Skeletal Muscle Interstitium and Blood pH at Rest and During Exercise in Humans

Street, Darrin

January 2003

The aims of this thesis were to: 1) develop a new method for the determination of interstitial pH at rest and during exercise in vivo, 2) systematically explore the effects of different ingestion regimes of 300 mg.kg-1 sodium citrate on blood and urine pH at rest, and 3) to combine the new interstitial pH technique with the findings of the second investigation in an attempt to provide a greater understanding of H+ movement between the extracellular compartments. The purpose of the first study was to develop a method for the continuous measurement of interstitial pH in vastus lateralis was successfully developed using microdialysis and 2,7-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF). To avoid the presence of an artificial alkalosis during exercise, it was necessary to add 25 mM HCO3- to the perfusate. The outlet of the probe was cut less than 10 mm from the skin and connected to a stainless steel tube completing the circuit to a microflow-through cuvette (8 fÝl) within a fluorescence spectrophotometer. This prevented the loss of carbon dioxide from the dialysate and any subsequent pH artefact. Interstitial pH was collected from six subjects before, during and after five minutes of knee-extensor exercise at three intensities 30, 50, and 70 W. Mean,,bSEM interstitial pH at rest was 7.38,,b0.02. Exercise reduced interstitial pH in an almost linear fashion. The nadir value for interstitial pH at 30, 50 and 70 W exercise was 7.27, 7.16 and 7.04, respectively. The lowest pH was obtained 1 min after exercise, irrespective of workload, after which the interstitial pH recovered in a nearly exponential manner. The mean half time of interstitial recovery was 5.2 min. The changes in interstitial pH exceeded the changes in venous blood pH. This study demonstrated that interstitial pH can be measured using microdialysis and that it is continuously decreased during muscle activity. The purpose of the second study was to establish an optimal ingestion regime for the ingestion of 300 mg.kg-1 of sodium citrate and maximise the alkalotic effect while minimising any side effects. Increasing the effectiveness of alkali ingestion may lead to further increases in muscle performance. Ingesting 300 mg.kg-1 sodium citrate at a rate of 300 mg.min-1 was identified as the optimal ingestion regime to maximise alkalosis at rest, which occurred 3.5 h post-ingestion. This was determined by monitoring eight human subjects ingesting 300 mg.kg-1 sodium citrate at five different rates, control (no ingestant), bolus, 300, 600 and 900 mg.kg.min-1 on five days separated by at least 48 hours. Sodium citrate was ingested in capsule form with water ad libitum, with the exception of bolus, which was combined with 400 ml less than 25 percent orange juice and consumed in less than 1 min. Arterialised blood (mean 71.3,,b3.5 mmHg) acid-base and electrolyte status was assessed via the withdrawal of ~5 ml of blood every 30 min across an eight hour duration, placed on ice and analysed within five minutes. No alkalotic difference was found between ingestion rates (mean 7.445,,b0.004, 7.438,,b0.004 and 7.442,,b0.004 for 300, 600 and 900 mg.min-1, respectively). All experimental ingestion regimes were associated with elevations in [HCO3-] (29.6, 29.7, 29.8, 29.9 and 26.3 mmol.l-1 for bolus, 300, 600, 900 and control, respectively). The 300 ingestion regime had the greatest impact on [H+], a 0.66 meq.l-1,,e10-8 change. Bolus ingestion (3.93,,b0.08 mmol.l-1) of sodium citrate had no effect on control (4.06,,b0.08 mmol.l-1) blood [K+], however, 300 mg.min-1 decreased blood [K+] (p less than 0.05). There was no effect of sodium citrate on blood [Cl-], but after 2.5 h blood [Cl-] was lower than pre-ingestion values (p less than0.05). All ingestion rates of sodium citrate increased (p less than 0.05) urine pH above control. This is the first study to investigate the effect of varying ingestion rates on acid-base status at rest in humans. The results suggest that ingesting sodium citrate in small doses in quick succession induce a greater blood alkalosis than the commonly practised bolus protocol. Using the interstitial pH technique described above and the optimal ingestion regime (300 mg.min-1) identified above, the final experiment was designed to assess the influence of sodium citrate ingestion on interstitial pH at both rest and during exercise. Five subjects ingested 300 mg.kg-1 sodium citrate at 300 mg.min-1 again in capsule form with water ad libitum. Prior to ingestion, each subject had a cannula placed into their cephalic vein and one microdialysis probe (CMA-60) inserted into their left thigh, orientated along the fibres of vastus lateralus. This probe was used for the measurement of pH as described above. At the end of this period, an exercise protocol required five subjects to perform light exercise (10 W) for 10 min, before starting an intense exercise period (~90-95% leg VO2peak) to exhaustion followed by a 15 min recovery period. Dialysate and blood samples were collected across all periods. Mean,,bSEM interstitial pH for placebo and alkalosis were 7.38,,b0.12 and 7.24,,b0.16, respectively. Sodium citrate ingestion was not associated with an interstitial alkalosis. An exercise induced acidosis was observed in the interstitium during placebo but not during alkalosis (p less than 0.05). Mean,,bSEM venous pH were 7.362,,b0.003 and 7.398,,b0.003 for placebo and alkalosis, respectively. Sodium citrate ingestion was not associated with a venous alkalosis. Sodium citrate ingestion was associated with an increase in mean,,bSEM venous [HCO3-] (placebo 25.5,,b0.2, alkalosis 28.1,,b0.2). This increase in the blood bicarbonate buffer system was not associated with an increase in time to exhaustion (placebo 352,,b71, alkalosis 415,,b171). This was the first study to investigate the effects of sodium citrate ingestion on interstitial pH. The results of this study demonstrated that an interstitial alkalosis does not ensue after alkali ingestion, however, it was associated with the lack of an exercise induced acidosis suggesting an improved pH regulation during exercise.

