JURNAL FARMASI SAINS DAN KOMUNITAS, November 2019, 63-67 Vol. 16 No. 2 
p-ISSN 1693-5683; e-ISSN 2527-7146 

doi:  http://dx.doi.org/10.24071/jpsc.001698 

 

*Corresponding author: Asril Burhan 

Email: asrilburhan@gmail.com 

ANTIOXIDANT AND ANTICANCER ACTIVITIES OF MURBEI (Morus alba L.)  

STEM EXTRACT ON IN VITRO WiDr CANCER CELLS 

 

Asril Burhan*), Akbar Awaluddin, Zulham, Burhanuddin Taebe, Abdul Gafur 

Sekolah Tinggi Ilmu Farmasi Makassar, Indonesia 

 

Received January 20, 2019; Accepted May 18, 2019 

 

 

ABSTRACT 
Mulberry is considered as an important plant in traditional Chinese medicine, due to its 

various compounds, including phenols and flavonoids. These flavonoids have antioxidant 

activities so that can be a potential anticancer candidate. The aims of this study were to 

determining antioxidant activity, phenolic content, and potential anticancer activity in Mulberry 

stem extract. The extraction was carried out by maceration using ethanol as the solvent, 

antioxidant activity test using ABTS (2,2′-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid) 

method, phenolic content determination using Folin-Ciocalteu reagents, and anticancer activity 

test using the MTT (3-(4,5- dimetiltiazol-2-il)-2,5-difenil tetrazolium bromida) method on WiDr 

cancer cells and Vero cells. The result of total phenolic Mulberry stem extract was 35.9%, the 

antioxidant activity value was 83.18 µg / mL, the IC50 value for anticancer activity for WiDr cells 

was 71.24 µg / mL and Vero cells IC50 value was 154.241 µg / mL. It could be concluded that the 

Mulberry stem ethanol extract had strong antioxidant activity and had the potential anticancer 

selectively against cancer cells WiDr. 

Keywords: anticancer; antioxidant; IC50; mulberry stem extract 

 

INTRODUCTION 

Cancer is one of the leading causes of 

death in the worldwide. The number of cancer 

patients is predicted to increase each year. 

Cancer patients reach 23.6 million cases per 

year in 2030 (Ministry of Health RI, 2016). 

One of the plants used by the community as 

medicine is Mulberry (Morus Alba L.) which 

has many potentials, including reduce blood 

cholesterol, antidiabetes, and antihypertension 

(Mallaleng et al., 2011). 

The plants generally contain phenolic 

compounds such as flavanoids, synamic acid 

derivatives, coumarins, and tocopherols 

(Gupita and Rahayuni, 2012). Antioxidant 

compounds produced as vitamin C, vitamin E, 

carotene, groups of phenolic compounds-

especially polyphenols and flavonoids-are 

known to have the potential to reduce the risk 

of degenerative diseases (Kuntorini and 

Astuti, 2010).  

Antioxidant activity is thought to inhibit 

the growth of cancer cells, due to the 

similarity of the mechanism of resistance at 

the cellular level (Anam et al., 2014). 

Compounds that act as antioxidants include 

flavonoids, alkaloids, tannins, and also 

phenolic. The content is thought to have 

anticancer activities such as flavonoids which 

work by inhibiting carcinogenesis inactivation, 

cell cycle inhibition, inhibition of 

angiogenesis, cell proliferation and apoptotic 

mechanisms (Ahmad et al., 2014; Meiyanto, et 

al., 2008). 

 Burhan A. and Aisyah (2018), studied 

about the toxicity test of mulberry stem extract 

with various solvents, found that the IC50 

values for ethanol extract was 2.8045 μg / mL. 

http://dx.doi.org/10.24071/jpsc.001698


Jurnal Farmasi Sains dan Komunitas, 2019, 16(2), 63-67 

64  Asril Burhan et al. 

This result showed the potential of mulberry 

stems as anti-cancer.  

Based on all of those studies above, The 

aim of this study was to determine antioxidant 

activity by the method of ABTS (2,2′-

azinobis-(3-ethylbenzothiazoline-6-sulfonic 

acid) and to determine anti-cancer activity 

using WIDR cells and vero cells. 

 

METHODS 

Instrument 

UV-Vis spectrophotometer (Shimadzu®), 

ELISA reader (Thermo fischer Scientific®), 

rotary evaporator (Buchi®), microplate 

(Iwaki®).  

