Background. Eucalyptus species have been used for the remediation of mine tailings dams in Zimbabwe. However, a traditional medicinal remedy (TMR) for the treatment of mild acute respiratory infections, such as common cold and flu includes the use of Eucalyptus leaves.

Objectives. The aim of the present study was to determine total concentrations of selected potentially toxic trace elements (PTEs) in gold mine tailings and leaves of Eucalyptus grandis and to identify extractable fractions of PTEs in leaves via boiling for 10 minutes in water, which is the process used to create TMRs to treat common cold and flu.

Methods. Mine tailings and leaves of E. grandis were randomly collected at a gold mine tailings dam between April and June 2019. They were digested for laboratory analysis using standard analytical methods. Leaves were boiled in water for 10 minutes to prepare the TMR as practiced by the local community. The concentrations of PTEs were determined spectrometrically. Significant differences between PTEs in young and mature leaves were determined by analysis of variance.

Results. Mine tailings were acidic (pH 4.52±0.62) with very low content of organic matter (0.02%) and contained PTEs in increasing concentrations of cadmium (Cd) < nickel (Ni) < lead (Pb) < chromium (Cr) < copper (Cu) < zinc (Zn) (n = 27). Mature leaves of E. grandis had higher concentrations than young leaves for Cr, Pb and Zn (p <0.05) which were lower than permissible limits in medicinal plants. Overall, boiling leaves in water for 10 minutes resulted in low extraction of PTEs (< 20%).

Participant Consent. Obtained

Conclusions. Concentrations of PTEs in leaves and leaf extracts of E. grandis were very low. However, TMRs should not be prepared from medicinal plants growing on metalliferous environments, such as mine tailings dams, due to the presence of cumulative toxins such as Cd and Pb. Further studies are needed to investigate the effect of various boiling times and should include arsenic in the studied PTEs.

Competing Interests. The authors declare no competing interests for this study.

eucalyptus, health risk, medicinal plants, mine tailings, phytoremediation, trace element, traditional medicinal remedy

The use of medicinal plants is an ancient medical practice dating back to nomadic life ways in hunter-gatherer communities.1 Despite developments in science and biotechnology, plants remain a key source of traditional medicinal remedies (TMRs) for various ailments across socio-cultural settings.2 However, plants can accumulate potentially toxic trace elements (PTEs) from the environment.3 Many plants, including eucalyptus, are used to prepare TMRs for the treatment of common cold and flu.4,5 The leaves of eucalyptus have antibacterial, antifungal, analgesic and anti-inflammatory effects, along with antioxidative properties.6 

Eucalyptus trees have a low to moderate rate of PTE accumulation in above-ground parts.7 The species gained attention for in situ remediation of mine sites in Zimbabwe. Revegetated mine tailings are exploited for non-timber products such as honey, fruits and herbs. Earlier studies showed that eucalyptus trees can accumulate PTEs from contaminated sites into their leaves.8,9Therefore, the consumption of TMRs made from leaves of eucalyptus growing in trace element-contaminated soil could be an important route of human exposure to PTEs. Potentially toxic trace elements (e. g. cadmium (Cd), chromium (Cr), copper (Cu), lead (Pb)) are harmful to human health.10,11 

In the present study, the total concentrations of PTEs in gold mine tailings and leaves (young and mature) of Eucalyptus grandis growing on an inactive revegetated gold mine tailings dam (GMTD) were determined. The extractable fraction of PTEs after boiling leaves in water for 10 minutes (the process by which TMRs for the treatment of common cold and flu are made) was also determined.

The study was performed at an inactive GMTD in northern Zimbabwe from April to June 2019. The tailings dam was revegetated with eucalyptus trees. Nine quadrants were randomly established on the dam's surface. Three sub-samples were collected at the surface from each quadrant and separately put into sealable polythene bags. Laboratory samples were prepared as described by Darus et al.12 Tailings were sieved (<2 mm), oven-dried (105°C, 24 hours), ground into powder and digested (0.500 g) in an acid mixture (37% hydrochloric acid: 65% nitric acid: water; 1: 1: 1 vol/vol; 3 ml) at 95°C until white fumes appeared. The digests (n = 27) were cooled, filtered (Whatman No. 42) and diluted to volume (50 ml) with deionized water. Separate oven-dried (<2 mm) samples (n = 27) were used for the determination of organic matter (OM) content and pH (calcium chloride).13,14 

