An optimization approach of dynamic maceration of <i>Centella asiatica</i> to obtain the highest content of four centelloids by response surface methodology

Monton, Chaowalit; Settharaksa, Sukanya; Luprasong, Chitradee; Songsak, Thanapat

doi:10.1016/j.bjp.2019.01.001

ABSTRACT

Centella asiatica (L.) Urb., Apiaceae, is commonly used as food, food supplement, and medicine. Development of the extraction process to obtain the high extent of the active compound is necessary. So, the response surface methodology was used in this work to optimize the dynamic maceration of C. asiatica to obtain the highest content of the four centelloids including asiatic acid, madecassic acid, asiaticoside, and madecassoside. Two factors: extraction temperature and extraction time, were studied. The content of four centelloids was observed. After the extraction of C. asiatica using ethanol, the content of four centelloids was analyzed using validated high performance liquid chromatography. The optimization result showed that madecassoside and asiaticoside had a similar pattern of the contour plots and response surfaces. These two centelloids were highly extracted at a high extraction time and high extraction temperature. The other two centelloids had the same pattern, they had a high content at a high temperature and time as well as at a low temperature and time. The simultaneous highest content of four centelloids was achieved when extracted at 60 °C for 120 min. The optimal condition could be used as standard condition for extraction of C. asiatica to provide the highest content of four centelloids.

Keywords:
Centelloids; Dynamic maceration; HPLC analysis; Optimization; Response surface methodology

Introduction

Centella asiatica (L.) Urb. is a plant in the family Apiaceae. It is an herbal medicinal plant which exhibits several biological and pharmacological activity including anti-ulcer (Sarma et al., 1995Sarma, D.N.K., Khosa, R.L., Chansauria, J.P.N., Sahai, M., 1995. Antiulcer activity of Tinospora cordifolia Miers and Centella asiatica Linn extracts. Phytother. Res. 9, 589-590.), antioxidation (Singh et al., 2014Singh, S., Singh, D.R., Banu, V.S.N.A., 2014. Functional constituents (micronutrients and phytochemicals) and antioxidant activity of Centella asiatica (L.) Urban leaves. Ind. Crops Prod. 61, 115-119.; Sultan et al., 2014Sultan, R.A., Mahmood, S.B.Z., Azhar, I., Ahmed, S.W., Mahmood, Z.A., 2014. Biological activities assessment of Centella asiatica (Linn.). J. Herbs Spices Med. Plants 20, 319-327.), antimicrobial (Ahmed et al., 2006Ahmed, K., Hossain, M.E., Mostafa, M., saha, B.K., Hossain, M.E., Begum, J., Roy, B.K., 2006. Antidiarrhoeal and antibacterial activities of Centella asiatica (L.) urban (Thankuni). Hamdard Med. 49, 12-18.; Oyedeji and Afolayan, 2005Oyedeji, O.A., Afolayan, A.J., 2005. Chemical composition and antibacterial activity of the essential oil of Centella asiatica growing in South Africa. Pharm. Biol. 43, 249-252.; Sultan et al., 2014Sultan, R.A., Mahmood, S.B.Z., Azhar, I., Ahmed, S.W., Mahmood, Z.A., 2014. Biological activities assessment of Centella asiatica (Linn.). J. Herbs Spices Med. Plants 20, 319-327.), anti-inflammation (Sultan et al., 2014Sultan, R.A., Mahmood, S.B.Z., Azhar, I., Ahmed, S.W., Mahmood, Z.A., 2014. Biological activities assessment of Centella asiatica (Linn.). J. Herbs Spices Med. Plants 20, 319-327.), analgesic (Sultan et al., 2014Sultan, R.A., Mahmood, S.B.Z., Azhar, I., Ahmed, S.W., Mahmood, Z.A., 2014. Biological activities assessment of Centella asiatica (Linn.). J. Herbs Spices Med. Plants 20, 319-327.), anti-hyperglycemic (Kabir et al., 2014Kabir, A.U., Samad, M.B., D'Costa, N.M., Akhter, F., Ahmed, A., Hannan, J., 2014. Anti-hyperglycemic activity of Centella asiatica is partly mediated by carbohydrase inhibition and glucose-fiber binding. BMC Complem. Altern. Med. 14, 31.), anti-diarrheal (Ahmed et al., 2006Ahmed, K., Hossain, M.E., Mostafa, M., saha, B.K., Hossain, M.E., Begum, J., Roy, B.K., 2006. Antidiarrhoeal and antibacterial activities of Centella asiatica (L.) urban (Thankuni). Hamdard Med. 49, 12-18.), wound healing (Azis et al., 2017Azis, H.A., Taher, M., Ahmed, A.S., Sulaiman, W.M.A.W., Susanti, D., Chowdhury, S.R., Zakaria, Z.A., 2017. In vitro and In vivo wound healing studies of methanolic fraction of Centella asiatica extract. S. Afr. J. Bot. 108, 163-174.; Ruszymah et al., 2012Ruszymah, B.H.I., Chowdhury, S.R., Manan, N.A.B.A., Fong, O.S., Adenan, M.I., Saim, A.B., 2012. Aqueous extract of Centella asiatica promotes corneal epithelium wound healing in vitro. J. Ethnopharmacol. 140, 333-338.; Saeidinia et al., 2017Saeidinia, A., Keihanian, F., Lashkari, A.P., Lahiji, H.G., Mobayyen, M., Heidarzade, A., Golchai, J., 2017. Partial-thickness burn wounds healing by topical treatment: a randomized controlled comparison between silver sulfadiazine and centiderm. Medicine 96, e6168.; Shetty et al., 2006Sultan, R.A., Mahmood, S.B.Z., Azhar, I., Ahmed, S.W., Mahmood, Z.A., 2014. Biological activities assessment of Centella asiatica (Linn.). J. Herbs Spices Med. Plants 20, 319-327.; Somboonwong et al., 2012Somboonwong, J., Kankaisre, M., Tantisira, B., Tantisira, M.H., 2012. Wound healing activities of different extracts of Centella asiatica in incision and burn wound models: an experimental animal study. BMC Complem. Altern. Med. 12, 103.; Suguna et al., 1996Suguna, L., Sivakumar, P., Chandrakasan, G., 1996. Effects of Centella asiatica extract on dermal wound healing in rats. Indian J. Exp. Biol. 34, 1208-1211.) etc. C. asiatica composed of several chemical constituents, while important chemical markers of C. asiatica were pentacyclic triterpenoids called centelloids such as madecassoside, asiaticoside, madecassic acid, and asiatic acid (Bylka et al., 2014Bylka, W., Znajdek-Awiżeń, P., Studzińska-Sroka, E., Dańczak-Pazdrowska, A., Brzezińska, M., 2014. Centella asiatica in dermatology: an overview. Phytother. Res. 28, 1117-1124.). There are formerly reported the wound healing activity of centelloids and C. asiatica extract. Tenni et al. (1988)Tenni, R., Zanaboni, G., De Agostini, M.P., Rossi, A., Bendotti, C., Cetta, G., 1988. Effect of the triterpenoid fraction of Centella asiatica on macromolecules of the connective matrix in human skin fibroblast cultures. Ital. J. Biochem. 37, 69-77. report that total triterpenoid fraction from C. asiatica can stimulate collagen and fibronectin production in human skin fibroblast. Maquart et al. (1990)Maquart, F.X., Bellon, G., Gillery, P., Wegrowski, Y., Borel, J.P., 1990. Stimulation of collagen synthesis in fibroblast cultures by a triterpene extracted from Centella asiatica. Connect. Tissue Res. 24, 107-120. report asiaticoside and Titrated Extract from C. asiatica (TECA) containing asiatic acid (30%), madecassic acid (30%), and asiaticoside (40%) stimulate collagen production in human foreskin fibroblast. Bonté et al. (1995)Bonté, F., Dumas, M., Chaudagne, C., Meybeck, A., 1995. Comparative activity of asiaticoside and madecassoside on type I and III collagen synthesis by cultured human fibroblasts. Ann. Pharm. Fr. 53, 38-42. report that asiaticoside and madecassoside stimulate type I collagen production in human fibroblast. In addition, madecassoside can stimulate type III collagen production as well. However, Lu et al. (2004a)Lu, L., Ying, K., Wei, S., Fang, Y., Liu, Y., Lin, H., Ma, L., Mao, Y., 2004. Asiaticoside induction for cell-cycle progression, proliferation and collagen synthesis in human dermal fibroblasts. Int. J. Dermatol. 43, 801-807. report asiaticoside increase both type I and type III collagen level in human dermal fibroblast. Furthermore, there are some studies that also explain about the stimulation of collagen production of C. asiatica extract (Bonte et al., 1994Bonte, F., Dumas, M., Chaudagne, C., Meybeck, A., 1994. Influence of asiatic acid, madecassic acid, and asiaticoside on human collagen I synthesis. Planta Med. 60, 133-135.; Nowwarote et al., 2013Nowwarote, N., Osathanon, T., Jitjaturunt, P., Manopattanasoontorn, S., Pavasant, P., 2013. Asiaticoside induces type I collagen synthesis and osteogenic differentiation in human periodontal ligament cells. Phytother. Res. 27, 457-462.). Other wound healing mechanisms of C. asiatica are also described, such as increase intracellular free proline in human foreskin fibroblasts (Maquart et al., 1990Maquart, F.X., Bellon, G., Gillery, P., Wegrowski, Y., Borel, J.P., 1990. Stimulation of collagen synthesis in fibroblast cultures by a triterpene extracted from Centella asiatica. Connect. Tissue Res. 24, 107-120.), changing of gene expression related to angiogenesis and wound healing (Coldren et al., 2003Coldren, C.D., Hashim, P., Ali, J.M., Oh, S.-K., Sinskey, A.J., Rha, C.K., 2003. Gene expression changes in the human fibroblast induced by Centella asiatica triterpenoids. Planta Med. 69, 725-732.), changing of gene related to cell proliferation, cell cycle, extracellular matrix synthesis (Lu et al., 2004aLu, L., Ying, K., Wei, S., Fang, Y., Liu, Y., Lin, H., Ma, L., Mao, Y., 2004. Asiaticoside induction for cell-cycle progression, proliferation and collagen synthesis in human dermal fibroblasts. Int. J. Dermatol. 43, 801-807.; Lu et al., 2004bLu, L., Ying, K., Wei, S., Liu, Y., Lin, H., Mao, Y., 2004. Dermal fibroblast-associated gene induction by asiaticoside shown in vitro by DNA microarray analysis. Br. J. Dermatol. 151, 571-578.), and increase migration and proliferation of fibroblast (Lee et al., 2012Lee, J.-H., Kim, H.-L., Lee, M.H., You, K.E., Kwon, B.-J., Seo, H.J., Park, J.-C., 2012. Asiaticoside enhances normal human skin cell migration, attachment and growth in vitro wound healing model. Phytomedicine 19, 1223-1227.).

