Content uploaded by Ozgur Oner
Author content
All content in this area was uploaded by Ozgur Oner
Content may be subject to copyright.
Effects of Zinc and Ferritin Levels on Parent and Teacher
Reported Symptom Scores in Attention Deficit Hyperactivity
Disorder
Ozgur Oner,
Child Psychiatry Department, Dr Sami Ulus Children’s Hospital, Telsizler, Altindag, Ankara,
Turkey. Fogarty International Center Mental Health and Developmental Disabilities Program,
Children’s Hospital, Boston, MA, USA
Pinar Oner,
Child Psychiatry Department, Dr Sami Ulus Children’s Hospital, Telsizler, Altindag, Ankara,
Turkey
Ozlem Hekim Bozkurt,
Child Psychiatry Department, Diskapi Children’s Hospital, Ankara, Turkey
Elif Odabas,
Child Psychiatry Department, Diskapi Children’s Hospital, Ankara, Turkey
Nilufer Keser,
Child Psychiatry Department, Diskapi Children’s Hospital, Ankara, Turkey
Hasan Karadag, and
Diskapi Yildirim Bayazit Training Hospital, Diskapi, Ankara, Turkey
Murat Kızılgün
Biochemistry Department, Diskapi Children’s Hospital, Ankara, Turkey
Ozgur Oner: ozgur.oner@yahoo.com
Abstract
Objective—It has been suggested that both low iron and zinc levels might be associated with
Attention Deficit Hyperactivity Disorder (ADHD) symptoms. However, the association of zinc
and iron levels with ADHD symptoms has not been investigated at the same time in a single
sample.
Method—118 subjects with ADHD (age = 7–14 years, mean = 9.8, median = 10) were included
in the study. The relationship between age, gender, ferritin, zinc, hemoglobin, mean corpuscular
volume and reticulosite distribution width and behavioral symptoms of children and adolescents
with ADHD were investigated with multiple linear regression analysis.
Results—Results showed that subjects with lower zinc level had higher Conners Parent Rating
Scale (CPRS) Total, Conduct Problems and Anxiety scores, indicating more severe problems.
CPRS Hyperactivity score was associated both with zinc and ferritin levels. Conners Teacher
Rating Scale (CTRS) scores were not significantly associated with zinc or ferritin levels.
Conclusions—Results indicated that both low zinc and ferritin levels were associated with
higher hyperactivity symptoms. Zinc level was also associated with anxiety and conduct problems.
© Springer Science+Business Media, LLC 2010
Correspondence to: Ozgur Oner, ozgur.oner@yahoo.com.
NIH Public Access
Author Manuscript
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
Published in final edited form as:
Child Psychiatry Hum Dev
. 2010 August ; 41(4): 441–447. doi:10.1007/s10578-010-0178-1.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
Since both zinc and iron are associated with dopamine metabolism, it can be speculated that low
zinc and iron levels might be associated with more significant impairment in dopaminergic
transmission in subjects with ADHD.
Keywords
ADHD; Zinc; Ferritin; Behavioral ratings
Introduction
Attention Deficit Hyperactivity Disorder (ADHD) is one of the most common
neuropsychiatric disorders of childhood, consisting of two symptom domains, hyperactivity/
impulsivity and inattentiveness [1]. The exact pathophysiology of the symptoms is unclear at
the moment, although several studies suggested that both genetic and environmental factor
and their interactions are important. Some studies investigated the association of iron and
zinc metabolisms with ADHD. A number of studies showed that children with ADHD had
lower mean ferritin levels when compared with normal controls and that low serum ferritin
levels were related with more severe symptoms reported by teachers or parents [2, 3 but also
see 4]. Other studies have focused on the utility of iron supplementation in ADHD, with
conflicting results [5, 6]. A relationship among iron deficit, restless legs syndrome (RLS)
and other sleep disorders and ADHD has also been reported, suggesting a common
dopaminergic impairment in these conditions [7, 8]. In our sample, we found that the rate of
iron deficiency was significantly higher in ADHD subjects with RLS when compared with
ADHD subjects without RLS, showing that depleted iron stores might increase the risk of
having RLS in ADHD subjects. We also reported that there were no significant correlations
between ferritin level and performance in vigilance and sustained attention tasks, executive
function tests like planning and organization, complex problem solving, set shifting and
response monitoring [3]. We also showed that in the ADHD group in general, parent and
teacher ratings were significantly negatively correlated with ferritin level. When only pure
ADHD subjects were taken into account, the correlations did not reach statistical signifance,
suggesting that lower ferritin level was associated with higher behavioral problems reported
by both parents and teachers. Presence of comorbid conditions might also increase the effect
of lower iron stores on behavioral measures [9].