Alkali ingestion rate

Alkalosis

Bicarbonate perfusate

Blood pH

Dialysate pH

Ergogenesis

Interstitial pH

Knee-extensor exercise

Microdialysis

pH

Proton

Skeletal muscle

Sodium citrate

Urine pH

Physiological characteristics of sodium lactate infusion during resistance exercise / Fysiologisk karakteristika av natriumlaktat infusion under styrketräning

Danielsson, Sebastian

January 2019

Previous studies that utilized sodium lactate infusion did not use resistance exercise protocol or analyzed muscle biopsies, or performed sex specific analysis. Aim: We initiated a project where resistance exercise was performed with low and high levels of lactate, acquired by venous lactate infusion where the specific aim of this study was to investigate and chart the physiological characteristics of sodium lactate infusion during a bout of resistance exercise on whole group level and sexes separated Method: A randomized, placebo controlled, cross-over design was implemented where male (n = 8) and female (n = 8) subjects accustomed to resistance exercise visited the laboratory three times for preliminary testing and training familiarization. In the following two experimental trials subjects arrived in an overnight fasted state. A resting state muscle biopsy was extracted from m. vastus lateralis and repeated blood samples were initiated which followed by 20 minute of baseline infusion of either infusate in resting state at 0.05 mmol/kg/min infusion rate with additional bolus doses during subsequent exercise. Following a brief warm up, unilateral knee-extensions (6 x 8-10 reps at 75% of 1-RM) were performered with or without venous infusion of sodium lactate, with volume matched saline as control. Exercise load and volume were matched between trials. Four additional biopsies were extracted at post-exercise, recovery period, and 24-hour post-exercise. Results: Sodium lactate infusion vs saline infusion respectively during resistance exercise yielded significantly higher blood lactate with sodium lactate (6.78 ± 0.33 mmol/l vs 2.99 ± 0.17 mmol/l), plasma lactate (8.86 ± 0.39 mmol/l vs 4.39 ± 0.22 mmol/l), blood sodium (143 ± 0.4 mmol/l vs 142 ± 0.3 mmol/l), blood pH (7.42 ± 0.01 vs 7.34 ± 0.01), but lower blood potassium (3.9 ± 0.1 mmol/l vs 4.2 ±  0.1 mmol/l), all  immediately following exercise. Sodium lactate infusion elicited main effect of trials and muscle lactate increased from baseline (8.5 ± 0.9 mmol·kg-1 dw vs 7.0 ± 0.6 mmol·kg-1 dw) to post-exercise (31.5 ± 2.8 mmol·kg-1 dw vs 26.9 ± 3.2 mmol·kg-1 dw) with sodium lactate and saline infusion respectively. Blood glucose, hemoglobin and muscle pH was not affected by sodium lactate infusion. Conclusions: Utilization of the sodium lactate infusion method during a bout of resistance exercise may be used as tool to effectively increase blood/plasma lactate and, to lesser extent, muscle content of lactate. However, a concomitant slightly alkalizing effect of blood likely will occur. / Tidigare studier som använt natriumlaktat infusion använde inte styrketräningsprotokoll, eller analyserade muskelbiopsier eller utförde könsspecifika