In vivo studies show that it exhibits antioxidant activity (Liu et al., 2008Liu, M., Dai, Y., Li, Y., Luo, Y., Huang, F., Gong, Z., Meng, Q., 2008. Madecassoside isolated from Centella asiatica herbs facilitates burn wound healing in mice. Planta Med. 74, 809-815.; Shukla et al., 1999aShukla, A., Rasik, A.M., Dhawan, B.N., 1999. Asiaticoside-induced elevation of antioxidant levels in healing wounds. Phytother. Res. 13, 50-54., 1999bShukla, A., Rasik, A.M., Jain, G.K., Shankar, R., Kulshrestha, D.K., Dhawan, B.N., 1999. In vitro and in vivo wound healing activity of asiaticoside isolated from Centella asiatica. J. Ethnopharmacol. 65, 1-11.), increase hydroxyproline level (Maquart et al., 1999Maquart, F.X., Bellon, G., Gillery, P., Wegrowski, Y., Borel, J.P., 1990. Stimulation of collagen synthesis in fibroblast cultures by a triterpene extracted from Centella asiatica. Connect. Tissue Res. 24, 107-120.; Shetty et al., 2006Shetty, B.S., Udupa, S.L., Udupa, A.L., Somayaji, S.N., 2006. Effect of Centella asiatica L (Umbelliferae) on normal and dexamethasone-suppressed wound healing in Wistar albino rats. Int. J. Low. Extrem. Wounds 5, 137-143.; Shukla et al., 1999aShukla, A., Rasik, A.M., Dhawan, B.N., 1999. Asiaticoside-induced elevation of antioxidant levels in healing wounds. Phytother. Res. 13, 50-54.), increase tensile strength of the wound (Brinkhaus et al., 2000Brinkhaus, B., Lindner, M., Schuppan, D., Hahn, E.G., 2000. Chemical, pharmacological and clinical profile of the East Asian medical plant Centella asiatica. Phytomedicine 7, 427-448.; Shukla et al., 1999aShukla, A., Rasik, A.M., Dhawan, B.N., 1999. Asiaticoside-induced elevation of antioxidant levels in healing wounds. Phytother. Res. 13, 50-54.; Somboonwong et al., 2012Somboonwong, J., Kankaisre, M., Tantisira, B., Tantisira, M.H., 2012. Wound healing activities of different extracts of Centella asiatica in incision and burn wound models: an experimental animal study. BMC Complem. Altern. Med. 12, 103.; Sunilkumar et al., 1998Parameshwaraiah, S., Shivakumar, H.G., 1998. Evaluation of topical formulations of aqueous extract of Centella asiatica on open wounds in rats. Indian J. Exp. Biol. 36, 569-572.), increase dry weight, DNA, protein of the wound (Maquart et al., 1999Maquart, F.X., Chastang, F., Simeon, A., Birembaut, P., Gillery, P., Wegrowski, Y., 1999. Triterpenes from Centella asiatica stimulate extracellular matrix accumulation in rat experimental wounds. Eur. J. Dermatol. 9, 289-296.), increase collagen synthesis (Brinkhaus et al., 2000Brinkhaus, B., Lindner, M., Schuppan, D., Hahn, E.G., 2000. Chemical, pharmacological and clinical profile of the East Asian medical plant Centella asiatica. Phytomedicine 7, 427-448.; Liu et al., 2008Liu, M., Dai, Y., Li, Y., Luo, Y., Huang, F., Gong, Z., Meng, Q., 2008. Madecassoside isolated from Centella asiatica herbs facilitates burn wound healing in mice. Planta Med. 74, 809-815.; Maquart et al., 1999Maquart, F.X., Bellon, G., Gillery, P., Wegrowski, Y., Borel, J.P., 1990. Stimulation of collagen synthesis in fibroblast cultures by a triterpene extracted from Centella asiatica. Connect. Tissue Res. 24, 107-120.; Sunilkumar et al., 1998Parameshwaraiah, S., Shivakumar, H.G., 1998. Evaluation of topical formulations of aqueous extract of Centella asiatica on open wounds in rats. Indian J. Exp. Biol. 36, 569-572.), decrease scar tissue (Brinkhaus et al., 2000Brinkhaus, B., Lindner, M., Schuppan, D., Hahn, E.G., 2000. Chemical, pharmacological and clinical profile of the East Asian medical plant Centella asiatica. Phytomedicine 7, 427-448.), increase breaking strength, wet and dry granulation tissue (Shetty et al., 2006Shetty, B.S., Udupa, S.L., Udupa, A.L., Somayaji, S.N., 2006. Effect of Centella asiatica L (Umbelliferae) on normal and dexamethasone-suppressed wound healing in Wistar albino rats. Int. J. Low. Extrem. Wounds 5, 137-143.), increase epithelization (Shetty et al., 2006bShetty, B.S., Udupa, S.L., Udupa, A.L., Somayaji, S.N., 2006. Effect of Centella asiatica L (Umbelliferae) on normal and dexamethasone-suppressed wound healing in Wistar albino rats. Int. J. Low. Extrem. Wounds 5, 137-143.; Somboonwong et al., 2012Somboonwong, J., Kankaisre, M., Tantisira, B., Tantisira, M.H., 2012. Wound healing activities of different extracts of Centella asiatica in incision and burn wound models: an experimental animal study. BMC Complem. Altern. Med. 12, 103.), increase wound contraction (Shetty et al., 2006Shetty, B.S., Udupa, S.L., Udupa, A.L., Somayaji, S.N., 2006. Effect of Centella asiatica L (Umbelliferae) on normal and dexamethasone-suppressed wound healing in Wistar albino rats. Int. J. Low. Extrem. Wounds 5, 137-143.), increase angiogenesis (Kimura et al., 2008Kimura, Y., Sumiyoshi, M., Samukawa, K.-i., Satake, N., Sakanaka, M., 2008. Facilitating action of asiaticoside at low doses on burn wound repair and its mechanism. Eur. J. Pharmacol. 584, 415-423.; Liu et al., 2008Liu, M., Dai, Y., Li, Y., Luo, Y., Huang, F., Gong, Z., Meng, Q., 2008. Madecassoside isolated from Centella asiatica herbs facilitates burn wound healing in mice. Planta Med. 74, 809-815.), stimulation of the production of vascular endothelial growth factor, monocyte chemoattractant protein-1, interleukin-1 (Kimura et al., 2008Kimura, Y., Sumiyoshi, M., Samukawa, K.-i., Satake, N., Sakanaka, M., 2008. Facilitating action of asiaticoside at low doses on burn wound repair and its mechanism. Eur. J. Pharmacol. 584, 415-423.), and anti-inflammation (Wan et al., 2013Wan, J., Gong, X., Jiang, R., Zhang, Z., Zhang, L., 2013. Antipyretic and anti-inflammatory effects of asiaticoside in lipopolysaccharide-treated rat through up-regulation of heme oxygenase-1. Phytother. Res. 27, 1136-1142.).

