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Determination of Zinc, Copper, Selenium, and 
Manganese in Human Milk using Acid Digestion 
by ICP-MS and its Application in Biological 
Trace Element Monitoring 
Nor Hidayah Mohd Taufek1*, Awis Sukarni Mohmad Sabere2, Ummi Syahidah Mohamad 
Jamahari1, Nur Balkhis Amran1, Abdul Rahman Fata Nahas1 and Joseph Bidai3 

*Corresponding author: 

Email address: 
hidayahtaufek@iium.edu.my  
 

 

Authors’ Affiliation: 
1 Department of Pharmacy Practice, Kulliyyah of Pharmacy, International Islamic University Malaysia, 
Jalan Sultan Ahmad Shah, 25200 Kuantan, Pahang, Malaysia. 
2 Department of Pharmaceutical Chemistry, Kulliyyah of Pharmacy, International Islamic University 
Malaysia, Jalan Sultan Ahmad Shah, 25200 Kuantan, Pahang, Malaysia. 
3 South China Sea Repository & Reference Center, Institute of Oceanography and Environment 
(INOS), University Malaysia Terengganu, 21030, Kuala Terengganu, Terengganu, Malaysia. 

 

 

ABSTRACT 

Introduction:  Human milk contains essential trace elements which support healthy development 
of infants. Previous studies have reported various analytical methods using different instruments 
to measure trace elements in human milk. This study aimed to determine trace element 
concentration in human milk using a validated acid digestion method and its application in 
biomonitoring among postpartum mothers. 
 
Method:  Human milk samples were collected from three postpartum mothers and prepared using 
acid digestion method. All samples were analysed using inductively coupled plasma mass-
spectrometry (ICP-MS) and all validation parameters were measured. 
 
Results: Four trace elements which were zinc, copper, manganese and selenium were found to 
have good linearity (r² > 0.99), limit of detection in µg/L (0.06, 0.0001, 0.005, 0.00003, 
respectively) and limit of quantification in µg/L (0.18,0.0003, 0.02, 0.0001, respectively). Good 
accuracy (83.4 – 112.7%), inter-day, and intra-day repeatability were obtained. Method 
application on trace element monitoring over postpartum period of three participants showed the 
median concentration of zinc, copper and selenium in human milk gradually decreased with slight 
variation, whereas manganese remained stable. Positive significant correlations were observed 
for most of the elements (r > 0.40, p < 0.001) except for copper-manganese. 
 
Conclusion: Acid digestion method is sensitive, accurate and precise to analyse and quantify 
zinc, copper, manganese and selenium concentrations in human milk simultaneously by ICP-MS. 
It can be applied to monitor trace elements concentration in human milk in clinical and public 
health settings. 

ARTICLE HISTORY:  

Received: 9 May 2023 
Accepted: 13 July 2023 
Published: 31 July 2023 

 

KEYWORDS:  

Trace elements, human milk, ICP-
MS, acid digestion, validation  

HOW TO CITE THIS 
ARTICLE: 

Mohd-Taufek, N. H., Mohmad 
Sabere, A. S., Mohamad 
Jamahari, U. S., Amran, N. B., 
Fata Nahas, A. R., & Bidai, J. 
(2023). Determination of Zinc, 
Copper, Selenium, and 
Manganese in Human Milk using 
Acid Digestion by ICP-MS and its 
Application in Biological Trace 
Element Monitoring. Journal of 
Pharmacy, 3(2), 129-139 

 

doi: 10.31436/jop.v3i2.226 



 

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Introduction 

Human milk has been reported to contain essential 
trace elements such as zinc, copper, iron, iodine, and 
selenium (Mohd-Taufek et al., 2016). The presence of 
these trace elements despite only in minute amount is very 
crucial to support infants’ development and prevent trace 
element deficiencies. Determining the optimum trace 
elements concentration in human milk will ensure that 
infants get the most benefits and prevent deficiencies. 
Trace elements play vital roles in growth and metabolisms, 
and the concentration have been reported to vary in human 
milk of different study populations and at different 
lactational stage according to infant’s requirement (Hunt & 
Nielsen, 2009). It is important to monitor trace elements 
concentration in human milk and identify reference range 
at different stages of lactation. 

