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CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim 
Copyright © 2017, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-47-1; ISSN 2283-9216 

LD50 Estimations for Diabecine
TM Polyherbal Extracts Based

on In Vitro Diabetic Models of 3T3-L1, WRL-68 and 1.1B4 
Cell Lines 

Tet Soon Wonga, Zanariah Hashima, Razauden Mohamed Zulkiflib, Hassan Fahmi 
Ismaila, Siti Nurazwa Zainola, Nurul Sariyah Md Rajiba, Liam Chee Teha, Fadzilah 
Adibah Abdul Majid*c 
aDepartment of Bioprocess Engineering, Faculty of Chemical and Energy Engineering, Universiti Teknologi Malaysia, 81310 
 Skudai, Johor, Malaysia 
bDepartment of Biosciences and Health Sciences, Faculty of Biosciences and Medical Engineering, Universiti Teknologi 
 Malaysia, 81310 Skudai, Johor, Malaysia  
cInstitute of Marine Biotechnology, Universiti Malaysia Terengganu, 21030 Kuala Terengganu, Terengganu, Malaysia 
f.adibah@umt.edu.my

Safety data of newly developed active pharmaceutical ingredient is of regulatory requirement. The LD50 value 
is important to estimate the suitable dosage of extract for acute toxicity study and determine its safe dosage. 
LD50 estimations for aqueous and ethanol extracts of polyherbal Diabecine™ were determined due to its 
potential to be used as active ingredient in herbal supplement for diabetic patients. Diabecine™ is a 
proprietary herbal blend of Curcuma xanthorriza, Cinnamomum zeylanicum, Andrographis paniculata, 
Orthosiphon stamineus and Eugenia polyantha Wight traditionally used as herbal medicine for diabetes. The 
cytotoxicity towards three cell lines commonly used for in vitro diabetic study namely, 3T3-L1, WRL-68 and 
1.1B4, was determined in this study using MTT assay method. The IC50 values were determined and used to 
estimate LD50 values using ICCVAM’s regression formula: log LD50 (mg/kg) = 0.372 log IC50 (µg/mL) + 2.024. 
All the extracts showed non-toxic effects against 3T3-L1, WRL-68 and 1.1B4 cell lines at concentration of 0.5 
to 100 µg/mL, but significantly cytotoxic to all the three cell lines at concentration of 1,000 µg/mL and above. 
The IC50 values for 3T3-L1, 1.1B4 and WRL-68 are in the range of 493.8 to 779.6 µg/mL, 258.4 to 386.7 
µg/mL and 630.9 to 2,785 µg/mL. The 1.1B4 cell line was shown to have the highest cytotoxic sensitivity to the 
extracts. The IC50 values for 1.1B4 were used to estimate the LD50 values for ethanol freeze-dried, ethanol 
spray-dried, aqueous freeze-dried and aqueous spray-dried extracts, which are 956.4 mg/kg, 969.4 mg/kg, 
834.4 mg/kg and 880.4 mg/kg. The starting dose of each extracts for acute toxicity study could be 3.2 factors 
lower than the estimated LD50 values, which was suggested to be 298.9 mg/kg, 302.9 mg/kg, 260.8 mg/kg and 
275.1 mg/kg for ethanol freeze-dried, ethanol spray-dried, aqueous freeze-dried and aqueous spray-dried 
extracts. 

1. Introduction

Natural extracts from the plant is the oldest form of pharmaceutical treatment and are in growing demand 
worldwide (Fernández-Ponce et al., 2013). They are widely relied by populations due to their effectiveness, 
negligible side effects, wide range of action and relatively low cost (Chawla et al., 2013). Some of these 
phytochemicals which are abundant in fruits, vegetables, spices and teas have been consumed for centuries 
to treat hyperglycemic condition. Due to the fact that ‘natural’ doesn’t always mean safer and better compared 

to synthetically made medicine, there is a need to scientifically establish the efficacy and toxicity of these 
phytochemicals. 
Diabecine™ is a herbal supplement for diabetes, with proprietary herbal blend of Javanese turmeric (Curcuma 
xanthorriza), cinnamon (Cinnamomum zeylanicum), the king of bitters (Andrographis paniculata), Java tea 
(Orthosiphon stamineus) and Indonesian bay leaves (Eugenia polyantha Wight). There is no documented 

