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Glycerol
"Glycerol studies"
by FRanier (9976 pt)
2022-Oct-17 11:11

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Compendium of the most significant studies with reference to properties, intake, effects.

Vassilev N, Malusa E, Requena AR, Martos V, López A, Maksimovic I, Vassileva M. Potential application of glycerol in the production of plant beneficial microorganisms. J Ind Microbiol Biotechnol. 2017 May;44(4-5):735-743. doi: 10.1007/s10295-016-1810-2. 

Abstract. This review highlights the importance of research for development of biofertilizer and biocontrol products based on the use of glycerol for further process scale-up to industrial microbiology. Glycerol can be used successfully in all stages of production of plant beneficial microorganisms. It serves as an excellent substrate in both submerged and solid-state fermentation processes with free and immobilized microbial cells. Glycerol is also one of the most attractive formulation agents that ensures high cell density and viability including in harsh environmental conditions. Future research is discussed to make this inexpensive material a base for industrial production of plant beneficial microorganisms.

Nelson JL, Robergs RA. Exploring the potential ergogenic effects of glycerol hyperhydration. Sports Med. 2007;37(11):981-1000. doi: 10.2165/00007256-200737110-00005.

Abstract. During athletic competition or recreational pursuits, a body's hydration level can become compromised, resulting in a decrement in performance. Glycerol (1,2,3-propanetriol) has been used to induce hyperhydration in an attempt to offset the deleterious effects of dehydration. When glycerol is consumed orally, it is rapidly absorbed primarily in the small intestine. It is reported to be evenly distributed among all fluid compartments, with the exception of the cerebral spinal fluid and aqueous humour, and promotes hyperhydration by inducing an osmotic gradient. Through an increase in the kidney's medullary concentration gradient, water absorption in the nephron is enhanced. When glycerol is consumed, the plasma glycerol concentration increases in proportion to the dose ingested, which easily exceeds the glycerol saturation point resulting in urinary glycerol excretion. Thus, without supplemental glycerol ingestion, there will be a decrease in the osmotic gradient resulting in a loss of hyperhydration. The ergogenic nature of glycerol has been investigated as to its effect on fluid retention, thermoregulation, cardiovascular responses and performance. While many studies provide evidence of hyperhydration, others do not. Only two studies reviewed showed a thermoregulatory advantage. Furthermore, the preponderance of evidence neither weighed for or against cardiovascular or performance advantages. What makes one study provide favourable results while another study does not is unclear. Possible explanations may include subject characteristics, environmental factors, research design, whether fluids with or without glycerol were given during exercise, the rate at which fluids are initially given to induce hyperhydration, the time between peak hyperhydration/peak plasma glycerol concentration and the trial (i.e. exercise), the glycerol dose (i.e. 1.0 g/kg body mass) and what it is based upon, the percentage glycerol solution (i.e. 5%, 20%), the variation of time between the end of the hydration protocol and the beginning of exercise, or perhaps the intensity of exercise (fixed, variable, percentage maximum oxygen uptake). What is clear is that glycerol has the capacity to enhance fluid retention. In so doing, glycerol hyperhydration may be a logistically preferred method due to concomitant decrease in urine output and free-water clearance, which may give a performance advantage by offsetting dehydration. Future research should focus on maintaining plasma glycerol concentrations at levels necessary to maintain osmotic forces required to support continued hyperhydration. Potential benefits of glycerol should be further explored to identify the circumstances or factors that may contribute to an ergogenic effect.

Johnston DG, Alberti KG, Wright R, Blain PG. Glycerol clearance in alcoholic liver disease. Gut. 1982 Apr;23(4):257-64. doi: 10.1136/gut.23.4.257. 

Abstract. Glycerol clearance was studied by a primed dose-constant infusion technique in 14 patients with alcoholic liver disease and six normal control subjects. Fasting blood glycerol concentrations were raised in the alcoholic subjects (0.09 +/- 0.01 vs 0.06 +/- 0.01 mumol/l, p less than 0.05) and glycerol clearance was impaired (24.5 +/- 1.9 vs 37.5 +/- 3.2 ml/kg/min, p less than 0.005). Endogenous production rate of glycerol and distribution space at steady state were similar in alcoholic and control subjects. The metabolic clearance rate of glycerol correlated negatively with basal glycerol concentrations. Thus tissue uptake of glycerol is impaired in liver disease. As glycerol is metabolised primarily in the liver by conversion to glucose, these data suggest a defect of gluconeogenesis in alcoholic liver disease.

Laino T, Tuma C, Curioni A, Jochnowitz E, Stolz S. A revisited picture of the mechanism of glycerol dehydration. J Phys Chem A. 2011 Apr 21;115(15):3592-5. doi: 10.1021/jp201078e.

