 |
Printable
PDF
Version
By E H Reynolds
It is becoming clear
that folic acid affects
mood and cognitive
function, especially in
older people. Edward
Reynolds draws together
the evidence Folic acid
is important for
functioning of the
nervous system at all
ages.1–4 In the fetus
the relation between
maternal folate status
and the risk of neural
tube defects is well
established: clinical
trials have shown that
periconceptual
preventive treatment
with 400 ìg or higher of
folic acid significantly
reduces the risks of
such defects.4 In
neonates, infants,
children, and
adolescents,
inborn errors of folate
transport and metabolism
are associated with a
variety of overlapping
syndromes
which are influenced by
age of clinical
presentation. These
include developmental
delay, cognitive deterio
ration, motor and gait
abnormalities,
behavioural or
psychiatric symptoms,
seizures, signs of
demyelination
or failure of
myelination, and
vascular changes seen on
magnetic resonance
imaging or postmortem
examination.4 Less
commonly, subacute
combined degeneration
and peripheral
neuropathy may also
occur. In adult patients
presenting with
megaloblastic anaemia
due to folate
deficiency,
approximately two
thirds have
neuropsychiatric
disorders which overlap
considerably with those
associated with anaemia
due to vitamin B12
deficiency.2 5 However,
depression is commoner
in patients with folate
deficiency, and
subacute combined
degeneration with
peripheral neuropathy is
more frequent in those
with vitamin B12
deficiency. The degree
of anemia is poorly
correlatedwith the
presence of
neuropsychiatric
disorders, but if
these anaemias were left
untreated nearly all
patients would
eventually develop
neuropsychiatric
complica
tions.2 Over the past 35
years numerous studies
have shown a high
incidence of folate
deficiency correlated
with mental symptoms,
especially depression
and cognitive decline in
epileptic, neurological,
psychiatric,
geriatric, and
psychogeriatric
populations.3 4
Furthermore, recent
studies in elderly
people suggest a link
between folic acid,
homocysteine, ageing,
depression, and
dementia, including
Alzheimer's disease and
vascular disease.4 6–9
In this paper I review
the evidence relating
folate deficiency to
depression and dementia,
especially in the ageing
nervous system.
Patients with epilepsy
Many studies of folate
in serum, red cells, or
cerebrospinal fluid have
shown a consistent
association between drug
induced deficiency and
mental changes,
especially depression,
apathy, psychomotor
retardation and
dementia.3 4 Treatment
of 26 folate deficient
epileptic patients with
5 mg of folic acid daily
for one to three years
resulted in improved
drive, initiative,
alertness,
concentration, mood, and
sociability in most.1
This contradicted the
prevailing view that
folic acid was harmful
only to the nervous
system, although that
concept was reinforced
by the additional
observation that seizure
control deteriorated in
several of the patients.
Although short term
clinical trials of folic
acid for one to three
months produced
conflicting results with
respect to mental
changes and seizure
control, there is
abundant experimental
evidence now of the
excitatory properties of
folate derivatives,
especially when the
efficient bloodbrain
barrier mechanism for
the vitamin is
circumvented.4 10 In
addition, folic acid
influences phenytoin
metabolism, leading to a
fall in blood
concentrations of this
drug.
Neurological patients
Several of the earliest
reports of neurological
disease associated with
severe folate deficiency
emphasise the importance
of dementia and
depression reversible
with vitamin therapy.2
11–13 For example, Botez
et al described 16
patients whose impaired
intellectual function,
confirmed on
neuropsychological
testing,
was strikingly improved
after six to 12 months
of folic acid therapy.
