exist in the relationships between dietary linoleic and a-linolenic acids and their respective long-chain metabolites13. Evangeline. Mantzioris,. Michael. J James,.
Differences exist in the relationships between dietary linoleic and a-linolenic acids and their respective long-chain metabolites13 Evangeline
Mantzioris,
ABSTRACT
Increased
entaenoic coronary
acid
(EPA)
ders.
heart Successful
EPA
concentrations
between
concentrations
have
been
require
acid
(LA),
eicosap-
on the
of
and
of
dietary conver-
sion to EPA. A dietary intervention study with healthy human volunteers that incorporated a-LA-rich vegetable oil (flaxseed oil),
against
a background
examine
these
between
dietary
cellular observed
diet
relationships. a-LA
low
Linear
and
EPA
in
LA,
allowed
relationships in plasma
phospholipids. By contrast between dietary LA and
there tissue
us
were
to
found
fractions
G Cleland
ratio
of n-6
to n-3
n-6
to n-3
eicosanoids
orders
amounts
of a-LA
Leslie
lular concentrations in coronary heart
relationships
EPA,
an antagonist
in
disorcellular
and dietary
a precursor
acid
and
to be beneficial
and inflammatory for increasing
of EPA
(a-LA),
A Gibson,
of cellular
shown
information
concentrations
of linoleic
Robert
and
in
was no relationship concentrations of its
by
(2).
precursor
nuclear
cells,
and platelets.
dietary
a-LA
will
dictable manner. ning of practical of EPA 320-4
elevate
The
results
tissue
EPA
This insight will dietary strategies
concentrations
WORDS
acid,
flaxseed
oil,
sapentaenoic
acid,
Am J Clin
a-linolenic
plasma
fatty
that
increasing
in a pre-
facilitate the rational planfor the long-term elevation
in tissues.
Dietary
KEY
indicate
concentrations
acids,
docosahexaenoic
acid,
1995;61:
dietary
cellular acid,
Nutr
fatty
arachidonic
eico-
acid
Once
(AA,
ingested,
acid) can
dietary
linoleic
and a-linolenic be desaturated
a 20-carbon
n
-
acid and 6 fatty
acid
period
320
formation
which
allowed
acid
group
of fatty
acid
metabolites
pathways to form and thromboxane), a involved
those ratio
that
are derived
of n -6
to n
-
from 3 fatty
EPA acids,
(1). which
in many
ho-
AA are potent by comparison
Western
diets
is reflected Am
J Clin
1
altering
elevated EPA-rich
remains
of these
the
relationships long-term
the cellular
ratios
the effect
exogenous
EPA
polyunsaturated in a domestic
both
groups
ingested
a-LA
tissue
and
EPA
group
di-
of n -6
on endoge-
incorporation
cooking setting.
continued
the same
of
oils for flaxThe study was
EPA
the
EPA
and
of Paediatrics
and Child
Bedford Park, 2 Supported
South Australia. by the National
Health
Health, and
This
the
dietary
Hospital, Flinders
Medical
from
either high or group had with
second
Unit, Royal Adelaide
the Department
oil.
formation
incorporation
compared
first
respective
of fish
background diets that the flaxseed-oil
concentrations
in both
their
amount
of endogenous
exogenous
From the Rheumatology
sun-
periods
Adelaide Medical
Research
and
Centre,
Council
of
Australia.. 3
Reprints
not available. Unit,
Australia,
Australia,
5000. 1 1, 1994.
have
Received
April
Accepted
for
1995;61:320-4.
Printed
Royal
Address
matology
in the Nutr
oil
of successful
the investigation
dietary
acid)
meostatic functions. Eicosanoids derived from proinflammatory and proaggregatory agonists a high
for favorably
during
flower-oil
eicosapentaenoic
fish
understanding
development
and in addition
elevated
respectively. The AA and can then be metabolized
was with
into two periods: 1) a 4-wk period during which one of volunteers used flaxseed oil and spread and another used sunflower oil and spread, and 2) a further 4-wk
n-6
via the lipoxygenase and cyclooxygenase eicosanoids (leukotrienes, prostaglandins,
with
Greater the
substituting high n-6 seed oil (high in a-LA)
fatty acid
or
an 18-carbon
of eel-
tissue EPA concentrations. on EPA concentrations has
(5) we described
(a-LA, an 18-carbon n-3 elongated to arachidonic
fatty acid), membranes
(LA,
EPA diet
Nevertheless,
fish-oil capsules given against low in a-LA. We observed
(EPA, a 20-carbon n-3 EPA present in cellular
diverse
(5-10).
and
from
Introduction
cellular
nous
diets
increased
shown to be beneficial and inflammatory dis-
Western
to n-3 fatty acids. In a previous report EPA
and the ratio
the mathematical relationships between din-6 and n-3 fatty acids and tissue concenrespective cellular 20-carbon metabolites have
for
strategies
design
fatty acid)
usual
acids
(1, 3, 4). Tissue concentrations of EPA have to increase in varying degrees when the diet with flaxseed oil, which is high in a-LA, the
reported.
is important
divided group group
linoleic
acids,
studies,
of the
to EPA
been documented, etary 18-carbon trations of their
etary
mono-
Importantly,
most efficient means of increasing Although the effect of dietary a-LA
centrations
neutrophils,
fatty
produced.