Abstract. The dehydration mechanism of neutral glycerol in the gas phase was investigated by means of metadynamics simulations. Structures, vibrational frequencies, Gibbs free energy barriers, and rate constants at 800 K were computed for the different steps involved in the pyrolytic process. In this article, we provide a novel mechanism for the dehydration of neutral glycerol, proceeding via formation of glycidol with a barrier of 66.8 kcal/mol. The formation of glycidol is the rate limiting step of the overall decomposition process. Once formed, glycidol converts into 3-hydroxypropanal with a barrier of 49.5 kcal/mol. 3-Hydroxypropanal can decompose further into acrolein or into formaldehyde and vinyl-alcohol with barriers of 53.9 and 35.3 kcal/mol, respectively. These findings offer new insights to available experimental data based on glycerol pyrolysis studies performed with isotopic labeling and on the interpretation of the chemistry of glycerol and sugars in pyrolytic conditions.

Samra JS, Ravell CL, Giles SL, Arner P, Frayn KN. Interstitial glycerol concentration in human skeletal muscle and adipose tissue is close to the concentration in blood. Clin Sci (Lond). 1996 Jun;90(6):453-6. doi: 10.1042/cs0900453.

Abstract. 1. The suggestion that the interstitial glycerol concentration in both adipose tissue and skeletal muscle is around 3 mmol/I (Maggs DG, Jacob R, Rife F, et al. J Clin Invest 1995; 96: 370-7), rather than close to the blood concentration as previously supposed, was tested by independent methods. 2. Free glycerol was infused, as part of a triacylglycerol emulsion, into six normal subjects and the arteriovenous difference for glycerol across the forearm was measured. In addition the relative interstitial glycerol concentration in subcutaneous adipose tissue was assessed simultaneously in four of the subjects by microdialysis. 3. During glycerol infusion the arterialized glycerol concentration rose from 52 +/- 5 mumol/I to 250-300 mumol/I (P < 0.001) in a square wave fashion. The net arteriovenous difference for glycerol across the forearm changed from negative (output) to positive (uptake) (P < 0.01). In subcutaneous adipose tissue the interstitial glycerol concentration rose during glycerol infusion (P < 0.001). 4. These observations are most easily explained by the movement of glycerol from plasma to interstitial fluid down a concentration gradient. We conclude that the interstitial glycerol concentration in skeletal muscle and adipose tissue is closer to the arterial concentration than to 3 mmol/I.

Pitlick WH, Pirikitakuhlr P, Painter MJ, Wessel HB. Effect of glycerol and hyperosmolality on intracranial pressure. Clin Pharmacol Ther. 1982 Apr;31(4):466-71. doi: 10.1038/clpt.1982.61.

Abstract. Glycerol has been used in cerebral edema for hyperosmolar dehydration of brain tissue, but only empirical relationships govern this use. Since the efficacy of treatment with glycerol would likely increase with data on the relationship between drug blood levels and intracranial pressure (ICP), we examined the clinical pharmacology of the drug. Plasma samples were assayed for glycerol by a new method using gas chromatography with a flame ionization detector. Data were collected from 12 children who were in Children's Hospital of Pittsburgh (CHP) and who had cerebral edema of differing etiology that was treated with glycerol; they were monitored by intraventricular catheter. Glycerol was infused according to CHP guidelines. ICP reduction correlated with glycerol concentration and plasma concentrations of 1 to 3 mg/ml (10 to 30 mOsm/ml) were necessary to maintain an ICP below 20 torr. The relationship between osmolality and plasma glycerol level was also examined; there was good correlation between the idiogenic osmolality and drug concentration. Our studies support the clinical observations that relatively high doses of glycerol (0.2 to 1.0 gm/kg/hr), leading to plasma concentrations of 10 to 30 mOsm/l, are necessary to control ICP in patients with cerebral edema. Glycerol blood levels may be estimated from serum osmolality.

Gonçalves ARP, Ribeiro APC, Orišková S, Martins LMDRS, Cristino AF, Dos Santos RG. Glycerol Valorization-The Role of Biochar Catalysts. Molecules. 2022 Sep 1;27(17):5634. doi: 10.3390/molecules27175634. 

Abstract. The conversion of renewable feedstocks into new added-value products is a current hot topic that includes the biodiesel industry. When converting vegetable oils into biodiesel, approximately 10% of glycerol byproduct is produced. Glycerol can be envisaged as a chemical platform due to its chemical versatility, as a scaffold or building block, in producing a wide range of added-value chemicals. Thus, the development of sustainable routes to obtain glycerol-based products is crucial and urgent. This certainly encompasses the use of raw carbonaceous materials from biomass as heterogeneous acid catalysts. Moreover, the integration of surface functional groups, such as sulfonic acid, in carbon-based solid materials, makes them low cost, exhibiting high catalytic activity with concomitant stability. This review summarizes the work developed by the scientific community, during the last 10 years, on the use of biochar catalysts for glycerol transformation.

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