i
PHYSICOCHEMICAL PROFILING AND DETECTION OF PHENOLIC CONSTITUENTS WITH ANTIOXIDANT AND ANTIBACTERIAL
ACTIVITIES OF Myristica fragrans HOUTT.
by
MARDIATY IRYANI BINTI ABDULLAH
Thesis submitted in fulfillment of the requirements for the degree of Master of Science
July 2009
ii
To my late grandmother, Hajah Siti Rafeah bt Haji Ahmad
ا 234567
iii
Nutmeg in literatureNutmeg in literatureNutmeg in literatureNutmeg in literature
I had a little nut tree,
Nothing would it bear,
But a silver nutmeg,
And a golden pear.
The King of Spain’s daughter,
Came and visit me,
And all for the sake,
Of my little nut tree.
I skipped over ocean,
I danced over sea,
And all the birds in the air,
Couldn’t catch me.
iv
Bismillahirrahmanirrahim
(In the name of Allah, The Most Gracious, Most Merciful)
I am indebted to all of generous individuals for their efforts, encouragement and
kindness. I acknowledge with gratitude the assistance received from the following:
Associate Professor Dr Shaida Fariza Binti Sulaiman, my supervisor for continuous
support in the research project and for her interest and comments throughout the
project. Without her encouragement and valuable guidance, I could not have
finished this dissertation. Her passionate is my inspiration.
I am grateful to Associate Professor Dr Noryati Binti Ismail, my co - supervisor,
lecturer of School of Industrial Technology, for her generous help and assist me
whenever I needed help.
I would like to thank both Deans and staff of the School of Biological Sciences and
Institutes of Graduate Studies for giving me the opportunity to be part of the family.
I am so grateful for their kindness during the preparation of this dissertation.
Not forgotten, Mr. Shahabudin, from the Soil Science and Ecology Laboratory, who
create a safety place of work during the mineral analysis. I am also grateful to Mr.
Mutalib and Mrs. Nurul from the Microbiology Laboratory. Thanks also go to Mr.
Joseph Hemandry, who was keen to help and assist me during my working section in
the Undergraduate Laboratory, School of Industrial Technology. I would like to
v
extend my appreciation to Kak Khuzma from School of Industrial Technology for
assisting with the handling of the ultraviolet spectrometer and nutritional analysis.
I should like to express my special appreciation to Kak Loh, Kak Bing, Kak Marissa,
Kak Rozi and June, my generous senior of Phytochemical Laboratory. Also thanks
for their kindhearted that made the atmosphere in the workplace more joyful and for
the meaningful guidance and support. To my colleague, Eng Meng, Adlin, Ernawita
and Suhail you really deserve a warm appreciation from me. Allow me to say ‘thank
you’ for your courage, commenting and offering help whenever I needed help. Your
unfailing support had kept me on track to continue my works. I am so glad to be
with and working with you guys.
This thesis would not have been possible without the valuable courage given by my
parent, Tuan Haji Abdullah Bin Haji Hashim and Puan Hajah Zainab Binti Haji
Yusuf. I want to say ‘thank you’ for your continuous prayers and unconditional
supports and faith on me. Both of them who are always supporting me to come this
far and make me strong to face the future. Without them, it might not be possible for
me to come up to this level. To my sister and brother, you rock!!!.
I also acknowledge with gratitude the financial assistance, National Science
Fellowship (NSF) received from Ministry of Science, Technology and Innovation,
Malaysia.
vi
Finally, and by no means least, I also dedicate my thesis to all those who formally
and informally gave me benefit of their interest, knowledge, views and experiences.
Without all of them, I won’t be able to finish up my thesis.
