Journal of Applied Botany and Food Quality 90, 205 - 213 (2017), DOI:10.5073/JABFQ.2017.090.026 1Dipartimento di Scienze Agrarie, Forestali e Alimentari, Università degli Studi di Torino, Torino, Italy 2Mention Agriculture Tropicale et Développement Durable - Ecole Supérieure des Sciences Agronomiques, Université d’Antananarivo, Antananarivo, Madagascar 3Dipartimento di Scienze della Vita e Biologia dei Sistemi, Università degli Studi di Torino, Torino, Italy Biodiversity and traditional medicinal plants from Madagascar: Phytochemical evaluation of Brachylaena ramiflora (DC.) Humbert decoctions and infusions Dario Donno*1, Denis Randriamampionona2, Harilala Andriamaniraka2, Valeria Torti3, Maria Gabriella Mellano1, Cristina Giacoma3, Gabriele Loris Beccaro1 (Received December 23, 2016; Accepted February 28, 2017) * Corresponding author Summary Madagascar is characterized by one of the highest rates of endemism and biodiversity in the world. Brachylaena preparations are exten- sively used in Malagasy folk medicine for treating gastrointestinal diseases and blenorrhagia. The aim of this study was a preliminary phytochemical fingerprint of Brachylaena ramiflora leaves infusions and bark decoctions, in order to characterize this species as source of biologically active compounds and their relative antioxidant activity by high-performance liquid chromatography-diode array detector. Sixteen and twenty-three biomarkers (molecules with health proper- ties selected for their demonstrated positive role on human organism) were identified in B. ramiflora leaf infusions and bark decoctions, respectively: the main compounds identified in the infusions were quinic acid (334.55±0.99 mg/100 gFW), chlorogenic acid (208.27± 7.74 mg/100 gFW), and g-terpinene (144.19±1.00 mg/100 gFW), while the major components in the decoctions were castalagin (2002.64± 13.96 mg/100 gFW), citric acid (1171.81±1.05 mg/100 gFW), and chlo- rogenic acid (646.44±2.31 mg/100 gFW). B. ramiflora could be con- sidered as a promising source of natural antioxidants that may pro- vide health-benefits. The development of pharmaceuticals based on a sustainable exploitation of wild medicinal plants or their cultivation by local villagers could offer a number of benefits to a wide range of people as an alternative source of income and a natural and acces- sible health remedy. Keywords: medicinal tree-species, antioxidant activity, phytochemi- cal fingerprint, ethnobotany, endemism. List of abbreviations: 1,2-phenylenediamine dihydrochloride: OPDA; ascorbic acid: AA; dehydroascorbic acid: DHAA; Botani- cal and Zoological Park of Tsimbazaza: BZPT; normal atmosphere: N.A.; relative humidity: R.H.; high-performance liquid chromatogra- phy: HPLC; diode array detector: DAD; total polyphenolic content: TPC; gallic acid equivalents: GAE; fresh weight: FW; total antho- cyanin content: TAC; cyanidin-3-O-glucoside: C3G; ferric reducing antioxidant power: FRAP; polytetrafluoroethylene: PTFE; fluoro- phore 3-(1,2-dihydroxyethyl)furo(3,4-b)quinoxalina-1-one: DFQ; total bioactive compound content: TBCC; Pearson’s correlation co- efficients: R Introduction The World Health Organization estimates that nearly 80% of the population in developing countries depends mainly on traditional medicine for the treatment of ailments (RandRiamihaRisoa et al., 2015; RazafindRaibe et al., 2013). The dependence on remedies derived from medicinal plants is particularly important in these countries, as Madagascar, where modern medicine is often absent or simply too expensive (novy, 1997): economic devaluation of the developing countries leads to higher prices of pharmaceuticals and makes medicinal plants and traditional medicine more attractive (RandRiamihaRisoa et al., 2015). Additionally, some prefer tradi- tional medicine for several reasons including familiarity, tradition and perceived safety (van andel and CaRvalheiRo, 2013). Traditional Malagasy medicine makes use of a wide variety of plants to treat gastrointestinal disorders as diarrhea and intestinal para- sites, which are particularly prevalent in rural areas of the country (leutsCheR and