Previously, numerous analytical instruments have 
been reported to measure trace element analysis in human 
milk. Some of the reported techniques were using 
inductively coupled plasma–optical emission spectrometry 
(ICP-OES) (Durović, et al., 2017), flame atomic absorption 
spectrometry (FAAS) (Kim et al., 2012), inductively 
coupled plasma sector field mass spectrometry (ICP-SF-
MS) (Ecsedi-Angyal et al., 2019) and graphite furnace 
atomic absorption spectroscopy (Ait lhaj et al., 2021). 
Currently, the inductively coupled plasma mass-
spectrometry (ICP-MS) has been widely utilised to 
determine multi-element concentration in human milk due 
to its capability to detect many elements simultaneously at 
very low concentrations (Mohd-Taufek et al., 2016; Rovira 
et al., 2022; Tahboub et al., 2021). 

Another advantage of ICP-MS is that it involves 
simple preparation of samples. For example, acid digestion 
and alkaline dissolution methods have been used to prepare 
human milk samples prior to analysis (Jagodic et al., 2020; 
Levi et al., 2018; Mohd-Taufek et al., 2016). Nitric acid 
and hydrochloric acid were the most often used acids in 
acid digestion method, whereas ammonium hydroxide and 
tetramethylammonium hydroxide (TMAH) were the most 
frequently used alkali in alkaline dissolution method 
(Wilschefski & Baxter, 2019). Nitric acid also has been 
reported to be the most optimum acid media for ICP-MS 
analysis due to its strong oxidising ability that is able to 
extract the trace element from the sample by forming 
soluble nitrate salts (Hu & Qi, 2014). Although there were 
studies which reported that the alkaline dissolution method 
was better than the acid digestion method, some elements 
were reported to be accurately analysed by the acid 
digestion method and there were also elements that 
produced the consistent results regardless of using alkaline 
dissolution or acid digestion method (Levi et al., 2018; 
Mohd-Taufek et al., 2016). 

In human milk studies, there is no certified reference 
material for human milk available. Therefore, various 
certified standard reference materials in the form of milk 

powder such as NIST 1549, CRM 8534, and NIST 8435 
and spiked samples have been used as the reference 
material to validate a developed analytical method (Alves 
Peixoto et al., 2019; Baranowska-Bosiacka et al., 2016; 
Jagodic et al., 2020; Mohd-Taufek et al., 2016; Pekou et 
al., 2022). Currently to our knowledge, there is no study 
available that has reported about a validated method to 
measure trace elements concentration in human milk in 
Malaysia probably due to limited access to analytical 
instruments and ethical issues about human milk samples. 
This study aimed to validate a simple acid digestion 
method to measure simultaneously the concentration of 
trace elements in human milk by ICP-MS and determine its 
application in biological monitoring among postpartum 
mothers. 

Methodology 

This study received International Islamic University 
Malaysia (IIUM) Research Ethics Committee (IREC) 
approval (ID No.: IREC 2021-053). 

Study participants 

A total of three postpartum women were recruited 
to provide milk samples. Participant information sheet and 
informed consent form were provided. The mothers were 
informed about the study and voluntarily provided human 
milk samples for analysis at their convenience. Data 
collection form was filled in by the participants for 
demographic information, medical and medication history, 
and their lifestyles. The participants provided expressed 
breast milk (EBM), which were collected in 2 mL syringes 
or the EBM plastic container, labelled with date of milk 
collection. All samples were frozen at -21ºC prior to 
analysis. Sample analyses were conducted at the Institute 
of Oceanography and Environment (INOS), University 
Malaysia Terengganu. 

Sample Preparation 

The frozen human milk samples were thawed at room 
temperature and manually shaken until the samples were 
completely homogenised. For the acid digestion method, 
15.4 mL of 65% (v/v) nitric acid (Merck Suprapur) was 
diluted with deionised water up to 1 L to prepare 1% (v/v) 
nitric acid. Then, 1 mL of samples was then added to 9 mL 
of 1% (v/v) nitric acid in a 15 mL polypropylene conical 
tube (Corning Falcon) and was shaken manually until a 
homogenous solution was formed. The prepared sample 
were then analysed using ICP-MS. 

Blanks Preparation 

A total of 10 sets of blanks were prepared by adding 10 
mL of 1% (v/v) nitric acid into a 15 mL polypropylene 
conical tube. The blanks were used to calculate the limit of 
detection (LOD) and limit of quantification (LOQ) for 



 

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method validation purpose. 

Wash solutions 

The Milli-Q water was used for wash purposes between 
samples analysis. Acid washout using 1% (v/v) nitric acid 
was done after analysing ten to twenty samples. 

