Lactate, ATP, and CP in working muscles during exhaustive exercise in man

1970 ◽  
Vol 29 (5) ◽  
pp. 598-602 ◽  
Author(s):  
Jan Karlsson ◽  
Bengt Saltin
Keyword(s):  
Blood Lactate ◽  
Muscle Tissue ◽  
Anaerobic Metabolism ◽  
Lactate Concentration ◽  
Oxygen Deficit ◽  
Bicycle Exercise ◽  
Muscle Lactate ◽  
Lactate Accumulation ◽  
Biopsy Specimens

The dynamics of lactate accumulation in working muscle was studied in three subjects performing maximal bicycle exercise of 2, 6, and 16 min duration. In separate experiments, the two longer maximal work periods were interrupted after 2 min and after 2 and 6 min, respectively. Biopsy specimens from the quadriceps femoris were obtained immediately after the work was terminated for determination of ATP, CP, glycogen, G-6-P and lactate. Blood lactate was also determined. The breakdown of the phosphagens (ATP and CP) was already maximal after 2 min of work in all experiments and averaged 2.7 and 3.6 mmole kg–1 wet muscle, respectively. The accumulation of lactate in the muscle and in the blood increased continuously until exhaustion and averaged in the muscle tissue both at the highest and medium loads 16.1 but was only 12.0 mmole kg–1 wet muscle at the lowest load. It is concluded that low ATP and CP stores in these experiments was not the reason for muscular fatigue. Further, if the muscle tissue lactate concentration was the reason for exhaustion on the two heaviest work loads another factor must be present to explain the exhaustion in the 16-min experiment. exhaustion; muscle metabolites; muscle lactate; blood lactate; anaerobic metabolism; oxygen deficit

Non-oxidative Energy Supply Correlates with Lactate Transport and Removal in Trained Rowers

2020 ◽  
Vol 41 (13) ◽  
pp. 936-943
Author(s):  
Hugo Maciejewski ◽  
Muriel Bourdin ◽  
Léonard Féasson ◽  
Hervé Dubouchaud ◽  
Laurent André Messonnier
Keyword(s):  
Blood Lactate ◽  
Energy Supply ◽  
Citrate Synthase ◽  
Monocarboxylate Transporter ◽  
Oxygen Deficit ◽  
Muscle Lactate ◽  
Lactate Accumulation ◽  
Accumulated Oxygen Deficit ◽  
Lactate Removal ◽  
Exercise Muscle

AbstractThis study aimed to test if the non-oxidative energy supply (estimated by the accumulated oxygen deficit) is associated with an index of muscle lactate accumulation during exercise, muscle monocarboxylate transporter content and the lactate removal ability during recovery in well-trained rowers. Seventeen rowers completed a 3-min all-out exercise on rowing ergometer to estimate the accumulated oxygen deficit. Blood lactate samples were collected during the subsequent passive recovery to assess individual blood lactate curves, which were fitted to the bi-exponential time function: La(t)= [La](0)+A1·(1–e–γ 1 t)+A2·(1–e–γ 2 t), where the velocity constants γ1 and γ2 (min–1) denote the lactate exchange and removal abilities during recovery, respectively. The accumulated oxygen deficit was correlated with the net amount of lactate released from the previously active muscles (r =0.58, P<0.05), the monocarboxylate transporters MCT1 and MCT4 (r=0.63, P<0.05) and γ2 (r=0.55, P<0.05). γ2 and the lactate release rate at exercise completion were negatively correlated with citrate synthase activity. These findings suggest that the capacity to supply non-oxidative energy during supramaximal rowing exercise is associated with muscle lactate accumulation and transport, as well as lactate removal ability.

Threshold for muscle lactate accumulation during progressive exercise

1989 ◽  
Vol 66 (6) ◽  
pp. 2710-2716 ◽  
Author(s):  
J. Chwalbinska-Moneta ◽  
R. A. Robergs ◽  
D. L. Costill ◽  
W. J. Fink
Keyword(s):  
Blood Lactate ◽  
Bicycle Ergometer ◽  
Exercise Tests ◽  
Muscle Lactate ◽  
Lactate Accumulation ◽  
Ergometer Exercise ◽  
Progressive Exercise ◽  
Blood Lactate Accumulation ◽  
Highly Correlated ◽  
The Relationship