analyser. Syfte och frågeställningar: Vi initierade ett projekt där styrketräning utfördes med låga eller höga nivåer av laktat som erhölls genom venös natriumlaktat infusion med det specifika syftet att undersöka och kartlägga fysiologisk karakteristiska av naturiumlaktat infusion under styrketräningsövning på helgrupps- och könsseparerad nivå. Följande frågeställningar inrättades; hur påverkar natriumlaktat infusion under styrketräning helblod- och plasma laktat, glukos, natrium, kalium, plasma volym genom hemoglobin och hematokrit, blod pH, muskellaktat- och muskel pH samt om skillnader i respons finns efter att könsspecifika analyser utförts på dessa variabler. Metod: En randomiserad, placebokontrollerad cross-over design implementerades där styrketräningsvana män (n = 8) och kvinnor (n = 8) besökte laboratoriet tre gånger för preliminäraför tester och träningsfamiliarisering. I efterföljande två experimentella försök anlände försökspersonerna i ett över nattligt fastande tillstånd. En baslinje biopsi extraherades från m. vastus lateralis och repeterade blodprover initierades med efterföljande 20 minuter av baslinje infusion av endera infusat i vilotillstånd med 0.05 mmol/kg/min infusionshastighet med ytterligare bolusdoser under efterföljande träning. Efter en kort uppvärmning utfördes unilaterala knäextensioner (6 x 8-10 reps vid 75% av 1-RM) med eller utan venös infusion av natrium laktat, med volymmatchande saltlösning som kontroll. Träningsbelastning och volym matchades mellan försök. Ytterligare fyra biopsier extraherades vid efter-träning, återhämtningsperiod, och efter 24 timmar. Resultat: Natriumlaktat respektive saltlösnings infusion under styrketräning gav signifikant högre blodlaktat med natriumlaktat infusion (6.78 ± 0.33 mmol/l mot 2.99 ± 0.17 mmol/l), plasmalaktat (8.86 ± 0.39 mmol/l mot 4.39 ± 0.22 mmol/l), blodnatrium (143 ± 0.4 mmol/l mot 142 ± 0.3 mmol/l), blod pH (7.42 ± 0.01 mot 7.34 ± 0.01), men lägre blod kalium (3.9 ± 0.1 mmol/l mot 4.2 ± 0.1 mmol/l), alla direkt efter träning. Natriumlaktat infusion framkallade huvudeffekt av försök och muskellaktat ökade från baslinje (8.5 ± 0.9 mmol·kg-1 dw mot 7.0 ± 0.6 mmol·kg-1 dw) till efter-träning (31.5 ± 2.8 mmol·kg-1 dw mot 26.9 ± 3.2 mmol·kg-1 dw) med natriumlaktat respektive saltlösnings infusion. Blodglukos, hemoglobin och muskel pH påverkades inte av natriumlaktat infusion. Slutsats: Användande av natriumlaktat infusion som metod under styrketräning kan effektivt användas som verktyg för att höja blod/plasma laktat, och i mindre utsträckning, muskellaktat. Emellertid är samtidig alkalisering av blod en sannolik följd. / Potential sex differences in the molecular response to resistance exercise with lactate infusion

sodium lactate

sodium lactate infusion

infusion

resistance exercise

knee-extensor

vastus lateralis

metabolic effects

hematological effects

plasma lactate

muscle lactate

muscle content of lactate

MHC

fiber type

blood pH

muscle pH

blood lactate

blood sodium

blood potassium

blood glucose

hemoglobin

in vivo

randomized

cross-over

Sport and Fitness Sciences

Idrottsvetenskap