Mardiaty Iryani Binti Abdullah
vii
TABLE OF CONTENT
Page
TABLE OF CONTENTS vii
LIST OF TABLES xiii
LIST OF FIGURES xv
LIST OF PLATES xviii
ABSTRAK xix
ABSTRACT xxi
CHAPTER 1 INTRODUCTION
1.1 Myristica fragrans Houtt. 1
1.1.1 Morphological description 1
1.1.2 Therapeutic values 2
1.1.3 Scientific biological and pharmacological studies 3
1.1.4 Phytochemical content 5
1.2 Nutritional aspect 6
1.3 Antioxidant activity 9
1.3.1 Oxidative damage and diseases 9
1.3.2 Phenolic compounds as natural antioxidant 10
1.4 Antibacterial activity 13
1.4.1 Diseases and antibacterial agents
1.4.2 Roles of phenolic compounds in treating bacterial diseases
13
14
1.5 Problem statement 17
1.6 Objectives of study 18
viii
CHAPTER 2 LITERATURE REVIEW
2.1 Physicochemical profiling of M. fragrans 19
2.2 Phenolic compounds of M. fragrans 20
2.3 Antioxidant properties of M. fragrans 22
2.4 Antibacterial properties of M. fragrans 24
CHAPTER 3 MATERIALS AND METHODS
3.1 Plant materials 26
3.2 Physicochemical study 26
3.2.1 Physical analysis 26
3.2.1.1 Color analysis 26
3.2.2 Chemical analysis 27
3.2.2.1 Proximate analysis 27
3.2.2.1.1 Moisture 27
3.2.2.1.2 Fat 27
3.2.2.1.3 Total ash 28
3.2.2.1.4 Crude fiber 29
3.2.2.1.5 Protein 30
3.2.2.1.6 Available carbohydrate 31
3.3.2.2 Mineral analysis 31
3.3 Extraction procedure 33
3.3.1 Acid hydrolysis 34
3.4 Antioxidant study 34
3.4.1 Folin - Ciocalteu assay 34
3.4.2 1, 1 - diphenyl - 2 - picryl hydrazyl (DPPH) radical
scavenging assay
35
3.4.3 Correlation between total phenolic content and antioxidant
activity
37
3.4.4 Identification of isolated compounds 38
3.4.4.1 Fractionation of crude extracts 38
3.4.4.1.1 Thin Layer Chromatography 38
ix
3.4.4.1.2 Paper Chromatography 39
3.4.4.1.3 Column Chromatography 40
3.4.4.1.4 Purification of fraction 40
3.4.4.2 Identification of isolated compounds 41
3.4.4.2.1 Compounds isolated from leaf extract 41
3.4.4.2.2 Compound isolated from pericarp extract 41
3.4.4.2.3 Spectrum analysis 42
3.4.4.2.4 Sugar analysis 44
3.4.4.2.4.1 Sample preparation 44
3.4.4.2.4.2 Paper Chromatography 44
3.5 Antibacterial study 45
3.5.1 Bacteria strains and culture condition 45
3.5.2 Screening test for antibacterial activity 46
3.5.2.1 Preparation of agar 46
3.5.2.2 Preparation of inoculum 47
3.5.2.3 Preparation of extracts 47
3.5.2.4 Diffusion sensitivity test 47
3.5.3 Minimum inhibitory concentration (MIC) assay 48
3.5.4 Minimum bactericidal concentration (MBC) assay 51
3.5.5 Identification of isolated compound 51
3.5.5.1 Partition procedure of 70% acetone extract of the seed 51
3.5.5.2 Fractionations of partition of seed extract 52
3.5.5.2.1 Chromatographic analysis 52
3.5.5.2.2 Column chromatography 52
3.5.5.2.3 Antibacterial activity of fractions on TLC plate 53
3.6 Comparative antioxidant and antibacterial evaluation of the active
phenolic fractions
54
3.7 Statistical analysis 54
x
CHAPTER 4 RESULTS
4.1 Physicochemical properties of M. fragrans 56
4.1.1 Physical analysis 56
4.1.1.1 Color parameter 56
4.1.2 Chemical composition 60
4.1.2.1 Proximate analysis 60
4.1.2.2 Mineral analysis 65
4.2 Antioxidant study 71
4.2.1 Screening test of various extracts of M. fragrans 71
4.2.1.1 Total phenolic content of various M. fragrans
extracts
4.2.1.2 Free radical scavenging activity of various M.
fragrans extracts
4.2.1.3 Correlation between total phenolic content and
antioxidant activity
71
75
81
4.2.2 Bioassay - guided fractionation 82
4.2.2.1 70% acetone extract of M. fragrans leaf 82
4.2.2.1.1 Fractionation of crude extract
4.2.2.1.2 Total phenolic content of fractions
4.2.2.1.3 Free radical scavenging activity of fractions
4.2.2.1.4 Refractionation of af4
4.2.2.1.5 Total phenolic content of sub - fractions
4.2.2.1.6 Free radical scavenging activity of sub -
fractions
82
84
86
91
92
93
4.2.2.2 Aglycone extract of M. fragrans pericarp 96
4.2.2.2.1 Fractionation of aglycone crude extract
4.2.2.2.2 Total phenolic content of fractions
4.2.2.2.3 Free radical scavenging activity of fractions
96
98
100
4.2.3 Identification of pure compounds 105
4.2.3.1 Compound af4i 105
4.2.3.2 Compound af4iii 107
4.2.3.3 Compound cf2 109
xi
4.3 Antibacterial study 115
4.3.1 Screening test of various extracts of M. fragrans 115
4.3.1.1 Diffusion sensitivity test of M. fragrans
extracts
4.3.1.2 Minimum inhibitory concentration (MIC) value of
M. fragrans extracts
4.3.1.3 Minimum bactericidal concentration (MBC) value of
M. fragrans extracts
115
120
121
4.3.2 Bioassay - guided fractionation
4.3.2.1 Determination of MIC and MBC values of partitions
of 70% acetone seed extract against Staphylococcus
aureus ATCC 12600
4.3.2.2 TLC chromatogram of ethyl acetate partition
4.3.2.3 Fractionation of ethyl acetate partition
4.3.2.4 Diffusion sensitivity test of fractions
4.3.2.5 Determination of MIC and MBC values of fractions
122
122
123
125
127
128
4.3.3 Bioautography screening 129
4.3.3.1 Antibacterial activity of fraction MFa10 on silica TLC
plate
4.3.3.2 Antibacterial activity of fraction MFa10 on cellulose
TLC plates
129
130
4.4 Determination of antioxidant and antibacterial activities of the active
phenolic fractions
131
4.4.1 Antioxidant activity
4.4.2 Antibacterial activity
131
134
CHAPTER 5 DISSCUSION
5.1 Physical evaluation of various parts of M. fragrans 135
5.1.1 Color analysis 135
5.2 Chemical analysis of various parts of M. fragrans 136
5.2.1 Proximate analysis 136
5.2.2 Mineral evaluation 140
xii
5.3 Total phenolic content of various M. fragrans extracts 146
5.4 Antioxidant activity 151
5.4.1 Antioxidant activity of various M. fragrans extracts 152
5.5 Correlation between total phenolic content and antioxidant activity 157
5.6 Antibacterial activity of various extracts of M. fragrans 159
5.7 Bioassay - guided fractionation 163
5.7.1 Antioxidant activity 163
5.7.2 Antibacterial activity 166
5.8 Structure elucidation 168
5.8.1 Compounds isolated from leaf of M. fragrans 169
5.8.2 Compound isolated from pericarp of M. fragrans 173
5.8.3 Compound isolated from seed of M. fragrans 175
CONCLUSION AND RECOMMENDATION FOR FUTURE RESEARCH
REFERENCES
xiii
LIST OF TABLES
Page
1.1 Comparison of constituents in M. fragrans 6
1.2 Phenolic antibacterial compounds and their mechanism of action 16
2.1 Analysis on M. fragrans 19
2.2 Total phenolic content of M. fragrans 21
2.3 Antioxidant evaluation of M. fragrans 23
3.1 Summary of serial dilution for MIC determination 49
3.2 Media and extract preparation for MIC micro - well dilution test 50
4.1 Color parameter of M. fragrans 59
4.2 Proximate composition of M. fragrans 61
4.3 Total phenolic content of various M. fragrans extracts 73
4.4 Antioxidant activity of various M. fragrans extracts and positive
controls
76
4.5 Chromatographic properties of fractions 83
4.6 Chromatographic properties of sub - fractions 91
4.7 Chromatographic properties of fractions 97
4.8 Rf values and colors of compound af4i 105
4.9 Rf values and colors of compound af4iii 107
4.10 Rf values and colors of sugar moiety of compound af4iii 108
4.11 Rf values and colors of compound cf2 109
4.12 UV - Visible spectra shifts for compound cf2 with different shift
reagents
112
4.13 The antibacterial activity of twenty four extracts of M. fragrans
against selected bacteria
116
4.14 MIC (µg/mL) value of five extracts of M. fragrans against five
bacteria
121
4.15 MBC (µg/mL) value of five extracts of M. fragrans against five
bacteria
122
4.16 MIC and MBC values (µg/mL) of partitions of 70% acetone seed 123
xiv
extract against Staphylococcus aureus ATCC 12600
4.17 Lignans identification of ethyl acetate partition of seed of M.
fragrans with n - hexane : ethyl acetate (7 : 3) as a mobile phase
124
4.18 Chromatographic properties of fractions 126
4.19 Antibacterial activity of fractions against Staphylococcus aureus
ATCC 12600
127
4.20 MIC and MBC values (µg/mL) of fractions against Staphylococcus
aureus ATCC 12600
128
4.21 Antibacterial activity of fraction MFa10 on silica TLC plate
developed using n - hexane : ethyl acetate (3 : 7)
129
4.22 Antibacterial activity of fraction MFa10 on cellulose TLC plates
developed using 50% acetic acid and Forestal
130
4.23 Antioxidant activity and total phenolic content of fraction MFa10 131
4.24 MIC and MBC values of isolated compounds against
Staphylococcus aureus ATCC 12600
134
xv
LIST OF FIGURES
Page
3.1 Overall flow chart of analyses which have been carried out in the
present study
55
4.1 The CIELAB color system 57
4.2 Comparison of major element concentrations (mg/100g dry weight)
in M. fragrans
66
4.3 Comparison of minor elements concentrations (mg/100g dry
weight) in M. fragrans
68
4.4 Gallic acid calibration curve for determination of total phenols
using Folin - Ciocalteau colorimetric assay
71
4.5 Antioxidant activities of M. fragrans extracts with the inhibition
percentage above 70% and positive controls at different
concentration defined as inhibition percentage of DPPH● in DPPH
assay
79
4.6 EC50 values of M. fragrans crude and aglycone extracts and
positive controls in DPPH free radical scavenging assay
80
4.7 Linear correlation between the DPPH free radical scavenging
activity and total phenolic content of various extracts of M.