On the basis of
clinical,
neuropsychological,
computed tomography, and
radionuclidecisternographic
findings, they concluded
that chronic folate
deficiency could induce
cerebral atrophy.11 In
general medical patients
admitted acutely to
hospital, 71% of those
with severe folate
deficiency had organic
brain syndrome, compared
with 31% of a control
group.12 Runcie, who
described 10 cases and
reviewed the literature,
emphasised that the
syndrome of folate
responsive dementia and
depression, sometimes
with additional cord or
peripheral nerve signs,
was much commoner in
geriatric and
psychogeriatric units
than was (or still is)
recognised.13
Psychiatric patients On
the basis of serum or
red cell assays, folate
deficiency has been
reported in up to one
third of psy chiatric
outpatients or
inpatients, more so in
the former.3 4 Carney
and colleagues
emphasised the link with
depression and “organic”
mental change, and a
closer association with
endogenous than neurotic
depression.14 Depressed
patients with folate
deficiency had higher
depression scores,
higher affective
morbidity indices, lower
MarkeNyman (drive)
scores, and a poorer
response to standard
treatment with
antidepressants.15
Although folate
deficiency is widely
regarded as a secondary
dietary consequence of
psychiatric illness,
nutritional studies have
not confirmed this
view.3 Poor diet no
doubt contributes to
some, perhaps many,
cases. Other factors are
drugs, including
antiepileptic drugs;
chronic illness;
increased
demand; and
malabsorption, and in
some patients the cause
is unexplained.
Bottiglieri et al
identified a biological
subgroup of patients
with depression, raised
plasma homocysteine
concentration, folate
deficiency, and impaired
monoamine
neurotransmitter
metabolism.16 The
observation of raised
plasma homocysteine in
2030% of depressed
patients is in keeping
with the earlier studies
of folate
concentrations.3 4 The
few controlled clinical
trials of vitamin
therapy in addition to
standard psychotropic
medication have all
reported positive
effects on patients'
mental state. In a
double blind placebo
controlled trial in
depressive patients
treated with lithium,
the addition of 200 ìg
of folic acid for one
year significantly
improved affective
morbidity.17 Similarly,
the addition of 500 ìg
of the vitamin to
fluoxitine for 10 weeks
significantly improved
antidepressant response,
especially in women.18
In a double blind
placebo controlled trial
Godfrey et al added 15
mg of methylfolate to
standard psychotropic
medication and reported
significant and
increasing clinical and
social recovery of
folate deficient
depressed and
schizophrenic groups
over six months.19
Earlier Botez et al had
reported improvement in
both mood and
neuropsychological
function in a controlled
trial of folic acid 15
mg daily alone for four
months in depression.20
Geriatric and
psychogeriatric patients
The highest incidence of
folate deficiency as
measured by serum and
red cell folate
concentrations is in
elderly populations,
especially
psychogeriatric
patients.3 A close
association with
dementia and depression,
apathy, withdrawal, and
lack of motivation has
been noted. One reason
for the apparently high
incidence of
folate deficiency in
elderly people is that
folate concentrations in
serum and cerebrospinal
fluid fall and
plasma homocysteine
rises with age, perhaps
contributing to the
ageing process.21
Among 115 admissions to
a geriatric unit, 16%
had low red cell
folate.22 The 14
patients with dementia
had
lower folate
concentrations than any
other diagnostic group
and the severity of the
dementia on the mental
assessment score was
significantly correlated
with folate
concentrations, raising
the possibility of an
aetiological role. In a
casecontrol study of
164 patients with
Alzheimer's disease,
cognitive decline was
significantly associated
with raised plasma
homocysteine and lowered
serum folate (and
vitamin B12)
concentrations.6
In a prospective
community based study of
370 healthy elderly
Swedish subjects, folate
or vitamin B12
deficiency doubled the
risk of subsequently
developing Alzheimer's
disease.23 Recently the
much larger and
longer Framlingham
community based study
confirmed that a raised
plasma homocysteine
concentration doubled
the risk of developing
Alzheimer's and
nonAlzheimer's
dementia.9
In open studies
Runcie,13 reviewing his
own and others'
experience with folic
acid, and Brocker et
al,24
who utilised folinic
acid in 50 deficient
subjects, emphasised the
effects of the vitamin
on mood and
cognitive function: some