Several researchers reported a link between zinc levels and ADHD symptoms [reviewed in
10]. Results of other studies suggested that zinc supplementation might be effective in
decreasing ADHD symptoms [11]. This makes sense since zinc is an inhibitor dopamine
transporter, which is also the main target of stimulant medications [12]. An event related
potentials study showed that zinc-deficient ADHD subjects might have different information
processing when compared with non-zinc-deficient subjects [13].
However, the association of both iron and zinc metabolisms and ADHD symptoms in a
single sample has not been investigated. This is important because both zinc and iron is
important in dopamine pathway [12, 14]. In this study, our aim was to investigate the
relationship between ferritin, zinc, hemoglobin, mean corpuscular volume (MCV) and
reticulosite distribution width (RDW) and behavioral symptoms of children and adolescents
with ADHD. We selected these hematological variables since iron deficiency is usually
defined by low serum ferritin levels, or low MCV and high RDW values. Our hypothesis
was that behavioral symptoms of subjects with ADHD were related to both ferritin and zinc
levels.
Oner et al. Page 2
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
Method
118 subjects with ADHD (97 boys (82.2%), 21 girls (17.8%); age 7–14 years, mean ± SD:
9.8 ± 2.3, median = 10) were included in the study. All of the cases were Caucasian. All
subjects were recruited from the general outpatient clinic of a general hospital, who fulfilled
the inclusion criteria [combined type ADHD diagnosis, being drug-naive, age 7–14; Conners
Parent Rating Scale Hyperactivity score above cut-off (7)]. Informed consent was obtained
from the parents before enrollment with local ethics committee approval for inclusion in the
study. Diagnosis was based on DSM-IV criteria and made by the first author (Ozgur Oner),
an experienced child psychiatrist using K-SADS-PL semi-structured interview. Informed
consent process was verbal as is customary given the literacy level of the parents. 50 cases
had comorbid oppositional defiant or conduct disorders, 32 cases had anxiety disorder or
depression. All ADHD cases had unremarkable medical history other than ADHD and were
clinically screened for psychosis, eating disorders, substance use disorders, pervasive
developmental disorders, and mental retardation. All patients were diagnosed for the first
time and had never been evaluated for psychiatric disorders or treated with
psychopharmacological medicine. All ADHD subjects were combined type since we
excluded other subtypes. The parents could select to opt out of the study but none of the
parents refused to participate Table 1.
Symptom severity was evaluated with Conners Parent and Teacher Rating Scales. The
subjects who had scores lower than the proposed cut-off scores (CPRS Hyperactivity score =
7 and CTRS Hyperactivity score = 6) were excluded.
Conners Parent Rating Scale (CPRS)
This form includes 48 items, which aims to evaluate behavior of children assessed by their
parents [15]. The scale includes oppositional behavior, inattentiveness, hyperactivity,
psychosomatic and irritability domains. Turkish translation has good validity and reliability
[16].
Conners Teacher Rating Form (CTRS)
This form includes 28 items, which aim to rate classroom behavior of children assessed by
teachers [17]. There are three subscales of the form: 8 items inattentiveness, 7 items
hyperactivity and 8 items conduct problems. CTRS is translated to Turkish by Şener [18],
and the Turkish form showed adequate validity and reliability (Cronbach’s alpha .95).
