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Impact of nutrition on cognition and affectivity in the elderly: A review
Arch. Gerontol. 0167-4943/98/$19.00 IMPACT
OF
Geriatr.
suppl. 6 (1998) 459-468 0 1998 Elsevier Science Ireland
NUTRITION
ON
COGNITION
Ltd. All right
AND
reserved
AFFECTIVITY
459
IN
THE
ELDERLY:
A REVIEW
G.
SALVIOLI,
Chair of of Modena,
P.
VENTURA
Geriatrics Viale
and Vittorio
and
J.M.
Gerontology, Veneto,
9,
PRADELLI Department of I-41100 Modena,
Internal Italy
Medicine,
University
SUMMARY Preventive nutritional health care of old people is a pressing topic for physicians. In fact, malnutrition is related to impaired cognitive and affective performance in the elderly. Depression and dementia may sometimes initiate with weight loss, and selective and subclinical malnutrition (folic acid, vitamin B ) can impair cognition and affectivity. The methods for revealing cobalamin &d folic acid deficiencies need to be revised, since recommended dietary allowances and serum levels of these nutrients have not yet been established for the elderly. Homocysteine plasma concentration seems’to be an appropriate and costeffective marker of inadequate intake or bioavailability of these two vitamins, which are related to cognitive and affective performances in the elderly. In clinical practice, it is important to dispose of an instrument for adequately detecting malnutrition. One must also keep in mind that vitamin supplements may be useful in a large number of elders with psychogeriatric symptoms. Keywords:
cognitive
performance,
nutrition,
vitamin
deficiencies,
homocysteine
INTRODUCTION
ent
Nutritional
surveys
deficiencies,
an
vitamins
and
mance
and
nutrition 1994).
appetite
with
[Rolls,
fore,
depression
part
of
well
15-25
decline
and
and
cognitive
the
% in
also
with
by
failure
mood
disorders
may
of
to
depression
home
patients
poor
nutritional
be
diagnose
ranges (Alpert
and
status
subclinical
Fava,
has and
not
the to
(Rush, reduce there-
intake; screened in
the
primary
1997). been
selective
to error
in help
food
routinely
S % in
mal-
disturbances
depression from
may
prone
compromise
should
Failure
status
recall
behavioral
of perfor-
[Blumberg,
nutritional
are
nutri-
subclinical
vitamins
dietary but
and
frank deficiencies
have as
and or
intake
impairment
especially
malnutrition,
for elderly
care
Moreover,
memory
exhaustively forms,
are
clinics
studied, not
always
physicians.
Depression impairment,
rate
nursing
associated
discovered
with
1993),
such
intake
cognition
to
cognitive
seniors
diet,
diaries
alimentary
assessment.
documented:
food
minimal subclinical
composition,
healthy of
food
impaired
out and
body
apparently
utilizing inadequate
nutritional
of
components
hand,
pointed
malnutrition
compromise
history
other
have of
changes
30 % of
situations
the
elderly risk
particular
elderly On
the
influencing
About
dietary
1997).
and
mood.
Various
identify
to
minerals
regarding
elderly;
of increased
and poor to
thrive,
dementia physical
may functioning
a syndrome
initiate
with and
characterized
weight
loss.
malnutrition by
Depression, are
weight
loss,
common reduced
cognitive in
elderly appetite
as is
460 and
poor
paired
nutrition
and
immune The
cal
absence
and
,
not
observable life
for
each
since
hindered
et
The
al.,
The
mammalian
The
number
rapid
gence not
quently,
yet
well
on
cognitive
score
and
nitive
performances.
derly
changes
and
25
can
be
is
is
1995). requires
floor
height
Follow good part
the
clining
health
health may
status play
an
The
role
lopment
and
than
longevity
80
the
1969);
of
period in
functioning
and
precursors
fact, intelli-
have
metabolism
a cause
of
volumes
most
to
high
may
common
urea
with
of al.,
complex and
conse-
morbidity
greatly
fluid
in
influence
disturbance
creatinine
1990).
et
is
the cog-
in
ratio
In
the
greater
(BMI)
Lee
than
elthan
role
on
cognitive
60
% of
brain
is
in
such
is
the
as
last
it
et elderly
the
Study
stable
6
the (Wallace
low
mortality;
weight
knee of
to
Aging
seems
during
that
the
last
1992).
symptoms
of
depression
depression Indeed,
versa.
mortality
or
preceding over
Longitudinal
reciprocal;
vice
and
Paffenbarger,
between and
weight
height,
tables) the
body
with if
and
over
(kg/m2)
Baltimore
probable,
1991;
or
% of
morbidity
the
age-adjusted
weight
4-5
associated
complex
malnutrition
(using
body
other
more
al.,
of
index
inversely
interrelationships
important
loss
significant mass
are
value % of
parameters
are
are
ideal 10
a
body
the status
% of than
(Lissner
some
may
and precede
vitamins
and
depoor
minerals
functioning.
lipids up
neuronal
water
the
malnutrition;
et
and
Comprising
antioxi-
senescence.
(Winick,
cognitive
are
plasma
greater
of
changes
of
of
during
neurotransmitter
brain is
utilization
or
variations and
during
neurons
balance
and
associated
BMI
life
wide
elderly,
performances.
when
accuracy
Therefore,
heal-
protection
1994).
(Haboubi
health of
also
have
the
malnutrition
intake
on
optimum
maximal
decrease
to
Dietary
water
body
loss
the
Up.
and
of
The
and
salt
less
indicative
months ,
al.,
weight weight
months
affective
suspected
et
body
involuntary
and
in
neurons
tests
effects
Dehydration
(Weinberg A
on
in
prevent
conditions.
specific
1995).
of
elderly,
of
poorly
understood
Derangements
many
of
RDA
vary
are
help
for for
known.
vulnerable
organization
( Grantham-McGregor,
and
not
activities
particularly
children
inadequate
old
(RDA)
levels
requirements
under
metabolic is
and
malnourished
is
of
allowances
these
probably
biochemiassessment
daily
absorption
increase
and
growth
are minimum
1996).
anthropometric,
though
im-
Laths,
nutritional
and
they The
symptoms, and
for
recommended
function
brain
values
elderly,
intestinal
requirements
depressive (Sarkisian
adequate
current the
1993).
and
dehydration,
cholesterol
validated
for
capacity
vitamin
al.
has
vitamin-dependent
dant
6
serum
syndromes,
(Ames
storage
of
1994).
appropriate deficiency
thy
by
low
age-adjusted
standards
(Blumberg
probably
and of
clinical
people
accompanied
function
to
processing.
weight, Dietary
lipids fat
are
manipulation
essential in
to animals
neural affects
devesy-
461
naptosomal
membrane
expression.
