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Interleukin-1 receptor antagonist protects against lipopolysaccharide induced diaphragm weakness in preterm lambsThree-dimensional optical coherence micro-elastography of skeletal muscle tissue.Lipopolysaccharide-induced weakness in the preterm diaphragm is associated with mitochondrial electron transport chain dysfunction and oxidative stress.Endothermic force generation, temperature-jump experiments and effects of increased [MgADP] in rabbit psoas muscle fibres.Force generation examined by laser temperature-jumps in shortening and lengthening mammalian (rabbit psoas) muscle fibres.Optical coherence tomography-based contact indentation for diaphragm mechanics in a mouse model of transforming growth factor alpha induced lung disease.Effect of maternal steroid on developing diaphragm integrity.Deletion of Dystrophin In-Frame Exon 5 Leads to a Severe Phenotype: Guidance for Exon Skipping Strategies.Influence of antenatal glucocorticoid on preterm lamb diaphragm.Increasing taurine intake and taurine synthesis improves skeletal muscle function in the mdx mouse model for Duchenne muscular dystrophy.Gestational age at initial exposure to in utero inflammation influences the extent of diaphragm dysfunction in preterm lambs.Beneficial effects of high dose taurine treatment in juvenile dystrophic mdx mice are offset by growth restriction.Developmental changes in diaphragm muscle function in the preterm and postnatal lamb.The effects of the myosin-II inhibitor N-benzyl-p-toluene sulphonamide on fatigue in mouse single intact toe muscle fibres.On the ascent: the soleus operating length is conserved to the ascending limb of the force-length curve across gait mechanics in humans.Gestational age at time of in utero lipopolysaccharide exposure influences the severity of inflammation-induced diaphragm weakness in lambs.Pre-clinical evaluation of N-acetylcysteine reveals side effects in the mdx mouse model of Duchenne muscular dystrophy.In utero LPS exposure impairs preterm diaphragm contractility.Reply from Gavin J. Pinniger, Jessica R. Terrill, Miranda D. Grounds and Peter G. Arthur.The force-velocity relationship of the human soleus muscle during submaximal voluntary lengthening actions.Fiber-type dependence of stretch-induced force enhancement in rat skeletal muscle.Effects of simulated viewpoint jitter on visually induced postural sway.Contractile properties of slow and fast skeletal muscles from protease activated receptor-1 null miceH-reflex modulation during passive lengthening and shortening of the human triceps suraeDysferlin-deficiency has greater impact on function of slow muscles, compared with fast, in aged BLAJ miceDoes fatigue induced by repeated dynamic efforts affect hamstring muscle function?Tension regulation during lengthening and shortening actions of the human soleus muscleResidual force enhancement after lengthening is present during submaximal plantar flexion and dorsiflexion actions in humansThe physiological effects of IGF-1 (class 1:Ea transgene) over-expression on exercise-induced damage and adaptation in dystrophic muscles of mdx miceBlockade of TNF in vivo using cV1q antibody reduces contractile dysfunction of skeletal muscle in response to eccentric exercise in dystrophic mdx and normal miceCrossbridge and non-crossbridge contributions to tension in lengthening rat muscle: force-induced reversal of the power strokeMechanism of force enhancement during and after lengthening of active muscle: a temperature dependence studySkeletal muscle weakness caused by carrageenan-induced inflammationWhat is the mechanism for in vivo loss of skeletal muscle function in elderly women?Intrauterine growth restriction affects diaphragm function in adult female and male mice
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Q28546032-49F34033-E99E-4F2F-90CA-E0A839A6C63CQ30426112-C0A3A57E-AD8C-477C-8EBA-760D5BDDCAFCQ31138969-0180A11F-4B41-4BCF-AA87-94C9E783D388Q33217802-BA16E2EE-54BA-4F76-9A33-E186A57B5AAEQ33301614-F03DE6CD-6262-4303-B37E-A54AF3753614Q33685332-6D3FC568-4760-4629-A413-6679E99BCDD6Q35134919-1F5D73DD-79CD-4329-9916-C16409F41D03Q35888871-19B4393A-A04A-49A4-B70F-EA2D831111D4Q38847716-5E5F66AB-D584-4783-8479-81F5D1BC30BEQ40219200-ECBFF6D9-6269-4787-A8BD-44BCF757C9A6Q41031384-A4D6B49D-B932-4BD9-826B-7592344CD65FQ43845526-7F67495E-7A88-4A0B-9F61-021624A14967Q44075339-B9F78460-1FC5-4F23-A3C8-89F145011E3DQ46959760-5FD72DEA-87CB-4AEF-8ED5-20900A701F5FQ47409643-69D13101-BF8A-4D76-B7A2-AD5408989B0AQ47688155-D0B99F14-23FB-4086-AD74-62CA7A8E4478Q47830220-3ED1DC98-9058-4DFE-8BE0-8DF3D082B8FBQ47996428-9477EBDD-C246-47C7-B1FB-89261B19E3D2Q48325165-B7BDFD8C-D64C-4CEF-B5AE-CE5C5C6E357BQ48950561-248CC732-190A-436B-969E-366E56ECEFF5Q51643753-0239E553-DA01-4336-868E-26148D2F3691Q51659620-91151F6A-467B-4543-97CA-F810F0A6050EQ59766717-5789F0C6-C67B-4BC1-B12A-3ADFE3D9499CQ63433542-767E6090-1C9D-4A1E-BE91-8803D135B90BQ64061047-859B337C-35A3-46BE-B0FE-F8AC84276F69Q73579435-8FE9AA9A-A453-4DEC-8A3A-D718F5111077Q73633869-A447F0AA-62FB-4A1C-B4DE-2CA86A229720Q80198752-6C44B610-C045-404F-8CC4-726EB5C37534Q81826532-8E3DD8A7-10FE-46AC-A314-74FF87D6E968Q82341401-D25D7AE1-56D1-41F0-A9D4-F9EC1894B0E4Q83181275-4DE1D397-8EDC-434A-8DE0-B8E561D284E4Q84395157-CAA184A5-8B8F-4F2C-ACB9-1EB97C33ACECQ84830156-E3C1D365-331D-4F62-B3BB-642920489B7FQ85506910-F9ED08FE-BC03-482D-9DBB-D7D2BDF24B1DQ90174671-C1251C54-DE32-484C-B8D1-7C97C8DF974F
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description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Gavin J Pinniger
@ast
Gavin J Pinniger
@en
Gavin J Pinniger
@es
Gavin J Pinniger
@nl
Gavin J Pinniger
@sl
type
label
Gavin J Pinniger
@ast
Gavin J Pinniger
@en
Gavin J Pinniger
@es
Gavin J Pinniger
@nl
Gavin J Pinniger
@sl
prefLabel
Gavin J Pinniger
@ast
Gavin J Pinniger
@en
Gavin J Pinniger
@es
Gavin J Pinniger
@nl
Gavin J Pinniger
@sl
P1053
F-1421-2013
P106
P21
P31
P3829
P496
0000-0002-4400-0817