 

   

DOI: 10.3303/CET1756262

 
 
 
 
 

 

 

 
 
 
 
 
 
 
 
 

 
 
 
 

 

 
 
 

 

 

 

 

 

Please cite this article as: Wong T.S., Hashim Z., Zulkifli R.M., Ismail H.F., Zainol S.N., Rajib N.S.M., Teh L.C., Majid F.A.A., 2017, Ld50 
estimations for diabecinetm polyherbal extracts based on in vitro diabetic models of 3t3-l1, wrl-68 and 1.1b4 cell lines, Chemical Engineering 
Transactions, 56, 1567-1572  DOI:10.3303/CET1756262   

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scientific publication currently available to validate the effectiveness and safeness of Diabecine™ except from 

consumers’ testimonials. However, previous studies have shown the anti-diabetic activity of the crude extracts 
of C. xanthorriza (Adnyana et al., 2013), C. zeylanicum (Ranasinghe et al., 2012), A. paniculata (Zhang and 
Tan, 2000), O. stamineus (Sriplang et al., 2007), and E. polyantha (Studiawan and Santosa, 2005) on mice or 
rats. 
Although Diabecine™ is being used traditionally for more than 50 y to treat conditions related to diabetes 

especially to lower blood glucose, there is no safety data available for DiabecineTM. 
Determination of the inhibitory concentration that kills 50 % of the cells (IC50) using in vitro cytotoxicity study is 
one of the ways to estimate the starting dose for in vivo acute toxicity study. The IC50 values can be converted 
to estimate the lethal dose that kills 50 % of the animals (LD50) following the regression formula given by the 
Interagency Coordinating Committee on the Validation of Alternative Methods (ICCVAM): log LD50 (mg/kg) = 
0.372 log IC50 (µg/mL) + 2.024 (ICCVAM, 2006). According to the Organization for Economic Co-operation 
and Development (OECD) Guideline 425 (OECD, 2008), the starting dose is recommended to be 3.2 factors 
lower than the calculated LD50 value of each compound under investigation. The guideline also suggested 
using two specific cell lines, which are NHK and 3T3 for general cytotoxicity evaluations of chemicals. 
However, in this report, three cell lines commonly used for in vitro diabetes investigation were used. The cells 
are mouse pre-adipocytes (3T3-L1), human hepatocytes (WRL-68) and human pancreatic beta cells (1.1B4). 
3T3-L1 is a clonal subline isolated from 3T3 mouse embryonic fibroblasts and can be differentiated to 
adipocytes as they progress from a rapidly dividing to a confluent and contact inhibited state (Green and 
Meuth, 1974). WRL-68 cell line was derived from an unexpected spontaneous transformation when human 
embryo liver tissue was trypsinised and kept in Eagle's Minimum Essential Medium mixed with 10 % bovine 
serum at 37 °C for a few month (Apostolov, 1976). 1.1B4 cell line was established by electrofusion of freshly 
isolated human pancreatic beta cells with the immortal human PANC-1 epithelial cell line (McCluskey et al., 
2011). 
This study aims to estimate the suitable in vivo starting dose for acute toxicity study of four types of 
Diabecine’s polyherbal extracts, namely, i) ethanol polyherbal extract-freeze dried (EPH-FD), ii) ethanol 
polyherbal extract-spray dried (EPH-SD), iii) water polyherbal extract-freeze dried (WPH-FD) and iv) water 
polyherbal extract-spray dried (WPH-SD) using 3T3-L1, WRL-68 and 1.1B4 cell lines. A 3-(4,5-
dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay is used to measure the in vitro cytotoxic 
effects of these extracts on the cells. The IC50 values were converted to LD50 values based on the regression 
formula and the starting dose was calculated using the lowering factor of 3.2 from the LD50 estimation. 

2. Materials and Methods 

2.1 Cell lines and materials 

3T3-L1 mouse pre-adipocytes and WRL-68 human hepatocytes were purchased from American Type Culture 
Collection (ATCC, Manassas, USA) and 1.1B4 human pancreatic beta cells were purchased from the 
European Collection of Cell Cultures (ECACC, Salisbury, UK). Dulbecco’s Modified Eagle Medium (DMEM), 

Penicillin-Streptomycin (PS), feotal calf serum (FCS) and feotal bovine serum (FBS) were purchased from 
Gibco, Invitrogen. 3-(4, 5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) was purchased from 
Sigma-Aldrich (USA). Polyherbal Diabecine, in its raw coarsely ground mixture, was supplied by Naturemedic 
Supply, Malaysia. 