The extraction method of plant raw material is an important step to yielding the high content of plant active compound that perhaps influence their activity. The aim of this work was to optimize the dynamic maceration of C. asiatica to obtain the highest content of the four centelloids i.e. madecassoside, asiaticoside, madecassic acid, and asiatic acid using response surface methodology. Furthermore, the high performance liquid chromatography (HPLC) method used for determination of four centelloids content was also validated to confirm the reliability of the analysis.

Materials and methods

Materials

Madecassoside was purchased from Sigma–Aldrich Inc., USA. Asiaticoside, madecassic acid, and asiatic acid were purchased from Chengdu Biopurify Phytochemicals Ltd., China. Solvents used as a mobile phase for HPLC analysis including acetonitrile and orthophosphoric acid were purchased from Honeywell-Burdick & Jackson, USA, and Carlo-Erba, France, respectively. Ultrapure water was produced in-house by Puris-Expe UP system, Korea. Ethanol (95%) was purchased from Samchai Chemical Co., Ltd., Thailand. The other chemicals were analytical grade.

Plant sample

Arial parts of Centella asiatica (L.) Urb., Apiaceae, were bought from the local market at Rangsit, Pathum Thani Province in March 2017, which C. asiatica originated from Sai Noi District, Nonthaburi Province. The plant sample was authenticated by Chair Prof. Dr. Nijsiri Ruangrungsi, Department of Pharmacognosy, College of Pharmacy, Rangsit University. A voucher specimen (CM-CA001-1-03-2017) was deposited at Drug and Herbal Product Research and Development Center, College of Pharmacy, Rangsit University.