fragrans
82
4.8 Total phenolic content of paper chromatographic fractions of M.
fragrans leaf and its crude extract, expressed as GAE (gallic acid
equivalent)
85
4.9 Antioxidant activities of 70% acetone extract of M. fragrans leaf,
its fractions and positive controls at different concentration defined
as inhibition percentage of DPPH● in DPPH assay
87
4.10 EC50 values of 70% acetone extract of M. fragrans leaf, its fractions
and positive controls in DPPH free radical scavenging assay
89
4.11 Linear correlation between the DPPH free radical scavenging
activity and total phenolic content of fractions and crude extract of
90
xvi
M. fragrans leaf
4.12 Total phenolic content of sub - fractions, fraction and crude extract
of M. fragrans leaf, expressed as GAE (gallic acid equivalent)
92
4.13 Antioxidant activities of sub - fractions, fraction and crude extract
of M. fragrans leaf and positive controls at different concentration
defined as inhibition percentage of DPPH● in DPPH assay
93
4.14 EC50 of sub - fractions, fraction and crude extract and positive
controls in DPPH assay
94
4.15 Linear correlation between the DPPH free radical scavenging
activity and total phenolic content of sub - fractions, fraction and
crude extract
95
4.16 Total phenolic content of aglycone of 70% acetone extract of M.
fragrans pericarp and its fractions, expressed as GAE (gallic acid
equivalent)
99
4.17 Antioxidant activities of aglycone of 70% acetone extract of M.
fragrans pericarp, its fractions and positive controls at different
concentration defined as inhibition percentage of DPPH● in DPPH
assay
101
4.18 EC50 values of aglycone of 70% acetone extract of M. fragrans
pericarp, its fractions and positive controls in DPPH free radical
scavenging assay
103
4.19 Linear correlation between the DPPH free radical scavenging
activity and total phenolic content of fractions and crude extract
104
4.20 Suggested structure of compound af4i, quercetin 106
4.21 Suggested structure of compound af4iii, quercetin - 3 - O -
glucoside
108
4.22 UV absorption spectrum of compound cf2 in 80% methanol and
shift reagents
111
4.23 The structure of pomiferin 113
4.24 Suggested structure of compound cf2, scandinone 114
4.25 Antibacterial activity of five extracts with the inhibition above
12mm against five bacteria
119
4.26 EC50 values and total phenolic contents of isolated compounds 132
xvii
5.1 Structural configuration of quercetin and its radical scavenging
activity
171
xviii
LIST OF PLATES
Page
1.1 Myristica fragrans Houtt. 2
4.1 Lignans identification of ethyl acetate partition of seed of M.
fragrans with n - hexane : ethyl acetate (7 : 3) as a mobile phase
124
4.2 Bioautography of fraction MFa10 against Staphylococcus aureus
ATCC 12600 developed using n - hexane : ethyl acetate (3 : 7)
129
4.3 Bioautography of fraction MFa10 against Staphylococcus aureus
ATCC 12600 developed using two solvent systems
130
xix
PEMPROFILAN FIZIKOKIMIA DAN PENGESANAN JUZUK FENOLIK
DENGAN AKTIVITI ANTIOKSIDAN DAN ANTIBAKTERIA BAGI Myristica
fragrans HOUTT.
ABSTRAK
Penyelidikan ini dijalankan untuk menilai ciri fizikal (warna) dan kimia (analisis
proksimat dan mineral) serta aktiviti antioksidan dan antibakteria ekstrak daun,
perikarpa, aril, biji, isi tempurung dan tempurung Myristica fragrans Houtt. Analisis
warna menunjukkan bahagian aril memiliki nilai a* dan C yang tinggi (28.14 ± 0.49
dan 29.92 ± 0.58, masing - masing) dengan sudut hue (ho) paling rendah (19.87 ±
0.35o), kulit perikarpa pula mencatatkan nilai b* paling tinggi (28.59 ± 0.78) dan isi
tempurung mencatatkan parameter L* paling tinggi (72.85 ± 0.16). Kandungan
lembapan adalah paling tinggi untuk semua sampel kecuali tempurung. Sementara
itu, kesemua sampel memiliki kandungan abu yang rendah kecuali bahagian daun
dan isi tempurung, di mana kandungan proteinnya lebih rendah berbanding abu.
Analisis unsur utama (Ca, Na, K, Mg) dan unsur surih (Cu, Mn, Fe, Zn)
menunjukkan kepekatan kalium (K) dan kalsium (Ca) yang tertinggi dalam perikarpa
manakala mangan (Mn) merupakan unsur surih paling tinggi dikesan. Ekstrak
mempamerkan julat kandungan fenolik total yang luas daripada 649.00 ± 2.16mg
GAE/g ekstrak kering hingga 8.66 ± 0.71mg GAE/g ekstrak kering. Aktiviti
antioksidan berbeza daripada 84.53 ± 0.89% hingga 12.57 ± 0.98%. Korelasi yang
signifikan dan positif telah direkodkan bagi kandungan fenolik total dan aktiviti
antioksidan (r2 = 0.7039, p < 0.0001). Ini menunjukkan bahawa fenolik merupakan
bahan antioksidan utama di dalam ekstrak. Sejumlah lapan fraksi diperolehi dari
xx
ekstrak krud aseton 70% bahagian daun dan af4 mempamerkan nilai terbaik bagi asai
antioksidan (nilai EC50 = 24.91 ± 0.29µg/mL) dan paling tinggi kandungan fenolik
total (526.68 ± 0.82mg GAE/g ekstrak kering). Sub - fraksi af4i pula menunjukkan
nilai terbaik untuk aktiviti antioksidan (nilai EC50 = 23.08 ± 0.61µg/mL) dan sub -
fraksi af4iii mengandungi kandungan fenolik total yang paling tinggi (579.05 ±
0.46mg GAE/g ekstrak kering). Daripada lapan fraksi dari kromatografi turus bagi
ekstrak aglikon aseton 70% bahagian perikarpa, cf2 mempamerkan nilai terbaik
untuk kedua - dua kandungan fenolik total (358.85 ± 1.32mg GAE/g ekstrak kering)
dan asai antioksidan (nilai EC50 = 38.91 ± 1.81µg/mL). Aktiviti antibakteria oleh
kesemua ekstrak adalah lebih menonjol ke atas bakteria Gram - positif berbanding
bakteria Gram - negatif. Diameter zon perencatan bagi ekstrak berada dalam julat
16.00 ± 0.00mm hingga 9.00 ± 0.00mm. MFa10 yang disisihkan daripada ekstrak
aseton 70% biji adalah juzuk yang paling poten dengan nilai MIC 37.50µg/mL dan
nilai MBC 150.00µg/mL terhadap Staphylococcus aureus ATCC 12600. Empat
komponen fenolik iaitu kuersetin, kuersetin - 3 - O - glukosida, skandinon dan
sebatian lignan yang tidak dikenalpasti telah disisihkan dan dicirikan sebagai juzuk
utama dengan aktiviti menyingkirkan radikal bebas dan antibakteria.
xxi
PHYSICOCHEMICAL PROFILING AND DETECTION OF PHENOLIC
CONSTITUENTS WITH ANTIOXIDANT AND ANTIBACTERIAL
ACTIVITIES OF Myristica fragrans HOUTT.
ABSTRACT
This study was conducted to evaluate physical (color) and chemical (proximate and
mineral analysis) characteristics as well as the antioxidant and antibacterial activity
of extracts from leaves, pericarps, maces, seeds, seed kernels and shells of Myristica
fragrans Houtt. The color analysis revealed that the mace has the highest a* and C
value (28.14 ± 0.49 and 29.92 ± 0.58, respectively) and the least hue angle (ho)
(19.87 ± 0.35o), skin of pericarp was detected to have the highest b* value (28.59 ±
0.78) and seed kernel exhibited the highest L* parameter (72.85 ± 0.16). Moisture
content was at the highest for all samples except for shell. Meanwhile, all samples
were low in ash content except for leaf and seed kernel, whereby their protein
contents were lower than ash. Analysis for the major elements (Ca, Na, K and Mg)
and for the minor and trace elements (Cu, Mn, Fe and Zn) showed the highest
concentration of potassium (K) and calcium (Ca) in the pericarp while manganese
(Mn) is the predominant microelement detected. These extracts exhibited a wide
range of total phenolic content varying from 649.00 ± 2.16mg GAE/g dry extract to
8.66 ± 0.71mg GAE/g dry extract. The antioxidant activity varied from 84.53 ±
0.89% to 12.57 ± 0.98%. Significant and positive linear correlation were recorded
for total phenolic content and antioxidant activity (r2 = 0.7039, p < 0.0001),
indicating that phenolics were the major antioxidant constituents in the extracts. A
total of eight fractions were collected from 70% acetone crude extract of the leaf and
xxii
af4 exhibited the greatest value in antioxidant assay (EC50 value = 24.91 ±
0.29µg/mL) and the highest in total phenolic content (526.68 ± 0.82mg GAE/g dry
extract). Sub - fraction af4i showed the greatest value in antioxidant activity (EC50
value = 23.08 ± 0.61µg/mL) and sub - fraction af4iii was the highest of total phenolic
content (579.05 ± 0.46mg GAE/g dry extract). From eight column chromatographic
fractions of the aglycone of 70% acetone extract of the pericarp, cf2 showed the
greatest values in both total phenolic content (358.85 ± 1.32mg GAE/g dry extract)
and antioxidant assay (EC50 value = 38.91 ± 1.81µg/mL). The antibacterial activity
of all the extracts was more pronounced against Gram - positive bacteria than Gram -
negative bacteria. The inhibition zone diameters of extracts were ranging from
16.00 ± 0.00mm to 9.00 ± 0.00mm. MFa10 that was purified from 70% acetone
extract of the seed was the most potent component with MIC value of 37.50µg/mL
and MBC value of 150.00µg/mL against Staphylococcus aureus ATCC 12600. Four
phenolic substances, which were quercetin, quercetin - 3 - O - glucoside, scandinone
and an unidentified lignan compound were purified and characterized as the main
constituents with free radical scavenging and antibacterial activities.