Standards Preparation 

For the preparation of standards, a multi-element standard 
solution (PerkinElmer Pure VIII) with 100 g/mL of Al, B, 
Ba, Be, Bi, Ca, Cd, Co, Cr, Cu, Fe, Ga, K, Li, Mg, Mn, Na, 
Ni, Pb, Se, Sr, Te, Tl, and Zn (Merck Certipur) were used. 
To make a standard stock solution, 1 mL of multi-element 
standard solution was added to a polypropylene conical 
tube that contained 49 mL of 1% (v/v) nitric acid. For 
calibration purposes, six calibration standard solutions 
were prepared by mixing 1 mL of milk sample with 0.1 
mL, 0.2 mL, 0.3 mL, 0.4 mL, 0.5 mL, and 0.6 mL of multi-
element stock solution. All the standard solutions were 
then further diluted up to 10 mL with 1% (v/v) nitric acid 
to produce the following final concentrations: 0.02 µg/mL, 
0.04 µg/mL, 0.06 µg/mL, 0.08 µg/mL, 0.1 µg/mL and 0.12 
µg/mL for all elements. 

Quality control 

Skimmed milk powder ERM-BD150 was used as a 
certified reference material for quality control in this study. 
A total of 0.02 g of ERM-BD150 was weighed and diluted 
up to 10 mL with 1% (v/v) nitric acid in a polypropylene 
conical tube. The solution was manually shaken until all 
milk powder was fully dissolved. Three replicates of 
certified reference material were prepared daily for method 
validation purpose. The milk samples were analysed 
together with the blanks, reference materials, and spiked 
samples. 

Samples Analysis 

Sample analysis was conducted using Perkin-Elmer 
SCIEX ICP-MS model ELAN 9000 connected with DELL 
PC equipped with ELAN Instrument Control Session 
software (PerkinElmer Inc., Massachusetts, USA). The 
working condition for this instrument is presented in Table 
1. During analysis, the samples were nebulised with a 
pneumatic nebuliser and then transported into the plasma 
for ion production using argon gas. Ions were brought into 
a quadrupole, where they were separated according to their 
mass/charge ratio (m/z), after passing through several 
focusing lenses and a reaction cell. On an electron 
multiplier detector (SimulScan™), specific isotopes of 
single-charged ions were identified, and the resulting 
electrical current was intensified to produce an intensity 
value in counts per second (cps). The system software was 
then used to translate the intensities for various isotopes in 
the tested samples into concentrations and compared them 
to those obtained from calibration standard solutions. Each 
sample underwent analysis for a total of one minute and 

forty seconds. 
 

Table 1: ICP-MS working conditions (ELAN 9000, Perkin-
Elmer SCIEX) 

 
Nebulizer gas flow (L min-1)  0.94 

RF power (W)  1100 

Analog stage voltage (V)  -1700 

Lens voltage (V)  6 

Pulse stage voltage (V)  900 

Ac rod offset (V)  -6 

Discriminator threshold (V)  70 

Scan mode  Peak hopping 

Speed of peristaltic pump (rpm)  26 

Detector Pulse Sweeps/Reading  50 

Replicates  2 

Sampler/Skimmer cones  Nickel 

Dwell Time (ms)  2.5 

Spray chamber  Ryton® Double-pass 
Scott-type spray 

chamber 

Nebulizer  Gem-tip Cross-Flow 
pneumatic nebulizer 

 

Linearity, LOD, LOQ, Accuracy and Repeatability 

The validation parameters that were assessed and 
calculated included linearity, LOD, LOQ, accuracy and 
repeatability. To assess the linearity of the method, 
calibration graphs for each element were generated by the 
system software at final concentrations of 0.02 g/mL, 0.04 
g/mL, 0.06 g/mL, 0.08 g/mL, 0.1 g/mL, and 0.12 g/mL. 
The linearity was assessed using the correlation coefficient 
value (r2) derived from the calibration graph given by the 
system software. Ten series of blank solutions were 
employed to calculate LOD and LOQ. The ICH 
Harmonised Tripartite Guideline (2005) formula were used 
in this study to determine LOD and LOQ based on the 
slope and the standard deviation of the blank: 
 

LOD = 3.3 σblank
b 

 



 

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LOQ = 10 σblank
b 

 

*σblank: standard deviation of 10 series of blanks 
*b: slope of calibration curve 
 
Accuracy which was reported in the form of recovery 
percentage was calculated using Microsoft Excel 2019 by 
comparing the result obtained from the analysis of ERM-
BD150 to the certified reference value provided by the 
manufacturer.  
 