Dietary
inadequate to
22:6w3
branes.
The
use
with
the
for
show
that
and
duates,
described
speed.
the
In
disease
are
lo-12
phospholipid Since
there
alimentary the
al.,
1982).
large
is
lecithin
but
be
low
of
Choline
in
for
age,
ceride
concentrations;
diac
lower
The
role
The
brain
total
represents utilizes
blood
hippocampus sufficiency,
its
also
be
reduced information
fact
it
19941,
heart
and
lipoprotein
(Muldoon
et
disease; et
is contained
in
which
tend
to
Controlling
subsets
block
al.,
dementia,
(Bartus
cholesterol on
a-
1992).
this
disease.
vocabulary [LDL)
performance
in in
benefit
Zeisel,
an
et al.,
neurons
limited
coronary
of
increased
represents
scores
in
and
None
phosphatidyl-
(Nitsch
test
lowered;
inversely
is and
show
(Canty
LDL-cholesterol
only about
Cerebral
50 % of
glucose
and
phospholipids
brain
or
be
study.
DNA
cognitive
better
contrast,
1997).
reduction
acetylcholine
density
to
al.,
men-
is assoand
design
triglyis corre-
1997).
of carbohydrates
glucose.
tracts
in
the tissue
negative
both
low
of
and
associated
et
longitudinal
total
improve
to
on and
this
choline undergra-
was
proved
(Kalmijn
controls;
may
advised
total
higher
output,
body
diets
consumption
phosphatidylcholine
of
foods
reduce
cholesterol
decline
depression
to 279
intake
in
are
intake
performance
with
with
trials
cholesterol-rich
common better
some
also task
al.,
respon-
observations
acid
degradation
of
may time
the
et
of
total
where
could
diet
risk
been in
be
Recent
serum
the
degeneration
in
may
the
mem-
ratio
(Adams
1983).
reaction
in
than
choline
fat
fish
of 2 nmolelpg
dietary
in
ciated
lated
a
or
results
amounts
% lower loss
acid
oils
increase
effects
cortex,
has
linoleic
and
(AD),
frontal
of
patients
depression
al.,
vulnerability
high
high
protective
the properties
eicosapentanoic
vegetable
E
functioning;
between Study,
whereas
and
of
relationship
impairment
depressed
et
a choice
Elderly
for
may
decline
cognitive
parietal
verage
The
synaptic
severe
[ Lieb serum
administering
showed
ethanolamine
the
1995).
Alzheimer’s
the
rate in
impairment,
antioxidants
acid-rich
depression
Zutphen
with
in
linoleic
apolipoprotein
neuronal
increases
the to
enhanced of
to
system in
arachidonic
often
a direct the
cognitive to
reduce
and
critical
nervous
changes
cholesterol
(1995),
In
related
in
Salem,
Benton
with
to is
lowering
intake.
tal
aim
rise
the
learning
are
supplement
consumption
the
[Hibbeln
in
nutritional
which
Increased
sible
a
thresholds, acids
through
of
membrane,
1996).
pain fatty
content
probably
suggested
in
acid
depression,
cell
composition, long-chain
the
main brain
with
blood and
substrate
for
vulnerable impaired
by
2 % of % of flow
oxygen
barrier is
20
is
weight, body
about
10 % of cognitive
specific to
body
total
57
the
declarative
(Kalaria damage (Craft
receives
15 % of
car-
burns
25 8 of
total
glmin, from
Glucose
transporters
memory
it and
ml/100
glucose
activity.
exocytotoxic
but
oxygen,
during et al.,
and
the
the
arterial is
and
brain blood,
transported Harik,
periods 1996).
across 1989).
of
exwith
glucose
The in-
462 The eval
importance
of
mechanisms
mances
after
levels
of
oral
brain
ticular, tasks
al.,
19941.
with
AD,
the
glucose
is marked
probably
is
synthesis
precursor
acetylcoenzyme
Glucose in
memory
with
possible
and
points be
levels
role
The
elderly
less
proteins
more
active
The
blood
The
of
seem
Rue
et
strictly
mory,
Low
also effect et
of
pletion
either
brain; such
given
utilization
in
age-related storage,
a role
in
neuro-
production
memory
in
by
of
the
as
for
improve-
the
a concomitant
after
requested
normal in
well
memory
pharmacological
conclusion,
consideration and
elderly
substrates
which In
the
verbal
biochemical
careful
serotonin,
less
or
subnor-
elderly
delayed
anemia
the
day
in
affectivity
than
due
capacity
to for
as
scores,
associated cognitive
severity;
values
in
only
not
and
are
1988). and
a longitudinal years
but
al.,
elusive
does
study
of
albumine
fact,
visceral has
cognitive
functioning. neurotransmitters influence and
the
with
impairment
of
dopamine,
In six
not
et
remains
after serum
fats snacks
(Wurtman
1993). do
intake
reflect
correlation
precursors
fewer
young
behavior
protein
and
eat
(La
follow-up levels
corwith
me-
scores.
with
most
the
and
protein-caloric
its
they
[Young,
are
also
carbohydrates
moreover,
in
memory
and
positive
declining synthesis
calories,
dietary
abstraction
reduced
dietary as
et
patients
memory
plays
declarative
1995).
serotonin
or
disease
and A
and The
to
but with
performance.
in
that of
glycolytic
and
of
people;
early
with
1993),
al.,
learning enhanced
(Gold,
concurrent
deficits,
correlate
and
a mechanisms
fewer
related
albumin
self-care
availability
transport
proteins
1997).
significantly
be
young
alert of
visuospatial
suggest
on
(Benton
glucose
regulation
par-
performance times
memory
glucose
higher in
sugar.
the
and
relate
to
achieved
consume than
al.,
studies
that
proteins
importance
not
and
promote
availability;
a deficit
transmembrane
low
list
retriperfor-
attention;
reaction
levels
of
fluency
likely
and
declarative
These
deficits;
should
reduced
correcting
seems
a word
quicker
metabolic
enhancing
suggests
may
glucose
It memory
improve
1996).
