Respiratory Ammonia Output and Blood Ammonia Concentration During Incremental Exercise

SummaryStudy aim: To compare the blood ammonia and lactate concentrations in sprinters and triathletes during an incremental treadmill exercise test and in the 30 minutes of recovery. Material and methods: The study included 10 male sprinters and 14 male triathletes who compete at the national and international level. A treadmill test until exhaustion was administered. Blood samples for ammonia and lactate were obtained when the athletes were at rest, during and immediately after exercise, and between 5 and 30 min after exercise. Results: The ammonia concentration and time course were similar in the sprinters and triathletes (F = 1.81, p ≥ 0.05, η2 = 0.08). An exercise-related increase in blood ammonia was almost linear, regardless of the exercise intensity. In the case of lactate, the interactions between the concentrations measured in the sprinters and triathletes were statistically significant (F = 5.78, p ≤ 0.001, η2 = 0.21). Post-hoc tests revealed that the lactate concentrations differed significantly between the sprinters and triathletes in the 18th min (p ≤ 0.01) and the 21st min (p ≤ 0.001) of the exercise test. The blood lactate increased in a nonlinear manner (slowly at lower intensities and rapidly at higher intensities). During the 30 min recovery period, both the ammonia and lactate levels decreased linearly. However, in the sprinters, the peak values were maintained in the first stage of recovery (5 min post-exercise). Conclusions: The study showed that the blood ammonia concentration may be a useful marker of exercise-related metabolic responses in sprint-trained as well as in endurance-trained competitive athletes. Blood ammonia levels were more intensity-sensitive across the whole intensity range during the incremental exercise when compared to the blood lactate levels.

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Comparison of the effect of various amino acids upon the blood ammonia concentration of patients with liver disease

American Journal of Clinical Nutrition ◽

10.1093/ajcn/26.9.916 ◽

1973 ◽

Vol 26 (9) ◽

pp. 916-925 ◽

Cited By ~ 48

Author(s):

Daniel Rudman ◽

John T. Galambos ◽

Robert B. Smith ◽

Atef A. Salam ◽

W. Dean Warren

Keyword(s):

Amino Acids ◽

Liver Disease ◽

Ammonia Concentration ◽

Blood Ammonia

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Transient hyperammonaemia following epileptic seizures in cats

Journal of Feline Medicine and Surgery ◽

10.1177/1098612x20962747 ◽

2020 ◽

pp. 1098612X2096274

Author(s):

Charlotta H Nilsson ◽

Mikael BT Svensson ◽

Susanne JM Säve ◽

Sofie AE Van Meervenne

Keyword(s):

Epileptic Seizure ◽

Specific Treatment ◽

Epileptic Seizures ◽

Reference Interval ◽

Ammonia Concentration ◽

Blood Ammonia ◽

Initial Testing ◽

Close Proximity ◽

Veterinary Hospital

Objectives The aim of this study was to determine whether transient postictal hyperammonaemia exists in cats. Methods The medical records of all feline patients that presented at a Swedish veterinary hospital between 2008 and 2018 were retrospectively reviewed to find those that had a recent or ongoing epileptic seizure. To qualify for inclusion, the medical record had to include information on at least one ammonia value taken in close proximity to, or during, an active seizure, the cat must have exceeded the normal upper limit of blood ammonia concentration on initial testing (reference interval 0–95 μmol/l), and there needed to be a follow-up ammonia value available within a maximum of 3 days. Results Five cats were included in the study, and they had blood ammonia concentrations on initial testing ranging from 146 to 195 µmol/l. They were all retested within a period of 2 h to 3 days of the original reading. All five cats had a spontaneous decrease in ammonia levels without any specific treatment for hyperammonaemia. Conclusions and relevance Pursuant to the findings of this retrospective study, transient hyperammonaemia may be noted after epileptic seizure in cats. Consequently, a differential diagnostic list in feline patients with hyperammonaemia could, depending on the context, include non-hepatic-related pathologies, such as epileptic seizures.

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BLOOD AMMONIA CONCENTRATION AND ANAEROBIC PERFORMANCE DURING THE WINGATE ANAEROBIC TEST AND NA ADAPTED WINGATE TEST

Medicine & Science in Sports & Exercise ◽

10.1097/00005768-200105001-01857 ◽

2001 ◽

Vol 33 (5) ◽

pp. S331

Author(s):

M N. O. Sevilio ◽

A C. R. Lacerda ◽

K E. S. Silva ◽

L S. Prado

Keyword(s):

Ammonia Concentration ◽

Wingate Test ◽

Anaerobic Performance ◽

Blood Ammonia ◽

Wingate Anaerobic Test ◽

Anaerobic Test

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Dependence of in vivo glutamine synthetase activity on ammonia concentration in rat brain studied by 1H - 15N heteronuclear multiple-quantum coherence-transfer NMR

Biochemical Journal ◽

10.1042/bj3110681 ◽

1995 ◽

Vol 311 (2) ◽

pp. 681-688 ◽

Cited By ~ 32

Author(s):

K Kanamori ◽

B D Ross ◽

E L Kuo

Keyword(s):