To determine the mass of leaves used, volume of water, and boiling time to prepare the TMR, local households (n = 20) familiar with the practice were purposively selected and consulted about typical practices. The selected households were educated about the purpose of the study, and gave informed consent for the results to be published. It was determined that leaves (9.56±1.34 g) are typically boiled in water (3004.35±79.65 ml) for 10.43±2.42 minutes. Households either added the leaves to water and brought the water to a boil (73.9%) or added the leaves to boiling water (26.1%). Five (5) E. grandis trees, about 4 m high, (16%) were randomly selected from the GMTD to sample leaves. They were typical trees whose leaves are used by the local community to make the TMR for the treatment of common cold and flu. Young and mature leaves were separately harvested using a stainless-steel scalpel and gloved hands above 1 m height off the ground. Three composites (young, mature) were separately made from the leaves from a single tree. Visibly diseased and pest-affected leaves were not sampled. Collected samples were kept in paper envelopes and preserved in polythene bags. At the laboratory, they were washed with deionized water. From each composite (young, mature leaves), duplicate sub-samples were made for the determination of total PTEs and hot water extractable concentrations of PTEs. For the determination of total PTE concentrations (mg/kg), sub-samples (9.56 g) were oven dried (90°C; 12 hours). A dried sample (0.500 g) was digested in 65% nitric acid and 30% hydrogen peroxide (5:1; vol/vol) at 150°C over a hot plate in a fume hood.15 Deionized water (10 ml) was added to the cooled digests which were filtered (Whatman No. 42) and diluted to 20 ml with deionized water to give 30 leaf sample solutions.

Abbreviations

Abbreviations
GMTD

Gold mine tailings dam

OM

Organic matter

PTEs

Potentially toxic trace elements

TMRs

Traditional medicinal remedies

To determine the concentrations of PTEs extracted from leaves in hot aqueous solution (mg/kg), fresh harvested young or mature leaves (9.56 g) were added to 300 ml deionized water and boiled on a hot plate (at 500°C) for 10 minutes. The solutions (n = 30) were separately concentrated by evaporation to about 60 ml, cooled, filtered and then diluted to 100 ml with deionized water. The concentration was expressed as a percentage of the total in the leaf. Tailings, leaf digests and hot water extracts were analyzed for Cd, Cr, Cu, nickel (Ni), Pb and zinc (Zn) using inductively coupled plasma - optical emission spectroscopy (Thermo Scientific iCAP 6500; England). The estimated quantity of PTE taken in by consuming 300 ml of the TMR was taken as the hot water-extractable concentration obtained by boiling (9.56 g in 300 ml water) expressed in μg/day assuming the volume was taken once per day.

Significant differences between the concentration of a PTE in mature and young leaves for a given tree were investigated using independent t-test. All analyses were performed using the Statistical Package for the Social Sciences (SPSS) version 23, at a 95% level of confidence and considered significantly different at p <0.05.

Table 1 shows the variation of measured parameters for gold mine tailings. Results indicate that the tailings were acidic (pH 4.52±0.62) with very low OM content (0.02%), and contained Cd, Cr, Cu, Ni, Pb and Zn. Overall, the total concentrations of PTEs in mine tailings appeared to increase in the order: Cd < Ni < Pb < Cr < Cu < Zn.

Total and extractable concentrations of potentially toxic trace elements in leaves of E. grandis

The total concentrations of PTEs in young and mature leaves of E. grandis growing on a revegetated GMTD are presented in Table 2. Results suggest that E. grandis accumulated Cd, Cr, Cu, Ni, Pb and Zn into its leaves. Further, the overall (n = 15) total concentrations of Cr, Pb and Zn were higher in mature leaves than in young leaves (p <0.05). Total concentrations of PTEs appeared to increase in young leaves in the order: Cd < Pb < Cr < Ni < Cu < Zn and in mature leaves: Cd < Ni < Cr < Pb < Cu < Zn. Values were lower than the Food and Agriculture Organization of the United Nations/World Health Organization (FAO/WHO) permissible limits in medicinal plants described for different countries (Table 2).