ATP
in
storage
mal
and
of
and insulin
glucose
memory
memory
of
facilitation
memory
A.
administration
ment
specific
1996).
recall
suboptimal
through
by both
better
levels
al.,
high
is effective
subjects
glucose
et
by
transmitter
as
glucose
reflect
improved
in
enhanced
(Craft may
al.,
with
attention
because
deficits
of
et
improvement
plasma
hippocampus
which
(Allen
associated
sustained
Elevated
demonstrated
enhancement
load are
requiring
memory
is
for
glucose
there
two
glucose
accounting
been
low or
and serum
between
(NT) rate
noradrenaline
of
is
synthesis formed
and
and
seems
and state
found
survival
albumin
disease
protein
reduced depression,
to
they be
inflammation and
protein
controlled from
(Katz
musculo-skeletal
visceral
of
the
within
biogenic aromatic
de-
the amines, amino
463 acids,
namely
from
tryptophan,
Factors probably
within more
Alterations
in
the
pathogenesis
the
precursor
and
in
tyrosine;
acetylcholine
is
formed
Selective
In
normal
al.,
1997).
present
in
in
availability are
al.,
involved
concentration
the
plasma et
are
1986).
are
brain
on
(Lucca
older
within
what
scores
al.,
on
are
elderly
with
cobalamin
of
required
to
1994).
In
significantly with
(Riggs
et
trations
al.,
of
vitamin
are
present
and
B,2
associated even
trations
of
though vitamin
19961.
Therefore,
vitamin
deficits The (MAT)
few
subjects
B,2
(namely
influence was
(<
plasma
of studied
acid
al.,
200
ngll)
vitamins
in
B B,2
6’ on
and
post-mortem
folic
difthe
B ,2
fo-
and
correlate
with
(Goodwin
a large in
sample
that
study
of many
deficient
higher
are
and
folic
in
(c
folic
to
of
concen-
total
homocys-
associations low
ug/l)
are concen-
(Riggs
a marker
of
et
methionine
patients
adenosyltransfewith
senile
al.,
multiple
acid). of
of
3 be
Study
lower
considered
acid
than
Aging
These
currently
score
concentration
years:
skills.
activity brains
58-81
seem
MMSE
Normative
concentrations
levels and
adequate
acid
The aged
what
the
in
with
1996).
copying
B,2
8
et
studied
tests
metabolically
those
subjects
spatial had
sometimes
are
erythrocyte
male
vitamin
area;
Rue
regards
been
attention
12
abstrac-
(La
1994).
and
homocysteine
vitamin
than
people,
folic poorer
are
Framingham
Spanish
70
with
greater the
et
functions
and
concentrations
(Ortega
examined
range
accompanied
past
have of
reasoning
et al.,
serum
results
1996)
in
vitamin
elderly
affective
Mexico
functioning
or
the
and
Herbert
New
are
in
deficiencies
normal
is
living
higher
poorer
the
the
visuospatial
concentrations
abstract
(Lindenbaum
177
and acid
serum
deficiency
acid of
folic
recall,
vitamins
by
cognitive
performances
some
cognitive
even
serum
folic
a group
those
on
of
and
on
fatigue
reported
members status
cognitive of
Insomnia, were
performances
intake
and
Americans
normal
or
best
considered
delayed
elderly
the
years,
nutritional
and
adults,
elderly. diet
66-90
the
6,2
Cobalamin
1983).
free-living
aged
vitamins but
the
acid-deficient
, 1994),
with
of
healthy
acid
teine
on
depends levels
be
and
(Young,
activities
depends
turn,
drugs
6 years;
associated
influence
In
have
in
specific
concentration,
supplements,
poorer
synthesis
tryptophan
folic
(Koehler
after
are
The
most.
degradation
availability
tryptamine
of
elderly
study
nutrient
tests
may
a 4-month
reassessed
tion
et
137
higher
ferent
normal
and
precursor
5-hydroxy its
efficacy
synthesis
of
which
malnutrition
process
by
central
plasma;
after
(1961).
were
and
NT
effect
MALNUTRITION
forgetfulness
aging
the
depression;
antidepressant
SELECTIVE
lit
of
control
than
L-tryptophan,
tryptophan
maintain
brain
peripheral
in
free
the
important
of
rase
phenylalanine
choline.
dementia;
464
IdAT “max in the
group
vides
samples
treated
evidence
chanisms
that
in
elderly
of
AD
patients
results
is
patients;
but
by
shown
the
acid
aged
OF
ELDERLY
AND
SIMPLE
not
study
in
levels al.,
matched
transmethylation
me-
different are
higher
1997).
healthy
in pro-
1996).
significantly
et
NUTRITIONAL
PATIENTS
in in
AD
subjects
healthy patients
We compared
BY
Notes:
by
t-test
Statistical
AD
evaluation
patients
had
perhomocysteinemia al.,
1993)
15 % of
as
a group
(controls).
The
mentia
as
coefficient, patients.
logistic the
a likelihood
markable
in
that
in
the
variable,
of
% based
76.2
hyperhomocysteinemia its
likely
HEALTHY
Signif.
7 3.2 12.0 0.4 52 0.6 226 1 .7 2.6 2.5
independent
p <
N.S. 0.01 0.01 0.03 0.02 0.05 0.01 0.05 0.01
samples.
serum
plasma
in
levels
than
higher
than
15
64 % of
patients
controls.