bagley, 2003). These diseases are rarely associ- ated with mortality (gastrointestinal bleeding), but they cause sig- nificant morbidity as impaired physical and mental development (aReeshi et al., 2013). Madagascar, located approximately 400 km off of the coast of Mozambique in southeastern Africa, is the fourth largest island in the world (Rasoanaivo, 1990). Due to such long isolation and to its tropical location, Madagascar is characterized by one of the high- est rates of endemism and biodiversity in the world (noRsCia and boRgognini-taRli, 2006): indeed, current floristic calculations indicate that Madagascar hosts many endemic plant species (90% of vascular plant species and 96% of tree species) (Rasoanaivo, 1990; RazafindRaibe et al., 2013). For this reason, it is not sur- prising that Malagasy flora can provide a wide variety of medicinal plants as an affordable alternative to expensive western medicine. In any case, only an estimated 10% of the Malagasy plant species has been screened for any biological activity until now (hudson et al., 2000). The literature provides evidences on antiplasmodial and anti- microbial properties of different ethnomedicinal plant species from Madagascar (noRsCia and boRgognini-taRli, 2006; Rasoanaivo et al., 2004; RakotoniRiana et al., 2010), but the available survey on Malagasy medicinal plants is far from being exhaustive (novy, 1997; Rasoanaivo, 1990). Rural communities of Madagascar still practice and often prefer traditional medicine, especially for treating common and infectious diseases (RazafindRaibe et al., 2013): in particular, about one third of the plants is used for the treatment of gastrointestinal disorders, one third in case of malaria/fever, and the remaining third in order to treat rheumatisms, cold, skin illnesses and inflammations (noRsCia and boRgognini-taRli, 2006). Moreover, reproductive, prenatal and postpartum health are the most frequently cited uses for medicinal plants in women’s health. Brachylaena, a member of the subfamily Inulae, is a genus of 20 species that occurs in tropical Africa and is questionably native of the Mascarenes. Five species occur in Madagascar, and B. ramiflora is widespread in highly disturbed areas, while in rainforest environ- ments it is common from 500 to 2000 m of elevation, and it may 206 D. Donno, D. Randriamampionona, H. Andriamaniraka, V. Torti, M.G. Mellano, C. Giacoma, G.L. Beccaro persist in secondary vegetation, due to the corky bark and stool shoots. B. ramiflora (DC.) Humbert (Family Asteraceae) is also one of the most diffused medicinal plant of Madagascar, mainly used by local population as purgative and against stomach-ache; barks, however, are also used against blenorrhagia. In some biological tests the extracts were not distinctly toxic (Rasoanaivo et al., 1999). Depending on the ethnic group and language, several names for B. ramiflora occur: Hazotokana (“isolated tree”) in Merina and Bet- sileo: 19 specimens; Mananotra/Mananitra in Betsileo, 7 specimens; Merana in Betsileo, 3 specimens; Kanda (near Ifanadiana), 2 speci- mens. As all of the Malagasy species of Brachylaena, the species ramiflora may reach 20 m in height and yields are very durable timber known to be termite resistant (trunks for construction) (ChatuRvedula et al., 2002). Leaves drop when new leaves deve- lop, either at or just after anthesis. The stalks to the capitula range considerably in length. The variant species with subglabrous leaves occurs scattered over the whole distribution area, with no obvious association with any particular habitat. The biological value of the genus Brachylaena has been documented (ChatuRvedula et al., 2002): it has been described as a rich source of a high number of polyphenolic, organic and terpenic compounds with antioxidant, anti-inflammatory and antibacterial activity (vieiRa et al., 1991). Leaves are often the most used items for medicinal treatment, fol- lowed by bark and the entire plant, while decoctions and infusions are the most used methods of preparation (to be taken 3 times/day). Infusion is the extraction process of phytochemical compounds from