Data Analysis
Multiple regression analysis was used in order to evaluate the effects of age, gender, ferritin,
zinc, and hemoglobin levels, mean corpuscular volume and RDW values on the CPRS
Learning Problems, Conduct Problems, Hyperactivity, Anxiety and Total scores as well as
CTRS Hyperactivity, Conduct Problems, Inattentiveness and Total scores. We chose ferritin,
hemoglobin; MCV and RDW values since they were the factors evaluated in anemia and
iron deficiency criteria. Model fit in the regression analysis was evaluated by Durbin-
Watson test. Two-tailed significance tests (
p
< .05) are reported throughout. SPSS 13.0
statistical package was used for the analysis.
Results
CPRS Total score was significantly related with serum zinc level; cases with lower zinc
level had higher scores, indicating more severe problems (
B
= −.22,
t
= −2.4,
p
= .02). CPRS
Conduct Problems score was associated with zinc level (
B
= −.20,
t
= −2.1,
p
= .04) and also
there was a statistical trend for higher scores in males (
B
= −.18,
t
= −1.49,
p
= .055). CPRS
Oner et al. Page 3
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
Hyperactivity score was associated with zinc and ferritin (
B
= −.26,
t
= −2.9,
p
= .005 and
B
= −.21,
t
= −2.3,
p
= .02, respectively) levels and with being male (
B
= −.18,
t
= −2.0,
p
= .
048). CPRS Anxiety score was associated with zinc level (
B
= −.19,
t
= −2.0,
p
= .044).
CTRS Hyperactivity and Total scores were significantly associated with being male (
B
= −.
31,
t
= −3.1,
p
= .002 and
B
= −.22,
t
= −2.3,
p
= .02, respectively) and RDW (
B
= .27,
t
=
2.3,
p
= .03 and
B
= .28,
t
= 2.4,
p
= .02, respectively).
Discussion
The results of the present study was consistent with previous studies, including our group’s,
showing that low ferritin level was associated with higher hyperactivity scores [2, 3].
However, in the present study we have found that low zinc level was also associated with
high CPRS Hyperactivity score as well as high CPRS Anxiety, Conduct Problems and Total
scores. That was also consistent with previous studies indicating higher scores in patients
with low zinc levels [10]. This result expanded previous findings by showing that both iron
and zinc metabolism were significantly associated with parental behavioral reports in a
single sample. Our findings suggested that subjects with low zinc and low iron levels might
have highest level of parent reported hyperactivity symptoms. Interestingly, neither ferritin
nor zinc levels were associated with Learning Problems score, suggesting that they were
more closely related with hyperactivity/impulsivity component of ADHD than inattention
component. This was also consistent with our previous results [3]. We also found an
association between RDW and teacher reported symptoms. High RDW is associated with
iron deficiency, but it is not easy to interpret the results.
It has been found that iron is closely related to dopamine metabolism being a coenzyme of
tyrosine hydroxylase, and that D2 and D4 receptor and dopamine transporter densities
decrease with decreased brain iron levels [14, 19, 20]. Zinc is a dopamine transporter
inhibitor, since dopamine transporter is the main factor that determines the synaptic
dopamine level, zinc level is supposed to be associated with dopaminergic transmission
[12]. Neuroimaging, genetics, and animal studies have suggested that dopaminergic
transmission is impaired in subjects with ADHD [21]. It can be speculated that iron and zinc
deficiencies might cause further alterations in brain dopaminergic system, which seems to be
already impaired in ADHD subjects [22]. Our results showed that both ferritin and zinc
levels were negatively correlated with CPRS Hyperactivity score, suggesting an additive
effect. On the other hand, only low zinc level was associated with CPRS Conduct Problems
and Anxiety scores, suggesting that zinc and iron levels might be associated with different
behaviors. It has recently been shown that zinc deficiency might induce depression-like
behaviors in rats [23]. However, the link between internalization disorders and zinc
deficiency is not very clear.
The most obvious limitation of the present study was the cross-sectional design. In cross-
sectional studies one can not infer on causality, but can only report associations. The other
potential limitation of the study was the clinical nature of the sample, these results may not
be valid for population samples.
Summary
In summary, our results supported and extended previous findings by showing that there was
a significant negative association between both zinc and ferritin levels and parent reported
hyperactivity symptoms, suggesting that subjects with low levels of iron and zinc might be
at increased risk of having higher levels of hyperactivity. Zinc level was also associated with
parent reported conduct problems and anxiety.