The purpose of this study was to investigate the relationship between muscle and blood lactate concentrations during progressive exercise. Seven endurance-trained male college students performed three incremental bicycle ergometer exercise tests. The first two tests (tests I and II) were identical and consisted of 3-min stage durations with 2-min rest intervals and increased by 50-W increments until exhaustion. During these tests, blood was sampled from a hyperemized earlobe for lactate and pH measurement (and from an antecubital vein during test I), and the exercise intensities corresponding to the lactate threshold (LT), individual anaerobic threshold (IAT), and onset of blood lactate accumulation (OBLA) were determined. The test III was performed at predetermined work loads (50 W below OBLA, at OBLA, and 50 W above OBLA), with the same stage and rest interval durations of tests I and II. Muscle biopsies for lactate and pH determination were taken at rest and immediately after the completion of the three exercise intensities. Blood samples were drawn simultaneously with each biopsy. Muscle lactate concentrations increased abruptly at exercise intensities greater than the “below-OBLA” stage [50.5% maximal O2 uptake (VO2 max)] and resembled a threshold. An increase in blood lactate and [H+] also occurred at the below-OBLA stage; however, no significant change in muscle [H+] was observed. Muscle lactate concentrations were highly correlated to blood lactate (r = 0.91), and muscle-to-blood lactate ratios at below-OBLA, at-OBLA, and above-OBLA stages were 0.74, 0.63, 0.96, and 0.95, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

scholarly journals Use of the Accusport semi-automated analyser to determine blood lactate as an aid in the clinical assessment of horses with colic

2001 ◽  
Vol 72 (1) ◽  
Author(s):  
M.L. Schulman ◽  
J.P. Nurton ◽  
A.J. Guthrie
Keyword(s):  
Blood Lactate ◽  
Laboratory Data ◽  
Lactate Concentration ◽  
Blood Lactate Concentration ◽  
Tissue Perfusion ◽  
Diagnostic Methods ◽  
Initial Assessment ◽  
Clinically Normal ◽  
Case Outcome

The most useful diagnostic methods in the initial evaluation of horses with colic assess the morphological and functional status of the gastrointestinal tract and cardiovascular status. This evaluation is best achieved using a combination of clinical and laboratory data. Blood lactate concentration (BL) is one of these variables. BL rises mainly due to poor tissue perfusion and anaerobic glycolysis associated with shock, providing an indicator of both the severity of disease and its prognosis. A hand-held lactate meter, Accusport, provides a rapid (60 seconds), inexpensive dry-chemical-based determination of BL. This trial evaluated the Accusport's ability to provide BL data as an adjunct to the initial clinical evaluation of horses with colic. The accuracy of the Accusport was tested by evaluation of its interchangeability with the benchmark enzymatic kit evaluation of BL in a trial using data collected firstly from 10 clinically normal control horses and subsequently from 48 horses presented with signs of colic. The BL values were recorded together with the clinical variables of heart rate (HR), capillary refill time (CRT), haematocrit (Hct), and pain character and severity on the initial assessment of the colic horses. Information regarding choice of therapeutic management (medical or surgical) and eventual case outcome (full recovery or died/euthanased) was recorded. The Accusport was found to be interchangeable with the enzymatic kit for recording BL values in colic horses with BL <10 mmol/ , which is within the BL range associated with survival. The interchangeability of an additional, laboratory-based wet chemical assay for BL, the Stat 7 was simultaneously evaluated for the colic and control horses. The Stat 7 was found to be interchangeable with the enzymatic kit for BL determination of colic horses. No linear associations between BL values with HR, CRT, Hct or pain assessment were observed. No relationship with either selection of therapeutic method or eventual case outcome was observed. All horses with BL >8 mmol/ died or were euthanased.

Disposal of blood [1-13C]lactate in humans during rest and exercise

1986 ◽  
Vol 60 (1) ◽  
pp. 232-241 ◽  
Author(s):  
R. S. Mazzeo ◽  
G. A. Brooks ◽  
D. A. Schoeller ◽  
T. F. Budinger
Keyword(s):  
Blood Lactate ◽  
Lactate Concentration ◽  
Blood Lactate Concentration ◽  
Curvilinear Relationship ◽  
O2 Consumption ◽  
Lactate Oxidation ◽  
Respiratory Parameters ◽  
Steady Rate ◽  
Lactate Levels