plant material in a solvent as water, oil or alcohol, by allowing the material to remain suspended in the solvent over time; the process of infusion is different from decoction, which involves boiling the plant material (Capasso et al., 2006). As the research on Malagasy medicinal plants resulted in the dis- covery of valuable drugs, the aim of this study was a preliminary phytochemical investigation on B. ramiflora leaves’ and barks’ infu- sions and decoctions, in order to characterize this species as source of biologically active compounds and adding new information on Malagasy ethnobotanical species, indentifying and quantifying the main biologically active compounds and their relative antioxidant activity. A better understanding of ethnopharmacological knowledge is crucial to Madagascar progress towards an improved self-sufficien- cy in health care and to the discovery of new natural treatments for glo- bally significant diseases (RandRiamihaRisoa et al., 2015). Materials and methods Study area and plant material The Maromizaha forest (18°56’49” S; 48°27’55” E) is located in Eastern Madagascar, in the Alaotra-Mangoro region (Moramanga district), within both the rural municipalities of Andasibe and Am- batovola. Maromizaha is a 1,880 ha New Protected Area of largely contiguous forest located 140 km east of Antananarivo and 225 km from Toamasina: it is bordered to the north by the Route Nationale 2, to the east by the Befody hills, to the west by the Madiorano River and to the south by the Ankazomirahavavy River (Fig. 1). The forest ranges between elevations of 794 m and 1,224 m. The Maromizaha forest is surrounded by three forest blocks, including the Special Re- serve Analamazaotra to the northwest, Vohimana forest to the north- east and Vohidrazana forest to the east. This region of Madagascar is characterized by a tropical/sub-tropical climate tempered by altitude with high rainfall and a specific rainy season. The analyzed samples of B. ramiflora (leaves and bark) are shown in Fig. 2. Leaves and bark of B. ramiflora were identified and authen- ticated by botanists of the Botanical and Zoological Park of Tsimba- zaza (BZPT, Flora department) in Madagascar; a voucher specimen (reference: J.S. Miller, number 3760) was prepared and deposited in Maromizaha forest Fig. 1: Geographical location of Brachylaena ramiflora. HPLC fingerprint of Brachylaena ramiflora extracts 207 the herbarium section of the BZPT. Samples were collected in No- vember 2015 in the region of Maromizaha forest where the plant is usually harvested for medicinal use by local population. Sampling was made in triplicate. According to local Malagasy traditions, infu- sions from leaves and decoctions from bark were prepared. In the infusion process, 200 mL of water was brought to an appropriate temperature (80 °C) and then poured over 5 g of leaves which were then allowed to steep in the liquid for 10 min. Each herbal infu- sion was filtered (Whatman Filter Paper, Hardened Ashless Circles, 185 mm Ø) and then stored at N.A., 4 °C and 95% R.H until analysis. In the decoction process, 20 g of bark were put in 200 mL of boiling water for 20 min; each sample was filtered (Whatman Filter Paper, Hardened Ashless Circles, 185 mm Ø) and then stored at N.A., 4 °C and 95% R.H until analysis. Materials, solvents and chemicals Sodium carbonate, Folin–Ciocalteu phenol reagent, sodium acetate, citric acid, potassium chloride, hydrochloric acid, iron(III) chlo- ride hexahydrate, 2,4,6-tripyridyl-S-triazine, 1,2-phenylenediamine dihydrochloride (OPDA), all polyphenolic and terpenic standards, potassium dihydrogen phosphate, phosphoric acid and HPLC-grade methanol and acetonitrile were purchased from Sigma-Aldrich (St. Louis, MO, USA). Acetic acid, ethanol, standards of organic acids and HPLC-grade formic acid were purchased from Fluka BioChe- mika, Buchs, Switzerland. Ethylenediaminetetraacetic acid disodium salt was purchased from AMRESCO (Solon, OH, USA). Sodium fluoride was purchased from Riedel-de Haen (Seelze, Germany). Cetyltrimethylammonium bromide (cetrimide), ascorbic acid (AA) and dehydroascorbic acid (DHAA) were purchased from Extrasynthése (Genay, France). Milli- Q ultrapure water was produced by Sartorius Stedim Biotech mod. Arium (Sartorius, Göttingen, Germany). Spectrophotometric analysis The amount of total polyphenolic content (TPC) was determined following the Folin-Ciocalteu colorimetric method (slinkaRd and singleton, 1977) and results were expressed as mg of gallic acid equivalents (GAE) per 100 g of fresh weight (FW). The total anthocyanin content (TAC) in the extracts was determined using the pH-differential method (lee et al., 2005). TAC was ex- pressed as milligrams of cyanidin-3-O-glucoside (C3G) per 100 grams of fresh weight (mgC3G/100 gFW). Antioxidant activity was evaluated by ferric reducing antioxidant power (FRAP) assay (benzie and stRain, 1999) and results were expressed as millimoles of ferrous iron (Fe2+) equivalents per kilo- gram (solid food) of FW. Chromatographic analysis Sample preparation protocols for HPLC analysis Small portions (2 mL) of obtained infusions and decoctions were filtered with circular pre-injection filters (0.45 μm, polytetrafluoro- ethylene membrane, PTFE) before HPLC-DAD analysis. In the case of vitamin C analysis, a C18 cartridge for solid phase ex- traction (Sep-Pak® C-18, Waters, Milford, MA, USA) was used to absorb the polyphenolic fraction. Then, 250 μL of OPDA solution (18.8 mmol·L-1) were added to 750 μL of samples for DHAA deri- vatization into the fluorophore 3-(1,2-dihydroxyethyl)furo(3,4-b) quinoxalina-1-one (DFQ) (gonzalez-molina et al., 2008). Standard calibration The external standard method was used for quantitative determi- nations. Twenty mL aliquot manual injections were performed in triplicate for each concentration level. The calibration curves were obtained by plotting the peak area (y) of the compound at each level versus the sample concentration (x). Apparatus and chromatographic conditions An Agilent 1200 High Performance Liquid Chromatograph coupled to an Agilent UV-Vis diode array detector (Agilent Technologies, Santa Clara, CA, USA), was used for the chromatographic analysis. Five chromatographic methods were used: a KINETEX – C18 col- umn (4.6 × 150 mm, 5 μm, Phenomenex, Torrance, CA, USA) was used to achieve the bioactive compound separation. Several mobile phases were used for the biomarker identification and UV spectra were recorded at different wavelengths. The chromatographic condi- tions of each method were reported in Tab. 1, while the main analyti- cal method validation data are summarized in Tab. 2. Identification and quantification of bioactive compounds in the extracts All the samples were analyzed in triplicate, and standard deviations are given in order to assess the repeatability of the used methods. All single compounds were identified in samples by comparison and combination of their retention times and UV spectra with those of authentic standards in the same chromatographic conditions. Total bioactive compound content (TBCC) was determined as the sum of the most important classes of selected biomarkers with an important role in the positive effects on human organism (“multi- marker approach”) (mok and Chau, 2006). By single bioactive com- pound profile, phytochemicals were grouped into different bioactive classes to evaluate the contribution of each class to total phytocom- plex composition. Biomarkers were selected for their demonstrated positive healthy properties and antioxidant activity by literature in relation to the use of this medicinal plant by local population. Five polyphenolic classes were considered: benzoic acids, catechins, cin- namic acids, flavonols, and tannins. Monoterpenes, organic acids, and vitamin C (as sum of ascorbic and dehydroascorbic acids) were also considered to obtain a complete analytical fingerprint. Mass spectrometry data of some selected phytochemicals in B. ramiflora Fig. 2: Morphological traits of Brachylaena ramiflora leaves (A) and bark (B). 