The proportions (%) of PTEs extracted by boiling leaves of E. grandis in water for 10 minutes are shown in Table 2. The results show that Cd, Cr and Pb were not extracted (0%) from young leaves. Nickel was the only fraction of PTE extracted from leaves (n = 15) that was not significantly different between young and mature leaves (p >0.05). Overall, extraction of PTEs in young leaves increased in the order: Cd = Cr = Pb (0%) < Zn < Cu < Ni, ranging from 0 to 11.582% and Cd < Cu < Pb < Zn < Cr < Ni for mature leaves (range 0 to 17.92%). For mature leaves, Cu, Pb and Zn were below 10%, while Cr and Ni were greater than 10 but less than 20%.

Table 3 shows the amount of PTEs in the prepared TMR made by boiling 9.56 g of E. grandis fresh leaves in 300 ml of water for 10 minutes. The results indicate that TMR made from young leaves did not contain Cr, Cd and Pb in detectable amounts, but had a higher concentration of Cu than TMR made from mature leaves. The TMR prepared from mature leaves contained more Cr, Pb and Zn than TMR prepared from young leaves (p <0.05).

Our results are consistent with previous findings that gold mine tailings are usually acidic, have low OM and are laden with PTEs.17,18 Low pH and OM generally favor the release of PTEs by soil, such as tailings, and eventual uptake by plants.19 Differences in the mineralogy of mined ore, extraction and natural biogeochemical processes may explain the variability of the concentrations of PTEs in tailings.20 While Cr, Cu and Zn are essential elements, Cd and Pb are non-essential.21 Results show very low concentrations of PTEs in tailings compared to similar studies. Revegetation of the GMTD, mineral ore processing and tailings management could explain their low concentrations in the present study.

Concentrations of potentially toxic trace elements in leaves of E. grandis growing on a gold mine tailings dam

To the best of the authors' knowledge and available literature, there have been no studies of the use of E. grandis growing on tailings dams for medicinal purposes. Nevertheless, the species is widely used for medicinal purposes. The findings of the present study are consistent with several previous reports that eucalyptus species accumulate some PTEs in leaves.7,22,23 Children who consume these TMRs may be at higher risk than adults, especially in the winter season when the common cold and flu occur more frequently. The physiology of the plant and PTE characteristics may explain the greater accumulation of Cr, Pb, and Zn in mature leaves compared to young leaves. In a study of heavy metal content of tea leaves in Puan County, China, by Zhang et al., Cr, Pb and Zn concentrations were higher in mature leaves compared to young leaves.24 However, Doganlar et al. reported higher concentrations for Cu, Pb and Zn in E. camaldulensis sampled from urban parks and streets of Adana city in Turkey.22 Variations in concentrations could be explained by the total PTE in the tailings, leaves and tailings characteristics such as pH and OM, which influence their bioavailability. The results suggest no potential safety risk in using the leaves of E. grandis, as concentrations were much lower than maximum allowable limits in medicinal plants.

Extractable fraction of total potentially toxic trace elements from leaves of E. grandis

The concentrations of PTEs in hot water extracts prepared from medicinal plants are affected by the OM content that can chelate them, solubility of each PTE and the quality of the water used.25 Furthermore, the extraction of PTEs from leaves appeared to depend on their total concentrations and leaf maturity. The non-essential trace elements, Cd and Pb, were poorly extractable compared to Ni and Cr. This could be an important property in the use of medicinal formulations requiring hot water extraction. Assessments of the safety of medicinal plants should mimic how they are used in practice and avoid reporting total concentrations where water extracts are used, as such reports give overestimated PTE intake values.

The species E. grandis extracts PTEs from the tailings into its leaves in very small quantities, resulting in low hot water extraction coefficients. Generally, mature leaves are used for the preparation of the TMR for the treatment of the common cold and flu. The presence of Pb in the aqueous solution is cause for concern, especially for children who frequently get the common cold and flu and use TMRs. Findings from the present study suggest that the intake of TMR prepared from leaves of E. grandis presented no potential health risk due to Cd and Pb. Furthermore, the TMR is not consumed as part of a diet but a remedy: that is, not consumed daily, but only as needed. Trace elements (Cr, Cu and Zn) are essential for human metabolism. Their concentrations were much lower than dietary daily requirements.26 Although the concentrations of PTEs were very low in the present study, they may be cumulative over time. Our results are generalizable to many low-income areas, especially in Africa, where mine sites are revegetated with eucalyptus trees which are eventually exploited for non-timber products.