Hy-
umole/l)
(Ue-
with
dementia
controls. I,
other
groups.
regression
88 + 7 7 7 3 7 7 7 T 2
values
fasting
Table
two
patients
homocysteine
healthy in
dependent
indicating
for
BETWEEN
observations)
82 22.7 20.7 3.1 198 11.2 350 2.3 31.0 24.3
homocysteine
present
shown
different
a multiple
with
was
10 3.3 3.4 0.4 33 0.8 309 3.1 3.0 3.0
mean as
age-matched
Moreover, nificantly
higher (taken
(own
AD
60 + 7 T 7 ‘i: 7 7 T 7 T
in
AD
Controls
77 24.0 11.8 3.8 227 13.8 465 5.8 34.0 28.7
et
PARAMETERS
AFFECTED
Number of patients Age (yearsi) BMI (kg/m ) Homocysteine [ ~molell) Albumin (gldl) Transferrin (mg/dl) Hemoglobin [g/dl) Vitamin B (pglml) Folic acid’&g/ml) Calf circumference (cm) Arm circumference (cm)
in
increased
This
I.
Parameter
and
is
1996).
et al.,
homocysteine
age
patients
I
COMPARISON
land
are
(Joosten
with
AD al.,
alterations
(Morrison
levels
blood
AD
from et
with brain
patients
in Table
cortex
(Comez-Trolin
associated of
folic
affected
are
Table
and
hospitalized
frontalis B,2
regions
B,2
and in
gyrus
vitamin AD
specific
Vitamin
than
of
with
nutritional
When
analysis, we on
all
taking obtained
the
important
the
a relatively contribution
were
parameters
presence
a model
parameters
showed
parameters
of these
or
able
shown
to in
high to the
also
were absence predict
Table partial identification
sig-
entered of
de-
dementia II.
It
is
re-
correlation of
AD
465 Table
II
THE
RESULTS
OF
MULTIPLE
REGRESSION
Variables/Parameters
IN OUR
B
Folic acid Arm circumference Hyperhomocyst( Hemoglobin Albumin Notes: variable;
ANALYSIS
-
e) inemia’
B = regression dependent
SAMPLE
R
0.36 0.24 1.19 0.49 4.61
-
Signif.
0.13 0.11 0.19 0.06 0.22
coefficient, R = correlation variable: presence or absence
p <
0.03 0.04 0.01 0.04 0.01 0
coefficient; of dementia.
Categorical
CONCLUSIONS Physical begin persons
the
have
poor
health
pairs
the
.
In
overweight with
meet
two
thirds
of
nutritional
status
phagia,
also
tification al.,
taken
The
a reduction
Even
though
monstrated (Sulway
et
common subjects
in
amin
B ,2
folic
acid
account. for
Some low
elderly
have moderate
rate
cognitive 1996).
among
AD
with
impairment
patients
deficiency deficiency.
is
and of
cognitive
changes, in
the Acute
that
not
elderly; or
elderly
also
impair do
indicators
of
not poor
as
anorexia,
dys-
and
oral
or
dental
status
poor arc and
available
for
health
of
out related
the
the
problems glucose
iden(Posner
counter-re-
moreover,
the
glucose
feeding
on
prisoners
to
the
clinically
subclinical
aging in
(Goodwin and
depression
amount
et
depression is
variations
of
brain old
the
guide of
war of
important
malnutrition
functions
subacute
associated
patients
and
that
delirium
is often
per-
memory.
carried is
in
Most
impairment
noteworthy
at
such
glucose,
study
fails;
indicators
intake
and
impairment it
memory
of
im-
eating
occur
can
hypoglycemia;
learning
se
frequently
malnutrition
instruments
nutrient
a subtle
metabolic
al.,
drugs,
a
deficiencies
supplementation; minor
per
influences
anorexia
elderly.
older
precede
aging
vitamin
should
15 % of
depression
depression
Tardive
the
III;
of further
specific
concurrent
during
that
of
loss
about
Moreover,
specific
dietary
Table
enhancing
versa.
elderly.
a longitudinal
Confusion,
that
in
weight
affect;
depression
diagnosis
without
risk
of
is effective
vice
subclinical
in
into at
response
shows
RDA listed
elderly
1993).
gulatory
sons
be
of
the
involuntary and
if symptoms
and
recalled
functioning
multiple
clear or
but
the
with mood
intake,
underweight
are
fatique,
should
be
than
affective
is not
medicine
symptoms,
and
it
food
should
rather
depressive
cognitive
et
it
patient
patient’s
malnutrition,
control
geriatric
time
older
the
and
and to
the of
depression, status
same
of
assessment
ability
behaviour the
examination
with
has
weight
weight occurs
al.,
1983). symptoms symptom
mental
loss loss
in
ary
de-
of (56
status
is
elderly
vit8)
makes
of
B,2/folic
acid
more
in
amin
I3 12 homocysteine.
mical combined
are
An tained
acid levels
and
Table
III
LIST
OF
they
high
still
subclinical. knowledge
affect
levels
of
of
estimation in
of
the
aging
OF
POOR
volume of
be
to
may
nutritional the
benefits
population
be
be
by
measuring most
are
in often
prevention of (Rush,
NUTRITIONAL
is
dietary
total
et
al.,
the
pathogenesis when
needed;
it
vit-
serum bioche-
present
specific
for of
frequent
(Nilsson
implicated
indicator
procedure
the
disorders
homocysteine
is an
diagnostic
obtained
seem
psychogeriatric
deficiencies;
the
may
homocysteine
with
and
INDICATORS
indicators
of
erythrocyte
Improvement
deficiencies
patients
extended through
cognition
Major
folic
vitamin diseases.
increased
investigation.
High of
deficiencies
advisable;
clinical
and
marker
these
testing
depth
will
intervention
1996); of vitamin
be
obon
1997).
STATUS
Minor
indicators
Weight loss of more than 3 kg Anorexia Low or high BMI Poor oral/dental Serum albumin lowe than 3 gldl Dysphagia Changes in functional status Fatigue and folic acid deficiencies Multiple drug ~?e~~rBO!fslosteomalacia Mid-arm circumference below the 10th percentile Triceps skinfold below or above the 95th percentile Erythrocyte volume larger than 100 fl Plasma homocysteine above 15 umole/l
status
assumption
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OF
Geriatr.
suppl. 6 (1998) 459-468 0 1998 Elsevier Science Ireland
NUTRITION
ON
COGNITION
Ltd. All right
AND
reserved
AFFECTIVITY
459
IN
THE
ELDERLY:
A REVIEW
G.