Lactate irreversible disposal (RiLa) and oxidation (RoxLa) rates were studied in six male subjects during rest (Re), easy exercise [EE, 140 min of cycling at 50% of maximum O2 consumption (VO2max)] and hard exercise (HE, 65 min at 75% VO2max). Twenty minutes into each condition, subjects received a Na+-L(+)-[1–13C]lactate intravenous bolus injection. Blood was sampled intermittently from the contralateral arm for metabolite levels, acid-base status, and enrichment of 13C in lactate. Expired air was monitored continuously for determination of respiratory parameters, and aliquots were collected for determination of 13C enrichment in CO2. Steady-rate values for O2 consumption (VO2) were 0.33 +/- 0.01, 2.11 +/- 0.03, and 3.10 +/- 0.03 l/min for Re, EE, and HE, respectively. Corresponding values of blood lactate levels were 0.84 +/- 0.01, 1.33 +/- 0.05, and 4.75 +/- 0.28 mM in the three conditions. Blood lactate disposal rates were significantly correlated to VO2 (r = 0.78), averaging 123.4 +/- 20.7, 245.5 +/- 40.3, and 316.2 +/- 53.7 mg X kg-1 X h-1 during Re, EE, and HE, respectively. Lactate oxidation rate was also linearly related to VO2 (r = 0.81), and the percentage of RiLa oxidized increased from 49.3% at rest to 87.0% during exercise. A curvilinear relationship was found between RiLa and blood lactate concentration. It was concluded that, in humans, 1) lactate disposal (turnover) rate is directly related to the metabolic rate, 2) oxidation is the major fate of lactate removal during exercise, and 3) blood lactate concentration is not an accurate indicator of lactate disposal and oxidation.

Anaerobic metabolism during pubertal development at high altitude

1988 ◽  
Vol 64 (4) ◽  
pp. 1382-1386 ◽  
Author(s):  
N. Fellmann ◽  
M. Bedu ◽  
H. Spielvogel ◽  
G. Falgairette ◽  
E. Van Praagh ◽  
...  
Keyword(s):  
High Altitude ◽  
Anaerobic Metabolism ◽  
Pubertal Development ◽  
Lactate Concentration ◽  
Blood Lactate Concentration ◽  
Bicycle Exercise ◽  
Gonadal Maturation ◽  
Testosterone Concentration ◽  
Salivary Testosterone ◽  
Low Altitude

In a previous study we showed that there were no differences in anaerobic metabolism between groups of 11-yr-old children living at high (3,700 m) and low (330 m) altitudes. The aim of this study is to investigate changes in this metabolism during pubertal development. We compare blood lactate concentration ([L]) after maximal bicycle exercise in 20 boys acclimatized to high altitude (HA, 12 yr old) and at low altitude in 14 boys (LA1, 12 yr old) and in 13 boys (LA2, 14 yr old). The subjects had the same level of physical fitness and the same nutritional and socioeconomic status. Pubertal development was identified by salivary testosterone concentration ([T]). Results (means ± SE) showed 1) at the age of 12 years, [L] and [T] in HA were significantly higher than in LA1 ([L] was 9.2 ± 0.5 vs. 6.8 ± 0.5 mmol/l, [T] was 233 ± 66 vs. 132 ± 30 pmol/l), 2) [L] and [T] in HA were statistically the same as in LA2, and 3) a linear relationship between [L] and [T] was significant (P less than 0.05) in all HA and LA subjects. This suggests that the higher [L] in 12-yr-old boys living at HA could result in an enhanced anaerobic metabolism linked to an earlier gonadal maturation evaluated by testosterone level.

Lactate accumulation in fully aerobic, working, dog gracilis muscle

1984 ◽  
Vol 246 (1) ◽  
pp. H120-H128 ◽  
Author(s):  
R. J. Connett ◽  
T. E. Gayeski ◽  
C. R. Honig
Keyword(s):  
Steady State ◽  
Lactate Concentration ◽  
Capillary Density ◽  
Gracilis Muscle ◽  
Tissue Sampling ◽  
Muscle Lactate ◽  
Lactate Accumulation ◽  
Atp Production ◽  
Work Transition ◽  
Red Muscle

Tissue lactate was measured in dog gracilis muscles frozen at rest and during phasic twitch contractions, which evoked 10-100% of maximum O2 consumption (VO2 max). Myoglobin cryomicrospectroscopy was used to obtain the distribution of PO2 in subcellular volumes. Tissue sampling was designed to estimate lactate concentration in the population of cells used for spectroscopy. Covariates included vascular resistance, functional capillary density, VO2, tissue pyruvate, ATP, phosphocreatine, and creatine, as well as lactate efflux. Myoglobin saturation did not decrease in the first seconds of stimulation at 1 or 4/s. In the steady state, muscle lactate accumulation was linear with stimulation rate and VO2. At 1 and 4/s the minimum PO2 found was greater than 5 Torr during the rest-work transition and greater than 2 Torr in the steady state. VO2 did not increase when flow was increased during contraction at 1/s, although the minimum PO2 found rose to approximately 10 Torr. If flow was restricted during stimulation, PO2 was 0 at many loci, and lactate concentration was elevated above the value predicted by its linear relationship with twitch rate. We conclude that fully aerobic lactate accumulation occurs in this pure red muscle. This accumulation results from causes other than a simple O2 limit on mitochondrial ATP production.