Preparation and extraction of Centella asiatica

Arial parts of C. asiatica were cleaned and dried for 24 h at 50 °C. Dried C. asiatica was ground using a grinder and passed through a 60-mesh sieve. Dried C. asiatica powder (20 g) was extracted by 100 ml of 95% ethanol in 250-ml erlenmeyer flask using a water bath (WNB-14, Memmert, Germany) with agitation by shaker (SV 1422, Memmert, Germany). The extraction temperature and extraction time were set as the following specific condition (Table 1). After the extraction process, the filtrate was collected and the marc was re-extracted for two times with same solvent volume. The filtrates were pooled and dried in a vacuum condition by a rotary evaporator (Büchi Labortechnik AG, Switzerland) follow by drying in a hot air oven at 50 °C for 24 h. The yield of the extraction was reported as plant dry weight basis.

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Table 1
Model conditions of circumscribed central composite experimental design.

Response surface methodology

The circumscribed central composite experimental design was used in this work. Extraction temperature (X₁) and extraction time (X₂) were two investigated independent factors. Each factor was varied in five levels. Extraction temperatures were coded as −√2, −1, 0, 1, and √2 which the actual values were 40, 42.9, 50, 57.1, and 60 °C, respectively. Extraction times were also coded as similar as extraction temperature which the actual values were 60, 68.8, 90, 111.2, and 120 min, respectively.

The four dependent factors including madecassoside content (Y₁), asiaticoside content (Y₂), madecassic acid content (Y₃), and asiatic acid content (Y₄), were monitored. The individual centelloids content was predicted using Design-Expert^® software version 11 (Stat-Ease, Inc., USA) and quantified by HPLC. Contour plots and response surfaces of the model conditions were reported. The reliability of the estimation was confirmed by the correlation plot between the predicted value and the actual value. The coefficients and p-value of individual centelloids in different polynomial terms were reported. Finally, the mathematics model, the coded equation, and the actual value obtained from the optimal condition were also reported. Furthermore, the desirability function was used to select the optimal condition that provided the high content of four centelloids.

Determination of individual centelloids content

The HPLC method was used for analysis of individual centelloids content. The HPLC instrument (Agilent 1260 infinity, Agilent, USA) equipped with an autosampler and photodiode array detector was used in this work. The ACE C18-PFP column (250 × 4.6 mm, i.d., 5 µm) connected with C18 guard column was used for the separation with temperature controlled at 25 °C. The gradient system comprised of acetonitrile (A) and 0.01% phosphoric acid aqueous solution (B). The gradient elution went from 2.5 min of 20% A, increased to 37.5% A within 9.5 min, increased to 45% A within 3 min and holding for 10 min, and decreased to 20% A within 1 min and holding for 2 min before the next injection. The flow rate of the mobile phase was 1 ml/min. The injection volume was 20 µl. The signal was detected at 210 nm.

The extract with a concentration of 400 µg/ml was used in the analysis. The methanolic solution of the extract was filtered and injected into the HPLC instrument. The content of individual centelloids was calculated from the calibration curve of standard madecassoside, asiaticoside, madecassic acid, and asiatic acid. The mean and standard deviation (SD) of the content of individual centelloids were reported.

Method validation

Method validation was investigated based on the ICH guideline. Five topics were studied i.e. linearity and range, detection limit (DL) and quantitation limit (QL), specificity, precision, and accuracy.

Linearity and range

The mixed standard of madecassoside, asiaticoside, madecassic acid, and asiatic acid were dissolved in methanol to obtain the concentration of 1 mg/ml of each compound. Then, it was diluted to seven concentration levels from 0.78 to 50 µg/ml. They were filtered through a syringe filter with 0.45 µm pore size and injected into the HPLC instrument (n = 3). A calibration curve of each centelloids was constructed. The three parameters i.e. linear equation, coefficient of determination (R²), and test range were reported.

DL and QL

DL and QL were calculated from the slope of calibration curve of each centelloids and SD of y-intercepts of the regression lines. DL and QL were calculated as equations below:

DL = \frac{3.3 σ}{S}

QL = \frac{10 σ}{S}

where σ = the SD of y-intercepts of the regression lines

S = the slope of the calibration curve

Specificity

The UV spectrum at the upslope, top, and downslope of the peak of each centelloids in the extract were collected. The specificity was achieved when UV spectrums of the peak were similar for three regions and similar to the UV spectrum of standard centelloids.

Precision

The mixed standard of madecassoside, asiaticoside, madecassic acid, and asiatic acid in a concentration of 1.5625, 12.5, and 25 µg/ml were prepared. They were filtered through a syringe filter with 0.45 µm pore size and injected into the HPLC instrument (n = 3). The content of each centelloid was calculated to obtain the mean and SD value of each compound. The percent relative SD (%RSD) of the analysis in the same day and in three different days was reported as intraday precision and inter-day precision, respectively.

Accuracy

Accuracy was investigated using a spike technique. The mixed standard of madecassoside, asiaticoside, madecassic acid, and asiatic acid in a concentration of 1.5625, 12.5, and 25 µg/ml were added into C. asiatica extract with a known amount of each centelloids. They were filtered through a syringe filter with 0.45 µm pore size and injected into the HPLC instrument (n = 3). Percent recovery was reported.

Results and discussion

Validation of the HPLC method is an important step to ensure the reliability of the analysis. Previously, we published a research article related to the HPLC method validation to determine the content of two centelloids i.e. madecassoside and asiaticoside in herbal formulation (Monton et al., 2018Monton, C., Luprasong, C., Suksaeree, J., Songsak, T., 2018. Validated high performance liquid chromatography for simultaneous determination of stability of madecassoside and asiaticoside in film forming polymeric dispersions. Rev. Bras. Farmacogn. 28, 289-293.). Then, in this work we validated the HPLC method for simultaneous determination of four centelloids containing in the plant raw material. Method validation results of this work are shown in Tables 2 and 3. Results showed that the response of the analysis and concentration of the standard compounds had a good linear correlation (R² close to 1.0). The UV spectrum at the upslope, top, and downslope of the peak of each centelloid in the extract were similar to those of standard centelloids (data not shown), indicating the specific of the analysis. The precision and accuracy results are shown in Table 3. The precision of the analysis presented as percent RSD of intraday and inter-day was less than 2% and 5%, respectively, indicating that the analysis of all four centelloids was precise. Accuracy represented as percent recovery was 93.03–98.19%, 97.88–109.40%, 102.39–105.08%, and 93.30–107.01% for madecassoside, asiaticoside, madecassic acid, and asiatic acid, respectively.