patients were strikingly
transformed into
independent, competent
people. Furthermore, in
a double blind trial for
eight weeks in 96
elderly depressed
patients with mild to
moderate
dementia, Passari et al
reported that
methylfolate 50 mg daily
was as effective as the
standard antidepressant
trazodone 100 mg daily
in improving depressive
symptoms rated on the
Hamilton scale,
irrespective of folate
status.25
Neuropsychological
studies
In a placebo controlled
trial of folic acid 15
mg daily for four months
in 24 folate deficient
depressed subjects with
mild cognitive
impairment, Botez et al
reported significant
improvement in the
Wechsler IQ
memory scale and Kohs
block design test.20 In
an open study of 38
folate deficient elderly
subjects with
depression, lethargy,
and memory impairment,
folinic acid 50 mg per
week for 120 days
significantly
improved visuomotor
performance,
visuospatial memory,
logical reasoning,
associative memory, and
activities for daily
living.26
In a survey of
nutritional status and
cognitive functioning in
260 healthy elderly
subjects aged 60 to 94
years in the community,
there was a significant
relation between
impaired abstract
thinking ability and
memory and lower folate
levels and intake.27 In
the New Mexico ageing
process study of 137
community residents aged
66 to 90 years, weak but
significant associations
were found between
measures of abstract
thinking and
concentrations of folate
(as well as other B
vitamins).28 In the
normative ageing study
of 70 men aged 54 to 81,
Riggs et al found that
low serum folate, low
vitamin B12, and
especially high plasma
homocysteine were
significantly associated
with impaired spatial
copying skills.29
In the Kingsholmen
ageing and dementia
project in Stockholm in
250 old (75 to 96 years)
and in 71 very
old (90 to 101 years)
otherwise healthy
subjects in the
community, impaired
episodic memory was
related to low serum
concentrations of
vitamin B12, but more
so to low serum
concentrations of
folate.30 The selective
effects of folate
deficiency on episodic
memory were suspected to
be related to encoding
and retrieval
mechanisms.Wahlin et al
extended their studies
of the same populations
to include a wider range
of cognitive
functions—spatial
orientation,
visuospatial
functioning, perceptual
motor speed, attention,
short termmemory, and
verbal fluency. They
found an overall effect
of folate status on
cognitive function,
whereas the overall
effect of vitamin B12
status did not approach
statistical
significance, although
it added to the effects
of reduced folate
status. In particular,
there were specific
effects on visuospatial
functioning, cognitive
shift and flexibility,
attention, working
memory, and phonemic
search, but only
marginal effects on
spatial orientation,
primary memory, and
category fluency. The
pattern of cognitive
dysfunction is claimed
to resemble that in
normal ageing—that is,
impairment in tasks that
involve little
structure, are
unfamiliar, speeded, and
attention demanding and
involve complex
processing of
information.
Neuropathological
studies
In the casecontrol
study of Clark et al the
diagnosis of Alzheimer's
disease was confirmed
neuropathologically in
76 patients in whom
higher plasma
homocysteine was
associated with a more
rapid
atrophy of the medial
temporal lobes over a
three year period.6 The
authors suspected a
toxic microvascular
mechanism.6
Snowden et al studied
prospectively 30 elderly
nuns from the same
environmental and
nutritional background.8
They died at the mean
age of 91 (range 78 to
101) years, and half had
neuropathological
lesions of Alzheimer's
disease. Of 18
nutritional factors
examined, only serum
folate was significantly
nega
tively correlated with
atrophy of the neocortex,
especially in the 15
nuns with Alzheimer's
disease but also in
those with minimal
atherosclerosis and no
infarcts.
Neurochemical aspects
Unusually, folic acid in
the form of methylfolate
is present in
cerebrospinal fluid in
humans in concentra
tions three times
greater than in serum.21
The active transport
mechanism for
methylfolate across the
bloodbrain barrier
strictly limits the
entry of the vitamin,
perhaps for reasons
concerned with the
excitatory (convulsant)
properties of folic
acid.2 4
Folates are involved in
onecarbon metabolism in
the brain as elsewhere.
The folate cycle is
responsible
for the synthesis of
methyl groups, which are
ultimately utilised by
Sadenosyl methionine in
innumerable
methylation reactions
involving
nucleoproteins,
proteins, membrane
phospholipids,
neurotransmitters
and monoamines.