Repeatability was assessed on the same day (intra-day) and 
three different days (inter-day). Inter-day repeatability was 
determined by analysing three ERM-BD150 samples and 
five human milk samples on three different days, whereas 
intra-day repeatability was determined by analysing three 
ERM-BD150 samples and five human milk samples on the 
same day. Repeatability was reported as %RSD and 
calculated using the following formula: 
 
%RSD = Standard deviation

mean
 ×100% 

The inter-day repeatability was computed using the pooled 
relative standard deviation formula derived from the 
formula provided by Mc Naught & Wilkinson (2012). The 
inter-day repeatability was calculated as follows: 
 

RSDpooled= (n1−1)RSD1
2+

 
(n2−1)RSD22+⋯+(nk−1)RSD!2

  

n1+ n2+⋯ +nk −!  

*k: different series of measurements 
*n: number of analysed samples 
 
 
The acceptance range for accuracy and repeatability are 
70-120% for recoveries with an RSD% ≤20% based on the 
2017 Codex Alimentarius Commission.  

Results 
Calibration data obtained from this analysis were tabulated 
in Table 2 that showed good linearity (r2 > 0.99) 
calibration curve for four trace elements which were zinc 

(Zn), copper (Cu), selenium (Se) and manganese (Mn). 
Zinc had the highest LOD value (0.06 µg/L), whereas Mn 
had the lowest (0.00003 µg/L).  

The concentration of Zn, Cu, Se and Mn were also 
analysed in certified reference material ERM-BD150 in 
µg/L. The concentrations in µg/L were multiplied by the 
dilution ratio for the ERM-BD150 solution, then divided 
by 1000 to get milligrams per kilogram for the purpose of 
comparison with the manufacturer's certified value to 
measure the accuracy. The accuracy values for all four 
trace elements from the analysed ERM-BD150 were 
between 83.4% and 112.7%. All trace elements achieved 
satisfactory percentage recoveries within the acceptable 
range (Table 3). Except for the inter-day repeatability 
value of Se (18.37%), the intra-day and inter-day 
repeatability values for other elements in the ERM-BD150 
samples were less than 10%. 

Table 4 showed the repeatability values for intra-day 
and inter-day measurements for human milk samples. It 
was notable that the very low concentration of Mn and Se 
found in human milk demonstrated significant variability 
that lowered the method precision. Nevertheless, this 
method is considered precise as all repeatability values for 
all four trace elements were less than 20% which is 
considered acceptable by the guideline of 2017 Joint 
FAO/WHO Codex Alimentarius Commissions.  

Application in biological trace element monitoring: Case 

studies 

The validated method was then applied to analyse a 
total of 105 milk samples donated by three postpartum 
mothers. The data were reported as case studies in this 
research and demographics of the mothers were presented 
in Table 5. 

Participant A was a 30-year old mother who delivered 
a male neonate at 41 weeks of gestation with a birth weight 
(BW) of 3.04 kilograms. She voluntarily donated a total of 
64 breast milk samples, collected at different times of the 
day over six months, at her convenience. The infant was 
healthy and fully breastfed during the study period. 

Participant B was a 27-year old mother who gave 
birth to a term male infant with a BW of 3.04 kilograms at 
38 weeks of gestation. A total of 30 breast milk samples

 
Table 2: LOD, LOQ, slope and correlation coefficient for four trace elements measured in acid digestion methods. 

 

Trace elements LOD (µg/L) LOQ (µg/L) Slope Correlation coefficient (r2) 

Zn 0.06 0.18 y= 937x - 5877 0.9976 

Cu 0.0001 0.0003 y= 3747x - 21033 0.9992 

Se 0.005 0.02 y= 203x - 967 0.9993 

Mn 0.00003 0.0001 y= 10617x - 47720 0.9992 



 

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Table 3: Accuracy, inter-day (3 days), and intra-day repeatability of ERM-BD150. 
 

ERM-BD150 (n=3) 

Trace elements Certified value [mg/kg] 
Observed value 

[mg/kg] 
Accuracy  

[%] 
Inter-day 
[%RSD] Intra-day [%RSD] 

Zn 44.8 ± 2.0 50.5 ± 3.7 112.7 4.79 4.39 

Cu 1.08 ± 0.06 0.92 ± 0.04 85.2 3.52 2.56 

Se 0.188 ± 0.014 0.188 ± 0.086 100 18.37 3.71 

Mn 0.289 ± 0.018 0.241 ± 0.042 83.4 9.94 9.48 

 
 

Table 4: Inter-day (3 days) and intra-day repeatability (n = 5) of human milk samples.. 
 