1
CHAPTER 1 INTRODUCTION
1.1 Myristica fragrans Houtt.
1.1.1 Morphological description
Myristica fragrans Houtt., locally known named pala in Malay is an evergreen tree
growing to a height of about 18m (Ong, 2004). It belongs to the Myristicaceae
family. The leaves are oval in shape, pinnately and alternately arranged with
fragrance odor when crush (Weiss, 2002). The aromatic flowers are pale yellow in
color and are clustered in sima umbellate inflorescence (Weiss, 2002; Ong, 2004).
M. fragrans produces drupe type fruits, pyriform in shape, 6cm to 9cm long,
yellowish skin with perpendicular groove around the fruit and whitish flesh (Weiss,
2002). The flesh is about 1.3cm thick and contributes 75% to 85% of total weight. It
splits when ripe revealing its red mace encasing its brown glossy seed (Felter &
Lloyd, 1898). Parts of M. fragrans fruit are shown in Plate 1.1.
1.1.2 The
The leaves
1999). The
The mace w
(Zaidi et a
rheumatism
beneficial e
is also usef
disease, liv
2002), flatu
the bark is a
Leaf
Skin
Mace
Flesh Seed
Plate 1.1 Myristica fragrans Houtt.
2
rapeutic values
are drunk as tea to relief flatulence and intestinal spasm (Flach & Willink,
shoots are also used medicinally to treat hypertension (Mustapa, 2008).
as also used as stomach tonic and for healing headache and migraine
l., 2009). In Indonesian folk medicine the mace is used for curing
. The seed kernel (nutmeg) is widely used as spice with possible health
ffects such as aphrodisiac, anthelmintic, anticonvulsant and antiseptic. It
ul in treating inflammation, vomiting, diarrhea, dysentery, asthma, heart
er and spleen disorder, insomnia, colic, menorrhagia (Sharma et al.,
lence, nausea and dyspepsia (Zaidi et al., 2009). A resin obtained from
pplied externally to treat polyarthritis and gout (Adams et al., 2009).
3
In addition to its medicinal uses, the sour ripe fruits are used for preparing pickles,
jams, sweets and jellies while the seed and mace are used as flavoring for fish, meat,
biscuits, cakes, sauces and soups (Ong, 2004).
1.1.3 Scientific biological and pharmacological studies
Various biological and pharmacological evaluations have been conducted to verify
the therapeutic values of M. fragrans. The ethanolic extract of the pericarp exhibited
hypolipidaemic effect by lowering the total cholesterol, low density lipoprotein
(LDL) cholesterol and triglycerides levels in the treated albino rabbits after 60 days.
In addition, the extract also showed platelet anti - aggregatory effect with no side
effects on various hematological and biochemical parameters (Ram et al., 1996).
Meanwhile, Ozaki et al. (1989) have reported the anti - inflammatory effect of
methanol extract of the mace and myristicin was detected as the active constituent.
Jannu et al. (1991) have tested the effectiveness of mace as chemotheraphy agent on
7, 12 - dimethylbenzanthracene (DMBA) - induced papillomagenesis in the skin of
male albino mice. The extract reduced 50% of papillomagenesis (as compared with
that of control (100%)). Hussain and Rao (1991) reported that at the dose of
10mg/mouse/day orally for seven days before and ninety following days, mace
exhibited good chemopreventive activity by reducing the cervical carcinoma
incidence from 73.90% (control) to 21.40%. Moreover, Kumari and Rao (1989)
reported the hepatoprotective effect of the mace based on a significant increase in
gluthathione - S - transferase (GST) and acid soluble sulfhydryl (SH) levels.
4
Another studied conducted by Sharma and colleagues (1995) demonstrated the
efficacy of seed extract as preventive agent for hypercholesterolemia and
atherosclerosis in rabbits. The extract assisted in reducing serum cholesterol, LDL
cholesterol and cholesterol/phosholipid ratio by 69.10%, 76.30% and 31.20%
respectively and also significantly elevated the decrease of high density lipoprotein
(HDL). Moreover, the extract also prevented the accumulation of cholesterol,
phospholipids and triglycerides in liver, heart and aorta, dissolved the atheromatous
plaques of aorta from 70.90% to 77.65% and increased the fecal excretion of
cholesterol and phospholipid. Furthermore, Olajide et al. (1999) found that the
chloroform extract of the seed showed anti - inflammatory activity by inhibiting the
rat paw oedema. The extract also has analgesic property by reducing writhings.
Sonavane et al. (2001) reported that the n - hexane extract of the seed has
anxiogenic, sedative and analgesic activities. The results obtained from Parle et al.
(2004) revealed that the n - hexane extract of the seed at lowest dose of 5mg/kg
administered for three days, improved learning and memory of young and aged mice.
This extract also reversed scopolamine - and diazepam - induced impairment in
learning process and memory. Goncalves et al. (2005) found that the aqueous seed
extract was able to inhibit only human rotavirus cell (HCR3) with 90.00% inhibition
at the maximum non - toxic concentration (MNTC) of 160.00µg/mL.
The crude suspension and petroleum ether extract of seed kernel possessed a good
antidiarrheal effect and sedative property, with weak analgesic effect (Grover et al.,
2002). An experimental study by Tajuddin et al. (2003) and Tajuddin et al. (2005)
were undertaken to evaluate the improving effect of 50% ethanolic extract of the
seed kernel on sexual function. The result indicated that the extract increased both
5
libido and potency, which might be attributed to its nervous stimulating property.
Apart from possessing aphrodisiac effect, the extract was observed to be devoided of
any adverse effects and acute toxicity. Meanwhile, Janssens et al. (1990) suggested
that eugenol and isoeugenol (the major components of seed kernel oil) play the major
role in the inhibiting platelet aggregation. Moreover, based on the plasma
aminotransferase activities, the seed kernel oil and myristicin showed a prominent
hepatoprotective activity (Morita et al., 2003). According to antidepressant study
conducted by Tan (2006) via tail suspension test (TST) and forced swimming test
(FST), the hexane, chloroform and 80% methanol extracts of pericarp, mace, kernel
and seed generally showed poor antidepressant effect.
Apart to its health beneficial effects on human, M. fragrans do play a role as insect
controlling agent. The results obtained from Huang et al. (1997) suggested that the
essential oil of the seed extract exhibited good grain protectant property as the oil
reduced the production of progeny of Tribolium castaneum and Sitophilus zeamais,
decreased in the percentage of eggs hatched and viable larvae after hatching at
various concentrations.