208 D. Donno, D. Randriamampionona, H. Andriamaniraka, V. Torti, M.G. Mellano, C. Giacoma, G.L. Beccaro decoctions and infusions were reported in supplementary materials (Fig. S1). All the results were expressed as mg per 100 g of fresh weight (FW). Statistical Analysis All samples were prepared and analyzed in triplicate. Results were subjected to t-Student test and ANOVA test for mean comparison (SPSS 22.0 Software) and HSD Tukey multiple range test (P < 0.05). The relationships between the TPC and antioxidant activity were in- vestigated using Pearson’s correlation coefficient (R). Results and discussion The beneficial effects of bark and leaves of Malagasy medicinal plants on human health have already been established in several stu- dies (RandRiamihaRisoa et al., 2015): in particular, the amount of total phenolics could be responsible for a great number of these effects. Nevertheless, studies on tree-species plant bioactive com- pounds (botanicals) are still very scarce: in this study, the phyto- chemical value of infusions and decoctions of different parts of Brachylaena ramiflora was investigated by chromatographic and spectrophotometric analyses (by determination of vitamins and or- ganic acids, simple phenolics, flavonoids, anthocyanins and tannins, and of the antioxidant activity). This is one of the first reports which evaluates the B. ramiflora leaf infusion and bark decoction for their chemical parameters, phytochemical profile and antioxidant activity. Total phenolics and anthocyanins Phenols and related compounds, as anthocyanins, have antioxidant potential owing to hydroxyl groups, which allow free ion pairs to be donated easily. The TPC determination in plant infusions and decoctions was carried out by the Folin-Ciocalteu method, which depends on electron transfer from phenolic compounds to the Folin- Ciocalteu reagent in alkaline medium (eRenleR et al., 2016; donno et al., 2015b), while the TAC was directly determined using the pH- differential method: the colored oxonium form of anthocyanin pre- dominates at pH 1.0, and the colorless hemiketal form at pH4.5; the pH-differential method is based on the reaction producing oxonium forms (donno et al., 2015d). TPC and TAC, spectrophotometrically estimated in the decoctions and infusions, are shown in Tab. 3. The results of the TPC revealed that infusions and decoctions have different phenolic content which ranged significantly from 11.15±3.17 to 96.10±1.77 mgGAE/100 gFW, respectively. With regard to the TAC, the infusion has shown a sig- nificantly higher content (27.86±13.99 mgC3G/100 gFW) compared to decoction (3.03±0.64 mgC3G/100 gFW). The results demonstrated that the highest polyphenol contents were found in the decoctions as reported in other studies (RazakaRivelo et al., 2015; kaRimi et al., 2010), even if these polyphenolic compounds were not antho- cyanins: the preparation method could have influence on polypheno- lic components, which leads to more efficient extraction for decoc- tion method, but could also affect the phenolic molecules during the continuous heat to which decoctions were subjected as reported by AmmaR et al. (2015). Phytochemical profile and phytocomplex Synergistic or additive therapeutic effects of several phytochemicals, rather than a single compound, could contribute to disease preven- tion and reduce the risk of addiction and toxicity, producing a more complete and less drastic pharmacological effect than that of one or a few of its components taken separately: the so-called phytocomplex consists of a combination of different substances, both active prin- ciples and other plant components, which contribute to the overall therapeutic effect (donno et al., 2015a). Since the biological activity of B. ramiflora infusions and decoctions is due to the sum of their bioactive components (phytocomplex), chemical composition of these preparations was analyzed by HPLC fingerprint: the main con- stituents identified in the present study (polyphenolic and terpenic compounds, organic acids, and vitamins) are known bioactive com- pounds. Sixteen and twenty-three biomarkers were identified in the B. ramiflora leaf infusions and bark decoctions, respectively (Tab. 4): the main compounds identified by HPLC-DAD in the infusions were quinic acid (334.55±0.99 mg/100 gFW), chlorogenic