Trace elements Inter-day [%RSD] Intra-day [%RSD] 
Zn 5.66 5.03 

Cu 6.74 3.78 

Se 14.10 16.24 

Mn 18.10 12.09 

 
 

Table 5: Demographics of participants (n = 3) 
 

Demographic A B C 
Race Malay Malay Malay 

Body Mass Index 23.19 24.0 21.83 

BW Pre-pregnancy (kg) 55 51.5 56 

BW Pre-delivery (kg) 64 62 62 

BW Post-delivery (kg) 55 54 58 

No. of pregnancies 4 1 5 

No. of deliveries 2 1 5 

No. of miscarriages 2 0 0 

Birth method Caesarean Normal Normal 

Dietary intake RCBV RCBV RFCVFr 

Medical history No No Gestational diabetes, 
Asthma 

Supplement No Yes (Se, Mn, Zn, Cu) Yes (Zn, Fe) 

BW: Body Weight; R: Rice; C: Chicken; B: Beef; F: Fish; V: Vegetable; Fr: Fruit 
 
were collected from 12 months until 15 months postpartum 
at her convenience. At birth, the infant presented with high 
fever and jaundice 10 days after birth. He was fully 
breastfed only until the first six months and then continued 
with partial breastfeeding and solid food. There were no 

abnormalities in the growth and development of the infant 
except he was underweight and had mild eczema.  

Participant C was a 27-year old mother who delivered 
a male infant with a BW of 3.08 kilograms at 37 weeks of 
gestation. She was able to donate a total of 11 human milk 



 

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samples that were expressed at different times of the day in 
the 21st month postpartum only, at her convenience. The 
infant showed normal growth and development with no 
other health problems except for jaundice after birth. He 
was fully breastfed only until the first six months and then 
continued with partial breastfeeding and solid food.  

Table 6 showed the concentrations of Zn, Cu and Se 
were found to be the highest at one month postpartum 
compared to the later months in participant A. However, 
only Se and Cu gradually decreased wheras Zn showed 
some fluctuations. On the other hand, Mn exhibited no 
significant changes in concentration over the time period. 
The concentration of Zn and Cu also showed relatively 
higher concentration than Mn and Se. The correlations 
between trace elements in human milk also were examined 
with p < 0.001 was considered as significant. The 
Spearman’s correlation coefficients and p-value between 
essential trace elements in human milk of participant A 
were: Zn-Se (r =0.607, p = <0.001), Zn-Cu (r = 0.615, p = 
<0.001), Zn-Mn (0.471, p = <0.001), Cu-Se (r=0.735, p = 

<0.001), Mn-Se (r=0.467, p = <0.001). All trace elements 
showed significant positive correlations (r > 0.40, p < 
0.001) except for Cu-Mn.  

Table 7 showed the concentrations of Zn, Cu, Se and 
Mn in participant B at 12 to 15 months postpartum and 
participant C at 21 month postpartum. For participant B, 
the median Zn concentrations were slightly decreased from 
430.5 µg/L at 12 months to 353 µg/L at 15 months 
postpartum. For Se, the median concentration was 
increased from 7.6 µg/L at 12 months to 10.9 µg/L at 13 
months and remained around 10 µg/L at 14 and 15 months 
postpartum. There was a fluctuation in the levels of Cu 
during 12 to 15 months postpartum. The median 
concentration of Mn increased from 5.8 µg/L to 7.1 µg/L at 
12-13 months and later declined to 4.5 µg/L and 4.7 µg/l at 
14-15 months. For participant C, the median values of Zn 
and Mn were similar but Se and Cu seemed to be higher 
than participant B despite later lactation period. 

 

 
 

Table 6: The concentrations of trace elements in the human milk of participant A over a period of 6 months postpartum (µg/L). 
 