The tailings at the studied GMTD contained PTEs which accumulated in leaves of E. grandis in trace amounts. Boiling the leaves in water resulted in low extraction of PTEs. Medicinal plants may contribute to the body's requirement of essential elements such as Cr, Cu and Zn. However, the use of TMRs made from E. grandis growing on metalliferous tailings dams may constitute a health risk due to the presence of cumulative toxic elements such as Pb. Formulations of TMRs should not be prepared from any parts of medicinal plants harvested from metalliferous habitats such as mine tailings dams.

This study was funded as part of employment.

1.
Salali
GD
,
Chaudhary
N
,
Thompson
J
,
Grace
OM
,
van der Burgt
XM
,
Dyble
M
,
Page
AE
,
Smith
D
,
Lewis
J
,
Mace
R
,
Vinicius
L
,
Migliano
AB.
Knowledge-sharing networks in hunter-gatherers and the evolution of cumulative culture
.
Curr Biol [Internet]
.
2016
Sep
26
[cited 2019 Nov 6]
;
26
(
18
):
2516
21
.
Available from: https://doi.org/10.1016/j.cub.2016.07.015
Google Scholar
Crossref
Search ADS
 
2.
Mousa
HA.
Prevention and treatment of influenza, influenza-like illness, and common cold by herbal, complementary, and natural therapies
.
J Evid Based Complementary Altern Med [Internet]
.
2017
Jan
[cited 2019 Nov 6]
;
22
(
1
):
166
74
.
Available from: https://doi.org/10.1177/2156587216641831
Google Scholar
Crossref
Search ADS
 
3.
Muthusaravanan
S
,
Sivarajasekar
N
,
Vivek
JS
,
Paramasivan
T
,
Naushad
M
,
Prakashmaran
J
,
Gayathri
V
,
Al-Dualj
OK.
Phytoremediation of heavy metals: mechanisms, methods and enhancements
.
Env Chem Lett [Internet]
.
2018
Dec
[cited 2019 Nov 6]
;
16
(
4
):
1339
59
.
Available from: https://doi.org/10.1007/s10311-018-0762-3 Subscription required to view
.
Google Scholar
Crossref
Search ADS
 
4.
Silva
PS
,
Francisconi
LS
,
Goncalves
RD.
Evaluation of major and trace elements in medicinal plants
.
J Braz Chem Soc [Internet]
.
2016
[cited 2019 Nov 6]
;
27
(
12
):
2273
89
.
Available from: http://dx.doi.org/10.5935/0103-5053.20160123
Google Scholar
 
5.
Thielmann
A
,
Gerasimovska-Kitanovska
B
,
Buczkowski
K
,
Koskela
TH
,
Mevsim
V
,
Czachowski
S
,
Petrazzuoli
F
,
Petek-Ster
M
,
Lingner
H
,
Hoffman
RD
,
Tekiner
S
,
Chambe
J
,
Edirne
T
,
Hoffmann
K
,
Pirrotta
E
,
Uludag
A
,
Yikilkan
H
,
Pestic
SK
,
Zielinski
A
,
Fernandez
CG
,
Weltermann
B.
Self-care for common colds by primary care patients: a European multicenter survey on the prevalence and patterns of practices—the COCO study
.
Evidence-Based Complementary Altern Med [Internet]
.
2016
[cited 2019 Nov 6]
;
2016
:
Article 6949202 [
9
p.]. Available from: http://dx.doi.org/10.1155/2016/6949202
Google Scholar
 
6.
Shaban
NS
,
Abdou
KA
,
Hassan
NE.
Impact of toxic heavy metals and pesticide residues in herbal products
.
Beni-Suef Univ J Basic Appl Sci [Internet]
.
2016
Mar
[cited 2019 Nov 6]
;
5
(
1
):
102
6
.
Available from: https://doi.org/10.1016/j.bjbas.2015.10.001
Google Scholar
Crossref
Search ADS
 
