65

Volume 46 Number 2 June 2013

A study of extraction and characterization of alginates obtained 
from brown macroalgae Sargassum duplicatum and Sargassum 
crassifolium from Indonesia

decky J. indrani1 and Emil Budianto2
1Department of Dental Materials Science, Faculty of Dentistry, Universitas Indonesia
2Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Indonesia
Jakarta – Indonesia

abstract 
Background: Worldwide commercially available alginate have been used for tissue engineering purposes. The macroalgae 

Sargassum obtained from Indonesia have been used for various purposes, however, they have not been applied for tissue engineering 
scaffolds. Purpose: This study was aimed to extract alginate from the macroalgae Sargassum from Indonesia sea and to characterize 
in morphology, chemical element and functional groups. Methods: Macroalgae Sargassum duplicatum (S. Duplicatum) and Sargassum 
crassifolium (S. Crassifolium) were collected from Banten, Indonesia. Extraction of alginates were carried out using the alkaline 
extraction procedure. Scanning electron microscopy as well as X-ray Fluorescence and Fouirer Transform Infra-Red spectroscopy were 
used to characterize the extracted powders. Obtained data from the extracted powders were compared to those of the commercially 
available alginate. results: Extraction using the alkaline method has resulted in S.duplicatum and S.crassifolium alginate powders. 
Alginate particles were suggested as irregular shapes with various dimension. Element components were mainly Na and Ca, whereas, 
minor elements were considered as negative impurities. COO- and C-O-C groups were evident in the finger print regio. The characteristics 
of Alginates extracted from the macroalgae S.duplicatum and S.crassifolium found similar to those of the commercially available 
alginate. Conclusion: Extraction obtained from the macroalgae S.duplicatum and S.crassifolium showed the typical alginate and the 
morphology, chemical element and functional groups were in agreement with those of the commercially available alginate.

Key words: Alginate extraction, morphology, chemical element, functional groups 

abstrak

latar belakang: Alginat dari berbagai penjuru dunia telah digunakan untuk kegunaan rekayasa jaringan. Alginat dari alga makro 
Sargassum yang diperoleh dari Indonesia telah digunakan untuk berbagai kegunaan, namun ini belum diterapkan untuk scaffold 
jaringan. tujuan: Untuk mengekstrak alginat dari alga makro Sargassum perairan Indonesia dan untuk memperoleh karakteristik 
alginat dalam morfologi, unsur kimia dan gugus fungsi. Metode: Alga makro Sargassum dari spesies Sargassum duplicatum (S. 
Duplicatum) dan Sargassum crassifolium (S. Crassifolium) diperoleh dari Banten, Indonesia. Ekstraksi alginat dilakukan dengan 
menggunakan prosedur ekstraksi alkali. Scanning electrone microscope, X-ray fluorescence dan Fouirer transform infra-red spektroscope 
digunakan untuk mengarakterisasi bubuk alginat hasil ekstraksi. Data yang diperoleh dari serbuk laginat dibandingkan dengan yang 
tersedia secara komersial. hasil: Ekstraksi menggunakan metode alkali telah menghasilkan serbuk alginat dari S.duplicatum dan S. 
crassifolium. Morfologi partikel alginat terlihat tidak teratur dengan berbagai dimensi. Elemen Na dan Ca muncul sebagai komponen 
utama, sedangkan, elemen minor dianggap sebagai pengotor. Gugus fungsi COO-dan COC terdeteksi di regio sidik jari. Karakteristik 
alginat S.duplicatum dan S.crassifolium ditemukan sesuai dengan karakteristik alginat yang tersedia secara komersial. Simpulan: 

Research Report



66 Dent. J. (Maj. Ked. Gigi), Volume 46 Number 2 June 2013: 65–70

Serbuk yang diperoleh dari alga makroi S. duplicatum dan S.crassifolium menunjukkan kekhasan alginat dan morfologi, unsur kimia 
dan kelompok fungsional alginat sesuai dengan yang tersedia secara komersial. 