SALVIOLI,
Chair of of Modena,
P.
VENTURA
Geriatrics Viale
and Vittorio
and
J.M.
Gerontology, Veneto,
9,
PRADELLI Department of I-41100 Modena,
Internal Italy
Medicine,
University
SUMMARY Preventive nutritional health care of old people is a pressing topic for physicians. In fact, malnutrition is related to impaired cognitive and affective performance in the elderly. Depression and dementia may sometimes initiate with weight loss, and selective and subclinical malnutrition (folic acid, vitamin B ) can impair cognition and affectivity. The methods for revealing cobalamin &d folic acid deficiencies need to be revised, since recommended dietary allowances and serum levels of these nutrients have not yet been established for the elderly. Homocysteine plasma concentration seems’to be an appropriate and costeffective marker of inadequate intake or bioavailability of these two vitamins, which are related to cognitive and affective performances in the elderly. In clinical practice, it is important to dispose of an instrument for adequately detecting malnutrition. One must also keep in mind that vitamin supplements may be useful in a large number of elders with psychogeriatric symptoms. Keywords:
cognitive
performance,
nutrition,
vitamin
deficiencies,
homocysteine
INTRODUCTION
ent
Nutritional
surveys
deficiencies,
an
vitamins
and
mance
and
nutrition 1994).
appetite
with
[Rolls,
fore,
depression
part
of
well
15-25
decline
and
and
cognitive
the
% in
also
with
by
failure
mood
disorders
may
of
to
depression
home
patients
poor
nutritional
be
diagnose
ranges (Alpert
and
status
subclinical
Fava,
has and
not
the to
(Rush, reduce there-
intake; screened in
the
primary
1997). been
selective
to error
in help
food
routinely
S % in
mal-
disturbances
depression from
may
prone
compromise
should
Failure
status
recall
behavioral
of perfor-
[Blumberg,
nutritional
are
nutri-
subclinical
vitamins
dietary but
and
frank deficiencies
have as
and or
intake
impairment
especially
malnutrition,
for elderly
care
Moreover,
memory
exhaustively forms,
are
clinics
studied, not
always
physicians.
Depression impairment,
rate
nursing
associated
discovered
with
1993),
such
intake
cognition
to
cognitive
seniors
diet,
diaries
alimentary
assessment.
documented:
food
minimal subclinical
composition,
healthy of
food
impaired
out and
body
apparently
utilizing inadequate
nutritional
of
components
hand,
pointed
malnutrition
compromise
history
other
have of
changes
30 % of
situations
the
elderly risk
particular
elderly On
the
influencing
About
dietary
1997).
and
mood.
Various
identify
to
minerals
regarding
elderly;
of increased
and poor to
thrive,
dementia physical
may functioning
a syndrome
initiate
with and
characterized
weight
loss.
malnutrition by
Depression, are
weight
loss,
common reduced
cognitive in
elderly appetite
as is
460 and
poor
paired
nutrition
and
immune The
cal
absence
and
,
not
observable life
for
each
since
hindered
et
The
al.,
The
mammalian
The
number
rapid
gence not
quently,
yet
well
on
cognitive
score
and
nitive
performances.
derly
changes
and
25
can
be
is
is
1995). requires
floor
height
Follow good part
the
clining
health
health may
status play
an
The
role
lopment
and
than
longevity
80
the
1969);
of
period in
functioning
and
precursors
fact, intelli-
have
metabolism
a cause
of
volumes
most
to
high
may
common
urea
with
of al.,
complex and
conse-
morbidity
greatly
fluid
in
influence
disturbance
creatinine
1990).
et
is
the cog-
in
ratio
In
the
greater
(BMI)
Lee
than
elthan
role
on
cognitive
60
% of
brain
is
in
such
is
the
as
last
it
et elderly
the
Study
stable
6
the (Wallace
low
mortality;
weight
knee of
to
Aging
seems
during
that
the
last
1992).
symptoms
of
depression
depression Indeed,
versa.
mortality
or
preceding over
Longitudinal
reciprocal;
vice
and
Paffenbarger,
between and
weight
height,
tables) the
body
with if
and
over
(kg/m2)
Baltimore
probable,
1991;
or
% of
morbidity
the
age-adjusted
weight
4-5
associated
complex
malnutrition
(using
body
other
more
al.,
of
index
inversely
interrelationships
important
loss
significant mass
are
value % of
parameters
are
are
ideal 10
a
body
the status
% of than
(Lissner
some
may
and precede
vitamins
and
depoor
minerals
functioning.
lipids up
neuronal
water
the
malnutrition;
et
and
Comprising
antioxi-
senescence.
(Winick,
cognitive
are
plasma
greater
of
changes
of
of
during
neurotransmitter
brain is
utilization
or
variations and
during
neurons
balance
and
associated
BMI
life
wide
elderly,
performances.
when
accuracy
Therefore,
heal-
protection
1994).
(Haboubi
health of
also
have
the
malnutrition
intake
on
optimum
maximal
decrease
to
Dietary
water
body
loss
the
Up.
and
of
The
and
salt
less
indicative
months ,
al.,
weight weight
months
affective
suspected
et
body
involuntary
and
in
neurons
tests
effects
Dehydration
(Weinberg A
on
in
prevent
conditions.
specific
1995).
of
elderly,
of
poorly
understood
Derangements
many
of
RDA
vary
are
help
for for
known.
vulnerable
organization
( Grantham-McGregor,
and
not
activities
particularly
children
inadequate
old
(RDA)
levels
requirements
under
metabolic is
and
malnourished
is
of
allowances
these
probably
biochemiassessment
daily
absorption
increase
and
growth
are minimum
1996).
anthropometric,
though
im-
Laths,
nutritional
and
they The
symptoms, and
for
recommended
function
brain
values
elderly,
intestinal
requirements
depressive (Sarkisian
adequate
current the
1993).
and
dehydration,
cholesterol
validated
for
capacity
vitamin
al.
has
vitamin-dependent
dant
6
serum
syndromes,
(Ames
storage
of
1994).
appropriate deficiency
thy
by
low
age-adjusted
standards
(Blumberg
probably
and of
clinical
people
accompanied
function
to
processing.
weight, Dietary
lipids fat
are
manipulation
essential in
to animals
neural affects
devesy-
461
naptosomal
membrane
expression.