2.2 Plant material extraction and drying 

2.2.1 Water extraction method 

Approximately 1.5 kg of coarse herbs was soaked in 20 L of filtered water in jacketed vessel for 3 h and 
regularly stirred. The extract was collected by filtration process. After extraction process, the extract was ready 
to be dried. 

2.2.2 Ethanol extraction method 

Approximately 1.5 kg of coarse herbs was soaked in 20 L of 70 % food grade ethanol in jacketed vessel for 3 
h and regularly stirred. The extract was collected by filtration process. The weight of the wet herbs and volume 
of extraction was measured. The ethanol was eliminated by using rotary evaporator at 60 °C. After extraction 
process, the extract was ready to be dried. 

2.2.3 Spray drying method 

The condition of the inlet and outlet temperature was 185 °C and 108.5 °C. The extract was fed into the dryer 
by a peristaltic pump at flow rate of 15.0 g/min. The duration of drying was 9 h and 45 min. The dried powder 

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extracts were produced and stored in containers with tight caps at around 4 °C in the cold room until further 
analysis. 

2.2.4 Freeze drying method 

This method was used to remove the moisture from a frozen extract using vacuum. The extract was put in a 
freezer at -20 °C to produce a frozen extract. Then, the frozen extract was put into the drying chamber of the 
freeze dryer (Labconco). The equipment was set to -50 °C and vacuum pressure was applied to facilitate the 
removal of moisture content on the frozen extract. After the dried powder extract was produced, the powders 
were stored in containers with tight caps at around 4 °C in the cold room until further analysis. 

2.3 Cells culture maintenance 

3T3-L1 mouse pre-adipocytes, WRL-68 hepatocytes and 1.1B4 pancreatic beta cells were cultured and 
maintained based on protocol provided by depositor. 3T3-L1 and WRL-68 were grown in DMEM 
supplemented with 10 % feotal calf serum (FCS) and 10 % feotal bovine serum (FBS) with additional 1 % of 
antibiotic solution (100 units/mL penicillin and 0.1 g/L streptomycin) (PS) at 37 °C in a humidified atmosphere 
of 5 % CO2. 1.1B4 were cultured in RPMI-1640 medium supplemented with 10 % FBS and 1 % PS at 37 °C in 
a humidified atmosphere of 5 % CO2. Cells at exponential growth phase were used for experimental work. 

2.4 MTT assay 

The viability of 3T3-L1, WRL-68 and 1.1B4 cells in the presence of EPH-FD, EPH-SD, WPH-FD, and WPH-
SD extracts was measured using MTT assay according to the method of Mosmann (1983) and Twentyman 
and Luscombe (1987). At 80 - 90 % confluency, 3T3-L1, WRL-68 and 1.1B4 cells were suspended using 
routine sub-culture methods. 10,000 cells/well were seeded in 96-well plates and incubated at 37 °C under a 
humidified atmosphere of 5 % CO2 for 24 h. Next, cells were further incubated for another 24 h at 37 °C in the 
absence or presence of EPH-FD, EPH-SD, WPH-FD and WPH-SD extracts at various concentrations (0.5, 1, 
5 µg/mL, 10 µg/mL, 50 µg/mL, 100 µg/mL, 500 µg/mL, 1,000 µg/mL, 5,000 µg/mL and 10,000 µg/mL). 20 µL 
of MTT solution (5 mg in 1 mL PBS, sterile filtered) was added to each well. Plates were wrapped in 
aluminium foil and incubated for 4 h at 37 °C. Subsequently, the medium was gently aspirated from the wells 
and 200 µL of DMSO was added to each well and mixed thoroughly to dissolve the formazan crystals. The 
absorbance was immediately measured at 570 nm using the ELx800 Absorbance Microplate Reader (BioTek 
Instruments, USA). Samples were run in 6 replicates per plate. Wells without treatments were used as a 
control. 