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Table 2
Linearity parameters (linear equation and R ²), range, DL and QL of the analysis.

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Table 3
Precision and accuracy of the analysis.

Extraction yield and content of individual centelloids are shown in Table 4. Extraction of C. asiatica using 10 model conditions provided extraction yield of 2.20–5.20%. Ranges of each centelloids content found in this work were 0.473–0.949%, 0.096–0.193%, 0.017–0.039%, and 0.003–0.022% for madecassoside, asiaticoside, madecassic acid, and asiatic acid, respectively based on raw data. However, we mentioned that the extraction procedure used in this work was not exhausting extraction. Extraction yield in this work was lower than the previous report by Niamnuy et al., as they reported the extraction yield of 11.41–17.87% (Niamnuy et al., 2013Niamnuy, C., Charoenchaitrakool, M., Mayachiew, P., Devahastin, S., 2013. Bioactive compounds and bioactivities of Centella asiatica (L.) Urban prepared by different drying methods and conditions. Drying Technol. 31, 2007-2015.). Randriamampionona et al. (2007)Randriamampionona, D., Diallo, B., Rakotoniriana, F., Rabemanantsoa, C., Cheuk, K., Corbisier, A.-M., Mahillon, J., Ratsimamanga, S., El Jaziri, M., 2007. Comparative analysis of active constituents in Centella asiatica samples from Madagascar: application for ex situ conservation and clonal propagation. Fitoterapia 78, 482-489. showed C. asiatica in Madagascar contained madecassoside, asiaticoside, madecassic acid, and asiatic acid of 0.46–1.40%, 0.58–1.78%, not detect–0.29%, and 0.03–0.36%, respectively. James et al. (2008)James, J.T., Meyer, R., Dubery, I.A., 2008. Characterisation of two phenotypes of Centella asiatica in Southern Africa through the composition of four triterpenoids in callus, cell suspensions and leaves. Plant Cell Tissue Organ Cult. 94, 91-99. reported C. asiatica in Southern Africa had content of four centelloids of 2.76–3.62%, 3.13–3.68%, 0.11–0.59%, and 0.05–0.64%, respectively. Rafamantanana et al. (2009)Rafamantanana, M.H., Rozet, E., Raoelison, G.E., Cheuk, K., Ratsimamanga, S.U., Hubert, P., Quetin-Leclercq, J., 2009. An improved HPLC-UV method for the simultaneous quantification of triterpenic glycosides and aglycones in leaves of Centella asiatica (L.) Urb (APIACEAE). J. Chromatogr. B 877, 2396-2402. reported C. asiatica in Madagascar had content of four centelloids of 1.27–1.70%, 1.63–2.00%, not detect–0.95%, and not detect–0.98%, respectively. The variation of the centelloids content of C. asiatica was dependent on cultivation location and harvesting period which was investigated by Puttarak and Panichayupakaranant (2012)Puttarak, P., Panichayupakaranant, P., 2012. Factors affecting the content of pentacyclic triterpenes in Centella asiatica raw materials. Pharm. Biol. 50, 1508-1512.. Furthermore, Niamnuy et al. (2013)Niamnuy, C., Charoenchaitrakool, M., Mayachiew, P., Devahastin, S., 2013. Bioactive compounds and bioactivities of Centella asiatica (L.) Urban prepared by different drying methods and conditions. Drying Technol. 31, 2007-2015. reported C. asiatica from Pathum Thani Province, Thailand had a summation of the content of asiaticoside and asiatic acid higher than those of madecassoside and madecassic acid. However, our work found that summation of the content of asiaticoside and asiatic acid was lower than those of madecassoside and madecassic acid.

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Table 4
Extraction yield and content of individual centelloids of model conditions.

Fig. 1 shows contour plots and response surfaces of the model conditions of four centelloids content. Results showed similar contour plots and response surfaces between madecassoside and asiaticoside, while madecassic acid had a similar pattern to asiatic acid. In case of madecassoside and asiaticoside, extraction temperature and extraction time had a positive effect on their content. Increasing of extraction temperature or extraction time, the content of madecassoside and asiaticoside was increased. The mathematics model of the model conditions of madecassoside and asiaticoside were fitted to the quadratic model. According to madecassic acid and asiatic acid, high content of these two centelloids achieved at two conditions: low extraction temperature with low extraction time as well as high extraction temperature with high extraction time. The mathematics model of the model conditions of madecassic acid and asiatic acid were fitted to 2 factor interaction (2FI) model. The correlation plots between the predicted and actual value of the model conditions of madecassoside, asiaticoside, madecassic acid, and asiatic acid are shown in Fig. 2. This result could be used to confirm the reliability of the prediction (Duangjit et al., 2012Duangjit, S., Obata, Y., Sano, H., Kikuchi, S., Onuki, Y., Opanasopit, P., Ngawhirunpat, T., Maitani, Y., Takayama, K., 2012. Menthosomes, novel ultradeformable vesicles for transdermal drug delivery: optimization and characterization. Biol. Pharm. Bull. 35, 1720-1728., 2014aDuangjit, S., Mehr, L.M., Kumpugdee-Vollrath, M., Ngawhirunpat, T., 2014. Role of simplex lattice statistical design in the formulation and optimization of microemulsions for transdermal delivery. Biol. Pharm. Bull. 37, 1948-1957., 2014bDuangjit, S., Pamornpathomkul, B., Opanasopit, P., Rojanarata, T., Obata, Y., Takayama, K., Ngawhirunpat, T., 2014. Role of the charge, carbon chain length, and content of surfactant on the skin penetration of meloxicam-loaded liposomes. Int. J. Nanomed. 9, 2005-2017.). The significant correlation between predicted and actual value of model conditions of four centelloids (p < 0.05) with relatively high R² for madecassoside and asiaticoside and moderate R² for madecassic acid and asiatic acid was observed in this work. However, correlation plots of the model conditions and R² of madecassic acid and asiatic acid indicated poor fitting between predicted and actual value. The assumption of this occurrence was degradation of madecassoside and asiaticoside into madecassic acid and asiatic acid during the extraction process, respectively. Puttarak et al. (2016)Puttarak, P., Brantner, A., Panichayupakaranant, P., 2016. Biological activities and stability of a standardized pentacyclic triterpene enriched Centella asiatica extract. Nat. Prod. Sci. 22, 20-24. revealed that glycoside form of centelloids were less stable in alkaline pH and accelerated condition compared to aglycone form. In our work, C. asiatica was extracted at high temperature in some condition with slightly alkaline pH of the solvent (approximately 8.0). The extraction condition might induce the degradation of both madecassoside and asiaticoside, so the content of analyzed madecassic acid and asiatic acid could be varied from madecassic acid and asiatic acid composed in C. asiatica in their nature with additional degradation of both madecassoside and asiaticoside during the extraction process.