In experimental
fish-oil capsules also been shown is supplemented
not been
of plasma,
membrane
of EPA have been disease, hypertension,
supplementation
metabolite, arachidonic acid (AA). There was an inverse relationship between dietary a-LA and docosahexaenoic acid conin the phospholipids
cell
Adelaide
publication
in USA.
correspondence Hospital,
August
© 1995
North
to E Mantzioris, Terrace,
Adelaide,
RheuSouth
8, 1994.
American
Society
for Clinical
Nutrition
Downloaded from www.ajcn.org by guest on July 15, 2011
a-linolenic
J James,
disease, hypertension, long-term strategies
cellular
amounts
Michael
DIFFERENCES (5).
Subsequently,
and
tissue
this
study.
acid
These
tionships
fatty
we
fatty
metabolites
the
individual
concentrations
data
between
now
and fatty
from
allow
a-LA) acids
METABOLISM
dietary
the
period
of n-6
of
AND
a-LA
relationships.
321
Fatty
supplementation
acid
were
of the 20-carbon
and
The
mean
daily
reduced
by
>50%
resulting
in a range
groups,
diet
as did
there Thirty
healthy
male
volunteers
were
randomly
allocated
two dietary treatment groups. The experimental was instructed to maintain a high n-3 (a-LA) cold-pressed
flaxseed
flaxseed
oil
ratio
acids.
The
a high
suitable keeping
high n-3
and
a flaxseed-oil
and
by
control n-6
group
diet
(n
foods 15)
=
(reflective
group diet
to
in n-6
instructed
of Western
n-6 fatty acid cooking oils (a-LA) fatty acid consumption
15) using
diets)
to
intake
of
relative
groups
two
distinct
subjects
to a maximum dietary
periods
maintained
second
period
of two
their
both
in
meals this
groups
and spreads while as low as possi-
plasma
fractions
per week. In
their
There
the
were
first diets.
allocated
4 wk In
diet
the
and
in
mononuclear
different
However,
Plasma
and
was
cellularfatty
Peripheral
fasting
acid blood
reported
previously
(5).]
samples
there
(20 mL)
were
taken
before
ously
(5).
TABLE
1
and
was
The
rather
that than
were
2).
of the
significantly
es-
Similarly, in the
neutrophils,
(Figure
1 and
correlated
with
and in the phoscells, erythrocytes,
Dietary a-LA concentrations
in the phospholipids
of the neutro-
decrease
in the
plasma fractions consumption in
intakes in the
3 and Table
(Figure
concentrations
with frac-
mean
or in the as reported
the
plasma
3). con-
cellular previfractions
the trial began, after the 4 wk of the respective prescribed diets, and after fish-oil supplementation. The blood was separated into
plasma,
neutrophils,
mononuclear
cells,
erythrocytes,
and
platelets by using standard cell-separation techniques as described elsewhere (5). The plasma and cellular lipid fractions were separated by thin-layer chromatography and then analyzed
by
using
elsewhere
capillary
gas
chromatography
Anthropometric nutrients
Age
(y)
BMI
(kg/m2)
Energy
analyses
and estimated and control
Flaxseed
as described
(1 1, 12).