2.5 IC50 calculation 

Median inhibitory concentrations (IC50) were statistically analysed by GraphPad Prism Version 6 software 
(GraphPad Software, 2016). Non-linear regressions of log (inihibitor) vs response with four parameters were 
selected for IC50 estimation. The bottom and top parameters were constrained to 0 % and 100 %. 

2.6 Estimation of LD50 based on in vitro IC50 value 

The in vivo LD50 of acute oral toxicity was estimated from in vitro IC50 by using the following formula: log LD50 
= 0.372 × log IC50 (µg/mL) + 2.024 (ICCVAM, 2006). 

2.7 Statistical analysis 

Results were expressed as mean ± standard error of the mean (SEM) of at least three independent 
experiments. Differences between treated samples and control were analysed using unpaired two-tailed 
Student’s t-test with correction for multiple comparisons using the Holm-Sidak method. Nonlinear regression 
analyses were used to calculate IC50 values and their 95 % confidence intervals. The IC50 values were 
compared with one another using the extra sum-of-squares F test. For all analyses, P-values < 0.05 were 
considered statistically significant and indicated with an asterisk (*) in the figures. 

3. Results and Discussions 

3.1 Diabecine polyherbal extracts effect on cells viability 

In the present study, cytotoxicity of Diabecine polyherbal extracts on 3T3-L1, 1.1B4 and WRL-68 cell lines was 
determined with the MTT assay (Figure 1). There were no significant differences (P > 0.05) in the viability of 
3T3-L1, 1.1B4 and WRL-68 cells after 24 h exposure of Diabecine polyherbal extracts from 1 - 100 µg/mL. 
However, the cells viability of the three cells types was significantly decreased (P < 0.05) when treated with 
concentration of 1,000 µg/mL of the extracts. WPH-FD extract was shown to significantly enhance proliferation 
of WRL-68 cells at 5 to 50 µg/mL via mechanisms yet unknown. 

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Figure 1: Viability of 3T3-L1, 1.1B4 and WRL-68 cells relative to vehicle control after treatment with Diabecine 

extracts at various concentrations for 24 h as determined by MTT assay 

The IC50 of EPH-FD, EPH-SD, WPH-FD and WPH-SD extracts on 3T3-L1, 1.1B4 and WRL-68 cells are listed 
in Table 1. As the MTT assay shows highest cytotoxic sensitivity in 1.1B4 cells (lowest IC50 values) compared 
to WRL-68 and 3T3-L1 cells after 24 h exposure to the Diabecine polyherbal extracts, the IC50 values for 
1.1B4 cells were chosen to estimate the LD50 values. 

Table 1:  IC50 values of Diabecine polyherbal extracts on 3T3-L1, 1.1B4 and WRL-68 cells 

Extracts  3T3-L1 1.1B4 WRL-68 
IC50 (µg/mL) 95 % CI (µg/mL) IC50 (µg/mL) 95 % CI (µg/mL) IC50 (µg/mL) 95 % CI (µg/mL) 

EPH-FD 493.8 192.5 – 1,267 372.9 274.4 – 506.8 2,785 2,343 – 3,311 
EPH-SD 779.6 225.1 – 2,699 386.7 312.9 – 477.8 1,948 1,324 – 2,866 
WPH-FD 501.5 103.2 – 2,436 258.4 164.5 – 406.0 630.9 319.3 – 1,247 
WPH-SD 716.3 326.8 – 1,570 298.5 211.1 – 422.2 2,059 1,746 – 2,960 

3.2 LD50 estimation for in vivo study based on in vitro IC50 data 

Using the regression formula: log LD50 = 0.372 × log IC50 (µg/mL) + 2.024, the LD50 values of rat were 
estimated from the IC50 values obtained from the in vitro cytotoxic MTT assay on 1.1B4 cells (Table 2). 
 