1.1.4 Phytochemical content
The identified constituents based on spectroscopic methods reported by numerous
authors were compiled in Table 1.1. As indicated in the Table, pericarp, mace and
seed kernel share constituents, such as α - pinene, β - pinene, limonene and sabinene.
Choo et al. (1999) asserted that the constituents present are similar in pericarp, mace
and seed kernel though the compositions are substantially different. As far as
6
literature survey could as certain, no report on chemical composition of essential oil
and extract of shell M. fragrans was obtained.
Plant part Constituents Leaf myristicin, quercetin and kaempferol (Suhaj, 2006). Pericarp α - pinene, β - pinene, γ - terpinene, α - terpinene, α - terpineol,
myristicin, limonene, sabinene, α - terpinolene, α - myrcene, terpinen - 4 - ol, isoeugenol, myristicin (Choo et al., 1999), ferulic acid (Wojdylo et al., 2007), caffeic acid, catechin (Shan et al., 2005), quercetin, and kaempferol (Suhaj, 2006).
Mace α - pinene, β - pinene, limonene, safrole, sabinene, lignans, neolignans (Hada et al., 1988), linoleic acid, palmitic acid, elemicin, isocroweacin, methoxyeugenol, isoeugenol (Singh et al., 2005), cyanidin, quercetin and kaempferol (Suhaj, 2006).
Seed isoeugenol, methyl-eugenol, eugenol, dihydroguaiaretic acid, γ - terpinene, terpinen - 4 - ol, myristic acid, oleanolic acid, palmitic acid, camphene, lauric acid, myrcene, quercetin and kaempferol (Suhaj, 2006)
Seed kernel α - pinene, β - pinene, sabinene, safrole, terpinen - 4 - ol, elemicin, myristicin, α - terpineol, myristicin, limonene, α - terpinene (Spricigo et al., 1999; Tomaino et al., 2005; Jukić et al., 2006), eugenol, isoeugenol (Janssens et al., 1990), neolignans (myrisfragransin) (Li & Yang, 2008), lignans (diarylbutane, 7 - methyl ether diarylbutane and aryltetralin) (Kwon et al., 2008), neolignan (myrislignan), macelignan (Chung et al., 2006).
1.2 Nutritional aspect
There are seven major classes of nutrients which are carbohydrates, fats, fiber,
minerals, proteins, vitamins, and water (Watkin, 1979). These nutrients can be
generally grouped into macronutrients and micronutrients (Whitney & Rolfes, 1996).
The macronutrients are carbohydrates, fats, fiber, proteins and water. On the other
hand, minerals and vitamins are called micronutrients. Minerals can be divided into
two groups. First group is macroelement (calcium, phosphorus, potassium, sodium
and sulfur) which are required in large quantities above 100mg/kg diet. Second
Table 1.1 Comparison of constituents in M. fragrans
7
group is microelements (ferum, cuprum, manganese, zinc, cobalt, molybdenum,
chromium, selenium, flour, iodine and nickel) which are required in small amount
below 100mg/kg diet.
Primarily, carbohydrates, proteins, and fats are metabolized to give energy. Protein
serves as the major structural component of all cells in the body, and functions as
enzymes, in membranes, as transport carriers, and as some hormones. Minerals are
essential chemical elements in human body which are involved in the formation of
skeletal structure, blood protein, enzymes and hormones, maintenance of colloidal
system and regulation of acid base equilibrium. They also act as component which
involved in enzyme activation, hemoglobin composition and lipid, amino acid and
carbohydrate metabolism (Mason, 2001).
Plants contribute notably to human nutrition and health, because they contain almost
all essential mineral and organic nutrients. Nutrient composition varies among
different plants’ parts and species (Sanchez - Castillo et al., 1998) and not all plants
contain essential nutrients needed for individual health. For instance, leafy
vegetables are good sources of most minerals and vitamins with less concentration of
protein and carbohydrates. Seeds are good sources of carbohydrates, proteins, lipids,
and lipid - soluble vitamins, but tend to have low concentrations of iron and calcium
(Grusak & DellaPenna, 1999). To ensure an adequate dietary intake of all essential
nutrients and to increase the consumption of various health - promoting plants, it is
an urgent need for researchers to quantify and compile all the nutritional information
of all food plants (Arzani et al., 2007).
8
The human body requires a number of minerals in order to maintain good health.
Malnutrition is major nutrition concern for tropical countries. Malnutrition is a
concept of nutrition disorder. The disorder may be due to excessive nutrition
(overnutrition) or deficiency nutrition (undernutrition) (McLaren, 1979). In the
developing world, many low - income families survive on a simple diet comprised
primarily of staple foods such as rice, wheat and maize that are poor in some
macronutrients and many micronutrients. As a result, 30% of the world’s population
is at risk for iron deficiency anemia (infants, children, and women at reproductive
age are particularly vulnerable) (Arzani et al., 2007). Hardisson et al. (2001)
reported that the risk of deficiencies depends on a number of factors such as the daily
dietary intake, the food content, the technical treatment of the products, the presence
of substances that limit or increase the bioavailability of minerals and the
physiological state of the food and overall health status of consumer.
The importance of optimal intakes of essential nutrient to maintain peak health is
widely recognized (Avioli, 1988). Optimal intakes of elements such as sodium,
potassium, magnesium, calcium, manganese, copper, zinc, and iodine could reduce
individual risk factors, including those related to cardiovascular disease (Mertz,
1982). It also has been recognized that some elements such as selenium could play a
protective role in decreasing the risk of some types of cancer (World Cancer Report,
1997). Thus, balance diet rich in minerals, fiber and vitamins are more than perfect
for the human health.
9
1.3 Antioxidant activity
1.3.1 Oxidative damage and diseases
Free radicals and other reactive species are waste products present in the body and
can be generated endogenously and exogenously (Gaté et al., 1999). Unhealthy
human diet containing mutagenic and carcinogenic substances and pathologic cell
metabolism also contribute to the formation of free radicals.
Free radicals are atom, molecule or mixture containing one or more unpaired electron
(Forrester et al., 1968). The species are capable to extract electron from other
molecules to stabilize the electron number, thus led to the formation of new free
radicals known as reactive oxygen species (ROS) (Stengler, 2001). Various ROS
such as singlet oxygen (1O2), superoxide radical (O-2●), hydroxyl radical (OH●) and
hydrogen peroxide (H2O2) are generated as by - products during aerobic metabolism
in cells (Gutteridge, 1994), which have the potential for bringing about extensive
damages to living cells (Darley - Usmar et al., 1995).
Within the cells, ROS will enter intercellular space and subsequently attack
oxidizable substrates such as DNA, lipids, proteins and carbohydrates (Halliwell,
1995). These will cause DNA lesions, lipid peroxidation, protein fragmentation
within the cells of biological macromolecules (Gutteridge, 1994) and subsequently
destroy membrane integrity and resulting cell lyses (Wei & Shiow, 2001). Vast
scientific reports acknowledged that the oxidative stress is an important contributor
to the pathophysiology of a variety of pathological conditions including
cardiovascular dysfunctions, atherosclerosis, carcinogenesis, inflammation,
10
neurodegenerative diseases such as such as Alzheimer’s disease, Parkinson’s disease
and Downs syndrome (Manach et al., 2004) and in natural aging processes
(Govindarajan et al., 2005).