Lactic acid infusion in dogs: effects of varying infusate pH

1983 ◽  
Vol 54 (5) ◽  
pp. 1254-1260 ◽  
Author(s):  
L. B. Gladden ◽  
J. W. Yates
Keyword(s):  
Lactic Acid ◽  
Blood Lactate ◽  
Muscle Blood Flow ◽  
Lactate Concentration ◽  
Blood Lactate Concentration ◽  
Weak Acid ◽  
Muscle Lactate ◽  
Acid Infusion ◽  
Arterial Blood ◽  
Arterial Ph

This study had two purposes: 1) to determine the effects of varying the pH of lactic acid infusion solutions on the acid-base status of anesthetized dogs, and 2) to determine the effect of elevated blood lactate concentration on muscle lactate concentration. The experiments were performed on the in situ gastro cnemius-plantaris muscle group in 14 mongrel dogs. The infusions increased the arterial blood lactate concentration to 11.0 +/- 0.5 (SE) mM after 20 min. Above an infusate pH of 4.4, the arterial pH increased by 0.118–0.167 during infusion; the arterial pH was unchanged when the infusate pH was between 3.4 and 4.0; and the arterial pH decreased as infusate pH decreased below 3.0. The effect of lactic acid infusion on blood pH appears to be the result of two opposing effects: 1) an acidifying effect due to its weak acid properties, and 2) an alkalinizing effect due to the metabolism of sodium lactate. The estimated ratio between intracellular muscle lactate and venous plasma water lactate averaged 0.647 +/- 0.038, indicative of a substantial gradient between blood and muscle. The infusion produced a significant change from lactate output to lactate uptake by the muscles. The infusion also transiently increased muscle blood flow and oxygen uptake.

Effect of Storage Techniques on Blood Lactate Concentration and Determination of Various Lactate Threshold Definitions

2006 ◽  
Vol 38 (Supplement) ◽  
pp. S514
Author(s):  
Matthew J. Garver ◽  
Leland J. Nielsen ◽  
Jared M. Dickinson ◽  
Derek S. Campbell ◽  
Charilaos Papadopoulos ◽  
...  
Keyword(s):  
Blood Lactate ◽  
Lactate Threshold ◽  
Lactate Concentration ◽  
Blood Lactate Concentration

Non-exhaustive test for aerobic capacity determination in swimming rats

2006 ◽  
Vol 31 (6) ◽  
pp. 731-736 ◽  
Author(s):  
Fúlvia de Barros Manchado ◽  
Claudio Alexandre Gobatto ◽  
Fabricio Azevedo Voltarelli ◽  
Maria Alice Rostom de Mello
Keyword(s):  
Blood Lactate ◽  
Body Mass ◽  
Aerobic Capacity ◽  
Lactate Concentration ◽  
Linear Interpolation ◽  
Progressive Increase ◽  
Blood Collection ◽  
Adult Rats ◽  
Capacity Determination

The aim of this study was to describe a double-bout exercise test for non-exhaustive aerobic capacity determination in swimming rats. Adult rats were submitted to 4 swimming tests at different intensities (4%, 6%, 7%, and 8% of body mass), with intervals of 48 h between them. Two exercise bouts of equal intensity lasting 5 min were performed, separated by 2 min with blood collection for lactate analysis. For each intensity, delta lactate was determined by subtracting lactate concentration at the end of the first effort from the lactate at the end of the second effort. Individual linear interpolation of delta lactate concentration enabled determination of a “null” delta, equivalent to the critical load (CL). Maximal lactate steady state (MLSS) was also determined. The estimated CL was of 4.8% body mass and the MLSS was observed at 100% of CL, with blood lactate of 5.20 mmol/L. At 90%, blood lactate stabilized, with a progressive increase to 110% CL. These results offer a potential determination of aerobic capacity in swimming rats.

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