Fig. 1
Contour plots (left) and response surfaces (right) of the model conditions of the content of (a) madecassoside, (b) asiaticoside, (c) madecassic acid, and (d) asiatic acid.

Fig. 2
The correlation plots between predicted vs actual value of model conditions of the content of (a) madecassoside, (b) asiaticoside, (c) madecassic acid, and (d) asiatic acid.

Table 5 shows the term of the significant model, regression coefficient, and p-value for the independent variable. According to the madecassoside and asiaticoside, p-value less than 0.05 indicated model terms are significant. In this case, X₁, X₂, X₁ X₂, X₁ ² were significant model terms. The Lack of Fit was not significant relative to the pure error, which non-significant Lack of Fit was good because we want the model to fit. In case of madecassic acid, X₁ and X₁ X₂ were significant model terms. Furthermore, X₁ X₂ was a significant model term for asiatic acid. The Lack of Fit is also significant for both madecassic acid and asiatic acid. These results indicated that the model could be affect by the pure error. The Lack of Fit data was related to the result of the correlation plots between the predicted and actual value of the model conditions above. Furthermore, the multiple regression analysis was investigated and adjusted R² was reported as an indicator of the suitability of each linear regression equation to estimate the coefficient of the determination (Duangjit and Kraisit, 2018Duangjit, S., Kraisit, P., 2018. Optimization of orodispersible and conventional tablets using simplex lattice design: relationship among excipients and banana extract. Carbohydr. Polym. 193, 89-98.). The predicted R² of four centelloids was in reasonable agreement with the adjusted R² because of the difference between two data less than 0.2. In addition, adequate precision measures the signal to noise ratio, a ratio greater than 4 was desirable for four centelloids.

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Table 5
The term of the significant model, regression coefficient, and p-value for the independent variable.

As the coefficient value in Table 5, the coded equations used for estimation of the content of four centelloids could show as the equation in Table 6. According to these equations, extraction temperature and extraction time play a positive effect on the content of four centelloids, except extraction temperature had a negative effect on asiatic acid content. Extraction temperature and extraction time affected the content of chemical constituents in the extract which was reported in previous reports. The high content of phenolic compound, flavonoid, and condensed tannins of C. asiatica was achieved when temperature increased. But, the extraction time had the optimum value due to prolongation of extraction time possibly decomposed of plant chemical compounds (Chew et al., 2011Chew, K.K., Ng, S.Y., Thoo, Y.Y., Khoo, M.Z., Aida, W.M.W., Ho, C.W., 2011. Effect of ethanol concentration, extraction time and extraction temperature on the recovery of phenolic compounds and antioxidant capacity of Centella asiatica extracts. Int. Food Res. J. 18, 571-578.). The effect of extraction temperature and extraction time was also reported in the extraction of other plants. Lv et al. (2005)Lv, W.F., Ding, M.Y., Zheng, R., 2005. Isolation and quantitation of amygdalin in Apricot-kernel and Prunus tomentosa Thunb. by HPLC with solid-phase extraction. J. Chromatogr. Sci. 43, 383-387. investigated the effect of extraction temperature and extraction time on the content of amygdalin of Apricot-kernel and Prunus tomentosa Thunb. using reflux extraction. The content of amygdalin increased when temperature and duration time was increased. After the maximum content reached, amygdalin content gradually decomposed. The longer extraction time leads to thermal instability and degradation of plant compound, which was reported in other publications. Polysaccharides from Hovenia dulcis peduncles degraded when longer extraction time was used (Liu et al., 2015Liu, Y., Qiang, M., Sun, Z., Du, Y., 2015. Optimization of ultrasonic extraction of polysaccharides from Hovenia dulcis peduncles and their antioxidant potential. Int. J. Biol. Macromol. 80, 350-357.) as well as polysaccharide from Angelica sinensis (Tian et al., 2017Tian, S., Hao, C., Xu, G., Yang, J., Sun, R., 2017. Optimization conditions for extracting polysaccharide from Angelica sinensis and its antioxidant activities. J. Food Drug Anal. 25, 766-775.). Furthermore, the higher extraction temperature and extraction time lead to degradation of Astragalus cicer polysaccharides (Shang et al., 2018Shang, H., Wang, M., Li, R., Duan, M., Wu, H., Zhou, H., 2018. Extraction condition optimization and effects of drying methods on physicochemical properties and antioxidant activities of polysaccharides from Astragalus cicer L. Sci. Rep. 8, 3359.), Tricholoma mongolicum polysaccharides (Wang et al., 2015Wang, J., Zhao, Y., Li, W., Wang, Z., Shen, L., 2015. Optimization of polysaccharides extraction from Tricholoma mongolicum Imai and their antioxidant and antiproliferative activities. Carbohydr. Polym. 131, 322-330.), and mulberry fruit polysaccharides (Chen et al., 2015Chen, C., You, L.-J., Abbasi, A.M., Fu, X., Liu, R.H., 2015. Optimization for ultrasound extraction of polysaccharides from mulberry fruits with antioxidant and hyperglycemic activity in vitro. Carbohydr. Polym. 130, 122-132.). In case of pectin isolated from sugar beet pulp, when pH of the extraction medium was constant, extraction time had a greater effect on pectin yield compared to extraction temperature (Yapo et al., 2007Yapo, B.M., Robert, C., Etienne, I., Wathelet, B., Paquot, M., 2007. Effect of extraction conditions on the yield, purity and surface properties of sugar beet pulp pectin extracts. Food Chem. 100, 1356-1364.). Vergara-Salinas et al. (2012)Vergara-Salinas, J.R., Perez-Jimenez, J., Torres, J.L., Agosin, E., Perez-Correa, J.R., 2012. Effects of temperature and time on polyphenolic content and antioxidant activity in the pressurized hot water extraction of deodorized thyme (Thymus vulgaris). J. Agric. Food Chem. 60, 10920-10929. studied the effect of temperature (50–200 °C) and time (5–30 min) on the polyphenolic content of deodorized thyme (Thymus vulgaris) using pressurized hot water extraction. They found that the content of polyphenols was diverse in different extraction temperature and extraction time. The maximum yield of polyphenols i.e. hydroxycinnamic acids, flavones, flavonols/flavanones, and total polyphenols achieved at 100 °C and 5 min. The higher extraction temperature and longer extraction time could reduce the diversity of polyphenols. The 3,4-dihydroxyphenyllactic acid was the only phenolic compounds that mostly extracted at high temperature. However, the nonphenolic antioxidant was favored at the higher extraction temperature and extraction time. Dent et al. (2013)Dent, M., Dragović-Uzelac, V., Penić, M., Brnčić, M., Bosiljkov, T., Levaj, B., 2013. The effect of extraction solvents, temperature and time on the composition and mass fraction of polyphenols in Dalmatian wild sage (Salvia officinalis L.) extracts. Food Technol. Biotechnol. 51, 84-91. established extraction temperature had a positive effect on mass fractions of sage (Salvia officinalis) total polyphenols, rosmarinic acid, and luteolin-3-glucuronide, while extraction time had a positive effect only on mass fractions of luteolin-3-glucuronide. Ultrasound-assisted extraction of rosmarinic acid and caffeic acid from Apeiba tibourbou showed that extraction time had a significant effect, while extraction temperature had a non-significant effect on both rosmarinic acid and caffeic acid (Martins and da Conceicao, 2015Martins, F.S., da Conceicao, E.C., 2015. Evaluation of extraction method on the chemical composition in Apeiba tibourbou Aubl's extracts. Pharmacogn. Mag. 11, 368-373.). Kuzmanović et al. (2015)Kuzmanović, M., Tišma, M., Bucić-Kojić, A., Casazza, A.A., Paini, M., Aliakbarian, B., Perego, P., 2015. High-pressure and temperature extraction of phenolic compounds from corn silage. Chem. Eng. Trans. 43, 133-138. using high temperature and high pressure reactor to extract the phenolic compound from corn silage. They varied extraction temperature, extraction time, etc. The optimization results showed that temperature was the most significant factor affecting phenolic compound content. These above results indicated that optimal temperature and time of the extraction should be optimized to obtain the maximum content of plant compounds that might affect their biological and pharmacological activity.