Trace 
Elements 

Mean/ 
Median 

Month postpartum 

1 2 3 4 5 6 
N = 15 N = 8 N = 10 N = 15 N = 6 N = 10 

 

Zn (µg/l) 

Mean±SD 2698±1010 1211±304 1480±355 1296±773 967±221 1254±541 

Median 
(Range) 

2640 
(1550-5870) 

1110 
(907-1810) 

1495 
(841-1960) 

1190 
(352-3780) 

886 
(716-1250) 

978 
(713-2350) 

 

Cu (µg/l) 

Mean±SD 403 ± 84 180 ± 20 164 ± 26 116 ± 46 93 ± 29 77 ± 18 

Median 
(Range) 

406 
(265-621) 

188 
(147-200) 

166 
(114-215) 

104 
(61-223) 

89 
(61-143) 

75 
(50-111) 

 

Se (µg/l) 

Mean±SD 24.8 ± 7.2 11.9 ± 4.7 14.8 ± 4.5 12.3 ± 6.8 9.8 ± 4.0 11.3 ± 4.1 

Median 
(Range) 

23.6 
(14.6-43.1) 

11.9 
(2.7-18.3) 

14.2 
(9.4-22.9) 

12.2 
(4.4-32.0) 

10.7 
(4.4-15.0) 

10.4 
(5.9-19.7) 

 

Mn (µg/l) 

Mean±SD 4.7 ± 1.2 3.6 ± 1.1 4.7 ± 1.8 4.7 ± 3.1 3.3 ± 0.5 5.1 ± 3.0 

Median 
(Range) 

4.4 
(3.5-7.6) 

3.6 
(2.2-5.9) 

4.3 
(1.8-7.7) 

3.8 
(2.6-14.8) 

3.2 
(2.9-4.0) 

3.5 
(2.7-10.5) 

 
 



 

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Table 7: The concentration of trace elements in human milk of participants B and C at 12 months postpartum and above (µg/L). 
 

Trace 
Elements 

Mean/ 
Median 

B C 

12 13 14 15 21 
n = 16 n = 4 n = 6 n = 4 n = 11 

 

Zn (µg/l) 
Mean±SD 450±117 1178±1557 373±126 390±86 606±532 

Median 
(Range) 

431 
(243-642) 

454 
(292-3510) 

354 
(203-585) 

353 
(338-518) 

450 
(179-2150) 

 

Cu (µg/l) 
Mean±SD 8.4±2.3 12.8±5.4 10.1±1.7 9.8±2.0 15.3±4.3 

Median 
(Range) 

7.6 
(5.1-14.0) 

10.9 
(8.9-20.7) 

10.3 
(7.9-12.6) 

10.2 
(7.4-11.5) 

16.4 
(7.2-21.7) 

 

Se (µg/l) 
Mean±SD 76.7±23.9 84.2±22.2 82.4±31.2 105.3±40.3 155±33 

Median 
(Range) 

72 
(47-136) 

84 
(57-111) 

72 
(62-144) 

106 
(56-154) 

166 
(83-200) 

 

Mn (µg/l) 
Mean±SD 5.7±2.3 7.1±1.7 20.8±34.7 4.6±0.4 3.5±1.3 

Median 
(Range) 

5.8 
(3.2-11.2) 

7.1 
(5.0-9.1) 

4.5 
(3.8-90.8) 

4.7 
(4.2-5.0) 

3.5 
(1.1-6.3) 

 

Discussion 

We report a method using acid digestion to measure 
total elements of Zn, Cu, Se and Mn concentration in 
human milk. Previous studies that reported acid digestion 
method have used heat application during sample 
preparation (Alves Peixoto et al., 2019; Jagodic et al., 
2020; Tahboub et al., 2021). Theoretically, by raising the 
temperature of the samples, the average kinetic energy will 
rise, thus increase the chances of acid and biological 
sample collisions and enhance trace element dissolution 
(Mohammed et al., 2017).  Our method did not require heat 
application since human milk is a biological matrix that 
contains proteins such as mucins, caseins and whey 
proteins that can be affected by high temperature. An 
increase in temperature has been reported to increase the 
amount of protein adsorbed onto solid surfaces resulting in 
a lower trace element content in the pasteurized milk 
solution possibly due to protein precipitation (da Costa et 
al., 2003; Rabe et al., 2011). Our method was simple and 
produced good results for the required validation 
parameters to determine four trace elements 
simultaneously in 1 mL of human milk for biological 
monitoring purpose. 