Deficiency of both folic
acid and vitamin B12
will impair methylation
processes with
the accumulation of
homocysteine amongst
other effects. The
intimate relations of
folate, homocysteine
and SAM are shown in the
figure. Concentrations
of folate in serum and
cerebrospinal fluid
decline and those of
plasma homocysteine rise
with age, which
contributes to the
apparently high
incidence of the vitamin
deficiency in geriatric
and psychogeriatric
populations.3 21 Low
concentrations of folate
in serum, red cells, and
cerebrospinal fluid are
associated with
depression and dementia
in a wide range of
clinical
neuropsychiatric
settings, as is raised
plasma homocysteine(see
above). There is also
increasing evidence of
an association between
plasma homocysteine and
vascular disease, and
the increased risk of
dementia, including
Alzheimer's disease,
associated with raised
plasma homocysteine may
be mediated by a
vascular or possibly a
neurotoxic mechanism.6 9
Mood and some cognitive
functions may be related
to methylation processes
in the brain.31 With
respect to depression,
this hypothesis is
supported by the similar
effect of
Sadenosylmethionine to
that of folates on mood,
and by the influence of
folates and
Sadenosylmethionine on
monoamine metabolism,
which is also
incriminated in
depression.3 31 The
lowest concentrations of
folate and
Sadenosylmethionine in
cerebrospinal fluid are
found in dementia,
including Alzheimer's
disease.32
Conclusions
Folates are important in
the nervous system at
all ages and there is
growing evidence of
their involvement in the
ageing brain, especially
in mood and cognitive
function. The
association of folate
deficiency, as reflected
by low concentrations of
folate in serum, red
cells, and cerebrospinal
fluid and raised plasma
concentrations of
homocysteine, with
depression and dementia
has been confirmed in
epileptic, neurological,
psychiatric, geriatric
and psychogeriatric
patients and is
supported by
neuropsychological,
neuropathological, and
neurochemical studies.
Some of the deficiency
may be related to
ageing, some may be
secondary to mental
illness, and some
primary, but whether it
is primary or secondary,
open and controlled
treatment studies
confirm an aetiological
link with specific
effects of the vitamin
on mood, drive,
initiative, alertness,
concentration,
psychomotor speed, and
social activity. These
observations are
reinforced by the
cognitive studies in
otherwise healthy
subjects, suggesting
that low folate levels
are associated with
patterns of impairment
also found in ageing.
Within the wide spectrum
of depressive disorders,
a subgroup has been
identified in which
folate and related
methylation process are
involved. With respect
to dementia, there is
evidence that folate
deficiency may
contribute to the
cognitive impairment of
the ageing brain,
sometimes leading to
reversible dementia but
also increasing the risk
of Alzheimer's disease
and vascular dementia,
perhaps by methylation
related processes or by
homocysteine mediated
vascular or neurotoxic
mechanisms. It is well
known that
depression may be a
precursor of dementia in
a range of
neuropsychiatric
syndromes. The diagnosis
of folate deficiency
still presents problems
for physicians and
neuropsychiatrists if
haematological
abnormalities are
absent. Some studies
suggest that folate
deficiency affects the
nervous system only at
certain not very well
defined critically low
concentrations of folic
acid or high
concentrations of
homocysteine. This
imprecision almost
certainly relates to the
important influence of
duration of deficiency
as well as degree of
deficiency, in addition
to other predisposing
factors—for example,
genetic factors. Other
data, especially in
relation to some
cognitive impairments in
otherwise healthy
elderly people in the
community, suggest more
of a continuum, with
folate levels related to
performance even within
the “normal range.” This
raises questions about
the optimum nutritional
environment for the
healthy brain, which may
not be closely related
to arbitrary blood
levels.
Clearly, further
clinical trials in
precisely defined
clinical categories are
needed, but they should
be long
term (at least six
months to one year) as
the impact of folate is
slow and cumulative over
many months, per
haps because bloodbrain
barrier mechanisms limit
entry to the brain.
Small doses over the
long term may
be preferable to larger
doses in the short or
long term, not least
because of risks to the
nervous system,
especially in vitamin
B12 deficiency and
epilepsy.4 It is not
clear which folate
formulation is
preferable: folic acid,
folinic acid, or perhaps
methylfolate (the
transport form across
the bloodbrain
barrier). The best way
forward may be to
undertake large scale
community based studies
of folate
supplementation or food
fortification to explore
the preventive potential
of the vitamin for mood
and cognitive disorders.
Such studies are being
designed or undertaken
for the possible
prophylaxis of vascular
disease and could be
adapted to address the
question of preventing
or reducing depression
and dementia, including
vascular dementia, while
taking into account the
special requirementsof
the nervous system.
Printable
PDF
Version
|