Dietary
inadequate to
22:6w3
branes.
The
use
with
the
for
show
that
and
duates,
described
speed.
the
In
disease
are
lo-12
phospholipid Since
there
alimentary the
al.,
1982).
large
is
lecithin
but
be
low
of
Choline
in
for
age,
ceride
concentrations;
diac
lower
The
role
The
brain
total
represents utilizes
blood
hippocampus sufficiency,
its
also
be
reduced information
fact
it
19941,
heart
and
lipoprotein
(Muldoon
et
disease; et
is contained
in
which
tend
to
Controlling
subsets
block
al.,
dementia,
(Bartus
cholesterol on
a-
1992).
this
disease.
vocabulary [LDL)
performance
in in
benefit
Zeisel,
an
et al.,
neurons
limited
coronary
of
increased
represents
scores
in
and
None
phosphatidyl-
(Nitsch
test
lowered;
inversely
is and
show
(Canty
LDL-cholesterol
only about
Cerebral
50 % of
glucose
and
phospholipids
brain
or
be
study.
DNA
cognitive
better
contrast,
1997).
reduction
acetylcholine
density
to
al.,
men-
is assoand
design
triglyis corre-
1997).
of carbohydrates
glucose.
tracts
in
the tissue
negative
both
low
of
and
associated
et
longitudinal
total
improve
to
on and
this
choline undergra-
was
proved
(Kalmijn
controls;
may
advised
total
higher
output,
body
diets
consumption
phosphatidylcholine
of
foods
reduce
cholesterol
decline
depression
to 279
intake
in
are
intake
performance
with
with
trials
cholesterol-rich
common better
some
also task
al.,
respon-
observations
acid
degradation
of
may time
the
et
of
total
where
could
diet
risk
been in
be
Recent
serum
the
degeneration
in
may
the
mem-
ratio
(Adams
1983).
reaction
in
than
choline
fat
fish
of 2 nmolelpg
dietary
in
ciated
lated
a
or
results
amounts
% lower loss
acid
oils
increase
effects
cortex,
has
linoleic
and
(AD),
frontal
of
patients
depression
al.,
vulnerability
high
high
protective
the properties
eicosapentanoic
vegetable
E
functioning;
between Study,
whereas
and
of
relationship
impairment
depressed
et
a choice
Elderly
for
may
decline
cognitive
parietal
verage
The
synaptic
severe
[ Lieb serum
administering
showed
ethanolamine
the
1995).
Alzheimer’s
the
rate in
impairment,
antioxidants
acid-rich
depression
Zutphen
with
in
linoleic
apolipoprotein
neuronal
increases
the to
enhanced of
to
system in
arachidonic
often
a direct the
cognitive to
reduce
and
critical
nervous
changes
cholesterol
(1995),
In
related
in
Salem,
Benton
with
to is
lowering
intake.
tal
aim
rise
the
learning
are
supplement
consumption
the
[Hibbeln
in
nutritional
which
Increased
sible
a
thresholds, acids
through
of
membrane,
1996).
pain fatty
content
probably
suggested
in
acid
depression,
cell
composition, long-chain
the
main brain
with
blood and
substrate
for
vulnerable impaired
by
2 % of % of flow
oxygen
barrier is
20
is
weight, body
about
10 % of cognitive
specific to
body
total
57
the
declarative
(Kalaria damage (Craft
receives
15 % of
car-
burns
25 8 of
total
glmin, from
Glucose
transporters
memory
it and
ml/100
glucose
activity.
exocytotoxic
but
oxygen,
during et al.,
and
the
the
arterial is
and
brain blood,
transported Harik,
periods 1996).
across 1989).
of
exwith
glucose
The in-
462 The eval
importance
of
mechanisms
mances
after
levels
of
oral
brain
ticular, tasks
al.,
19941.
with
AD,
the
glucose
is marked
probably
is
synthesis
precursor
acetylcoenzyme
Glucose in
memory
with
possible
and
points be
levels
role
The
elderly
less
proteins
more
active
The
blood
The
of
seem
Rue
et
strictly
mory,
Low
also effect et
of
pletion
either
brain; such
given
utilization
in
age-related storage,
a role
in
neuro-
production
memory
in
by
of
the
as
for
improve-
the
a concomitant
after
requested
normal in
well
memory
pharmacological
conclusion,
consideration and
elderly
substrates
which In
the
verbal
biochemical
careful
serotonin,
less
or
subnor-
elderly
delayed
anemia
the
day
in
affectivity
than
due
capacity
to for
as
scores,
associated cognitive
severity;
values
in
only
not
and
are
1988). and
a longitudinal years
but
al.,
elusive
does
study
of
albumine
fact,
visceral has
cognitive
functioning. neurotransmitters influence and
the
with
impairment
of
dopamine,
In six
not
et
remains
after serum
fats snacks
(Wurtman
1993). do
intake
reflect
correlation
precursors
fewer
young
behavior
protein
and
eat
(La
follow-up levels
corwith
me-
scores.
with
most
the
and
protein-caloric
its
they
[Young,
are
also
carbohydrates
moreover,
in
memory
and
positive
declining synthesis
calories,
dietary
abstraction
reduced
dietary as
et
patients
memory
plays
declarative
1995).
serotonin
or
disease
and A
and The
to
but with
performance.
in
that of
glycolytic
and
of
people;
early
with
1993),
al.,
learning enhanced
(Gold,
concurrent
deficits,
correlate
and
a mechanisms
fewer
related
albumin
self-care
availability
transport
proteins
1997).
significantly
be
young
alert of
visuospatial
suggest
on
(Benton
glucose
regulation
par-
performance times
memory
glucose
higher in
sugar.
the
and
relate
to
achieved
consume than
al.,
studies
that
proteins
importance
not
and
promote
availability;
a deficit
transmembrane
low
list
retriperfor-
attention;
reaction
levels
of
fluency
likely
and
declarative
These
deficits;
should
reduced
correcting
seems
a word
quicker
metabolic
enhancing
suggests
may
glucose
It memory
improve
1996).