Homogenisation of milk samples before the digestion 
process is also a crucial step during sample preparation 
prior to the analysis. After being thawed, human milk is 
known to form two different layers, the fatty and aqueous 
layers. A study has reported that the concentration of 

iodine in the fatty layers was significantly different than 
those in the aqueous layers (Huynh et al., 2015). Therefore, 
sample homogenisation prior to mixing with nitric acid 
would ensure that all trace elements in the samples 
uniformly dispersed. Information about amounts of trace 
elements in two different layers of human milk have not 
been available to date. Further studies are needed to 
investigate the differences in the amount of trace elements 
in two distinct layers of human milk after thawing.  

All validation parameters measured in this study 
produced good measurements which were within the 
acceptable range specified by the guideline, indicating that 
this method performed satisfactorily. The employed 
method in this study had a lower LOQ value for all four 
trace elements compared to other studies (Alves Peixoto et 
al., 2019; Mohd Taufek et al., 2016). The fact that the 
LOQ values of Zn, Cu, Se and Mn obtained using this 
method were also significantly lower than the anticipated 
range concentrations in human milk reported in other 
countries showed that this method may be used to 
determine the levels of trace elements in human milk over 
a wide variety of populations. This method did not utilise 
any internal standard. It has been demonstrated that the 
implementation of internal standards that had the mass 
numbers almost the same as tested trace elements could 
enhance the precision of the methods used (Vanhaecke et 
al., 1992). Although still within the acceptable range, Mn 
and Se in human milk samples had slightly lower precision 
in the present study. Therefore, the precision of this 



 

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method may be further optimised by utilising internal 
standards in the future. 

For the purpose of method application in biological 
monitoring, we measured the concentration of Zn, Cu, Se 
and Mn in human milk collected at different postpartum 
period from three mothers as case studies. The median Zn 
concentration in participant A was high (2640 µg/L) at the 
first month postpartum and rapidly decreased (978 µg/L) at 
6 months postpartum. This pattern was found to be similar 
to a previous report that highlighted a rapid decline of zinc 
concentration in term breast milk from 3000 µg/L  at one 
month to 1200 µg/L  at six months postpartum (Hunt & 
Nielsen, 2009). We found the mean±SD of Zn 
concentration at 1 month was 2698 ± 1010 µg/L and 1480 
± 355 µg/L at 3 months postpartum. A study by Motoyama 
et al. (2021) involving 78 Japanese mothers reported 
higher mean Zn concentration at 1-month and 3-months 
postpartum with levels of 3000 ± 1300 µg/L and 1680 ± 
950 µg/L respectively. Similarly, another study by 
Dumrongwongsiri et al. (2015) also reported higher Zn 
levels with a range of 500-3200 µg/L at 4-6 months 
postpartum than the present case study (352-2350 µg/L). 
However, lower mean Zn values were found in term milk 
of 70 mothers in Spain of 1237.76 ± 949 µg/L at 1 month 
postpartum (Mandiá et al., 2021). In Table 7, the median 
levels of Zn for both participant B at month 12-15 and 
participant C at month 21 appeared to be relatively similar. 
Further monitoring on zinc concentrations in human milk 
over postpartum period may be needed to understand the 
relevance and factor behind its variation relative to the 
needs of infant’s growth and development. 

In our study, the median Cu values were 406 µg/L in 
the first month postpartum and 166 µg/L at 3 months, 
which were lower compared to the values reported by 
Motoyama et al. (2021) with values of 500  µg/L and 330 
µg/L respectively. However, the mean Cu concentration in 
the first month postpartum in our case study was 403 ± 84 
µg/L, which was higher than the reported value by Mandia 
et al. (2021) of 250.11 ± 163 µg/L. In Iran, a study also 
reported a higher mean Cu concentration of 1070 ± 1140 
µg/L in the breast milk of 160 lactating mothers at 6 
months postpartum (Sadeghi et al., 2020). A previous 
report also highlighted the decline of mean Cu levels from 
250 µg/L in the first six months to 100-200 µg/L in seven 
to 12 months postpartum (Hunt & Nielsen, 2009). 
Currently, optimal levels of Cu in human milk have not yet 
been determined at different lactation stages. 

The median Se concentration found in the current 
study was 23.6 µg/L in the first month then decreased to 
14.15 µg/L at 3 months and 10.41 µg/L at 6 months 
postpartum. Another study also found similar level of Se at 
1-month which was 22 (17-29) µg/L but higher level at 3 
months postpartum, of 21 (16-25) µg/L (Motoyama et al., 
2021). However, a previous study by Mandiá et al. (2021) 
reported lower mean Se values of 8.87 µg/L in the mature 
milk compared to the current study which was 24.82 µg/L. 