 

Materials  

MTT (3-(4,5-dimetiltiazol-2-il)-2,5-difenil 

tetrazolium bromida) (Sigma®), ABTS (2,2′-

azinobis-(3-ethylbenzothiazoline-6-sulfonic 

acid) (Merck®), n-hexane (Brataco Chemica®), 

ethanol (Onemed®), Follin-Cioucalteu 

(Merck®), Phosphate Buffer-Saline (PBS) 

(Gibco®), gallic acid (Sigma®), Sodium 

dodesil sulfat (SDS) (Merck®).  

 

Extraction of mulberry steam  

The preparation of the material begins 

with taking mulberry stems which is 60-90 

days old in The Mountainous Area of 

Sidenreng Rappang, South Sulawesi. 

Extraction was carried out by maceration 

method using ethanol solvent, then extract was 

applied with rotary evaporator until it got thick 

extract. 

 

Phytochemical screening  

Phytochemical screening includes 

examination of alkaloids, flavonoids, tannins, 

phenols and saponins. 

 

Quantitative testing of antioxidant activity 

using the ABTS method. Samples were made 

in series with concentrations of 40 ppm, 80 

ppm, 120 ppm, 160 ppm, each concentration 

mixed with ABTS solution and then let stand 

for 12 hours, then measured by UV-Vis 

spectrophotometry with a wavelength of 750 

nm, the comparison used in this experiment 

was vitamins C. Total phenol was tested using 

the UV-Vis spectrophotometer method with 

Follin-Cioucalteu reagent with a wavelength 

of 714 nm and gallic acid as a control. 

 

In Vitro Test of Anticancer Activity 

In vitro test of anticancer was carried out 

using WiDr cells and vero cells, cells were 

inserted into the wellplate, then the cells were 

incubated for 24 hours, after the cell was 

ready, the well plate was taken from the 

incubator then discarded the cell media, then 

inserted 100 μL PBS into the well cells have 

been filled, then discard PBS. The 

concentration of the sample was included in 

the well (triplo) then incubated in a 5% CO2 

incubator for 24 hours at 37ºC. The MTT 100 

μL reagent was added to the well. Cell 

suspension was incubated again for 2-4 hours 

in a CO2 incubator. SDS 100 μL was added 

when formazan was clearly formed, then 

wrapped in paper and stored overnight at room 

temperature in a dark place, the color intensity 

that occurred was read by ELISA reader at a 

wavelength of 595 nm. 

 

RESULTS AND DISCUSSION 

The extraction process was carried out by 

maceration using ethanol solvents with a yield 

value of 4.91%. The study which was carried 

out by Burhan A. and Aisyah (2018), showing 

the yield obtained in the extraction of 

mulberry stems in 3 solvents namely non-melt, 

ethyl 70% acetate and ethanol, ie 0.34%, 

0.859% and 1.51% of the yield obtained 

showed that the larger polar solvents produced 

yields, but with the amount of yield obtained 

not necessarily proportional to the quality of 

the extract obtained. 



Jurnal Farmasi Sains dan Komunitas, 2019, 16(2), 63-67 

Antioxidant and Anticancer Activities …  65 

Table I. Results of phytochemical screening of mulberry stem extract 

No. Compounds Result 

1 Alkaloid + 

2 Fenol + 

3 Flavanoid + 

4 Tanin - 

5 Saponin + 

 

Table II. Results of the antioxidant activity of stem extract using the ABTS method 

Sample 

concentrations 

(ppm) 

Absorbance % inhibition Probit IC50 

Value 

(ppm) 

Equation linear 

regression 

40 0.550 18.599 4.12  

83,18 

 

 

y = 2.8979x – 0.559 80 0.351 48.002 4.95 

120 0.270 60.089 5.25 

160 0.111 83.572 5.99 

Screening of phytochemical compounds 

aimed to determine the class of compounds 

contained in mulberry stem extracts. The 

results of phytochemical screening of 

mulberry stem extract can be seen in Table I. 

The results of phytochemical screening 

Mulberry stem extract showed that the plant 

contained flavonoid compounds, alkaloids, 

phenols and saponins. The presence of 

flavonoid compounds causes mulberry stem 

extract to have antioxidant potential. 

Flavonoid compounds have many hydroxyl 

(OH) groups, hydroxyl atoms can be donated 

to unstable radical compounds so that radical 

compounds can be stable, alkaloid compounds 

also have OH groups so that they can also 

donate to radical compounds as well as phenol 

compounds. 

Total phenolic test with quantitative test 

using spectrophotometric method with Folin–

Ciocalteu reagent and comparison of gallic 

acid. Gallic acid is used because gallic acid is 

a derivative of benzoate hydroxyl acid which 

is classified as simple phenolic acid and also 

as a stable and pure standard (Rahmawati, 

2009). From the total phenolic test, mulberry 

stem extract was obtained by 35.9%. 