Oner et al. Page 4
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
Acknowledgments
Ozgur Oner, MD and Pinar Oner, MD are supported by Fogarty International Center Mental Health and
Developmental Disabilities Program (D43TW05807) at Children’s Hospital, Boston (Kerim Munir, PI).
References
1. American Psychiatric Association. Diagnostic and statistical manual of mental disorders. IV.
Washington DC: 1994.
2. Konofal E, Lecendreux M, Arnulf I, Mouren MC. Iron deficiency in children with attention deficit
hyperactivity disorder. Arch Pediatr Adolesc Med. 2004; 158:1113–1115. [PubMed: 15583094]
3. Oner O, Alkar O, Oner P. Relation of ferritin levels with symptom ratings and cognitive
performance in children with ADHD. Ped Int. 2008; 50:40–44.
4. Millichap JG, Yee MM, Davidson SI. Serum ferritin in children with attention-deficit hyperactivity
disorder. Pediatr Neurol. 2006; 34:200–203. [PubMed: 16504789]
5. Sever Y, Ashkenazi A, Tyrano S, Weizman A. Iron treatment in children with attention deficit
hyperactivity disorder. Neuropsychobiology. 1997; 35:178–180. [PubMed: 9246217]
6. Konofal E, Lecendreux M, Deron J, Marchand M, Cortese S, Zaïm M, Mouren MC, Arnulf I.
Effects of iron supplementation on attention deficit hyperactivity disorder in children. Pediatr
Neurol. 2008; 38:20–26. [PubMed: 18054688]
7. Oner P, Dirik EB, Taner Y, Caykoylu A, Anlar O. Association between low serum ferritin and
restless legs syndrome in patients with attention deficit hyperactivity disorder. Tohoku J Exp Med.
2007; 213:269–276. [PubMed: 17984624]
8. Cortese S, Konofal E, Bernardina BD, Mouren MC, Lecendreux M. Sleep disturbances and serum
ferritin levels in children with attention-deficit/hyperactivity disorder. Eur Child Adolesc
Psychiatry. 2009; 18:393–399. [PubMed: 19205783]
9. Oner P, Oner O. Relationship of ferritin to symptom ratings children with attention deficit
hyperactivity disorder, effect of comorbidity. Child Psychiatry Hum Dev. 2008; 39:323–330.
[PubMed: 18165896]
10. Arnold LE, Bozzolo H, Hollway J, Cook A, DiSilvestro RA, Bozzolo DR, Crowl L, Ramadan Y,
Williams C. Serum zinc correlates with parent- and teacher- rated inattention in children with
attention-deficit/hyperactivity disorder. J Child Adolesc Psychopharmacol. 2005; 15:628–636.
[PubMed: 16190794]
11. Uçkardeş Y, Ozmert EN, Unal F, Yurdakök K. Effects of zinc supplementation on parent and
teacher behaviour rating scores in low socioeconomic level Turkish primary school children. Acta
Paediatr. 2009; 98:731–736. [PubMed: 19133873]
12. Krause J. SPECT and PET of the dopamine transporter in attention-deficit/hyperactivity disorder.
Expert Rev Neurother. 2008; 8:611–625. [PubMed: 18416663]
13. Yorbik O, Ozdag MF, Olgun A, Senol MG, Bek S, Akman S. Potential effects of zinc on
information processing in boys with attention deficit hyperactivity disorder. Prog
Neuropsychopharmacol Biol Psychiatry. 2008; 32:662–667. [PubMed: 18083281]
14. Erikson K, Pinero D, Connor J, Beard J. Iron status and distribution on iron in the brains of the
developing rats. J Nutr. 1997; 127:2030–2038. [PubMed: 9311961]
15. Conners, CK. Conners’ rating scales- revised. Multi-Health Systems Publishing; North Tonawada:
1997.
16. Dereboy, C.; Senol, S.; Sener, S. Adaptation of Conners’ parent rating scale in Turkish.
Proceedings 10th National Congress of Psychology; Ankara. 1998.