Kata kunci: Ekstraksi alginat, morfologi, elemen kimiawi, gugus fungsi 

Correspondence: Decky J. Indrani, c/o: Departemen Ilmu Material Kedokteran Gigi, Fakultas Kedokteran Gigi Universitas Indonesia. 
Jl. Salemba Raya No. 6 Jakarta 10430, Indonesia. E-mail: decky@ui.ac.id

introduction

The failure or loss of an organ or tissue is one of the 
most numerous and costly problems in human health care. 
Tissue engineering, that integrates a variety of science 
and engineering disciplines to create functional organ 
or tissues for transplantation, evolved as one of the most 
promising therapies in regenerative medicine.1 Scaffold-
guided tissue engineering for cells growth matrix made 
of biopolymer were appealing due to their structural 
similarities to the macromolecular-based human tissues.2 
Among biopolymers, alginate enabled more efficient 
penetration of cells into scaffold matrices.3,4 To enhance its 
biological performance, alginate has been combined with 
other biomaterials. Blends of alginate and chitosan have 
been used to regenerate cell in soft tissues.5,6 Composites 
of alginate and hydroxyapatite seeded with osteoblast have 
also been observed for bone tissue engineering.7,8 Bone 
tissue engineering may be an advantage, for instance, to 
increase ridge width due to resorption from tooth loss or 
for the treatment of edentulous patients if they lack the 
appropriate bone volume.

Worldwide alginates are collected from macroalgae of 
sub-tropical seas. For example, algae species of Laminaria 
from Norwegia, France, and Japan, as well as, species 
of Macrocystis from North America and Australia have 
produced alginates and made them important industries 
for food and nutrients,9 and other industries, such as, 
cosmetics, textile protection, fertilizers, pharmaceuticals, 
and biotechnology.10 In dentistry, alginates have been 
applied for impression materials.11 In tropical seas of 
Malaysia, Phillipine and Indonesia, more than 400 species 
of macroalgae are widely spreaded and mainly consist 
of Sargassum and Turbinaria. Indonesia has a lot of 
islands with broad coral rock, allowing huge supply of 
macroalgae as raw material for alginate and is a potential 
renewable marine resource in great abundance.12,13 Of the 
locals observation around Pamengpeuk shore, Banten, 
Indonesia, the macroalgae Sargassum are abundant and 
floated to the beach, at high tide. The locals had not 
have much information about the role of alginate in the 
industry, accept its downstream products, such as for 
food, syrup and gelling. Small industries of alginates have 
produced cosmetics, textile protection, fertilizers, and 
pharmaceuticals, limited for thickening, stabilizing and 
emulsifying agent.13,14 

Sargassum, as one of the many species of macroalgae 
from Indonesia, are currently being researched. 

Characterization of alginates have been based on 
requirements for quality standards, i.e. water and ash 
content, ashing temperature, and biochemistry analysis, 
such as thickening and stabilizing properties, gel-forming, 
estimation of content, etc.9,14,15 Although pharmaceutical 
uses from Sargassum alginates has not been evaluated fully, 
they have started an early stage of research as scaffold 
materiasl for tissue engineering scaffolds. However, 
neither of their characterizations were available. For tissue 
engineering, alginates scaffolds should be biocompatible to 
facilitate the process of cell regeneration.16,17 

Biocompability of alginate scaffold including the 
biodegradability and pore size for growth of cells was 
necessary.18 Biodegradability is an essential factor as 
scaffolds were absorbed by the surrounding tissues. 
Alginate is generally accumulated by minerals from the 
sea.10 Besides, there were also fukosantin pigment and 
polyphenol bound in the plant that make them become dark 
brownish colour.9 For this, pure alginate is required. Next, 
a high porosity and adequate pore size which can seed and 
grow cells are necessary; to secure mechanical properties 
of the scaffold appropriate for the cells.8,18 For this, 
alginate should be able to gelled and cross-linked through 
ionic bonding with divalent cations that act as bridges.19,20 
Essential factor to cross-linked alginate was the presence 
of carboxyl and carbonyl functional groups;17 besides, 
the existance of those functional groups are admired as 
they mimic the part of the protein group in human.2 As 
an addition, algiante powder should show morphology 
typical alginate. 