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Table 6
Mathematics model and coded equation of the model conditions.

Optimal condition provided the simultaneous highest content of four centelloids was extraction temperature of 60 °C and extraction time of 120 min with desirability value of 0.980. The predicted values and actual values of the content of four centelloids predicted follow the optimal condition, percent error, and the range of 95% CI are shown in Table 7. The C. asiatica extracted follow the optimal condition provided the content of madecassoside, asiaticoside, madecassic acid, and asiatic acid of 0.855%, 0.174%, 0.053%, and 0.025%, respectively (Table 7). The actual values of the four centelloids were slightly different from the predicted value, however, they were still within 95% CI. These results indicated that the prediction by the computer software was accurate.

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Table 7
Predicted value, actual value, percent error, and range of 95% CI.

Conclusions

The response surface methodology could be used to optimize the dynamic maceration of C. asiatica to obtain the simultaneous high of four centelloids content with the reliable result. The simultaneous high content of madecassoside, asiaticoside, madecassic acid, and asiatic acid achieved when extraction was at 60 °C for 120 min. The contents of these four centelloids analyzed by validated HPLC were 0.855%, 0.174%, 0.053%, and 0.025%, respectively. This optimal condition could be used as a standard condition for extraction of C. asiatica to provide the highest content of four centelloids.

Acknowledgements

The authors would like to acknowledge the College of Pharmacy, Rangsit University for research facilities. We would like to thank Mr. Chaiyaporn Songsangsirisak and Ms. Niratcha Chuenwiset for research assistance. We also thank Edward Devere Bacon for editing the English language in this paper with the supporting of Research Institute of Rangsit University.

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Publication Dates

Publication in this collection
27 May 2019
Date of issue
Mar-Apr 2019

History

Received
10 Sept 2018
Accepted
10 Jan 2019
Published
30 Jan 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] Ahmed, K., Hossain, M.E., Mostafa, M., saha, B.K., Hossain, M.E., Begum, J., Roy, B.K., 2006. Antidiarrhoeal and antibacterial activities of Centella asiatica (L.) urban (Thankuni). Hamdard Med. 49, 12-18.

[2] Azis, H.A., Taher, M., Ahmed, A.S., Sulaiman, W.M.A.W., Susanti, D., Chowdhury, S.R., Zakaria, Z.A., 2017. In vitro and In vivo wound healing studies of methanolic fraction of Centella asiatica extract. S. Afr. J. Bot. 108, 163-174.

[3] Bonte, F., Dumas, M., Chaudagne, C., Meybeck, A., 1994. Influence of asiatic acid, madecassic acid, and asiaticoside on human collagen I synthesis. Planta Med. 60, 133-135.

[4] Bonté, F., Dumas, M., Chaudagne, C., Meybeck, A., 1995. Comparative activity of asiaticoside and madecassoside on type I and III collagen synthesis by cultured human fibroblasts. Ann. Pharm. Fr. 53, 38-42.

[5] Brinkhaus, B., Lindner, M., Schuppan, D., Hahn, E.G., 2000. Chemical, pharmacological and clinical profile of the East Asian medical plant Centella asiatica Phytomedicine 7, 427-448.

[6] Bylka, W., Znajdek-Awiżeń, P., Studzińska-Sroka, E., Dańczak-Pazdrowska, A., Brzezińska, M., 2014. Centella asiatica in dermatology: an overview. Phytother. Res. 28, 1117-1124.

[7] Chen, C., You, L.-J., Abbasi, A.M., Fu, X., Liu, R.H., 2015. Optimization for ultrasound extraction of polysaccharides from mulberry fruits with antioxidant and hyperglycemic activity in vitro. Carbohydr. Polym. 130, 122-132.