acid (208.27± 7.74 mg/100 gFW), and γ-terpinene (144.19±1.00 mg/100 gFW), while the major components in the decoctions were castalagin (2002.64± 13.96 mg/100 gFW), citric acid (1171.81±1.05 mg/100 gFW), and chlo- rogenic acid (646.44±2.31 mg/100 gFW). Overall, infusions and decoctions have shown different phenolic profile. Seven (leaf infusions) and fourteen (bark decoctions) phe- Tab. 1: Chromatographic conditions of each used method (donno et al., 2015c). Method Compounds of interest Stationary phase Mobile phase Flow Wavelenght (mL min-1) (nm) A cinnamic acids, flavonols KINETEX – C18 column A: 10 mM KH2PO4/H3PO4, pH=2.8 1.5 330 (4.6 × 150 mm, 5 μm) B: CH3CN B benzoic acids, catechins, KINETEX – C18 column A: H2O/CH3OH/HCOOH (5:95:0.1 v/v/v), pH=2.5 0.6 280 tannins (4.6 × 150 mm, 5 μm) B: CH3OH/HCOOH (100:0.1 v/v) C monoterpenes KINETEX – C18 column A: H2O 1.0 210, 220, (4.6 × 150 mm, 5 μm) B: CH3CN 235, 250 D organic acids KINETEX – C18 column A: 10 mM KH2PO4/H3PO4, pH=2.8 0.6 214 (4.6 × 150 mm, 5 μm) B: CH3CN E vitamins KINETEX – C18 column A: 5 mM C16H33N(CH3)3Br/50 mM KH2PO4, pH=2.5 0.9 261, 348 (4.6 × 150 mm, 5 μm) B: CH3OH Elution conditions Method A / gradient analysis: 5% B to 21% B in 17 min + 21% B in 3 min (2 min conditioning time) Method B / gradient analysis: 3% B to 85% B in 22 min + 85% B in 1 min (2 min conditioning time) Method C / gradient analysis: 30% B to 56% B in 15 min + 56% B in 2 min (3 min conditioning) Method D / isocratic analysis ratio of phase A and B: 95:5 in 13 min (2 min conditioning time) Method E / isocratic analysis: ratio of phase A and B: 95:5 in 10 min (5 min conditioning time) HPLC fingerprint of Brachylaena ramiflora extracts 209 T ab . 2 : M ai n va lid at io n pa ra m et er s of th e us ed m et ho ds fo r e ac h ca lib ra tio n st an da rd ( d o n n o e t a l., 2 01 5c ). M et ho d C la ss St an da rd ID c od ea R et en ti on W av el en gh t C al ib ra ti on c ur ve e qu at io n R 2 C al ib ra ti on c ur ve r an ge L O D b L O Q c ti m e (t R ) (m in ) (n m ) (m g L -1 ) (m g L -1 ) (m g L -1 ) A C in na m ic a ci ds ca ff ei c ac id 1 4. 54 33 0 y = 59 .0 46 x + 20 0. 6 0. 99 6 11 1 - 5 00 0. 30 5 1. 01 6 ch lo ro ge ni c ac id 2 3. 89 33 0 y = 13 .5 83 x + 76 0. 05 0. 98 4 11 1 - 5 00 0. 94 0 3. 13 4 co um ar ic a ci d 3 6. 74 33 0 y = 8. 93 42 x + 21 7. 4 0. 99 7 11 1 - 5 00 2. 90 7 9. 69 0 fe ru lic a ci d 4 7. 99 33 0 y = 3. 39 63 x - 4 .9 52 4 1. 00 0 11 1 - 5 00 1. 24 5 4. 15 0 Fl av on ol s hy pe ro si de 5 10 .8 9 33 0 y = 7. 13 22 x - 4 .5 83 0. 99 9 11 1 - 5 00 3. 37 2 11 .2 41 is oq ue rc itr in 6 11 .2 4 33 0 y = 8. 30 78 x + 26 .6 21 0. 99 9 11 1 - 5 00 0. 25 2 0. 84 0 qu er ce tin 7 17 .6 7 33 0 y = 3. 40 95 x - 9 8. 30 7 0. 99 8 11 1 - 5 00 4. 05 5 13 .5 18 qu er ci tr in 8 13 .2 8 33 0 y = 2. 74 13 x + 5. 63 67 0. 99 8 11 1 - 5 00 5. 45 6 18 .1 87 ru tin 9 12 .9 5 33 0 y = 6. 58 08 x + 30 .8 31 0. 99 9 11 1 - 5 00 2. 93 7 9. 79 0 B B en zo ic a ci ds el la gi c ac id 10 18 .6 5 28 0 y = 29 .9 54 x + 18 4. 52 0. 99 8 62 .5 - 25 0 0. 61 1 2. 03 5 ga lli c ac id 11 4. 26 28 0 y = 44 .9 96 x + 26 1. 86 0. 99 9 62 .5 - 25 0 0. 43 5 1. 45 1 C at ec hi ns ca te ch in 12 10 .3 1 28 0 y = 8. 91 97 x + 66 .9 52 1. 00 0 62 .5 - 25 0 2. 34 3 7. 80 9 ep ic at ec hi n 13 14 .3 0 28 0 y = 12 .8 8x - 43 .8 16 0. 99 9 62 .5 - 25 0 0. 76 3 2. 54 3 Ta nn in s ca st al ag in 14 16 .3 5 28 0 y = 4. 23 6x - 8. 53 5 1. 00 0 62 .5 - 25 0 1. 00 9 3. 36 3 ve sc al ag in 15 17 .2 5 28 0 y = 4. 93 9x - 1. 23 2 1. 00 0 62 .5 - 25 0 0. 60 3 2. 01 0 C M on ot er pe ne s lim on en e 16 3. 35 25 0 y = 0. 18 94 x - 5 .4 20 0. 99 9 12 5 - 1 00 0 8. 65 4 28 .8 47 ph el la nd re ne 17 3. 57 21 0 y = 8. 78 3x - 14 5. 3 0. 99 8 12 5 - 1 00 0 0. 56 2 1. 87 4 sa bi ne ne 18 3. 45 22 0 y = 18 .1 4x - 10 04 0. 99 8 12 5 - 1 00 0 0. 09 4 0. 31 4 γ- te rp in en e 19 3. 28 23 5 y = 0. 48 86 x - 2 3. 02 0. 99 9 12 5 - 1 00 0 17 .5 77 58 .5 90 te rp in ol en e 20 4. 83 22 0 y = 26 .5 2x + 8 76 .8 0. 99 9 12 5 - 1 00 0 0. 24 1 0. 80 4 D O rg an ic a ci ds ci tr ic a ci d 21 5. 30 21 4 y = 1. 06 03 x - 2 2. 09 2 1. 00 0 16 7 - 1 00 0 18 .8 05 62 .6 82 m al ic a ci d 22 4. 