Characterizations of alginate scaffolds for tissue 
engineering have not been well addressed. To achieve the 
goal, therefore, characterization of Sargassum powder, i.e. 
morphology of alginate, chemical element and functional 
groups, should be carried out procede the characterization 
of alginate scaffold. Furthermore, extraction of alginate 
from the the macroalgae Sargassum was needed. Extracted 
and named by a Scottish scientist in 1881, alginic acid 
was realized as a kind of polysaccharide consisting of 
copolymers D-mannuronic and L-guluronic acids. They 
were found in cell walls of macroalgae and composed of 
3 kinds of polymers: i.e. alginates, cellulose, and complex 
heteroglycans. Alginates were presented mainly as the 
Ca salt of alginic acid, although Mg, K and Na salts may 
also be present; they do not dissolve in water.21 This 
structural integrity of alginate can be broken down with 
the use of extraction, to allow the direct transformation 
of the mixed salts (Na+, Mg+2+, and Ca2+) of alginate into 



67Indrani: A study of extraction and characterization of alginates obtained

sodium alginate, in order to obtain alginate that dissolves in  
water.15,22 The purpose of the present study, therefore, 
was to extract alginate obtained from the macroalgae 
Sargassum from Indonesia and to characterize the 
morphology, chemical element and functional groups. The 
information obtainded from the present study can be used 
partly to consider the use of the alginate extracted from 
the macroalgae in preparing scaffold of hydroxyapatite 
and alginate composite for scaffoled material for tissue 
engineering.

materials and methods

All chemicals used for alginate extraction process 
were analyst grade, obtained from Merck (USA). Two 
species of the macroalgae, i.e. Sargassum duplicatum JG 
Agardh (S. duplicatum) and Sargassum crassifolium JG 
Agardh (S. crassifolium), collected in November 2009 
from Pamengpeuk shore of Banten, Indonesia, were 
obtained from the Biotechnology Laboratory, Ministry 
of Marine Affairs and Fisheries–RI. A commercially 
available alginate powder of alginic acid sodium salt from 
brown algae, purchased from Sigma (Germany), was used 
routinely for a comparison. 

Macroalgae were collected by cutting the thallus about 
40 cm from the top of the plant and were washed with 
water to remove impurities, such as sand, etc, and were 
sun-dried for at least three days. All alginate extraction 
experiment were conducted on fronds of S.duplicatum and 
S. crassifolium macroalgae. Leaves of the plant were cut 
into pieces, stored in aerated bags and kept in shaded and 
ventilated site, until they were taken for extraction. 

Alginate extraction using alkaline protocol used in the 
present study was a laboratory adaptation of the industrial 
process and was conducted with a serial step, as described 
earlier.15–23 First of all, pieces of algae leaves were rinsed 
and immersed in water until they were expanded and then 
immersed in a 0.3% HCl solution for one hour. For each 
extraction experiment, 50 g of algae pieces were rinsed with 
distilled water and soaked in 1 L of a 4% (w/w) Na2CO3 
solution under continuous stirring a least two hours. At the 
end of the extraction, supernatant were separated from the 
solution by means of a vibrating screen and then acidified 
using HCl 10%. The resulting alginic acid, in the form 
of fiber foam, were rinsed with water on a filter screen. 
Solution of 10% NaOH was added to produce sodium 
alginate (Na-alginate). No decoloration procedure was 
included to the extraction process. Extracted Na-alginate 
fibers were recovered from solution by oven drying. 
Finally, dried Na-alginate fibers were milled to obtain 
smooth powders. Samples were powders of the Na-alginate, 
extracted from the macroalgae S. duplicatum (S. duplicatum 
alginate) and from the macroalgae S. crassifolium (S. 
crassifolium alginate), and, the commercially available 
alginate. All samples were then characterized. 