7.
Madejon
P
,
Maranon
T
,
Navarro-Fernandez
CM
,
Dominguez
MT
,
Alegre
JM
,
Robinson
B
,
Murillo
JM.
Potential of Eucalyptus camaldulensis for phytostabilization and biomonitoring of trace-element contaminated soils
.
PLoS One [Internet]
.
2017
Jun
30
[cited 2019 Nov 6]
;
12
(
6
):
Article e0180240 [
22
p.]. Available from: https://doi.org/10.1371/journal.pone.0180240
Google Scholar
 
8.
Nirola
R
,
Megharaj
M
,
Palanisami
T
,
Aryal
R
,
Venkateswarlu
K
,
Naidu
R.
Evaluation of metal uptake factors of native trees colonizing an abandoned copper mine – a quest for phytostabilization
.
J Sustain Min [Internet]
.
2015
[cited 2019 Nov 6]
;
14
(
3
):
115
23
.
Available from: https://doi.org/10.1016/j.jsm.2015.11.001
Google Scholar
Crossref
Search ADS
 
9.
Ahmad
F
,
Ahmad
N
,
Masood
KR
,
Hussain
M
,
Malik
MF
,
Qayyum
A.
Phytoremediation of arsenic-contaminated soils by Eucalyptus camaldulensis, Terminalia arjuna and Salix tetrasperma
.
J Appl Bot Food Qual
.
2018
;
91
:
8
13
.
Google Scholar
 
10.
Tchounwou
PB
,
Yedjou
CG
,
Patlolla
AK
,
Sutton
DJ.
Heavy metal toxicity and the environment
.
Exp Suppl
.
2012
;
101
:
133
64
.
Google Scholar
PubMed
 
11.
Jaishankar
M
,
Tseten
T
,
Anbalagan
N
,
Mathew
BB
,
Beeregowda
KN.
Toxicity, mechanism and health effects of some heavy metals
.
Interdiscip Toxicol [Internet]
.
2014
Jun
[cited 2019 Nov 6]
;
7
(
2
):
60
72
.
Available from: https://doi.org/10.2478/intox-2014-0009
Google Scholar
Crossref
Search ADS
 
12.
Darus
FM
,
Nasir
RA
,
Sumari
SM
,
Ismail
ZS
,
Omar
NA.
Heavy metals composition of indoor dust in nursery schools building
.
Proceedia Soc Behav Sci [Internet]
.
2012
[cited 2019 Nov 6]
;
38
:
169
75
.
Available from: https://doi.org/10.1016/j.sbspro.2012.03.337
Google Scholar
Crossref
Search ADS
 
13.
Sutherland
RA.
Loss-on-ignition estimates of organic matter and relationships to organic carbon in fluvial bed sediments
.
Hydrobiol [Internet]
.
1998
Dec
[cited 2019 Nov 6]
;
389
(
1–3
):
153
67
.
Available from: https://doi.org/10.1023/A:1003570219018 Subscription required to view
.
Google Scholar
Crossref
Search ADS
 
14.
Miller
RO
,
Kissel
DE
Comparison of soil pH methods on soils of North America
.
Soil Sci Soc Am J
.
2010
Jan
;
74
(
1
):
310
6
.
Google Scholar
Crossref
Search ADS
 
15.
Junior
AF
,
Matos
RA
,
Andrade
EM
,
dos Santos
WN
,
Magalhaes
HI
,
Costa
FN
,
Korn
MG.
Multielement determination of macro and micro contents in medicinal plants and phytomedicines from Brazil by ICP OES
.
J Braz Chem Soc [Internet]
.
2017
Feb
[cited 2019 Nov 6]
;
28
(
2
):
376
84
.
Available from: http://dx.doi.org/10.5935/0103-5053.20160187
Google Scholar
 
16.
Maobe
MA
,
Gatebe
E
,
Gitu
L
,
Rotich
H.
Profile of heavy metals in selected medicinal plants used for the treatment of diabetes, malaria and pneumonia in Kisii region, southwest Kenya
.
Glob J Pharmacol
.
2012
;
6
(
3
):
245
51
.
Google Scholar
 