In a previous study involving 470 lactating women from 
Slovenia, the mean Se levels found in the human milk at 6 
to 8 weeks after delivery was 12.6 µg/L (Snoj Tratnik et 
al., 2019). Based on the findings by Han et al. (2019), the 
adequate intake of Se for 0-3 months Chinese infants was 
15.29 µg/day, which is almost the same with the levels 
reported in the current study (14.15 µg/L at 3 month). It is 
important to monitor selenium status in infants receiving 
different amounts of selenium from human milk to prevent 
deficiency or toxicity. 

We also observed median Mn concentration that were 
relatively stable with 4.44 µg/L in the first month 
postpartum, 4.29 µg/L at three months and 3.54 µg/L at 6 
months. These results were lower than those reported by a 
previous study by Motoyama et al. (2021) which found 
median Mn levels of 8 µg/L in the first month and 7 µg/L 
at 3 months postpartum. Similarly, Li et al. (2016) also 
reported higher Mn levels of 9.33 to 11.53 µg/L in the first 
2 months and then declined at 4 to 6 months to a mean 
value of 7.69 µg/L. Our study suggests that Mn 
concentrations in human milk are relatively stable over the 
postpartum period. Human milk was reported to provide an 
adequate amount of Mn to prevent deficiency at about 3–
10 µg/L (Horning et al., 2015). This study observed that 
trace elements concentration in human milk varied over 
postpartum period. The variations in the trace elements 
levels might be due to several factors such as lactation 
stages, geographical regions, dietary intakes or trace 
element supplements that were taken by some of the 
participants. Consistent with the previous reports (Li et al., 
2016; Motoyama et al., 2021), we found positive 
significant correlations for most of the elements (r > 0.40, 
p < 0.001) except for Cu-Mn. 

The limitation of our study includes the small 
population size due to challenges in recruiting participants. 
However, the milk samples provided by these participants 
were sufficient to validate the method and its application in 
biomonitoring of trace elements in human milk. Future 
studies with large sample size would be able to produce a 
thorough investigation on the factors that may influence 
the trace element concentrations in human milk. This study 
did not seek to evaluate the association of factors affecting 
trace elements in human milk.  However, the findings from 
this study are important since this is the first study reported 
in Malaysia using a validated acid digestion method that is 
simple, accurate and sensitive to measure Zn, Cu, Se, and 
Mn. It is applicable and relevant for clinical and public 
health settings by using minimal amount of sample for 
biomonitoring to detect potential deficiency or toxicity 
relative to the needs of infants. Previous studies reporting 
data of Malaysian population have examined the 
concentration of a single trace element (Pb and Fe) in 
human milk in the past few decades (Huat et al., 1983; Loh 
& Sinnathuray, 1971). New data can be produced for 
Malaysian population using a simple and robust method 
reported in the present study. 



 

Page 137  

 

Conclusion 

Acid digestion method was simple, sensitive, accurate, 
precise, and robust to quantify zinc, copper, manganese 
and selenium simultaneously in human milk by ICP-MS. 
Human milk analysis is challenging due to high variability 
of trace elements contents between individuals and across 
postpartum period. There were significant correlations 
between concentration of Zn-Se, Zn-Cu, Zn-Mn, Cu-Se 
and Mn-Se.  Future studies may utilise this method to 
determine reference range of trace elements concentration 
in human milk in larger study population.  

Author Contribution 

N.H. Mohd-Taufek, A.S. Mohmad Sabere & J. Bidai 
conceived and designed the experiment, conducted sample 
and data collection, data analysis, N.B. Amran, U.S. 
Mohamad Jamahari and A.R. Fata Nahas analysed the 
sample and data, all authors wrote the manuscript. 

Acknowledgements 

The authors would like to thank Institute of 
Oceanography and Environment (INOS), University 
Malaysia Terengganu for their cooperation and assistance 
with method development and validation.  

Data Availability 
The datasets analysed in the current study are 

available from the corresponding author upon reasonable 
request. 

Competing Interest 

N.H. Mohd-Taufek, A.S. Mohmad Sabere, J.A. 
Bidai, N.B. Amran, U.S. Mohamad Jamahari and A.R. 
Fata Nahas declare that there is no competing interest in 
this research. 

Funding 
This work was supported by Research Management 

Centre Grant 2020 (RMCG20-046-0046) of 
International Islamic University Malaysia. 

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