Scanning electron microscopy (SEM) was conducted 
to study the morphology of the alginate samples. Alginate 
powder samples were mounted on a sample holder. The 
convert into electrically conductive samples, the samples 
were coated with an ultrathin gold coating deposited on 
the surface of the samples by low-vacuum ion sputter 
apparatus. Coated samples were moved to scanning electron 
microscope (Zeus, Germany) and were then scanned and 
convert to an image through a monitor to visualize particle 
shapes. 

X-ray fluoroscence (XRF) spectroscopy was used to 
quantify chemical elements of the alginate samples. Each 
sample was prepared in a plastic ring mold (2.5 cm in 
diameter and 0.5 mm in thickness) and was compressed 
under a hydraulic press. The Na-alginate powder together 
with the mold was then loaded in XRF spectrometer 
(JEOL JSX-3211, Japan). The samples were scanned 
by XRD spectrometer and X-ray beam would interact 
with the samples. Data collected from the measurements 
were recorded using a software programme in the XRF 
spectrometer. Measurements were conducted three times. 

Fouirer transform infra-red (FTIR) spectroscopy was 
utilized to confirm the existance of functional groups in the 
alginate samples. A total of 5% (w/w) sample was mixed 
with dry potassium bromide (KBr), with respect to the pellet 
technique. The mixture was ground into a fine powder using 
an agate mortar and was compressed into a disc under a 
hydraulic press. Each sample was then mounted in and 
scanned by FTIR Spectroscopy (SpectrumOne, Perkin 
Elmer, Japan) at 4 mm/s over a wave number region of 
4000-450cm-1. FTIR transmission spectra obtained from the 
measurement were recorded using a software programme 
for FTIR. Measurements were conducted three times in 
the alginate samples. 

results 

Alkali extraction used in the extraction of the 
macroalgae S. duplicatum and S. crassifolium has resulted 
solid powder of alginates (Figure 1). S. duplicatum and S. 
crassifolium alginates were pale yellow and dark brown, 
respectively. In contrast, and the commercially available 
alginate were in white. Results from the characterizations 
showed comparison of S. duplicatum, S. crassifolium and 
the commercially available alginates in the morphology, 
chemical elemental and functional groups.

Morphology of S. duplicatum, S. crassifolium and the 
commercially available alginates revealed from SEM were 
presented in Figure 2. S. duplicatum and S. crassifolium 
alginates displayed shapes of irregular particles in varied 
size. Some were long, whereas, others were round. Some 
of which form the helical structure extending up to 200 μm 
and 20 μm in diameter. The variation in morphology and 
dimension coincided with those seen in the commercially 
available alginate. 



68 Dent. J. (Maj. Ked. Gigi), Volume 46 Number 2 June 2013: 65–70

Quantitative chemical elements detected in S. 
duplicatum, S. crassifolium and the commercially available 
alginates yielded by XRF spectroscopy were listed in  
Table 1. It can be seen from Table 1 that S and Fe 
elements were seen in low amount in all alginate powders. 
Surprisingly, the quantitative of Si (16%) in S. duplicatum 
alginate and Cl (30%) in S. crassifolium alginate were 
considerable. All chemical elemental were not detected in 
the commercially available alginate. As expected, the major 
chemical element components were Na and then Ca. 

