Applying physicochemical principles to skeletal muscle acid-base status.
about
The influence of intracellular lactate and H+ on cell volume in amphibian skeletal muscle.Glycolytic activation at the onset of contractions in isolated Xenopus laevis single myofibres.Protein and Essential Amino Acids to Protect Musculoskeletal Health during Spaceflight: Evidence of a Paradox?Expression and purification of TAT-fused carbonic anhydrase III and its effect on C2C12 cell apoptosis induced by hypoxia/reoxygenationSodium bicarbonate ingestion augments the increase in PGC-1α mRNA expression during recovery from intense interval exercise in human skeletal muscleRegulation of pH in human skeletal muscle: adaptations to physical activity.Pulmonary gas exchange and acid-base balance during exercise.Effects of gas exchange on acid-base balance.Energy demand and supply in human skeletal muscle.Lactate provides a strong pH-independent ventilatory signal in the facultative air-breathing teleost Pangasianodon hypophthalmusComments on Point:Counterpoint: Muscle lactate and H⁺ production do/do not have a 1:1 association in skeletal muscle. Calculations of Robergs support the view of Vinnakota and Kushmerick.Common phenotype of resting mouse extensor digitorum longus and soleus muscles: equal ATPase and glycolytic flux during transient anoxia.Effect of Two Types of Active Recovery on Fatigue and Climbing Performance.Is lactate production related to muscular fatigue? A pedagogical proposition using empirical facts.Reply to Robergs et al.Mathematical modelling of the acid-base chemistry and oxygenation of blood: a mass balance, mass action approach including plasma and red blood cells.Point: Lactic acid is the only physicochemical contributor to the acidosis of exercise.Creatine loading elevates the intracellular phosphorylation potential and alters adaptive responses of rat fast-twitch muscle to chronic low-frequency stimulation.Explaining pH Change in Exercising Muscle: Lactic acid, Proton Consumption, and Buffering vs. Strong Ion Difference
P2860
Q33239880-5D6D5A53-1153-471B-97E2-702F94B61035Q33822775-F86057C2-F12E-43D2-A331-2A0F9C3202FEQ34390397-67F151AF-EBD4-48EE-B1A7-7FBA4B4CF44AQ34440733-EB8DA76E-B12E-46F6-8939-48CBA65805C5Q36345886-1F9504F4-0901-40A6-9B60-A36236BAE708Q37081803-206E4A74-4B76-49BB-919B-258D1B93510CQ38110521-7B6215F9-8569-4541-931C-CB0B5CBE7E83Q38110759-D60FDD26-CF78-4845-A9E7-DBBEE61D74FAQ39175680-52A313A6-20CD-426D-9694-2113489F5B4AQ41124847-107248C3-2171-41D9-B51B-0A3446C56B3BQ41986557-1EF64314-4EC1-42D5-AA26-DEB5F8FD70C3Q43121785-519FB39A-903F-4265-B1D7-0B657503EE6FQ43158601-14743246-B162-4896-8B09-4A26F171DD09Q43233495-A67BEB6C-F4FE-4DAE-B003-3096DFE7D6C8Q50045886-39C9D018-60D5-41F8-AE82-C9C27926A6BFQ50594884-C9F089C4-4113-45B8-BDEE-5991E87970A3Q52920239-D5C15629-9FD3-4A43-8952-ADFEB2C6BDEAQ52939082-4F7640FF-1599-40AF-A4BB-7571055D5639Q56964889-C82608CB-749D-49D2-B76D-1BA412E11847
P2860
Applying physicochemical principles to skeletal muscle acid-base status.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Applying physicochemical principles to skeletal muscle acid-base status.
@en
Applying physicochemical principles to skeletal muscle acid-base status.
@nl
type
label
Applying physicochemical principles to skeletal muscle acid-base status.
@en
Applying physicochemical principles to skeletal muscle acid-base status.
@nl
prefLabel
Applying physicochemical principles to skeletal muscle acid-base status.
@en
Applying physicochemical principles to skeletal muscle acid-base status.
@nl
P2093
P2860
P1476
Applying physicochemical principles to skeletal muscle acid-base status.
@en
P2093
George J F Heigenhauser
John M Kowalchuk
Michael I Lindinger
P2860
P304
R891-4; author reply R904-910
P356
10.1152/AJPREGU.00225.2005
P577
2005-09-01T00:00:00Z