1.3.2 Phenolic compounds as natural antioxidant
Phenolic substances are secondary metabolites compounds synthesized by plant and
derived from phenylalanine and tyrosine pathways (Shahidi & Naczk, 2004). Plant
phenolics include simple phenols, phenolic acids (both benzoic and cinnamic acid
derivatives), coumarins, flavonoid, stilbenes, hydrolysable and condensed tannins,
lignins and lignans. Structurally, phenolic compounds comprise an aromatic ring,
bearing one or more hydroxyl substituents and range from simple phenolic molecules
to highly polymerized compounds (Sakihama et al., 2002). These substances may
act as phytoalexins, pigments, antioxidants, attractant for pollinators and protective
agents against UV light (Harborne, 1967; McClure, 1975; Timberlake & Bridle,
1975; Heim et al., 2002). In food, phenolic substances may contribute to the
bitterness, astringency, flavor, odor and color (Shahidi & Naczk, 1995). Phenolic
compounds are not uniformly distributed in plant at the tissue, cellular and
subcellular levels (Maisuthisakul et al., 2008). The content in plants are differed due
to genetic and environmental factors as well as post - harvest and storage conditions
(Franke et al., 2004).
Halliwell (1995) defined antioxidant as a substance that, when present at low
concentrations compared to substrate, significantly inhibit or delay the oxidation of
substrates by inhibiting the initial or propagation of oxidation chain reactions.
11
Antioxidants are actively involved in preventing free radical damage (Seifried et al.,
2007). Antioxidants are divided into two main types according to their action.
Primary antioxidants can inhibit or delay oxidation by scavenging reactive oxygen
species. Secondary antioxidants function by binding metal ions, converting
hydroperoxides to non - radical species, absorbing UV radiations or deactivating
singlet oxygen (Gordon, 2001). Antioxidants are also believed to contribute to the
beneficial effects through stimulating the antioxidative defense enzyme activities
(Saha et al., 2004).
Among the various kinds of natural antioxidants, polyphenols have received much
attention (Luo et al., 2002). The ability of natural phenolic substances including
flavonoids and phenolic acids as antioxidant agents has been extensively investigated
(Rice - Evans et al., 1996; Shui & Lai, 2004; Kim et al., 2005; Duarte - Almeida et
al., 2007). Phenolic antioxidants in plants tend to be water soluble and most of them
appear as glycosides and they are located in the cell vacuoles (Harborne, 1998).
Dietary consumption of fruits and vegetables contain abundant of natural ROS
scavenging molecules including phenolic compounds (Shahidi & Naczk, 1995;
Aruoma, 2003). These exogenous antioxidants are required to maintain adequate
level of antioxidants in human body for disease prevention and health promotion.
These natural diets tend to be safer than synthetic antioxidant such as butylated
hydroxyl anisole (BHA) and butylated hydroxyl toluene (BHT), which are
extensively used in food processing industry (Mathew & Abraham, 2006).
Among the phenolic compounds, flavonoids are the most well - known antioxidant.
Phenolic structure provided a primer factor of antioxidant property (Rice - Evans &
Miller, 1998). The basic flavonoids structure is the flavan nucleus, which consists of
15 carbon atoms arranged in three rings (C6 - C3 - C6), labeled A, B and C. Vary in
plant antioxidant properties mostly due to hydroxylation, glycosylation, aromatic
substitution and conjugation with phenolic compounds or organic acid (Heim et al.,
2002). In addition to antioxidant properties of natural flavonoids, extensive
investigation has been done to reveal the pharmacological aspects such as
antiallergic, antiatherogenic, antiinflammatory, antimicrobial, antithrombotic,
cardioprotective and vasodilatory effects (Balasundram et al., 2006).
Natural phenolic antioxidants (NPH) hinder the oxidation process of substrates by
rapid donation of a hydrogen atom to radicals (RO●).
A stable intermediate substance, phenoxy radical (NP●) act as terminators of the
propagation route by reacting with other free radicals (Ferguson, 2001).
RO● + NPH → NP● + ROH
12
RO● + NP● → RONP
13
1.4 Antibacterial activity
1.4.1 Diseases and antibacterial agents
Throughout history, there has been a continual battle between humans and the
multitude of microorganisms that cause various types of infections and diseases. A
variety of microorganisms may also lead to food spoilage that will threaten for both
consumers and the food industries.
Cheesbrough (1984) defined antibacterial agents as any chemical substances that,
when present at certain concentration are capable to kill or inhibit the growth of
bacteria. Bacteriostatic agents prevent the growth of bacteria while bactericidal
agents are capable to kill the bacteria (Nester et al., 2007). Action of antibacterial
agents falls into four general categories; through inhibition of cell wall, protein and
nucleic acid synthesis or by disturbing the cell membrane function (Talaro & Talaro,
2002).
Multiple drug resistance has become a global concern (Westh et al., 2004) due to
indiscriminate use of commercial antimicrobial drugs in the treatment of infectious
diseases (Service, 1995). In a recent study done in New York City, up to 50% of
Streptococcus pneumonia isolates obtained from two institutions were resistant to
erythromycin (Lin et al., 2004). Resistance among bacteria genera are due to, first,
by prevention of interaction of drugs with target, secondly by effluxing of the
antibacterial agent from the cell and lastly, by modification of bacteria’s structure
(Mendonco - Filho, 2006).
14
Numerous studies have identified compounds within plants that are effective
antibacterial (Basile et al., 1997; Cowan, 1999; Basile et al., 2000; Mackeen et al.,
2000). Herbal remedies utilized in traditional healing systems around the world are
important resources for the discovery of new antibacterial compounds (Okpekon et
al., 2004).
1.4.2 Roles of phenolic compounds in treating bacterial diseases
Natural products have served as an important source of drugs since ancient times and
about half of the useful drugs today are derived from natural sources. However, the
development of bacterial resistance to the available known antibiotics, the emergence
of uncommon infections (Liu et al., 2008), the undesirable side effects of certain
antibiotics such as hypersensitivity, immunosuppression and allergic (Ahmad et al.,
1998; Sudha et al., 2001) and the acceptance of traditional medicine as an alternative
form for health care have led researchers to investigate the antibacterial activity of
medicinal plants (Mahasneh & El - Oqlah, 1999; Sahin et al., 2003; Baydar et al.,
2004; Venkat Reddy et al, 2004; Loziene et al., 2007; Adedapo et al., 2008).
According to Atlas (1984), the commercialization of antibacterial agents as
chemotherapeutic drugs is influenced by several factors such as solubility, stability,
excretion rate, allergic reaction and toxicity to cell.
The use of complementary and alternative medicine has increased dramatically. This
situation forced the scientists to validate the therapeutic values of various sources
medicinal plants thus ascertain new antimicrobial substances. For instance,
antibacterial activity of common herbal remedies of Texas: Achillea millefolium,
15
Berberis vulgaris, Commiphora molmol, Galium aparine, Glycyrrhiza glabra,
Matricaria chamomilla, Pimenta dioica, Salvia greggii, Uncaria tomentosa and Zea
mays were reported by Romero et al. (2005). Mothana and Lindequist (2005) have
screened the antimicrobial activity of extracts of 25 selected plants belonging to 19
families from the island Soqotra against several bacteria including Staphylococcus
strains. The results revealed the potential value of Punica protopunica, Boswellia
species, Commiphora parvifolia, Buxus hildebrandtii, Jatropha unicostata,
Kalanchoe farinacea and Withania species as antibacterial drugs against Gram -
positive bacteria.
