni, B. Noble (2007)
The biology of osteocytesCurrent Osteoporosis Reports, 5
Gray (1933c)
88Journal of Experimental Biology, 10
V. Laizé, P. Gavaia, M. Cancela (2014)
Fish: a suitable system to model human bone disorders and discover drugs with osteogenic or osteotoxic activitiesDrug Discovery Today: Disease Models, 13
A. Fiaz, K. Léeon‐Kloosterziel, J. Leeuwen, S. Kranenbarg (2014)
Exploring the molecular link between swim‐training and caudal fin development in zebrafish (Danio rerio) larvaeJournal of Applied Ichthyology, 30
C. Boglione, P. Gavaia, G. Koumoundouros, E. Gisbert, M. Moren, Stéphanie Fontagn, P. Witten (2013)
Skeletal anomalies in reared European fish larvae and juveniles. Part 1: normal and anomalous skeletogenic processesReviews in Aquaculture, 5
S. Mccullen, C. Haslauer, E. Loboa (2010)
Musculoskeletal mechanobiology: interpretation by external force and engineered substratum.Journal of biomechanics, 43 1
A. Palstra, Daan Mes, Kasper Kusters, Jonathan Roques, G. Flik, K. Kloet, R. Blonk (2015)
Forced sustained swimming exercise at optimal speed enhances growth of juvenile yellowtail kingfish (Seriola lalandi)Frontiers in Physiology, 5
S. Badilatti, P. Christen, A. Levchuk, J. Marangalou, B. Rietbergen, I. Parkinson, R. Müller (2015)
Large-scale microstructural simulation of load-adaptive bone remodeling in whole human vertebraeBiomechanics and Modeling in Mechanobiology, 15
J. Cardeira, A. Mendes, P. Pousão‐Ferreira, M. Cancela, P. Gavaia (2015)
Micro-anatomical characterization of vertebral curvatures in Senegalese sole Solea senegalensis.Journal of fish biology, 86 6
E. Burger, J. Klein-Nulend, T. Smit (2003)
Strain-derived canalicular fluid flow regulates osteoclast activity in a remodelling osteon--a proposal.Journal of biomechanics, 36 10
L. Bonewald, Mark Johnson (2008)
Osteocytes, mechanosensing and Wnt signaling.Bone, 42 4
D. R. Carter, G. S. Beaupré (2001)
Skeletal function and form: Mechanobiology of skeletal development, aging, and regeneration
S. Yano, K. Kitamura, Y. Satoh, Masaki Nakano, A. Hattori, T. Sekiguchi, M. Ikegame, H. Nakashima, Katsunori Omori, K. Hayakawa, A. Chiba, Y. Sasayama, S. Ejiri, Y. Mikuni‐Takagaki, H. Mishima, H. Funahashi, T. Sakamoto, N. Suzuki (2013)
Static and Dynamic Hypergravity Responses of Osteoblasts and Osteoclasts in Medaka Scales, 30
S. Kranenbarg, T. Cleynenbreugel, H. Schipper, J. Leeuwen (2005)
Adaptive bone formation in acellular vertebrae of sea bass (Dicentrarchus labrax L.)Journal of Experimental Biology, 208
G. McClelland, P. Craig, K. Dhekney, Shawn Dipardo (2006)
Temperature‐ and exercise‐induced gene expression and metabolic enzyme changes in skeletal muscle of adult zebrafish (Danio rerio)The Journal of Physiology, 577
P. E. Witten, W. Villwock (1997)
Growth requires bone resorption at particular skeletal elements in a teleost fish with, 13
L. Parenti (1986)
The phylogenetic significance of bone types in euteleost fishesZoological Journal of the Linnean Society, 87
Carter (2001)
318
B. K. Hall, P. E Witten (2007)
Major transitions in vertebrate evolution
P. Witten, W. Villwock (1997)
Growth requires bone resorption at particular skeletal elements in a teleost fish with acellular bone (Oreochromis niloticus, Teleostei: Cichlidae)Journal of Applied Ichthyology, 13
J. Gray (1933)
STUDIES IN ANIMAL LOCOMOTION: III. THE PROPULSIVE MECHANISM OF THE WHITING (GADUS MERLANGUS)The Journal of Experimental Biology, 10
Hall (2015)
892
K. B. Tierney (2011)
Swimming performance assessment in fishes, 51
D. Carter, D. Carter, P. Blenman, G. Beaupré (1988)
Correlations between mechanical stress history and tissue differentiation in initial fracture healingJournal of Orthopaedic Research, 6
D. Sfakianakis, E. Georgakopoulou, I. Papadakis, P. Divanach, M. Kentouri, G. Koumoundouros (2006)
Environmental determinants of haemal lordosis in European sea bass, Dicentrarchus labrax (Linnaeus, 1758)Aquaculture, 254
Meulen (2006)
R1040American Journal of Physiology: Regulatory, Integrative and Comparative Physiology, 291
N. Suzuki, Katsunori Omori, Masahisa Nakamura, M. Tabata, M. Ikegame, K. Ijiri, K. Kitamura, T. Nemoto, N. Shimizu, T. Kondo, K. Matsuda, H. Ando, H. Kasahara, Mutsumu Nagase, M. Nara, A. Hattori (2008)
Scale osteoblasts and osteoclasts sensitively respond to low-gravity loading by centrifugeBiological Sciences in Space, 22
Leah Lewis, S. Lall (2006)