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Table 2:  Estimated LD50 values based on in vitro IC50 data on 1.1B4 cells 

Extracts  IC50 (µg/mL) LD50 (mg/kg) 
EPH-FD 372.9 956.4 
EPH-SD 386.7 969.4 
WPH-FD 258.4 834.4 
WPH-SD 298.5 880.4 
 
Toxicology testing of herbal formulated supplement is essential to estimate the safe dosage required for 
efficacy and efficiency study, optimisation of product and also to evaluate potential adverse effect. 
Assessment of in vitro toxicity assay and genotoxicity is undoubtedly important to measure toxicology effect at 
molecular levels. The liver plays multiple important roles, including detoxification of toxic substances (Grant, 
1991), production of biles for digestion of fats and in glucose homeostasis (Sherwin, 1980). The pancreatic 
beta cells play important role in the regulation of glucose homeostasis through synthesis and secretion of 
insulin, and its impairment leads to diabetes (Leibiger et al., 2008). Adipose tissue plays important role in lipid 
and glucose homeostasis, and its dysfunction leads to insulin resistance and type 2 diabetes (Guilherme et al., 
2008). Taking into account of these characteristics of liver, pancreatic beta cells and adipose tissue, 
cytotoxicity of Diabecine™ polyherbal extracts were assessed in vitro via MTT cell viability assay on WRL-68 
hepatocyte, 1.1B4 pancreatic beta cell and 3T3-L1 pre-adipocyte cell lines. As this assay suggested that 
exposure to concentrations of 100 µg/mL of the Diabecine™ polyherbal extracts are not cytotoxic towards 

WRL-68, 1.1B4 and 3T3-L1 cells, further in vitro studies on these cells with the extracts can be done at 100 
µg/mL and below. 
Traditionally, the safety of substances is determined through in vivo acute oral toxicity test by estimating the 
dose that produces lethality in 50 % of the animals tested (LD50) (Botham, 2004). According to the Interagency 
Coordinating Committee on the Validation of Alternative Methods (ICCVAM, 2006), the LD50 value of rat can 
be estimated from the IC50 value obtained from in vitro cytotoxicity assay, by using the regression formula 
described previously. This approach enables the estimation of a starting dose closer to the actual LD 50 value 
for in vivo acute oral toxicity studies. Hence, this will reduce the numbers of animals needed for range finding, 
as well as reduce the numbers of animals that die or need to be humanely killed. 
According to OECD Guideline 425 (OECD, 2008), the starting dose for acute oral toxicity study is 
recommended to be a step (factor 3.2 or one half log) below the estimated LD50 value. Based on the 
estimated LD50 values as shown in Table 2, the starting dose of each extracts for acute toxicity study was 
suggested to be 298.9 mg/kg, 302.9 mg/kg, 260.8 mg/kg and 275.1 mg/kg for EPH-FD, EPH-SD, WPH-FD 
and WPH-SD extracts. 
The limitation of this method on predicting the LD50 value for Diabecine polyherbal extracts is that the 
accuracy of correctly predicting the Globally Harmonized System of Classification and Labelling of Chemicals 
(GHS) acute oral toxicity classification category for the extracts could be around 30 % as reported on other 
substances tested in the validation study (ICCVAM, 2006). The low level of accuracy could be due to the 
differences between cell cultures and whole animals in regards to the absorption, distribution, availability, 
metabolism and excretion of tested compounds. 

4. Conclusion 

This study revealed that 1.1B4 pancreatic beta cells has the highest cytotoxic sensitivity to the Diabecine 
polyherbal extracts compared to WRL-68 hepatocyes and 3T3-L1 pre-adipocytes. The LD50 values for EPH-
FD, EPH-SD, WPH-FD and WPH-SD extracts were estimated to be 956.4 mg/kg, 969.4 mg/kg, 834.4 mg/kg 
and 880.4 mg/kg. The starting dose of each extracts was calculated to be 298.9 mg/kg, 302.9 mg/kg, 260.8 
mg/kg and 275.1 mg/kg for EPH-FD, EPH-SD, WPH-FD and WPH-SD extracts. 

Acknowledgments  

This study was supported by Research University Grant (RUG) of Universiti Teknologi Malaysia (Vot: 10H27), 
NKEA Research Grant Scheme (NRGS) from Ministry of Agriculture (MOA) (Vot: 4H016), Fundamental 
Research Grant Scheme (FRGS) from Ministry of Higher Education (MOHE) (Vot: 59424) and Proliv Life 
Sciences Sdn Bhd. 
 
 
 
 

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Reference  

Adnyana I.K., Yulinah E., Yuliet, Kurniati N.F., 2013, Antidiabetic activity of aqueous leaf extracts of Guazuma 
ulmifolia Lamk., ethanolic extracts of Curcuma xanthorrhiza and their combinations in alloxan-induced 
diabetic mice, Research Journal of Medicinal Plants 7, 158-164. 