Among the various kinds of secondary metabolites in plants polyphenols have
received much attention as antibacterial agents (Karamanoli, 2002). Extracts of
various medicinal plants containing flavonoids have been reported to possess
antimicrobial activity (El - Abyad et al., 1990; Singh & Nath, 1999; Cakir et al.,
2003; Sato et al., 2004). For centuries, preparations containing phenolic compounds
as the active constituents have been utilized by physicians and lay healers in attempt
to treat infectiuos diseases (Havsteen, 1983). Huang chin (Scutellaria baicalensis) is
yet a good example. This herb is believed for many thousands of years in China for
the treatment of periodontal abscesses and infected oral wounds, by applying
systemically and topically. A flavone, baicalein was reported as the antibacterial
compound of this plant (Tsao et al., 1982). A list of plants with antibacterial
phenolic compounds and its mechanism of action are shown in Table 1.2.
of a
ctio
n
s
ynth
esis
se IV
- de
pend
ent D
NA
cle
avag
e IV
- de
pend
ent d
ecat
enat
ion
activ
ity
d th
e re
lativ
ely
hom
olog
ous
gyra
se e
nzym
e ar
e in
volv
ed
ne fl
uidi
ty in
hyd
roph
ilic
and
hydr
opho
bic
regi
ons
thus
redu
ced
the
nn
er la
yers
of m
embr
anes
er
s by
dir
ectly
pen
etra
ting
them
and
dis
rupt
ing
the
barr
ier f
unct
ion
roce
ss th
at re
sults
in le
akag
e of
intr
amem
bran
ous
mat
eria
ls a
nd a
ggre
gatio
n
acte
rial
mem
bran
e
lity
of th
e ce
llula
r mem
bran
e an
d da
mag
ing
mem
bran
e fu
nctio
n m
embr
ane
dam
age
and
pota
ssiu
m le
akag
e ity
of t
he in
ner b
acte
rial
mem
bran
e an
d a
diss
ipat
ion
of th
e m
embr
ane
cter
ial m
otili
ty
y m
etab
olis
m,
mpt
ion
and
NA
DH
- cy
toch
rom
e c
redu
ctas
e m
etab
olis
m
ir m
echa
nism
of a
ctio
n (C
ushn
ie &
Lam
b, 2
005)
16 M
echa
nism
1) I
nhib
itio
n of
nuc
leic
aci
d sy
nthe
sis
Phe
nolic
com
poun
ds
Rob
inet
in, m
yric
etin
and
(-)
- epi
gallo
cate
chin
In
hibi
t DN
A a
nd R
NA
Que
rcet
in, a
pige
nin
and
3, 6
, 7, 3
', 4'
-
Inhi
bit D
NA
gyr
ase
Pen
tahy
drox
yfla
vone
Rut
in
Prom
ote
topo
isom
era
In
hibi
t top
oiso
mer
ase
Gal
angi
n T
opoi
som
eras
e IV
an
2) I
nhib
itio
n of
cyt
opla
smic
mem
bran
e fu
ncti
on
Phe
nolic
com
poun
ds
S
opho
rafl
avan
one
G a
nd n
arin
geni
n A
ltera
tion
of m
embr
a
flui
dity
of o
uter
and
i (
-) -
epig
allo
cate
chin
gal
late
Pe
rtur
b th
e lip
id b
ilay
m
embr
ane
fusi
on, a
p (
-) -
epic
atec
hin
galla
te a
nd 3
- O
- oc
tano
yl -
Act
on
and
dam
age
b (
+) –
cat
echi
n
2, 4
, 2' -
trih
ydro
xy -
5' -
met
hylc
halc
one
Cha
nge
the
perm
eabi
Gal
angi
n In
duce
s cy
topl
asm
ic
Nar
inge
nin
and
quer
cetin
In
crea
se in
per
mea
bil
po
tent
ial i
nhib
ited
ba
3)
Inh
ibit
ion
of e
nerg
y m
etab
olis
m
Phe
nolic
com
poun
ds
R
etro
chal
cone
s (l
icoc
halc
one
A a
nd C
) In
terf
erin
g w
ith e
nerg
In
hibi
t oxy
gen
cons
u L
onch
ocar
pol A
In
terf
eres
with
ene
rgy
Tab
le 1
.2 P
heno
lic a
ntib
acte
rial
com
poun
ds a
nd th
e
17
The antimicrobial mode of action is related with the phenolic compounds (Cakir et
al., 2004). It is also worth determining the antibacterial mechanism of action of
various phenolic compounds. Phenolics attack and disturb the structure of lipid
bilayers membrane by penetrating into them and disturbing the barrier function. This
may cause membrane fusion, a process that results in leakage of intramembranous
materials and aggregation (Ikigai et al., 1993), capable to change the permeability of
the cellular membrane and damaging membrane potential (Sato et al., 1997). They
also interfere with membrane function via electron transport, nutrient uptake, protein
and nucleic acid synthesis and enzyme activity (Denyer & Hugo, 1991). It is also
believed that chelation of transition reactive metals ions, such as iron and copper, by
phenolic compounds reduces bioavailability for bacterial growth (Jay, 1996).
1.5 Problem statement
None of the previous studies were ever highlighted on the physicochemical
characteristic including color parameter, proximate and mineral analyses of different
parts of M. fragrans. Even though many scientific studies have been conducted on
this plant, more emphasis was given to mace, seed and seed kernel extracts. There
have been no attempts to verify the therapeutic values of leaf, pericarp and shell
extracts. Comparative evaluation between extracts of different plant parts is also
lacking.
Due to the limited data, the aim of this study is to provide new information on the
physicochemical profiling, phenolic content, antioxidant activity and antibacterial
activity of the plant.
18
1.6 Objectives of study
The aims of the present study are as follows:
1. To quantify and compare the physicochemical properties of six parts of M.
fragrans.
2. To determine and compare the total phenolic content, free radical scavenging
activity and the antibacterial property of the extracts.
3. To correlate between total phenolic content and free radical scavenging
activity of the extracts.
4. To detect the active antioxidant and antibacterial compounds.
CHAPTER 2 LITERATURE REVIEW
2.1 Physicochemical profiling of M. fragrans
Limited data is available on physicochemical properties of M. fragrans. The only
data is on the general composition of seed kernel and mace that was obtained from
Gopalakrishnan (1992) and is presented in Table 2.1.
Bas
mac
fruc
kern
Table 2.1 Analysis on M. fragrans (Gopalakrishnan, 1992)
19
Composition Plant part Seed kernel (%) Mace (%) Moisture 40.00 40.00 Volatile oil 11.00 15.30 Non - volatile oil ether extract 33.60 21.98 Starch 30.20 44.05 Sugar Glucose 0.10 0.17 Fructose 0.07 0.10 Total reducing sugars 0.17 0.27 Sucrose 0.72 0.39 Total sugars 0.89 0.65 Protein 7.16 9.91 Crude fiber 11.70 3.93 Total ash 2.57 1.56 Ash insoluble in HCl 0.20 0.15 Polyphenols Total tannins 2.50 - True tannins 1.00 -
ed on the data in Table 2.1, the moisture content level of the seed kernel and
e were equal (40.00%). In mace, the amounts of volatile oil, starch, glucose,
tose, total reducing sugars, sucrose and protein were higher than that of the seed
el. The seed kernel has higher amount of non - volatile oil ether extract, sucrose,
20
total sugars, crude fiber, total ash and ash insoluble in acid hydrochloric (HCl).
Polyphenol was only detected in seed kernel (2.50% of total tannin and 1.00% of true
tannins).
2.2 Phenolic compounds of M. fragrans
Phenolic substances are ubiquitously distributed throughout the plant kingdom
especially in fruits and vegetables. Several studies have quantified the total phenolic
content in pericarp, mace and seed kernel of M. fragrans. The results are
summarized in Table 2.2. However, the result cannot be compared among one
another due to the different in extraction procedures and phenolic content estimation
protocols.
Various phenolic compounds have been isolated from M. fragrans. According to a
review by Suhaj (2006), quercetin and kaempferol were widely distributed in leaf,
pericarp, mace and seed. On the other hand, Shan et al. (2005) have detected the
presence of caffeic acid and catechin in the pericarp. Ferulic acid was also found in
the pericarp (Wojdylo et al., 2007). Hada et al. (1988) have isolated eight
neolignans and five lignans from the mace part. Kwon et al. (2008) reported the
presence of six diarylbutane lignans and one aryltetralin lignan in the 95% methanol
extracts of the seeds and 7 - methyl ether diarylbutane lignan was a novel compound.
Li and Yang (2008) found that myrislignan is a major acyclic neolignan in seeds.