03 21 4 y = 1. 41 5x - 80 .2 54 0. 99 6 16 7 - 1 00 0 15 .7 21 52 .4 04 ox al ic a ci d 23 7. 85 21 4 y = 6. 45 02 x + 6. 15 03 0. 99 8 16 7 - 1 00 0 0. 55 0 1. 83 5 qu in ic a ci d 24 3. 21 21 4 y = 0. 80 87 x - 3 8. 02 1 0. 99 8 16 7 - 1 00 0 26 .1 06 87 .0 21 su cc in ic a ci d 25 3. 46 21 4 y = 0. 92 36 x - 8 .0 82 3 0. 99 5 16 7 - 1 00 0 7. 13 5 23 .7 83 ta rt ar ic a ci d 26 5. 69 21 4 y = 1. 84 27 x + 15 .7 96 1. 00 0 16 7 - 1 00 0 8. 52 0 28 .4 01 E V ita m in s as co rb ic a ci d 27 4. 14 26 1 y = 42 .7 1x + 2 7. 96 9 0. 99 9 10 0 - 1 00 0 0. 83 6 2. 78 6 de hy dr oa sc or bi c ac id 28 3. 41 34 8 y = 4. 16 28 x + 14 0. 01 0. 99 9 30 - 30 0 1. 09 5 3. 64 9 a I D c od e = id en tifi ca tio n co de ; b L O D = li m it of d et ec tio n; c L O Q = li m it of q ua nt ifi ca tio n 210 D. Donno, D. Randriamampionona, H. Andriamaniraka, V. Torti, M.G. Mellano, C. Giacoma, G.L. Beccaro nolic compounds were detected, identified, and quantified by their retention times and UV spectra compared with those of analytical standards analyzed in the same chromatographic conditions using a HPLC-DAD: polyphenols represented 46.43% of the infusion phytocomplex and 66.08% of the decoction phytocomplex (Fig. 3), accor-ding to other researches (Rasoanaivo et al., 2004; Raza- kaRivelo et al., 2015). Phenolic compounds may be found in plant infusions and decoctions by boiling water particularly due to solu- tion of hydrolysable tannins and flavonoids and water-soluble lignin fragments solved under acidic conditions (eRenleR et al., 2016). The main polyphenolic compounds found in infusions and decoctions of B. ramiflora leaves and bark were phenolic acids (31.88%) and tan- nins (28.95%), respectively (Tab. 5). Concerning the phenolic acids, they were identified as cinnamic and benzoic acids and tentatively identified as caffeic, chlorogenic, coumaric, and ferulic acids and ellagic and gallic acids, respectively. The presence of phenolic acids, as caffeic, ferulic and coumaric acids, has been already reported in plant material of different species with the same therapeutic effects (ammaR et al., 2015). The present study did not report the presence of phenolic acid derivatives even if these compounds are present mainly as water soluble glycosides. Moreover, the leaf infusion has revealed a considerably lower tannin content than the bark decoction: indeed, bark was expected to contain higher mass fraction of tannins since these compounds have a defensive role (majiC et al., 2015). The presence of tannins in adequate amounts in bark extracts could be advantageous as they are able to very effectively quench free radicals (ammaR et al., 2015). The identified biomarkers have a pharmaceuti- cal and medicinal importance: in general, the antioxidant effects of phenolic compounds have been studied in relation to the prevention of coronary diseases and cancer, as well as age-related degenerative brain disorders (CanteRino et al., 2012). In addition, phenolic com- pounds, associated with antioxidant activity, play an important role in stabilizing lipid peroxidation (beyhan et al., 2010). Terpenic compounds were dominant in B. ramiflora infusions in con- trast to the decoctions: as shown in Tab. 5, monoterpenes represented 17.33% of the infusion phytocomplex and 1.63% of the decoction phytocomplex. The main terpenic compounds of infusions were γ- terpinene (144.19±1.00 mg/100 gFW) and sabinene (20.37±0.59 mg/ 100 gFW) followed by phellandrene (13.83±0.40 mg/100 gFW), while the only identified monoterpene of decoctions was phellandrene (116.67±17.17 mg/100 gFW) as reported in Tab. 4. This difference in terpenic compound composition is probably due to the different ex- traction methods (piRy et al., 1995), in particular to the temperature: these molecules are volatile compounds with anti-inflammatory ac- tivities (de Cassia da silveiR et al., 2013) and the obtained results could explain the differences in the antioxidant activity between in- fusions and decoctions. The monoterpene separation was very dif- Fig. 3: Phytocomplex representation of the Brachylaena ramiflora extracts. Mean