Apostolov K., 1976, Cell Lines, US Patent 3935066. 
Botham P.A., 2004, Acute systemic toxicity—prospects for tiered testing strategies, Toxicology in Vitro 18, 

227-230. 
Chawla R., Thakur P., Chowdhry A., Jaiswal S., Sharma A., Goel R., Sharma J., Priyadarshi S., Kumar V., 

Sharma R., Arora R., 2013, Evidence based herbal drug standardization approach in coping with 
challenges of holistic management of diabetes: a dreadful lifestyle disorder of 21st century, Journal of 
Diabetes & Metabolic Disorders 12, 35. 

Fernández-Ponce M.T., Casas L., Mantell C., Martínez de la Ossa E.J., 2013, Potential use of mango leaves 
extracts obtained by high pressure technologies in cosmetic, pharmaceutics and food industries, Chemical 
Engineering Transactions 32, 1147-1152. 

GraphPad Software Inc., 2016, GraphPad Prism, California, United States. 
Grant D.M., 1991, Detoxification pathways in the liver, Journal of Inherited Metabolic Disease 14, 421-430. 
Green H., Meuth M., 1974, An established pre-adipose cell line and its differentiation in culture, Cell 3, 127-

133. 
Guilherme A., Virbasius J.V., Puri V., Czech M.P., 2008, Adipocyte dysfunctions linking obesity to insulin 

resistance and type 2 diabetes, Nature Reviews Molecular Cell Biology 9, 367-377. 
ICCVAM, 2006, ICCVAM Test Method Evaluation Report: In Vitro Cytotoxicity Test Methods for Estimating 

Starting Doses for Acute Oral Systemic Toxicity Tests, NIH Publication No. 07-4519, National Institute for 
Environmental Health Sciences, Research Triangle Park, North Carolina, United Stated. 

Leibiger I.B., Leibiger B., Berggren P.O., 2008, Insulin signaling in the pancreatic beta-cell, Annual Review of 
Nutrition 28, 233-251. 

McCluskey J.T., Hamid M., Guo-Parke H., McClenaghan N.H., Gomis R., Flatt P.R., 2011, Development and 
functional characterization of insulin-releasing human pancreatic beta cell lines produced by electrofusion, 
The Journal of Biological Chemistry 286, 21982-21992. 

Mosmann T., 1983, Rapid colorimetric assay for cellular growth and survival: application to proliferation and 
cytotoxicity assays, Journal of Immunological Methods 65, 55-63. 

OECD, 2008, Guideline for Testing of Chemicals, 425, Acute Oral Toxicity – Up-and-Down Procedure, 
Organization for Economic Co-operation and Development, Paris, France.  

Ranasinghe P., Perera S., Gunatilake M., Abeywardene E., Gunapala N., Premakumara S., Perera K., 
Lokuhetty D., Katulanda P., 2012, Effects of Cinnamomum zeylanicum (Ceylon cinnamon) on blood 
glucose and lipids in a diabetic and healthy rat model, Pharmacognosy Research 4, 73-79. 

Sherwin R.S., 1980, Role of liver in glucose homeostasis, Diabetes Care 3, 261-265. 
Sriplang K., Adisakwattana S., Rungsipipat A., Yibchok-Anun S., 2007, Effects of Orthosiphon stamineus 

aqueous extract on plasma glucose concentration and lipid profile in normal and streptozotocin-induced 
diabetic rats, Journal of Ethnopharmacology 109, 510-514. 

Studiawan H., Santosa M.H., 2005, Uji aktivitas penurun kadar glukosa darah ekstrak daun Eugenia polyantha 
pada mencit yang diinduksi aloksan, Media Kedokteran Hewan 21, 62-65. 

Twentyman P.R., Luscombe M., 1987, A study of some variables in a tetrazolium dye (MTT) based assay for 
cell growth and chemosensitivity, British Journal of Cancer 56, 279-285. 

Zhang X.F., Tan B.K., 2000, Anti-diabetic property of ethanolic extract of Andrographis paniculata in 
streptozotocin-diabetic rats, Acta Pharmacologica Sinica 21, 1157-1164. 

 

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