Posted by Larry Hoover on November 20, 2002, at 8:32:31
In reply to Hemp doesn't contain EPA DHA !??!?, posted by linkadge on November 20, 2002, at 5:47:15
> Or does it? I was under the impression
> that EPA and DHA could only be found in
> fish/animal sources.Hemp oil has no appreciable amounts of EPA or DHA. The only 'vegetarian' source of either is algal oil, and it contains only DHA. There is one product that I know of, containing this alga-based DHA, called Neuromin. Your body will convert some of it to EPA, but not any more efficiently than it does the opposite. See below:
I believe that HEMP contains
> Alpha Linolicalpha-linolenic is 18:3 omega-3
gamma-linolenic is 18:3 omega-6
alpha-linoleic is 18:2 omega-9Hemp oil (like flaxseed oil) is a good source of alpha-linolenic acid.
which is then converted to
> EPA and DHA, (although some may have an
> impaired conversion process)Females are consitutionally more efficient at the elongation and desaturation processes than are males, presumably to provide for the demands of pregnancy and lactation. It may be a sampling artifact, but in the first study, males converted none of a radio-labelled alpha-linolenic acid sample to DHA. An alternative explanation is that it takes time to induce enzymes on that pathway, and conversion might gradually increase (from zero), given time for the body to adjust.
From the first abstract:
"Since the capacity of adult males to convert ALNA to DHA was either very
low or absent, uptake of pre-formed DHA from the diet may be critical for
maintaining adequate membrane DHA concentrations in these individuals."
Br J Nutr 2002 Oct;88(4):355-64Eicosapentaenoic and docosapentaenoic acids are the principal products of
alpha-linolenic acid metabolism in young men*.Burdge GC, Jones AE, Wootton SA.
Institute of Human Nutrition, Level C, West Wing, Southampton General
Hospital, Tremona Road, Southampton, SO16 6YD, UK.The capacity for conversion of alpha-linolenic acid (ALNA) to n-3 long-chain
polyunsaturated fatty acids was investigated in young men. Emulsified
[U-13C]ALNA was administered orally with a mixed meal to six subjects
consuming their habitual diet. Approximately 33 % of administered [13C]ALNA
was recovered as 13CO2 on breath over the first 24 h. [13C]ALNA was
mobilised from enterocytes primarily as chylomicron triacylglycerol (TAG),
while [13C]ALNA incorporation into plasma phosphatidylcholine (PC) occurred
later, probably by the liver. The time scale of conversion of [13C]ALNA to
eicosapentaenoic acid (EPA) and docosapentaenoic acid (DPA) suggested that
the liver was the principal site of ALNA desaturation and elongation,
although there was some indication of EPA and DPA synthesis by enterocytes.
[13C]EPA and [13C]DPA concentrations were greater in plasma PC than TAG, and
were present in the circulation for up to 7 and 14 d, respectively. There
was no apparent 13C enrichment of docosahexaenoic acid (DHA) in plasma PC,
TAG or non-esterified fatty acids at any time point measured up to 21 d.
This pattern of 13C n-3 fatty acid labelling suggests inhibition or
restriction of DHA synthesis downstream of DPA. [13C]ALNA, [13C]EPA and
[13C]DPA were incorporated into erythrocyte PC, but not
phosphatidylethanolamine, suggesting uptake of intact plasma PC molecules
from lipoproteins into erythrocyte membranes. Since the capacity of adult
males to convert ALNA to DHA was either very low or absent, uptake of
pre-formed DHA from the diet may be critical for maintaining adequate
membrane DHA concentrations in these individuals.Br J Nutr 2002 Oct;88(4):411-421
Conversion of alpha-linolenic acid to eicosapentaenoic, docosapentaenoic and
docosahexaenoic acids in young women.Burdge GC, Wootton SA.
Institute of Human Nutrition, University of Southampton, Southampton, UK.