21
Pla
nt p
art
Ext
ract
T
otal
phe
nolic
con
tent
R
efer
ence
s
Pe
rica
rp
80%
met
hano
l 1.
61 ±
0.0
0g G
AE
/100
g of
dry
wei
ght
Shan
et a
l. (2
005)
80%
met
hano
l 8.
95 ±
0.4
5mg
GA
E/1
00g
of d
ry w
eigh
t W
ojdy
lo et a
l. (2
007)
M
ace
A
ceto
ne
40m
g C
E/1
00g
of fr
esh
wei
ght
Cha
tterj
ee et a
l., (2
007)
80%
met
hano
l 1.
98g
GA
E/1
00g
dry
wei
ght
Surv
esw
aran
et a
l. (2
007)
Se
ed k
erne
l 80
% m
etha
nol
1.30
g G
AE
/100
g dr
y w
eigh
t Su
rves
war
an et a
l. (2
007)
80%
met
hano
l and
50%
ace
tone
2.
68 ±
0.1
20m
g G
AE
/g e
xtra
ct fo
r 50%
ace
tone
ext
ract
, Su
et a
l. (2
007)
2.
62 ±
0.0
1mg
GA
E/g
ext
ract
for 8
0% m
etha
nol e
xtra
ct
Met
hano
l 15
3.00
± 1
.00m
g G
AE
/g d
ry w
eigh
t H
o et al.
(200
8)
Tab
le 2
.2 T
otal
phe
nolic
con
tent
of M
. fra
gran
s
Dat
a ex
pres
sed
as g
allic
aci
d eq
uiva
lent
s (G
AE
) or c
atec
hin
equi
vale
nt (C
E).
22
2.3 Antioxidant properties of M. fragrans
Various researches were done to determine the antioxidant properties of the M.
fragrans. The results were compiled in Table 2.3. Several assays were used such as
2, 2’ - azino - bis - 3 - ethyl benzthiazoline - 6 - sulfonic acid (ABTS●+) and 1, 1 -
diphenyl - 2 - picryl hydrazyl (DPPH●) radical scavenging activities, ferric reducing/
antioxidant power (FRAP), ferric thiocyanate (FTC), thiobarbituric acid (TBA), in
vitro thiobarbituric acid reactive substances (TBARS) and oxygen radical absorbance
capacity (ORAC). The 2, 2’ - bipyridyl competition assay was also conducted to
measure the Fe2+ - chelating activity and hydroxyl radical (HO●) - scavenging
capacity was examined by the electron spin resonance (ESR) spectroscopy method.
The result obtained from FRAP and ABTS●+ assay were categorized into five main
groups. The sample with trolox equivalent antioxidant capacity (TEAC) over
500µM/100g is classified as containing extremely high activity, from 100 to
500µM/100g, 50 to 100µM/100g and 10 to 50µM/100g and less than 10µM/100g
were classified as containing high, good, low and very low antioxidant capacities,
respectively. Thus, the outcomes in Table 2.3 were discussed based on these
categories.
23
P
lant
par
t E
xtra
ct
Ant
ioxi
dant
test
O
utco
me
Ref
eren
ces
Pe
rica
rp
80%
met
hano
l A
BT
S●+
Ext
ract
has
low
ant
ioxi
dant
act
ivity
Sh
an et a
l. (2
005)
80%
met
hano
l FR
AP,
AB
TS●
+ E
xtra
ct h
as a
mod
erat
e an
tioxi
dant
val
ues
in A
BT
S●+ a
nd
DPP
H●
+ ass
ay a
nd h
igh
antio
xida
nt c
apac
ity in
FR
AP
test
W
ojdy
lo et a
l. (2
007)
an
d D
PPH
●+
Mac
e A
ceto
ne
FTC
, T
BA
an
d D
PPH
●+
Ext
ract
and
ess
entia
l oi
l sho
wed
str
onge
r ac
tivity
tha
n B
HA
an
d B
HT
Si
ngh et al.
(200
5)
Ace
tone
D
PPH
●+
and
β -
caro
tene
- lin
olei
c
acid
Ext
ract
sho
wed
bet
ter
radi
cal
scav
engi
ng a
ctiv
ity t
han
its
thre
e lig
nan
frac
tions
and
the
se f
ract
ions
wer
e ca
pabl
e to
in
hibi
t per
oxid
atio
n
Cha
tterj
ee et a
l.
(200
7)
80%
met
hano
l A
BT
S●+ , D
PPH
●+
and
FRA
P E
xtra
ct w
as c
onsi
dere
d ha
ving
goo
d an
tioxi
dant
cap
acity
Su
rves
war
an et a
l.
(2
007)
Seed
95
% m
etha
nol
TB
RA
S E
xtra
ct
has
the
abili
ty
to
prot
ect
hum
an
LD
L
agai
nst
Cu2+
indu
ced
pero
xida
tion
Kw
on et a
l. (2
008)
Seed
ker
nel
80%
met
hano
l A
BT
S●+ , D
PPH
●+
50%
ace
tone
ext
ract
has
low
er E
C50
val
ue,
high
er c
hela
ting
activ
ity a
gain
st F
e2+ a
nd s
cave
ngin
g ac
tivity
on
HO
● t
han
80%
met
hano
l ex
trac
t. 80
% m
etha
nol
extr
act
has
grea
ter
AB
TS●
+ and
OR
AC
val
ue th
an 5
0% a
ceto
ne e
xtra
ct
Su et a
l. (2
007)
and
50%
ace
tone
2,
2’ -
bip
yrid
yl
com
petit
ion
assa
y,
ESR
and
OR
AC
80
% m
etha
nol
AB
TS●
+ , DPP
H●
+ E
xtra
ct w
as c
onsi
dere
d ha
ving
goo
d an
tioxi
dant
cap
acity
Su
rves
war
an et a
l.
and
FRA
P
(200
7)
M
etha
nol
AB
TS●
+ , DPP
H●
+ E
xtra
ct w
as c
onsi
dere
d ha
ving
goo
d an
tioxi
dant
act
ivity
H
o et al.
(200
8)
and
OR
AC
Tab
le 2
.3 A
ntio
xida
nt e
valu
atio
n of
M. fra
gran
s
24
As indicated in Table 2.3, Surveswaran et al. (2007) have compared the antioxidant
activities of the 80% methanol extract of the mace and seed kernel through ABTS●+,
DPPH● and FRAP assays. It was found that the TEAC value of ABTS●+ assay of
the mace was higher than the seed kernel extracts with 26.03mmol trolox per 100g
dry weight (mmol trolox/100g) and 17.92mmol trolox/100g, respectively. Moreover,
the seed kernel (13.31mmol trolox/100g) was highly capable to scavenge DPPH free
radical as compared to mace extract (9.70mmol trolox/100g). The authors also found
that the 80% methanol extract of both parts exhibited more or less similar FRAP
capacity.
2.4 Antibacterial properties of M. fragrans
Based on anti - Helicobacter pylori comparative evaluation of various Thai
medicinal plants, M. fragrans mace extract gave the lowest minimum inhibitory
concentration (MIC) that was 12.50µg/mL (Bhamarapravati et al., 2003). The leaf
extract also has low MIC of 50.00µg/mL. Zaidi et al. (2009) found that 70% ethanol
extract of mace (minimum bactericidal concentration (MBC) value ranged from
62.50µg/mL to 31.20µg/mL) showed stronger bactericidal activity than 70% ethanol
extract of seed (MBC value ranged from 125.00µg/mL to 62.50µg/mL).
Screening by Rani and Khullar (2004) on some traditional Ayurvedic medicine
against resistant Salmonella thypi, resulted a strong antibacterial activity of the
methanol extract of the seed. Consequently, Mahady and colleagues (2005) found
that the MIC value of the methanol extract of the seed was 12.50µg/mL against
Helicobacter pylori. Chung et al. (2006) have investigated the antibacterial activities