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EC number: 425-180-1 | CAS number: 66170-10-3
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Description of key information
Short description of key information on bioaccumulation potential result:
The toxicokinetik assessment was done by expert judgment based on the toxicological profile of Ascorbic acid as Sodium ascorbyl phosphate is assumed to be hydrolysed to ascorbic acid by phosphatases.
Short description of key information on absorption rate:
Based on the results of a dermal penetration study in vitro with L-ascorbic acid-2-phosphate magnesium salt, as structural analogue of Sodium Ascorbyl Phosphate, as a worst case assumption a dermal penetration rate of 1 % is assumed. For detailed calculation see discussion section.
Key value for chemical safety assessment
- Absorption rate - dermal (%):
- 1
Additional information
Toxicokinetic Assessment of Sodium ascorbyl phosphate
The substance Sodium ascorbyl phosphate is the tri-sodium salt of the L-Ascorbic acid 2-monophosphate ester. Concerning the toxicological behaviour it can be assumed that Sodium ascorbyl phosphate is hydrolysed to ascorbic acid in the gastrointestinal tract by phosphatases to a great extent. If an absorption of unchanged Sodium ascorbyl phosphate occurs, it is supposed to be also degraded by phosphatases in different tissues and organs. It can be thus concluded that the toxicokinetic behaviour of Sodium ascorbyl phosphate is almost identical with the toxicokinetics of Ascorbic acid, which is described more detailed below. A 28-day oral toxicity study in rats after administration via the drinking water shows that Sodium ascorbyl phosphate and Ascorbic acid is available systemically. The findings in the urinary bladder of the animals indicate that the excretion occurs mainly via the urine [4]. Due to the hydrophilic character of Sodium ascorbyl phosphate and Ascorbic acid an accumulation in the body can be excluded. These assumptions are confirmed by experimental data described below. Furthermore Ascorbic acid represents a physiological molecule. Sodium ascorbyl phosphate may after phosphatase-mediated hydrolysis become part of the physiological Ascorbic acid pool in the body.
Although no experimental data are available concerning the absorption of Sodium ascorbyl phosphate itself, a dermal penetration study was performed with the derivative L-ascorbic acid-2 -phosphate magnesium (A2P). Since the chemical / physical properties and therewith the dermal penetration behavior can be assessed to be comparable for the two derivatives, the data for the magnesium salt are summarized in the following section. Consequently, the assessment of the sodium salt is based on the data for the magnesium salt, taking worst case penetration scenarios into account.
In the dermal penetration study an absorption of 0.019 %/h of the applied amount L-ascorbic acid-2-phosphate magnesium salt (A2P) was resorbed via the skin [5]. Thus for an 8 h working day a dermal penetration of 0.16 % is calculated.
As outlined before, these data are taken as a basis for a worst case assumption for sodium ascorbyl phosphate assuming a maximum dermal penetration of 1% of the applied dose.
In the following the toxicokinetic behaviour of Ascorbic acid is summarised.
Absorption and tissue concentrations
Absorption studies have been carried out in rats and humans. In rats after an IP injection of 1.5-5.9 mg of 14C-labeled ascorbic acid, 19 - 29 % was converted to CO2 and only 0.4 % was excreted as oxalic acid within 24 h. The average absorption of Ascorbic acid has been estimated to be 84 % in humans. Ascorbic acid is considered to enter in the physiological Ascorbic acid (vitamin C) pool. It was observed that increasing, oral intake from 1.5 to 12 g decreased the relative absorption of Ascorbic acid from about 50 % to only 16 % [summarised in 1].
The effect of ascorbic acid supplementation on CF1 mice fed ascorbic acid for approximately six months at dose levels of 1 %, 5 %, and 10 % of diet was investigated by analysis of tissue ascorbic acid concentration in the liver, kidney, stomach, small intestine, and large bowel. In the control animals, Ascorbic acid concentration was lowest in the liver (0.406 ±: 0.07 mg/g) and highest in the small bowel (0.754 ± 0.16 mg/g). Dietary intake of 5 % and 10 % ascorbic acid significantly elevated levels in the liver (0. 741 ± 0.13), and all doses of ascorbic acid significantly raised tissue concentrations in the kidney and colon [2].
L-Ascorbic acid was found in the adrenal and pituitary glands of rats at concentra-tions of 280 - 400 mg/100 g tissue and 100 – 130 mg/100 g tissue, and in the adrenal and pituitary glands of adult humans at concentrations of 30 – 40 mg/100 g tissue and 40 – 50 mg/100 g tissue. Concentrations exceeding 10 – 15 mg/100 g tissue are found in the spleen, brain, liver, kidney, testes, eye lens, and white blood cells of both rats (strain unstated) and humans. In another study, rats and mice of unspecified strains were found to have L-ascorbic acid concentrations of 508 and 808 mg/100 g tissue in the adrenal glands and 349 and 1,052 mg/100 g in the ovaries. Concentrations of L-ascorbic acid in the pituitary gland were not reported. The body pool of ascorbic acid in rats (strain unspecified) has been calculated to be 10.7 mg/100 g body weight [summarised in 3].
