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Department of Health Studies and Gerontology, University of Waterloo, Waterloo, ON, N2L 3G1, Canada and * Ross Laboratories, Columbus, OH 43215–1724
3To whom correspondence should be addressed.
Four groups of male Long-Evans rats were reared artificially from
postnatal d 5 to 18 by being fed through a gastrostomy tube with rat
milk substitutes containing oils providing 10% linoleic acid and 1%
-linolenic acid (g/100 g fat); with the use of a 2 x 2 design,
they were fed one of two levels of arachidonic acid (AA) and
docosahexaenoic acid (DHA) (0.0 and 2.5 g/100 g of fatty acids). A
fifth artificially reared group was fed a diet high in saturated fat,
and a sixth group was reared by dams fed a standard AIN-93M diet. The
pups were weaned onto modified AIN-93G diets, with a fat composition
similar to that fed during the artificial rearing period. Behavioral
testing was conducted between 6 and 9 wk of age; brain lipid
composition was then assessed. Relative to the unsupplemented group
(0.0 g/100 g AA and DHA), dietary supplementation resulted in a wide
range of AA (84–103%) and particularly DHA (86–119%) levels in
forebrain membrane phospholipids. AA supplementation increased AA
levels and decreased DHA levels, and DHA supplementation increased DHA
levels and decreased AA levels, with the magnitude of these effects
dependent on the level of the other fatty acid. DHA levels were very
low in the saturated fat group. The groups did not differ on the place
or cued version of the Morris water-maze, but on a test of working
memory, the saturated fat group was impaired relative to the suckled
control group. Further correlational analyses in the artificially
reared animals did not support a relationship between the wide range of
DHA and AA levels in the forebrain and working-memory
performance.
KEY WORDS: • rat • brain development • water-maze learning • arachidonic acid • docosahexaenoic acid
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