ATP
in
storage
mal
and
of
and insulin
glucose
memory
memory
of
facilitation
memory
A.
administration
ment
specific
1996).
recall
suboptimal
through
by both
better
levels
al.,
high
is effective
subjects
glucose
et
by
transmitter
as
glucose
reflect
improved
in
enhanced
(Craft may
al.,
with
attention
because
deficits
of
et
improvement
plasma
hippocampus
which
(Allen
associated
sustained
Elevated
demonstrated
enhancement
load are
requiring
memory
is
for
glucose
there
two
glucose
accounting
been
low or
and serum
between
(NT) rate
noradrenaline
of
is
synthesis formed
and
and
seems
and state
found
survival
albumin
disease
protein
reduced depression,
to
they be
inflammation and
protein
controlled from
(Katz
musculo-skeletal
visceral
of
the
within
biogenic aromatic
de-
the amines, amino
463 acids,
namely
from
tryptophan,
Factors probably
within more
Alterations
in
the
pathogenesis
the
precursor
and
in
tyrosine;
acetylcholine
is
formed
Selective
In
normal
al.,
1997).
present
in
in
availability are
al.,
involved
concentration
the
plasma et
are
1986).
are
brain
on
(Lucca
older
within
what
scores
al.,
on
are
elderly
with
cobalamin
of
required
to
1994).
In
significantly with
(Riggs
et
trations
al.,
of
vitamin
are
present
and
B,2
associated even
trations
of
though vitamin
19961.
Therefore,
vitamin
deficits The (MAT)
few
subjects
B,2
(namely
influence was
(<
plasma
of studied
acid
al.,
200
ngll)
vitamins
in
B B,2
6’ on
and
post-mortem
folic
difthe
B ,2
fo-
and
correlate
with
(Goodwin
a large in
sample
that
study
of many
deficient
higher
are
and
folic
in
(c
folic
to
of
concen-
total
homocys-
associations low
ug/l)
are concen-
(Riggs
a marker
of
et
methionine
patients
adenosyltransfewith
senile
al.,
multiple
acid). of
of
3 be
Study
lower
considered
acid
than
Aging
These
currently
score
concentration
years:
skills.
activity brains
58-81
seem
MMSE
Normative
concentrations
levels and
adequate
acid
The aged
what
the
in
with
1996).
copying
B,2
8
et
studied
tests
metabolically
those
subjects
spatial had
sometimes
are
erythrocyte
male
vitamin
area;
Rue
regards
been
attention
12
abstrac-
(La
1994).
and
homocysteine
vitamin
than
people,
folic poorer
are
Framingham
Spanish
70
with
greater the
et
functions
and
concentrations
(Ortega
examined
range
accompanied
past
have of
reasoning
et al.,
serum
results
1996)
in
vitamin
elderly
affective
Mexico
functioning
or
the
and
Herbert
New
are
in
deficiencies
normal
is
living
higher
poorer
the
the
visuospatial
concentrations
abstract
(Lindenbaum
177
and acid
serum
deficiency
acid of
folic
recall,
vitamins
by
cognitive
performances
some
cognitive
even
serum
folic
a group
those
on
of
and
on
fatigue
reported
members status
cognitive of
Insomnia, were
performances
intake
and
Americans
normal
or
best
considered
delayed
elderly
the
years,
nutritional
and
adults,
elderly. diet
66-90
the
6,2
Cobalamin
1983).
free-living
aged
vitamins but
the
acid-deficient
, 1994),
with
of
healthy
acid
teine
on
depends levels
be
and
(Young,
activities
depends
turn,
drugs
6 years;
associated
influence
In
have
in
specific
concentration,
supplements,
poorer
synthesis
tryptophan
folic
(Koehler
after
are
The
most.
degradation
availability
tryptamine
of
elderly
study
nutrient
tests
may
a 4-month
reassessed
tion
et
137
higher
ferent
normal
and
precursor
5-hydroxy its
efficacy
synthesis
of
which
malnutrition
process
by
central
plasma;
after
(1961).
were
and
NT
effect
MALNUTRITION
forgetfulness
aging
the
depression;
antidepressant
SELECTIVE
lit
of
control
than
L-tryptophan,
tryptophan
maintain
brain
peripheral
in
free
the
important
of
rase
phenylalanine
choline.
dementia;
464
IdAT “max in the
group
vides
samples
treated
evidence
chanisms
that
in
elderly
of
AD
patients
results
is
patients;
but
by
shown
the
acid
aged
OF
ELDERLY
AND
SIMPLE
not
study
in
levels al.,
matched
transmethylation
me-
different are
higher
1997).
healthy
in pro-
1996).
significantly
et
NUTRITIONAL
PATIENTS
in in
AD
subjects
healthy patients
We compared
BY
Notes:
by
t-test
Statistical
AD
evaluation
patients
had
perhomocysteinemia al.,
1993)
15 % of
as
a group
(controls).
The
mentia
as
coefficient, patients.
logistic the
a likelihood
markable
in
that
in
the
variable,
of
% based
76.2
hyperhomocysteinemia its
likely
HEALTHY
Signif.
7 3.2 12.0 0.4 52 0.6 226 1 .7 2.6 2.5
independent
p <
N.S. 0.01 0.01 0.03 0.02 0.05 0.01 0.05 0.01
samples.
serum
plasma
in
levels
than
higher
than
15
64 % of
patients
controls.