Dietary
measurements
in the flaxseed-oil
intake
(MJ/d)
oil
daily
dietary
intakes
of
groups’ (n =
Control
15)
(n =
15)
36.1
± 6.2
(25-44)
34.5
± 5.2
(25-44)
25.6
± 3.3
(20.7-35.1)
25.1
± 4.4
(16.4-35.9)
±
(6.3-12.7)
9.2 ± 2.1
(6.0-13.7)
9.6
1.8
Protein
All
subjects
were
records
for
3 d/wk
using
standard
instructed
by a dietitian
throughout
metric
the trial
household
days comprised two weekdays diet diaries were analyzed for the
1 program
Diet
(Xyris
to maintain
by weighing
measurements. and 1 d from LA and a-LA
Software
Pty
dietary foods
The
and
recorded
the weekend. The intakes by using Ltd,
Highgate
Hill,
Queensland, Australia), which uses the Australian nutrient database Nuttab 91-92 (13). The database was modified to include LA and a-LA contents of food items ingested during the trial. Because tween
the
plasma and
we and
were
dietary tissue
docosahexaenoic
interested
only
18-carbon
fatty
concentrations acid
(DHA),
in the acids of the
(LA LA,
relationships and a-LA,
estimated
be-
a-LA) AA,
and EPA,
individual
dietary intakes of LA and a-LA, and the fatty acid tissue concentrations from these individuals in both groups during the first 4 wk of the trial were combined and used to assess
(g/d) (% of energy)
105
±
19.4
(67-144)
18.9 ± 3.4
(14-25)
19.0
±
2.2
(15-24)
72.9
± 24.8
(42-128)
73.7
± 20.4(53-123)
29.6
± 5.3
(18-38)
29.1
± 6.3
(23-44)
269
± 72.9
(136-395)
286
± 73.5
(173-445)
47.2
± 6.3
(37-57)
47.9
± 6.2
(36-58)
98.7
±
17.2
(68-127)
Fat
(g/d) (% of energy) Carbohydrate
(g/d) (% of energy) Alcohol
(g/d) (% of energy) a-Linolenic
I
± 16.7 (0-62) ± 5.4
(0-20)
± 6.3
12.6 3.9
± 14.3 (0-40) ± 4.6
(0-14)
13.0
(3.6-22.0)
1.1 ± 0.6
(0.3-2.5)
5.3 ± 1.7
(2.3-7.1)
0.4 ± 0.2
(0.1-1.0)
8.2 ± 3.4
(2.9-15.6)
3.3
(1.8-4.6)
acid
(g/d) (% of energy) ,
4.1
acid
(g/d) (% of energy) Linoleic
13.0
±
SD;
range
±
0.8
in parentheses.
a
mononuclear
platelets
and platelets
in the a-LA
AA
indicating
concentrations
and
no significant
DI-LA after
fat,
Table
a-LA
phospholipids
(g/d)
cells,
to
and cholesterol
1 and with
erythrocytes,
phospholipids mononuclear
1), 2.9
of these the two
fats,
of the neutrophils,
in the
intakes
centration of phospholipids
composition
of
and platelets (Figure 2 and Table 3). were inversely correlated with DHA phils,
from
The total intake similar between dietary
was
(Table
groups
EPA concentrations in the plasma fractions pholipids of the neutrophils, mononuclear
plasma
backgrounds
two
type
(Figure
cells,
group
group
triglycerides,
correlated and
Table 3). Dietary a-LA
addition consumed nine fish-oil capsules. [The effect of uniform fish-oil intake in the second period against the two dietary
erythrocytes (g/d)
flaxseed
in the diet.
phospholipids,
a-LA
prescribed
continued
(plasma
and in the phospholipids
dietary
trial.
respective
fish-oil
(g/d) were significantly correlated of total fatty acids) in the plasma
ters)
and
in the
the
fat intake
tions cells,
the control
of total of
Dietary LA intakes concentrations (%
LA
in
the
g a-LAId. remained
intake
exchange
in total
LA to
of intakes
the
an
by using
ble. Both dietary groups were given guidelines to avoid monounsaturated and saturated fats. Fish meals were limited in both
was
difference
=
(butter rich
was
into
(n by
spread
avoiding
after (5).
20.5
± 8.6
7.8 ± 2.3
(9.9-41.4) (4.1-12.8)
Downloaded from www.ajcn.org by guest on July 15, 2011
maintain
oil
of 2:1)
observed
previously
Results
41.4 g LA/d and 0.3 to 22.0 two fatty acids (LA + a-LA)
Subjects
changes
published
18-carbon
and tissue concentrations and of their respective
Methods
fatty
LA
of the rela-
or n-3
and EPA).
(AA
OF the
intakes
initial
an examination
amounts
dietary
acids (LA 18-carbon
same
analyzed
IN
at
322
MANTZIORIS
r= .
Ea
I
20
Correlations
in tissue
1.5
i.o
I
of total
fatty
Tissue
fraction
and n
Plasma
phospholipids
a-Linolenic
I
0
10
20
D_
30
40
5
l’s
.5 ___________________________ ;5 10
.0.5
LA (gld)
DIta,y
a-LA
1.0 14
I
I
12
2;
5
(gld)
r=0.85
0.8
r_0.58>
I
I
a-linolenic
fatty
acid
acid
fatty
acids
Correlation
coefficients
0.4
II
02
I
0
10
20
Docosahexaenoic
acid
cholesteryl
50
.5
0
5
panels.
10
of dietary
linoleic
and neutrophil of total
fatty
r, correlation
acids.
Note
(PL) content