17.
Ayangbenro
AS
,
Olanrewaju
OS
,
Babalola
OO.
Sulfate-reducing bacteria as an effective tool for sustainable acid mine bioremediation
.
Front Microbiol [Internet]
.
2018
Aug
22
[cited 2019 Nov 6]
;
9
:
Article 1986 [
10
p.]. Available from: https://doi.org/10.3389/fmicb.2018.01986
Google Scholar
Crossref
Search ADS
 
18.
Festin
ES
,
Tigabu
M
,
Chileshe
MN
,
Syampungani
S
,
Oden
PC.
Progresses in restoration of post-mining landscape in Africa
.
J For Res [Internet]
.
2019
[cited 2019 Nov 6]
;
30
(
2
):
381
96
.
Available from: https://doi.org/10.1007/s11676-018-0621-x
Google Scholar
Crossref
Search ADS
 
19.
Rieuwerts
JS
,
Thornton
I
,
Farago
ME
,
Ashmore
MR.
Factors influencing metal bioavailability in soils: preliminary investigations for the development of a critical loads approach for metals
.
Chem Speciat Bioavailab [Internet]
.
1998
[cited 2019 Nov 6]
;
10
(
2
):
61
75
.
Available from: https://doi.org/10.3184/095422998782775835
Google Scholar
Crossref
Search ADS
 
20.
Mohapatra
DP
,
Kirpalani
DM
Process effluents and mine tailings: sources, effects and management and role of nanotechnology
.
Nanotechnol Environ Eng [Internet]
.
2017
Dec
[cited 2019 Nov 6]
;
2
(
1
):
Article 1 [
12
p.]. Available from: https://doi.org/10.1007/s41204-016-0011-6
Google Scholar
Crossref
Search ADS
 
21.
Emamverdian
A
,
Ding
Y
,
Mokhberdoran
F
,
Xie
Y.
Heavy metal stress and some mechanisms of plant defense response
.
Sci World J [Internet]
.
2015
[cited 2019 Nov 6]
;
2015
:
Article 756120 [
18
p.]. Available from: http://dx.doi.org/10.1155/2015/756120
Google Scholar
 
22.
Doganlar
ZB
,
Doganlar
O
,
Erdogan
S
,
Onal
Y.
Heavy metal pollution and physiological changes in the leaves of some shrub, palm and tree species in urban areas of Adana, Turkey
.
Chem Speciat Bioavailab [Internet]
.
2012
[cited 2019 Nov 6]
;
24
(
2
):
65
78
.
Available from: https://doi.org/10.3184/095422912X13338055043100
Google Scholar
Crossref
Search ADS
 
23.
Xie
Q
,
Li
Z
,
Yang
L
,
Lv
J
,
Jobe
TO
,
Wang
Q.
A newly identified passive hyperaccumulator Eucalyptus grandis × E. urophylla under manganese stress
.
PLoS One [Internet]
.
2015
Sep
1
[cited 2019 Nov 6]
;
10
(
9
):
Article e0136606 [
22
p.]. Available from: https://doi.org/10.1371/journal.pone.0136606
Google Scholar
 
24.
Zhang
J
,
Yang
R
,
Chen
R
,
Peng
Y
,
Wen
X
,
Gao
L.
Accumulation of heavy metals in tea leaves and potential health risk assessment: a case study from Puan County, Guizhou Province, China
.
Int J Env Res Public Health [Internet]
.
2018
[cited 2019 Nov 6]
;
15
(
1
):
Article 133 [
22
p.]. Available from: https://doi.org/10.3390/ijerph15010133
Google Scholar
 
25.
Randelovic
SS
,
Kostic
DA
,
Zarubica
AR
,
Mitic
SS
,
Mitic
MN.
The correlation of metal content in medicinal plants and their water extracts
.
Hem Ind
.
2013
;
67
(
4
):
585
91
.
Google Scholar
Crossref
Search ADS
 
26.
Ross
AC
,
Taylor
CL
,
Yaktine
AL
,
Del Valle
HB
,
editors
.
Dietary reference intakes for calcium and vitamin D
.
Washington, DC
:
The National Academies Press
;
2011
.
11140
p
.
Google Scholar
PubMed
 

Copyright Policy

This is an Open Access article distributed in accordance with Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/).

© Pure Earth
2019