The extent to which women of reproductive age are able to convert the n-3
fatty acid alpha-linolenic acid (ALNA) to eicosapentaenoic acid (EPA),
docosapentaenoic acid (DPA) and docosahexaenoic acid (DHA) was investigated
in vivo by measuring the concentrations of labelled fatty acids in plasma
for 21 d following the ingestion of [U-13C]ALNA (700 mg). [13C]ALNA
excursion was greatest in cholesteryl ester (CE) (224 (sem 70) &mgr;mol/l
over 21 d) compared with triacylglycerol (9-fold), non-esterified fatty
acids (37-fold) and phosphatidylcholine (PC, 7-fold). EPA excursion was
similar in both PC (42 (sem 8) &mgr;mol/l) and CE (42 (sem 9) &mgr;mol/l)
over 21 d. In contrast both [13C]DPA and [13C]DHA were detected
predominately in PC (18 (sem 4) and 27 (sem 7) &mgr;mol/l over 21 d,
respectively). Estimated net fractional ALNA inter-conversion was EPA 21 %,
DPA 6 % and DHA 9 %. Approximately 22 % of administered [13C]ALNA was
recovered as 13CO2 on breath over the first 24 h of the study. These results
suggest differential partitioning of ALNA, EPA and DHA between plasma lipid
classes, which may facilitate targeting of individual n-3 fatty acids to
specific tissues. Comparison with previous studies suggests that women may
possess a greater capacity for ALNA conversion than men. Such metabolic
capacity may be important for meeting the demands of the fetus and neonate
for DHA during pregnancy and lactation. Differences in DHA status between
women both in the non-pregnant state and in pregnancy may reflect variations
in metabolic capacity for DHA synthesis.Int J Vitam Nutr Res 1998;68(3):159-73
Can adults adequately convert alpha-linolenic acid (18:3n-3) to
eicosapentaenoic acid (20:5n-3) and docosahexaenoic acid (22:6n-3)?Gerster H.
Vitamin Research Department, F. Hoffman-Roche Ltd, Basel, Switzerland.
A diet including 2-3 portions of fatty fish per week, which corresponds to
the intake of 1.25 g EPA (20:5n-3) + DHA (22:6n-3) per day, has been
officially recommended on the basis of epidemiological findings showing a
beneficial role of these n-3 long-chain PUFA in the prevention of
cardiovascular and inflammatory diseases. The parent fatty acid ALA
(18:3n-3), found in vegetable oils such as flaxseed or rapeseed oil, is used
by the human organism partly as a source of energy, partly as a precursor of
the metabolites, but the degree of conversion appears to be unreliable and
restricted. More specifically, most studies in humans have shown that
whereas a certain, though restricted, conversion of high doses of ALA to EPA
occurs, conversion to DHA is severely restricted. The use of ALA labelled
with radioisotopes suggested that with a background diet high in saturated
fat conversion to long-chain metabolites is approximately 6% for EPA and
3.8% for DHA. With a diet rich in n-6 PUFA, conversion is reduced by 40 to
50%. It is thus reasonable to observe an n-6/n-3 PUFA ratio not exceeding
4-6. Restricted conversion to DHA may be critical since evidence has been
increasing that this long-chain metabolite has an autonomous function, e.g.
in the brain, retina and spermatozoa where it is the most prominent fatty
acid. In neonates deficiency is associated with visual impairment,
abnormalities in the electroretinogram and delayed cognitive development. In
adults the potential role of DHA in neurological function still needs to be
investigated in depth. Regarding cardiovascular risk factors DHA has been
shown to reduce triglyceride concentrations. These findings indicate that
future attention will have to focus on the adequate provision of DHA which
can reliably be achieved only with the supply of the preformed long-chain
metabolite.
Just to
> be on the safest side I would take fish
> oil or any other direct source of EPA + DHA,
> these are the ones used in the studies
> and plus these two fats go right to the brain
>
> LinkadgeAbsorption of these two fatty acids from the gut is strongly influenced by the amount of fat in the meal in which they were consumed. Always take fish oil with your fattiest meal of the day. If you eat "Atkins-style", you have no worries.
Lar
poster:Larry Hoover
thread:128343
URL: http://www.dr-bob.org/babble/20021116/msgs/128432.html