17. Goyette CH, Conners CK, Ulrich RF. Normative data on revised Conners’ parent and teacher
rating scales. J Abnorm Child Psychol. 1978; 6:221–236. [PubMed: 670589]
18. Sener S, Dereboy C, Dereboy IF, Sertcan Y. Conners’ teacher rating scale Turkish version-I. Tr J
Child Adolesc Ment Health. 1995; 2:131–141.
19. Wigglesworth, JM.; Baum, H. Iron dependent enzymes in the brain. In: Youdim, MBH., editor.
Brain ıron: neurochemical and behavioral aspects. Taylor and Francis; New York: 1988. p. 25-66.
Oner et al. Page 5
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
20. Ashkenazi R, Ben-Shachar D, Youdim MBH. Nutritional iron deficiency and dopamine binding
sites in the rat brain. Pharmacol Biochem Behav. 1982; 17:43–47. [PubMed: 7184034]
21. Swanson JM, Kinsbourne M, Nigg J, Lanphear B, Stefanatos GA, Volkow N, Taylor E, Casey BJ,
Castellanos FX, Wadwha PD. Etiological subtypes of attention deficit hyperactivity disorder: brain
imaging, molecular genetics and environmental factors and the dopamine hypothesis.
Neuropsychol Rev. 2007; 17:39–59. [PubMed: 17318414]
22. Volkow N, Wang J, Newcorn J, Telang F, Solanto MV, Fowler JS, Logan J, Ma Y, Schulz K,
Pradhan K, Wong J, Swanson JM. Depressed dopamine activity in caudate and preliminary
evidince of limbic involvement in adults with attention deficit hyperactivity disorder. Arch Gen
Psychiatry. 2007; 64:932–940. [PubMed: 17679638]
23. Whittle N, Lubec G, Singewald N. Zinc deficiency induces enhanced depression-like behaviour
and altered limbic activation reversed by antidepressant treatment in mice. Amino Acids. 2009;
36:147–158. [PubMed: 18975044]
Oner et al. Page 6
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript
Oner et al. Page 7
Table 1
Multiple regression analysis results showing the
B
,
t
and
p
values for each dependent (Conners Parent or Teacher Rating Scale scores) varible with age,
gender, ferritin, zinc, hemoglobin (Hb), mean corpuscular volume (MCV) and reticulosite distribution width (RDW) as independent factors
Conners Parent Rating Scale Conners Teacher Rating Scale
Total B; t; p Conduct problems B; t;
pLearning problems B;
t; p Hyperactivity B; t; p Hyperactivity B; t; p Inattention B; t; p Conduct problems B; t;
pTotal B; t; p
Age .11; 1.1; .28 .01; .06; .95 .18; 1.8; .08 −.02; −.17; .87 −.07; −.65; .52 .08; .72; .47 −.01; −.11; .91 .0; .0; .98
Gender −.04; −.50; .62 −.18; −1.9; .06 −.04; −.41; .68 −1.8; −2.0; .048 −.31; −3.1; .002 −.05; −.44; .66 −.19; −1.8; .07 −.22; −2.2; .03
Zinc −.22; −2.3; .02 −.20; −2.1; .04 −1.0; −.98; .32 −.26; −2.9; .005 −.01; −.05; .96 .08; .72; .47 .13; 1.3; .20 .08; .79; .43
Hb .02; .14; .89 .05; .44; .66 .08; .67; .51 .09; .84; .41 .04; .30; .77 −.07; −.55; .58 −.08; −.67; .50 −.05; −.37; .71
MCV .08; .71; .48 .16; 1.4; .17 −.08; −.71; .48 .17; 1.5; .13 .08; .68; .50 .18; 1.4; .17 .16; 1.3; .19 .17; 1.4; .17
RDW .04; .32; .75 .08; .69; .49 .04; .37; .71 .20; 1.9; .06 .27; 2.3; .02 .19; 1.6; .12 .23; 1.9; .06 .28; 2.4; .02
Ferritin −.16; −1.6; .10 −.11; −1.2; .25 .01; .12; .91 −.21; −2.3; .02 .08; .84; .40 −.16; −1.5; .14 −.02; −.20; .85 −.03; −.33; .74
Child Psychiatry Hum Dev
. Author manuscript; available in PMC 2012 July 18.