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Journal of Lipid Research, Vol 31, 1535-1548, Copyright © 1990 by Lipid Research, Inc.
KC Lewis, MH Green, JB Green and LA Zech
A compartmental model was developed to describe the metabolism of vitamin A
in rats with low vitamin A status maintained by a low dietary intake of
vitamin A (approximately 2 micrograms retinol equivalents/day). After the
IV bolus injection of [3H]retinol in its physiological transport complex,
tracer and trace data were obtained from plasma, organs (liver, kidneys,
small intestine, eyes, adrenals, testes, lungs, carcass), and tracer data
were obtained from urine and feces. The dietary protocol developed for this
study resulted in animals having plasma vitamin A levels less than 10
micrograms retinol/dl and total liver vitamin A levels of approximately 1
microgram retinol equivalent. Four compartments were used to model the
plasma: one to describe retinol, one to describe the nonphysiological
portion of the dose, and two to simulate polar metabolites derived from
retinol. The liver required two compartments and a delay, the carcass
(small intestine, eyes, adrenals, testes, and lungs, plus remaining
carcass) required three compartments, and the kidneys required two. The
model predicted a vitamin A utilization rate of 1.65 micrograms retinol
equivalents/day with the urine and feces accounting for most of the output.
The plasma retinol turnover rate was approximately 20 micrograms retinol
equivalents/day; this was 12 times greater than the utilization rate. This
indicated that, of the large amount of retinol moving through the plasma
each day, less than 10% of this was actually being irreversibly utilized.
Similarly, as compared to the whole-body utilization rate, there was a
relatively high turnover rate of retinol in the kidneys, carcass, and liver
(9.0, 8.2, and 5.8 micrograms retinol equivalents/day, respectively),
coupled with a high degree of recycling of vitamin A through these tissues.
Of the total vitamin A that entered the liver from all sources including
the diet, approximately 86% was mobilized into the plasma. Similarly, of
the vitamin A that entered the carcass, approximately 76% was returned to
the plasma. All of the retinol that entered the kidneys was modeled as
recycling to the plasma. The present studies provide quantitative and
descriptive evidence of an efficient metabolism of vitamin A from
absorption through turnover and utilization in rats with very low vitamin A
status. Furthermore, although their body stores of vitamin A were extremely
low, these rats maintained a high level of recycling of vitamin A
throughout the body.
ARTICLES
Retinol metabolism in rats with low vitamin A status: a compartmental model
Nutrition Department, Pennsylvania State University, University Park 16802.
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