According to several studies it is known that 

the phenolic component has high antioxidant 

activity, therefore to determine the potential of 

compounds that act as antioxidants from 

mulberry stem extract, activity tests were 

carried out using the ABTS method. 

Test for antioxidant activity using the 

ABTS method. Antioxidant activity testing 

using the ABTS method, antioxidant activity 

is known by looking at how much IC50 

produced by mulberry stem extract in reducing 

ABTS free radical compounds, IC50 shows 

50% reduction of free radicals, smaller the 

IC50 is obtained the greater the potential of the 

extract as an antioxidant. The comparison used 

is vitamin C as it is known that vitamin C is a 

compound that is used as one of the natural 

antioxidants. The result of antioxidant activity 

can be seen in Table II.  

Obtaining IC50 from the extract can be 

calculated using a linear regression equation. 

The results of IC50 obtained at 83.18 µg / mL. 

From the results of mulberry stem extract 

measurements IC50 results were 83.18 µg / 

mL, according to Blois (1985), a compound 

has a very strong antioxidant if the IC50 value 

is <50 ppm, strong if the IC50 is worth 50-100 

ppm, if the IC50 is worth 101-150 ppm, and 

weak if the IC50 is worth 151-200 ppm, 

according to the classification above the 

mulberry stem mulberry extract is in the 

strong category.  



Jurnal Farmasi Sains dan Komunitas, 2019, 16(2), 63-67 

66  Asril Burhan et al. 

 

Table III. Results of cytotoxic activity of mulberry stem extract on WiDr cancer cells and normal vero cells

Sample 

concentration 

(ppm) 

% death IC50 value (µg/ml) Equation linear regression 

WiDr 

cells 

vero 

cells 

WiDr 

cells 

vero 

cells 

WiDr cells vero cells 

7,8 22,90 1,73  

 

 

71,24 

 

 

 

 

154,24 

 y = 1,6724x + 1,9015 y = 1,4603x + 1,8045 

15,6 30,49 8,36 

31,2 36,08 18,30 

62,5 44,04 35,30 

125 58,41 43,84 

250 75,03 66,21 

500 93,45 70,21 

1000 97,66 88,35 

One way to prevent the formation of free 

radicals is to use nutrients that can act as 

antioxidants such as vitamin E, carotene, 

vitamin C and other drugs that can capture 

these free radicals. Free radicals are 

considered dangerous because they become 

very reactive in an effort to get an electron 

pair, the damage that can be caused by free 

radicals includes damage to cell membranes, 

proteins, DNA and lipids. The damage can 

cause various kinds of degenerative diseases, 

one of which is cancer (Auroma, 1994). To 

find out the anticancer activity in extracts 

there are various methods used, one of which 

is the MTT method. 

Anticancer activity test. Anticancer 

activity test using MTT method using WiDr 

cells and Vero cells. Anticancer activity is 

known by looking at IC50 values, IC50 

obtained using probit analysis, probit analysis 

is usually used to determine the response of 

the subject under study. The calculation results 

obtained in testing the anticancer activity of 

mulberry extract with WIDR cells and Vero 

cells can be seen in Table III. The toxicity test 

results of mulberry stem extract on WiDr cells 

and vero cells can be seen in Table II, showing 

IC50 values for WiDr cells 71,24 µg / ml and 

for vero cells having IC50 values 154,241 

µg/mL, toxic boundary determination of this 

study using National criteria Cancer Institute 

(NCI) 2009, stated that an extract was 

declared to have active activity having an IC50 

value <30 µg/mL, moderate active if it had an 

IC50 value ≥ 30 µg /mL and was said to be 

inactive if IC50> 100 µg /mL, from the 

calculation results IC50 value obtained from 

mulberry stem extract against WiDr cancer 

cells has a value of 71.24 µg/mL, the value 

obtained is in the moderate active range. In 

this study it was found that mulberry stem 

extract was moderate active, but did not work 

selectively because of the results of the 

selectivity comparison between WiDr cancer 

cells and vero cell 2.16. A chemotherapy agent 

is said to have a high selectivity if the SI value 

is ≥ 3, and is said to be less selective if the SI 

value is <3 (Rahmawaty, I, 2016).  