Quantum Coherence ◽

Ammonia Concentration ◽

Multiple Quantum ◽

Blood Ammonia ◽

Coherence Transfer ◽

Heteronuclear Multiple Quantum Coherence ◽

Glutamine Synthesis ◽

Gaba Synthesis ◽

Multiple Quantum Coherence

The dependence of the in vivo rate of glutamine synthesis on the substrate ammonia concentration was studied in rat brain by 1H-15N heteronuclear multiple-quantum coherence-transfer NMR in combination with biochemical techniques. In vivo rates were measured at various steady-state blood and brain ammonia concentrations within the ranges 0.4-0.55 mumol/g and 0.86-0.98 mumol/g respectively, after low-rate intravenous 15NH4+ infusion (isotope chase). The rate of glutamine synthesis at steady state was determined from the change in brain [5-15N]glutamine levels during isotope chase, observed selectively through the amide proton by NMR, and 15N enrichments of brain glutamine and of blood and brain ammonia measured byN gas chromatography-MS. The in vivo rate (v) was 3.3-4.5 mumol/h per g of brain at blood ammonia concentrations (s) of 0.40-0.55 mumol/g. A linear increase of 1/v with 1/s permitted estimation of the in vivo glutamine synthetase (GS) activity at a physiological blood ammonia concentration to be 0.4-2.1 mumol/h per g. The observed ammonia-dependence strongly suggests that, under physiological conditions, in vivo GS activity is kinetically limited by sub-optimal in situ concentrations of ammonia as well as glutamate and ATP. Comparison of the observed in vivo GS activity with the reported in vivo rates of glutaminase and of gamma-aminobutyrate (GABA) synthesis suggests that, under mildly hyperammonaemic conditions, glutamine is synthesized at a sufficiently high rate to serve as a precursor of GABA, but glutaminase-catalysed hydrolysis of glutamine is too slow to be the sole provider of glutamate used for GABA synthesis.

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The Mechanism of Increase of Blood Ammonia Concentration

The Journal of Urology ◽

10.1016/s0022-5347(17)72172-6 ◽

1936 ◽

Vol 35 (1) ◽

pp. 82-85 ◽

Cited By ~ 1

Author(s):

H.E. Shih

Keyword(s):

Ammonia Concentration ◽

Blood Ammonia

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Failure of L-arginine to protect in ammonia intoxication: its role in urea source

American Journal of Physiology-Legacy Content ◽

10.1152/ajplegacy.1962.202.2.364 ◽

1962 ◽

Vol 202 (2) ◽

pp. 364-366 ◽

Cited By ~ 1

Author(s):

Herman Villarreal ◽

Regino Ronces ◽

Vidal Sánchez ◽

Heriberto Arcila

Keyword(s):

Protective Effect ◽

Ammonium Chloride ◽

Ammonia Concentration ◽

Blood Ammonia ◽

The Difference

The protective effect of l-arginine against ammonia intoxication produced by ammonium chloride was investigated in dogs. When l-arginine was administered together with NH4Cl, the increase in blood ammonia was approximately 25% less than when NH4Cl alone was given. Similar results with these substances were observed in dogs with hyperammoniemia. This protection, however, was only apparent since the variation was not statistically significant. Blood urea rose when NH4Cl was infused. When l-arginine was added, this increase was even greater and the difference was statistically significant. l-Arginine alone produced a definite rise in blood urea without blood ammonia concentration being affected. The conclusions are drawn that l-arginine does not protect against ammonia intoxication by NH4Cl and that increase in blood urea is due mainly to the metabolism of exogenous arginine rather than to the transformation of ammonia into urea.

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Valproic Acid and Topiramate Induced Hyperammonemic Encephalopathy in a Patient With Normal Serum Carnitine

The Journal of Pediatric Pharmacology and Therapeutics ◽

10.5863/1551-6776-18.2.128 ◽

2013 ◽

Vol 18 (2) ◽

pp. 128-136 ◽

Cited By ~ 1

Author(s):

Martha G. Blackford ◽

Stephanie T. Do ◽

Thomas C. Enlow ◽

Michael D. Reed

Keyword(s):

Valproic Acid ◽

Mental Status ◽

Pediatric Intensive Care ◽

Altered Mental Status ◽

Ammonia Concentration ◽

Normal Serum ◽

Urine Drug Screen ◽

Blood Ammonia ◽

Persistent Symptoms ◽

Hyperammonemic Encephalopathy

A 17-year-old female developed hyperammonemic encephalopathy 2 weeks after valproic acid (VPA), 500 mg twice a day, was added to her regimen of topiramate (TPM), 200 mg twice a day. She presented to the emergency department (ED) with altered mental status, hypotension, bradycardia, and lethargy. Laboratory analysis showed mild non-anion gap hyperchloremic acidosis, serum VPA concentration of 86 mg/L, and urine drug screen result that was positive for marijuana. She was admitted to the pediatric intensive care unit for persistent symptoms, prolonged QTc, and medical history. Blood ammonia concentrations were obtained because of her persistent altered mental status, initially 94 μmol/L and a peak of 252 μmol/L. A serum carnitine profile was obtained at the time of hyperammonemia and was found to be normal (results were available postdischarge). VPA and TPM were discontinued on day 1 and day 2, respectively, as the patient's blood ammonia concentration remained elevated. On day 3, her mental status had returned to baseline, and blood ammonia concentrations trended downward; by day 4 her blood ammonia concentration was 23 μmol/L. VPA has been associated with numerous side effects including hyperammonemia and encephalopathy. Recently, drug interactions with TPM and VPA have been reported; however, serum carnitine concentrations have not been available. We discuss the possible mechanisms that VPA and TPM may affect serum ammonia and carnitine concentrations and the use of levocarnitine for patients or treating toxicity.

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Blood ammonia concentration in cord blood during pregnancy

Early Human Development ◽

10.1016/0378-3782(93)90168-t ◽

1993 ◽

Vol 33 (1) ◽

pp. 1-8 ◽

Cited By ~ 8

Author(s):

Janice T. Desanto ◽

Wallace Nagomi ◽

Edward A. Liechty ◽

James A. Lemons

Keyword(s):

Cord Blood ◽

Ammonia Concentration ◽

Blood Ammonia

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