Development of the axial skeleton and skeletal abnormalities of Atlantic halibut (Hippoglossus hippoglossus) from first feeding through metamorphosisAquaculture, 257
Webb (1975)
1Bulletin Fisheries Research Boad of Canada, 190
P. Witten, A. Huysseune (2009)
A comparative view on mechanisms and functions of skeletal remodelling in teleost fish, with special emphasis on osteoclasts and their functionBiological Reviews, 84
T. Skerry, L. Lanyon, L. Bitensky, J. Chayen (1989)
Early strain‐related changes in enzyme activity in osteocytes following bone loading in vivoJournal of Bone and Mineral Research, 4
Jaquan Horton, Adam Summers (2009)
The material properties of acellular bone in a teleost fishJournal of Experimental Biology, 212
A. Fiaz, J. Leeuwen, S. Kranenbarg (2010)
Phenotypic plasticity and mechano-transduction in the teleost skeletonJournal of Applied Ichthyology, 26
P. W. Webb (1975)
Hydrodynamics and energetics of fish propulsion, 190
Tate (2004)
1International Journal of Biochemistry & Cell Biology, 36
P. Witten, Brian Hall (2015)
Teleost Skeletal Plasticity: Modulation, Adaptation, and RemodellingCopeia, 103
R. Shahar, M. Dean (2013)
The enigmas of bone without osteocytes.BoneKEy reports, 2
S. Kranenbarg, J. Waarsing, M. Muller, H. Weinans, J. Leeuwen (2005)
Lordotic vertebrae in sea bass (Dicentrarchus labrax L.) are adapted to increased loads.Journal of biomechanics, 38 6
Holk (1998)
1373Journal of Experimental Biology, 201
S. Nagatomi, H. Singer, R. Bizios (2011)
Effects of Pressure on Vascular Smooth Muscle Cells
P. Blazka, M. Volf, M. Cepela (1960)
A new type of respirometer for the determination of the metabolism of fish in an active state, 9
M. Kihara, S. Ogata, N. Kawano, Itsuo Kubota, Ryoichi Yamaguchi (2002)
Lordosis induction in juvenile red sea bream, Pagrus major, by high swimming activityAquaculture, 212
J. Brett (1967)
Swimming Performance of Sockeye Salmon (Oncorhynchus nerka) in relation to Fatigue Time and TemperatureWsq: Women's Studies Quarterly, 24
J. Renn, D. Seibt, R. Goerlich, M. Schartl, C. Winkler (2006)
Simulated microgravity upregulates gene expression of the skeletal regulator core binding factor α1/Runx2 in Medaka fish larvae in vivoAdvances in Space Research, 38
J. Cardeira, A. Bensimon-Brito, P. Pousão‐Ferreira, M. Cancela, P. Gavaia (2012)
Lordotic-kyphotic vertebrae develop ectopic cartilage-like tissue in Senegalese sole (Solea senegalensis)Journal of Applied Ichthyology, 28
E. Ytteborg, J. Torgersen, M. Pedersen, S. Helland, B. Grisdale-Helland, H. Takle (2013)
Exercise induced mechano-sensing and substance P mediated bone modeling in Atlantic salmon.Bone, 53 1
A. Palstra, C. Tudorache, Mireia Rovira, Sebastiaan Brittijn, E. Burgerhout, G. Thillart, H. Spaink, J. Planas (2010)
Establishing Zebrafish as a Novel Exercise Model: Swimming Economy, Swimming-Enhanced Growth and Muscle Growth Marker Gene ExpressionPLoS ONE, 5
J. Hutcheson, Michael Nilo, W. Merryman (2011)
Mechanobiology of Heart Valves
T. Meulen, H. Schipper, J. G. M. Boogaart, M. O. Huising, S. Kranenbarg, J. L. Leeuwen (2006)
Endurance exercise differentially stimulates heart and axial muscle development in zebrafish (Danio rerio), 291
Vertebrate tissues are plastic and actively adapt to the mechanical environment. Teleost bone, despite differences with its mammalian counterpart, also responds to mechanical loading, evidencing the presence of a functional mechanosensing system. Deformities such as spinal curvatures and vertebral compressions can result in internal loading disturbances. On the other hand, the external mechanical loading can be modulated by controlling gravity (i.e. inducing micro‐ or hyper‐gravity) or swimming conditions. There is an increasing interest in understanding teleost bone mechanobiology resulting from the current importance of teleosts as aquaculture resources and as biomedical models. Thus, this paper aims at reviewing relevant data that contribute to understanding fundamental questions, such as how teleost bone recognizes the biomechanical environment and how it phenotypically responds to specific mechanical changes. Particularly relevant for research purposes, technological and technical aspects of one of the most used loading‐induced systems, the swimming exercise, are also presented.
Journal of Applied Ichthyology – Wiley
Published: Jan 1, 2018
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