Compounds that are thought to play an 

anticancer role in mulberry plants are 

quercetin and anthocyanin which are potential 

substances as chemo preventive agents. The 

anthocyanin type which has the effect of being 

a chemo preventive agent is cyanidin-3-O-

glucoside. In vitro, cyanidin-3-O-glucoside is 

known to be able to reduce invasion of A549 

lung cancer cells and reduce cell motility 

(Chen, 2006) and quercetin is known to 

significantly inhibit HL-60 cell growth and 

can induce differentiation HL-60 cells to 

express CD 66B and CD 14 antigens (Kim et 

al., 2000). Quercetin is also known to be able 

to inhibit development, adhesion and 



Jurnal Farmasi Sains dan Komunitas, 2019, 16(2), 63-67 

Antioxidant and Anticancer Activities …  67 

migration of hela cells and can trigger 

apoptosis in hela cell cultures. 

CONCLUSION 

It can be concluded that mulberry stem 

extract has the value of total phenolic was 35.9 

%, while the value of antioxidant activity was 

83.18 µg / mL. The value of anticancer 

activity for WiDr cells IC50 value 71.24 µg / 

mL and for vero cells has IC50 value 154.241 

µg / mL. 

REFERENCES 

Ahmad, H., Suprianto, Marhamah, Rasmidar. 

2014. Aktivitas Antikanker dan 

Antiproliferasi fraksi etanol sarang 

semut (Myrmecodya pendans) pada 

sel kanker lidah manusia SP-C1. 

Dentofasial, Vol. 13(1), 1-6. 

Anam, S., Yuliet, Agus, R., Firmanita, D., 

Dewi, R., Muhammad, S.Z. 2014. 

Aktivitas Sitotoksik Ekstrak Metanol 

Benalu Batu (Begonia sp.): 

ethnomedicine Suku Wana Sulawesi 

Tengah. Jurnal Ilmu Kefarmasian 

Indonesia, Vol.12(1), 10-16. 

Arnoma O.I. 1994. Free radicals and 

antioxidant strategies in sports. J.Nutr 

Biochem. 

Blois, M.S. 1985. Antioxidant determinations 

by the use of a stable free radical. 

Nature, 181, 199-120. 

Burhan A., dan Aisyah N.A. 2018. Skrining 

fitokimia dan penentuan LC50 dengan 

metode BSLT (Brine Shrimp 

Lethality Test) ekstrak batang murbei 

(Morus alba l.) dengan variasi pelarut 

sebagai kandidat antikanker. Jurnal 

Ilmiah Pharmacy, 5(2), 159-167. 

Chen, P.N., 2006. Mulberry anthocyanins, 

cyanidin 3-rutinoside and cyanidin 3-

glucoside, exhibited an inhibitory 

effect on the migration and invasion 

of a human lung cancer cell line. 

Cancer Letter, 235(2), 248-259. 

Gupita, C.M dan Rahayuni, A. 2012. Pengaruh 

berbagai pH Sari Buah Dan Suhu 

Pasteurisasi Terhadap Aktivitas 

Antioksidan Dan Tingkat Penerimaan 

Sari Kulit Buah Manggis. Journal of 

Nutrition College, Vol. 1(1). 

Kim, S. Y., Gao J. J., Kang H. K. 2000. Two 

flavonoids from the leaves of Morus 

alba induce differentiation of the 

human promyelocytic leukemia (HL-

60) cell line.  Biol Pharm Bull. 

23(4),451-455. 

Kuntorini, E.M. and Astuti, M.D. 2010. 

Penentuan Aktivitas Antioksi dan 

Dari Ekstrak Etanol Bulbus Bawang 

Dayak. fmipa.unlam.ac.id/.../vol-4- 

No-1_pp,-15-22.pdf (acessed 09 01 

2017). 

Mallaleng, H.R., Purwaningtyas, U., 

Hermawati, R., Solichah, N., dan 

Syah, F.Z.N. 2011. Tanaman Obat 

untuk Penyakit Sindrom Metabolisme 

(Metabolic Syndrome Disease). 

Malang: Penerbit Universitas Negeri 

Malang (UM Press). 

Ministry of Health Republic of Indonesia. 

2016. Pusat data dan Informasi 

Kementerian Kesehatan RI. Kanker 

Payudara. Jakarta: Kemenkes RI. 

National Cancer Institute  (NCI). 2009. 

Measuring cancer death, Cited. 

(Online) (http://www.cancer.gov/csr), 

(acessed 21 05 2017). 

Rahmawaty, I. 2016.  Selektivitas Ekstrak 

Etanolik Buah Makassar (Brucea 

javanica) pada Kanker Payudara 

Metastasis secara In Vitro. 

Yogyakarta:Fakultas Farmasi UGM. 

 

http://www.cancer.gov/csr