Metabolism
Ascorbic acid undergoes biochemical degradation in the body and, when excess is administered, can be excreted unchanged. Ascorbic acid is oxidized to carbon dioxide in guinea pigs and rats and to oxalate in man. When 14C-ascorbic acid was administered by intraperitoneal injection to rats of an unspecified strain of doses of 44 or 51 mg, 0.57 % or 1.18 % of the dose was found as labeled oxalic acid in the urine. L-Xylonic acid, L-lyxonic acid, ascorbic acid-2-sulfate, and 2-methyl-L-ascorbic acid have been identified as metabolites of L-ascorbic acid in rats. The metabolism of ascorbic acid depends on several factors, including (among other things) the route of administration, dosage, and the nutritional status of the animal [summarised in 3].
Excretion
Ascorbic acid is excreted by glomerular filtration and active tubular reabsorption. The renal excretion threshold for vitamin C in humans is approximately 1.4 mg %. High doses of Ascorbic acid (4 g or more) increased the urinary excretion of oxalate. About 40 % of the urinary oxalate was derived from Ascorbic acid. It was observed that at daily intakes of 4 g of Ascorbic acid, the urinary oxalate level increased 10-fold, which may lead to the formation of kidney stones. However, in an evaluation of the safety of high vitamin C intakes, it was observed that even with large daily intakes the amount of oxalic acid formed was far too little to contribute significantly to oxalate formation [summarised in 1, 3].
References
[1] Madhavi, D.L. and Salunkhe, D.K. (1996):
Toxicological Aspects of Food Antioxidants, Food Science and Technology 71, 267-359
[2] Deschner, E.E., Alcock, N., Okamura, T., DeCosse, J.J. and Scherlock, P. (1983):
Tissue Concentrations and proliferative effects of massive doses of Ascorbic acid in the mouse, Nutrition and Cancer, Vol. 4, No. 4, 241-246
[3] US Department of Health and Human Services (1983):
NTP Technical Report on the carcinogenesis bioassay of L-Ascorbic acid (vitamin C) (CAS No. 50-81-7) in F344/N Rats and B6C3F1 mice (feed study).
[4] Mellert, W., Deckardt, K., Gembardt, C. and Hildebrand, B. (1998):
Sodium ascorbyl phosphate: Repeated dose oral toxicity study in Wistar rats, Administration in drinking water for 4 weeks and recovery period of 2 weeks, un-published BASF-Report
[5] Yoo, J., Shanmugam, S., Song, C., Kim, D., Choi, H., Yong, C., Woo, J., Yoo, B. (2008):
Skin Penetration and Retention of L-Ascorbic Acid 2 -Phosphate Using Multilamellar Vesicles, Arch Pharm Res Vol 31, No. 12, 1652 -1658
Discussion on bioaccumulation potential result:
The substance Sodium ascorbyl phosphate is the tri-sodium salt of the L-Ascorbic acid 2-monophosphate ester. Concerning the toxicological behaviour it can be assumed that Sodium ascorbyl phosphate is hydrolysed to ascorbic acid in the gastrointestinal tract by phosphatases to a great extent. If a resportion of unchanged Sodium ascorbyl phosphate occurs, it is supposed to be also degraded by phosphatases in different tissues and organs. It can be thus concluded that the toxicokinetic behaviour of Sodium ascorbyl phosphate is almost identical with the toxicokinetics of Ascorbic acid. A 28-day oral toxicity study in rats after administration via the drinking water shows that Sodium ascorbyl phosphate respectively Ascorbic acid is available systemically. The findings in the urinary bladder of the animals indicate that the excretion occurs mainly via the urine. Due to the hydrophilic character of Sodium ascorbyl phosphate and Ascorbic acid an accumulation in the body can be excluded. Further-more Ascorbic acid represents a physiological molecule. Sodium ascorbyl phosphate may after phosphatase-mediated hydrolysis become part of the physiological Ascorbic acid pool in the body.
Discussion on absorption rate:
Although no experimental data are available concerning the absorption of Sodium ascorbyl phosphate itself, a dermal penetration study was performed with the derivative L-ascorbic acid-2 -phosphate magnesium (A2P). The chemical / physical properties and therewith the dermal penetration behavior can be assessed to be comparable for the two derivatives.
In this dermal penetration study in vitro L-ascorbic acid-2-phosphate magnesium salt (A2P) was administered to the skin prepared from hairless mice. 0.4 mL were applied on the skin and allowed to spread over the skin. The penetration was determined by HLPC analysis.
The dermal penetration of L-ascorbic acid-2-phosphate magnesium salt (A2P) was determined to be 0.6926 nmole x cm2/h. For the dermal penetration assay 0.4 ml were applied on a surface area of 2 cm2. As a worst case assumption 1 mg/cm2 was used for calculation. In conclusion 0.019 %/h of L-ascorbic acid-2-phosphate magnesium salt (A2P) is resorbed via the skin. For an 8 h working day a dermal penetration of 0.16 % is calculated. For the structural analogue Sodium Ascorbyl Phosphate a dermal penetration of 1 % is assumed as worst case assumption.
This dermal penetration study in the prepared skin of the mouse is classified acceptable.
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