FTIR spectra of the S. duplicatum, S.c rassifolium and 
the commercially available alginates in the band range of 
4000–450 cm-1 were illustrated in Figure 3. A broad envelop 
occured between the band of 3500-3000 cm-1 was assigned 
to stretching vibration of OH (hydroxyl) group. It is obvious 
that the presence of OH- ions around 3000 cm-1 correspond 
to adsorbed H2O, derived from moist of the samples. In the 
fingerprint region, the band around 1626-1623 cm-1 were 
correspond to asymmetrical and symmetrical stretching 
modes of COO (carboxyl) group. Another COO with 
similar modes also appeared at the band at 1421 cm-1. Other 
charateristic peaks around the band at 1027 cm-1 derived 

from C-O-C (ether) group, as aliphatic alcohol with C-O 
(carbonyl) substituent. The functional groups obtained 
from both extracted alginate were in agreement with those 
appeared in the commercially available alginate. As an 
addition, the extraction has resulted Na-alginate as ini 
Figure 4. A possible mechanism of the addition of NaOH 
into alginic acid producing Na-alginate was because of the 
weak bond between H+ and COO- was broken causing Na+ 
ions, possibly, forming COO-Na.

(a) (b) (c)

figure 1. Alginate powders from the macroalgae a) S. 
duplicatum, b) S. crassifolium and the c) commercially 
available alginate.

(a) (b) (c)

figure 2. SEM micrographs of the Na-alginates obtained from 
the macroalgae a) S. duplicatum, b) S. crassifolium 
and c) commercially available.

figure 3. FTIR spectra of Na-alginates obtained from the 
macroalgae a) S. duplicatum, b) S.crassifolium and 
c) available commercially.

     

figure 4. Schematic diagram of the incorporation of NaOH 
into (a) alginic acid, consisting the M and G groups 
resulting the (b) Na-alginate.9 

table 1. Chemical elements contained in the macroalgae a) 
S. duplicatum, b) S. crassifolium and c) available 
commercially

Source of alginate
Chemical 
elemental

wt (%)

S.duplicatum  Na
Ca
S
Fe
Si

50,5
12,1
 3,5
 6,9
16,4

S.crassifolium Na
Ca
S
Fe
Cl

49,3
10,2
 2,6
 3,2
30,8

Commercially 
available
 

 Na
Ca
S
Fe

73,2
 6,7
 8,2
 5,0



69Indrani: A study of extraction and characterization of alginates obtained

discussion

Macroalgae Sargassum were used in the present study 
because they grew abundant in areas near the shore; the 
collection was far easier compared with other macroalgae, 
and was routinely accomplished by the Ministry of Marine 
Affairs and Fisheries–RI. The Sargassum were identified as 
S.duplicatum and S. crassifolium by the Research Centre of 
Oceanography-Indonesian Institute of Sciences. 

The alkaline extraction procedure used in the present 
study was possible to to produce S.duplicatum and S. 
crassifolium alginates. As mentioned previously, that 
alginic acid in macroalgae were presented mainly as the 
Ca-alginat, a salt of alginic acid which were insoluble in 
water. The extraction process has converted the insoluble 
Ca salts into S.duplicatum and S. crassifolium alginates 
which were soluble in water. Alkali treatment was necessary 
for an ion exchange process. The process was carried out by 
2 steps; the first was a more efficient extraction by treating 
the seaweed with dilute mineral acid, as in reaction (1):
Pre-extraction:

Ca(Alg)2 + 2H+  2HAlg + Ca2+................................ (1)

According to several authors,15, 24, 25 when Ca-alginate 
was converted to alginic acid, it was more readily to be 
extracted with alkali than the original calcium alginate. 
Reaction (1) was continued by extraction using alkali as 
shown in reaction (2). 
Extraction:

2Halg + Na+  NaAlg + Ca2+...................................... (2)

No coloring agent was given in the extraction process. 
Both S. duplicatum and S. crassifolium alginates showed a 
distinctive brownish (Figure 1). The extremely dark brown 
colour demonstrated in S. crassifolium alginate powder 
was probably a reflection of fucosantin pigment, that often 
contained in certain algae, and probably covered other 
pigments. White color reflected from the commercially 
available alginate was ascertained as a result of color 
treatment at the time of the extraction process; this was 
always did as an effort to make alginate interesting. During 
alginate extraction, following the acid pre-treatment, a 
brown discoloration develops and this carries through 
the rest of the process resulting in a dark sodium alginate 
powder.10 Previously, it was demonstrated that phenolic 
compounds are responsible for the discoloration. 