Hy-
umole/l)
(Ue-
with
dementia
controls. I,
other
groups.
regression
88 + 7 7 7 3 7 7 7 T 2
values
fasting
Table
two
patients
homocysteine
healthy in
dependent
indicating
for
BETWEEN
observations)
82 22.7 20.7 3.1 198 11.2 350 2.3 31.0 24.3
homocysteine
present
shown
different
a multiple
with
was
10 3.3 3.4 0.4 33 0.8 309 3.1 3.0 3.0
mean as
age-matched
Moreover, nificantly
higher (taken
(own
AD
60 + 7 T 7 ‘i: 7 7 T 7 T
in
AD
Controls
77 24.0 11.8 3.8 227 13.8 465 5.8 34.0 28.7
et
PARAMETERS
AFFECTED
Number of patients Age (yearsi) BMI (kg/m ) Homocysteine [ ~molell) Albumin (gldl) Transferrin (mg/dl) Hemoglobin [g/dl) Vitamin B (pglml) Folic acid’&g/ml) Calf circumference (cm) Arm circumference (cm)
in
increased
This
I.
Parameter
and
is
1996).
et al.,
homocysteine
age
patients
I
COMPARISON
land
are
(Joosten
with
AD al.,
alterations
(Morrison
levels
blood
AD
from et
with brain
patients
in Table
cortex
(Comez-Trolin
associated of
folic
affected
are
Table
and
hospitalized
frontalis B,2
regions
B,2
and in
gyrus
vitamin AD
specific
Vitamin
than
of
with
nutritional
When
analysis, we on
all
taking obtained
the
important
the
a relatively contribution
were
parameters
presence
a model
parameters
showed
parameters
of these
or
able
shown
to in
high to the
also
were absence predict
Table partial identification
sig-
entered of
de-
dementia II.
It
is
re-
correlation of
AD
465 Table
II
THE
RESULTS
OF
MULTIPLE
REGRESSION
Variables/Parameters
IN OUR
B
Folic acid Arm circumference Hyperhomocyst( Hemoglobin Albumin Notes: variable;
ANALYSIS
-
e) inemia’
B = regression dependent
SAMPLE
R
0.36 0.24 1.19 0.49 4.61
-
Signif.
0.13 0.11 0.19 0.06 0.22
coefficient, R = correlation variable: presence or absence
p <
0.03 0.04 0.01 0.04 0.01 0
coefficient; of dementia.
Categorical
CONCLUSIONS Physical begin persons
the
have
poor
health
pairs
the
.
In
overweight with
meet
two
thirds
of
nutritional
status
phagia,
also
tification al.,
taken
The
a reduction
Even
though
monstrated (Sulway
et
common subjects
in
amin
B ,2
folic
acid
account. for
Some low
elderly
have moderate
rate
cognitive 1996).
among
AD
with
impairment
patients
deficiency deficiency.
is
and of
cognitive
changes, in
the Acute
that
not
elderly; or
elderly
also
impair do
indicators
of
not poor
as
anorexia,
dys-
and
oral
or
dental
status
poor arc and
available
for
health
of
out related
the
the
problems glucose
iden(Posner
counter-re-
moreover,
the
glucose
feeding
on
prisoners
to
the
clinically
subclinical
aging in
(Goodwin and
depression
amount
et
depression is
variations
of
brain old
the
guide of
war of
important
malnutrition
functions
subacute
associated
patients
and
that
delirium
is often
per-
memory.
carried is
in
Most
impairment
noteworthy
at
such
glucose,
study
fails;
indicators
intake
and
impairment it
memory
of
im-
eating
occur
can
hypoglycemia;
learning
se
frequently
malnutrition
instruments
nutrient
a subtle
metabolic
al.,
drugs,
a
deficiencies
supplementation; minor
per
influences
anorexia
elderly.
older
precede
aging
vitamin
should
15 % of
depression
depression
Tardive
the
III;
of further
specific
concurrent
during
that
of
loss
about
Moreover,
specific
dietary
Table
enhancing
versa.
elderly.
a longitudinal
Confusion,
that
in
weight
affect;
depression
diagnosis
without
risk
of
is effective
vice
subclinical
in
into at
response
shows
RDA listed
elderly
1993).
gulatory
sons
be
of
the
involuntary and
if symptoms
and
recalled
functioning
multiple
clear or
but
the
with mood
intake,
underweight
are
fatique,
should
be
than
affective
is not
medicine
symptoms,
and
it
food
should
rather
depressive
cognitive
et
it
patient
patient’s
malnutrition,
control
geriatric
time
older
the
and
and to
the of
depression, status
same
of
assessment
ability
behaviour the
examination
with
has
weight
weight occurs
al.,
1983). symptoms symptom
mental
loss loss
in
ary
de-
of (56
status
is
elderly
vit8)
makes
of
B,2/folic
acid
more
in
amin
I3 12 homocysteine.
mical combined
are
An tained
acid levels
and
Table
III
LIST
OF
they
high
still
subclinical. knowledge
affect
levels
of
of
estimation in
of
the
aging
OF
POOR
volume of
be
to
may
nutritional the
benefits
population
be
be
by
measuring most
are
in often
prevention of (Rush,
NUTRITIONAL
is
dietary
total
et
al.,
the
pathogenesis when
needed;
it
vit-
serum bioche-
present
specific
for of
frequent
(Nilsson
implicated
indicator
procedure
the
disorders
homocysteine
is an
diagnostic
obtained
seem
psychogeriatric
deficiencies;
the
may
homocysteine
with
and
INDICATORS
indicators
of
erythrocyte
Improvement
deficiencies
patients
extended through
cognition
Major
folic
vitamin diseases.
increased
investigation.
High of
deficiencies
advisable;
clinical
and
marker
these
testing
depth
will
intervention
1996); of vitamin
be
obon
1997).
STATUS
Minor
indicators
Weight loss of more than 3 kg Anorexia Low or high BMI Poor oral/dental Serum albumin lowe than 3 gldl Dysphagia Changes in functional status Fatigue and folic acid deficiencies Multiple drug ~?e~~rBO!fslosteomalacia Mid-arm circumference below the 10th percentile Triceps skinfold below or above the 95th percentile Erythrocyte volume larger than 100 fl Plasma homocysteine above 15 umole/l
status
assumption
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