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Compounds	Equation	R ²	Range (µg/ml)	DL (µg/ml)	QL (µg/ml)
Madecassoside	$y = 3922.5 x + 1354.7$	0.9999	0.78-50	0.21	0.61
Asiaticoside	$y = 5199.6 x + 1398.3$	0.9999	0.78-50	0.20	0.60
Madecassic acid	$y = 16018 x + 2342.6$	0.9999	0.78-50	0.19	0.59
Asiatic acid	$y = 22659 x + 5060.4$	0.9998	0.78-50	0.22	0.65

Compounds	Conc. (µg/ml)	Precision (%RSD)		Spike amount (µg/ml)	Accuracy
		Intraday	Inter-day		Recovery (%)
Madecassoside	1.5625	1.47	2.22	1.5625	93.68 ± 0.72
	12.5	0.33	1.41	12.5	93.03 ± 0.44
	25	0.45	0.98	25	98.19 ± 0.04
Asiaticoside	1.5625	0.84	1.87	1.5625	109.40 ± 1.64
	12.5	0.15	1.36	12.5	97.88 ± 2.55
	25	0.16	0.91	25	98.74 ± 3.11
Madecassic acid	1.5625	0.66	2.20	1.5625	105.08 ± 0.55
	12.5	1.05	0.62	12.5	102.39 ± 0.08
	25	1.07	1.18	25	104.91 ± 0.04
Asiatic acid	1.5625	0.15	1.76	1.5625	93.30 ± 0.36
	12.5	0.18	0.64	12.5	104.66 ± 0.10
	25	0.06	0.52	25	107.01 ± 0.06

Condition	Yield (%w/w)	Content (%w/w)
		Madecassoside	Asiaticoside	Madecassic acid	Asiatic acid
1	3.30	0.475 ± 0.002	0.096 ± 0.001	0.039 ± 0.000	0.022 ± 0.000
2	4.55	0.818 ± 0.004	0.166 ± 0.001	0.028 ± 0.000	0.005 ± 0.001
3	3.25	0.810 ± 0.017	0.156 ± 0.002	0.025 ± 0.000	0.008 ± 0.000
4	5.20	0.904 ± 0.006	0.182 ± 0.001	0.037 ± 0.000	0.014 ± 0.000
5	3.20	0.661 ± 0.060	0.151 ± 0.016	0.020 ± 0.001	0.005 ± 0.001
6	4.65	0.941 ± 0.005	0.192 ± 0.000	0.034 ± 0.000	0.008 ± 0.001
7	2.20	0.617 ± 0.052	0.127 ± 0.013	0.018 ± 0.001	0.007 ± 0.000
8	3.75	0.856 ± 0.080	0.169 ± 0.018	0.034 ± 0.002	0.011 ± 0.001
9	2.30	0.623 ± 0.059	0.122 ± 0.013	0.020 ± 0.001	0.006 ± 0.001
10	2.90	0.743 ± 0.002	0.151 ± 0.000	0.032 ± 0.000	0.012 ± 0.000

Polynomial term	Madecassoside		Asiaticoside		Madecassic acid		Asiatic acid
	Coefficient	p-value	Coefficient	p-value	Coefficient	p-value	Coefficient	p-value
Model	-	<0.0001^a a Significant value.	-	<0.0001^a a Significant value.	-	0.0020^a a Significant value.	-	0.0003^a a Significant value.
Intercept	0.6833	-	0.1364	-	0.0286	-	-.0097	-
X₁: temp.	0.1041	<0.0001^a a Significant value.	0.0192	<0.0001^a a Significant value.	0.0026	0.0384^a a Significant value.	-0.0008	0.3373
X₂: time	0.0947	<0.0001^a a Significant value.	0.0168	<0.0001^a a Significant value.	0.0022	0.0770	0.0001	0.8674
X ₁ X ₂	-0.0624	0.0002^a a Significant value.	-0.0109	0.0096^a a Significant value.	0.0058	0.0024^a a Significant value.	0.0056	<0.0001^a a Significant value.
X ₁ ²	0.0547	0.0005^a a Significant value.	0.0153	0.0003^a a Significant value.	-	-	-	-
X ₂ ²	0.0224	0.1086	0.0034	0.3596	-	-	-	-
R ²	0.9042	-	0.8252	-	0.4278	-	0.5101	-
Adjusted R²	0.8843	-	0.7888	-	0.3618	-	0.4536	-
Predicted R²	0.8543	-	0.7315	-	0.2376	-	0.3401	-
Adequate precision	19.7686	-	14.3129	-	7.7524	-	9.1687
Lack of Fit	-	0.6034	-	0.0675	-	<0.0001^a a Significant value.	-	<0.0001^a a Significant value.

Compound	Model	Coded equation
Madecassoside	Quadratic	$Y_{1} = 0.6833 + 0.1041 (X_{1}) + 0.0947 (X_{2}) - 0.0624 (X_{1}) (X_{2}) + 0.0547 {(X_{1})}^{2} + 0.0224 {(X_{2})}^{2}$
Asiaticoside	Quadratic	$Y_{2} = 0.1364 + 0.0192 (X_{1}) + 0.0168 (X_{2}) - 0.0109 (X_{1}) (X_{2}) + 0.0153 {(X_{1})}^{2} + 0.0034 {(X_{2})}^{2}$
Madecassic acid	2FI	$Y_{3} = 0.0286 + 0.0026 (X_{1}) + 0.0022 (X_{2}) + 0.0058 (X_{1}) (X_{2})$
Asiatic acid	2FI	$Y_{4} = 0.0097 - 0.0008 (X_{1}) + 0.0001 (X_{2}) + 0.0056 (X_{1}) (X_{2})$

Brasil

Brasil

An optimization approach of dynamic maceration of Centella asiatica to obtain the highest content of four centelloids by response surface methodology

ABSTRACT

Introduction

Materials and methods

Materials

Plant sample

Preparation and extraction of Centella asiatica

Response surface methodology

Determination of individual centelloids content

Method validation

Linearity and range

DL and QL

Specificity

Precision

Accuracy

Results and discussion

Conclusions

Acknowledgements

References

Publication Dates

History

Factor	Condition
	1	2	3	4	5	6	7	8	9	10
X ₁ ^a a X1 was extraction temperature; -√2 = 40 °C, -1 = 42.9 °C, 0 = 50 °C, 1 = 57.1 °C, and √2 = 60 °C.	-1	1	-1	1	-√2	√2	0	0	0	0
X ₂ ^b b X2 was extraction time; -√2 = 60 min, -1 = 68.8 min, 0 = 90 min, 1 = 111.2 min, and √2 = 120 min.	-1	-1	1	1	0	0	-√2	√2	0	0

Response	Predicted value (%w/w)	Actual value (%w/w)	Error (%)^a a %Error = (actual value - predicted value) × 100/actual value.	95% CI (lower-upper)
Y ₁	0.993	0.855 ± 0.0005	-16.1	0.854-1.132
Y ₂	0.203	0.174 ± 0.0001	-16.7	0.165-0.240
Y ₃	0.047	0.053 ± 0.0001	11.3	0.032-0.062
Y ₄	0.020	0.025 ± 0.0003	20.0	0.010-0.030