X-ray fluoroscence results showed chemical elemental 
contained in S. duplicatum and S. crassifolium alginates 
(Table 1). Observing reaction (1), the incorporation of 
Na+ ions from NaOH into Ca2+ ions from Ca-alginate had 
made them rich with both Na+ and Ca2+ ions. Therefore, 
the quantitative chemical elemental of Ca and Na yielded 
by XRF was high. As Na and Ca elements were also in a 
considerable amount found in the commercially available 
alginate, it implied that the material experienced similar 

method of alginate extraction and NaOH was used in the 
extraction process. 

Chemical elemental occcured in the sample alginates 
were impurities. The minor amount of Fe and S elements 
in S. duplicatum and S. crassifolium alginates, as well 
as, in the commercially available alginate (Table 1) were 
impurities which likely to occure from the XRF instrument 
at the time of measurement. This possibilitiy was supported 
by the occurance Fe and S elements in the commercialy 
available alginates, as well. Whereas, the existance of the 
considerable amount of Si and Cl in S. duplicatum and S. 
crassifolium alginates, respectively, may due to mineral 
contaminations that originated from sea environment. It 
was presumed that they accumulated inside the macroalgae 
when producing M and G acids. This idea were supported 
by the absent of either Si or Cl in the commercialy available 
alginates. A purification process, actually, may omit 
impurities in S. duplicatum and S. crassifolium alginates. 
Nevertheless, impurities in alginate were presumed not to 
cause negative reaction during the overall biocompatibility 
of the material to human. In fact, bone mineral was known 
to compose of hydroxyapatite with substitutes, such as 
Ca Na, K, Cl, Fe, F, etc, originated from the welknown 
biomineralization in human.24 

FTIR spectra showed the occurance of carboxyl and 
carbonyl groups in S.duplicatum and S.crassifolium 
alginates implied the typical alginate (Figure 3). These 
functional groups showed the similarity to human protein, 
as in most organisms, polysaccharides and amino acids 
contained carboxylic acid (-COOH). The presence of 
carboxyl and carbonyl groups in S.duplicatum and S. 
crassifolium alginates coincided with those revield in the 
commercial available alginate, as well as, in a commercial 
available alginate analyzed studied.17    

The present study was an initial report describing 
both S. duplictum and S. crassifolium alginates powders, 
obtained from macroalgae of Banten, Indonesia. The use 
of SEM, XRF and FTIR have helped in identifying and 
verifying the material to describe the characteristic of 
alginate powder. The morphology of alginate, the chemical 
elemental, as well as the functional groups contained in the 
material were found similar with those of the commercially 
available alginate. The commercially available alginate use 
in the present study has been used as scaffold material for 
research. It was a great expectation of both S. duplictum and 
S. crassifolium alginates to be used as alginate for scaffold 
material. Further studies, therefore, need to characterized 
both S. duplictum and S. crassifolium alginates to explore 
the posibility of the material to be used as material for 
scaffolds, procede to further research in application of 
alginate scaffolds for tissue engineering applications.

It is concluded that extraction obtained from the 
macroalgae S. duplicatum and S. crassifolium showed the 
typical alginate; the morphology, chemical element and 
functional groups were in agreement with those of the 
commercially available alginate.



70 Dent. J. (Maj. Ked. Gigi), Volume 46 Number 2 June 2013: 65–70

acknowledgement

The financial support rendered by the Ministry of 
Education through the Universitas Indonesia is greatly 
acknowledged.

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