value of each analyzed sample is given (N = 3). Tab. 3: Total polyphenolic content (TPC), antioxidant activity, and total an- thocyanin content (TAC) data in the analyzed plant extracts. TPC Antioxidant activity TAC Mean value±SD Mean value±SD Mean value±SD (mgGAE/100 gFW) (mmol Fe2+/kg) (mgC3G/100gFW) Infusion 11.15±3.17a 1.07±0.03a 27.86±13.99b Decoction 96.10±1.77b 6.42±0.08b 3.03±0.64a Mean value and standard deviation of each sample is given (N = 3). Different letters in superscript for each sample indicate the significant differences at P < 0.05. aGAE = gallic acid equivalents; bC3G = cyanidin-3-O-glucoside; cFW = fresh weight Tab. 4: Phytochemical fingerprint of analyzed samples. Class Bioactive marker Infusion Decoction Mean value±SD Mean value±SD (mg/100gFW) (mg/100gFW) Cinnamic acids caffeic acid 13.10±0.63 5.44±0.34 chlorogenic acid 208.27±7.74 646.44±2.31 coumaric acid 90.20±8.30 426.86±2.52 ferulic acid n.d. 58.30±3.13 Flavonols hyperoside n.d. 12.62±2.39 isoquercitrin 9.67±0.54 418.39±17.95 quercetin 120.44±0.86 293.47±7.47 quercitrin n.d. 54.44±0.93 rutin n.d. 85.98±7.17 Benzoic acids ellagic acid 13.13±0.41 447.95±4.82 gallic acid 21.45±1.36 58.32±8.32 Catechins catechin n.d. 149.24±6.43 epicatechin n.d. n.d. Tannins castalagin n.d. 2002.64±13.96 vescalagin n.d. 71.77±1.21 Monoterpenes limonene n.d. n.d. phellandrene 13.83±0.40 116.67±1.17 sabinene 20.37±0.59 n.d. γ-terpinene 144.19±1.00 n.d. terpinolene 9.79±0.94 n.d. Organic acids citric acid n.d. 1171.81±1.05 malic acid n.d. 476.41±1.57 oxalic acid 4.46±0.30 85.18±0.65 quinic acid 334.55±0.99 16.00±0.18 succinic acid 34.83±0.15 14.15±0.10 tartaric acid n.d. 536.80±1.35 Vitamins ascorbic acid 12.38±0.09 12.51±0.06 dehydroascorbic acid 7.31±0.14 0.71±0.04 Mean value and standard deviation of each sample is given (N = 3). an.d. = not detected; bFW = fresh weight HPLC fingerprint of Brachylaena ramiflora extracts 211 Tab. 5: Phytocomplex of Brachylaena ramiflora infusions and decoctions. Infusions Decoctions Mean value±SD phytocomplex percentage Mean value±SD phytocomplex percentage Bioactive class (mg/100gFW) (%) (mg/100gFW) (%) Cinnamic acids 311.56±8.53e 28.69 1137.04±6.34f 15.87 Flavonols 130.11±0.58c 11.98 864.90±14.86e 12.07 Benzoic acids 34.57±1.62b 3.18 506.28±3.81d 7.07 Catechins n.d. / 149.24±6.43c 2.08 Tannins n.d. / 2074.41±13.17g 28.95 Anthocyanins 27.86±5.17ab 2.57 3.03±0.64a 0.04 Monoterpenes 188.17±0.33d 17.33 116.67±1.17b 1.63 Organic acids 373.85±0.90f 34.43 2300.35±1.80h 32.10 Vitamins 19.69±0.16a 1.81 13.21±0.02a 0.18 TBCC 1085.81±12.21 7165.13±11.64 Mean value and standard deviation of each sample is given (N = 3). Different letters in superscript for each sample indicate the significant differences at P < 0.05. an.d. = not detected; bFW = fresh weight ficult (not so much high resolution), and for this reason the separation was also achieved by four different wavelengths. Organic acids and vitamin C (as sum of ascorbic acid and dehydro- ascorbic acid) are another important antioxidant components with multi-purpose uses in pharmacology (eyduRan et al., 2015). In B. ramiflora infusions they represented 34.43% and 1.81% of the total phytocomplex, respectively; in the decoctions, instead, organic acids represented 32.10% of the phytocomplex, while vitamin C partici- pated in the phytocomplex with only 0.18% (Fig. 3) because of the high extraction temperature that degrades the most heat-sensitive molecules. Antioxidant activity Antioxidant capacity is widely used as a parameter for medicinally bioactive and functional components in plant material and derived- products: the reducing capacity of specific compounds may serve as a significant indicator of total potential antioxidant activity (donno et al., 2013). The mechanisms of antioxidant activity of polypheno- lic compounds and vitamins, as flavonoids and vitamin C, are well discussed but the mechanisms and structural requirements have not been fully understood (Amić et al., 2003). The antioxidant proper- ties of monoterpenes and organic acids have been also referred to by several authors (eyduRan et al., 2015). In this study, B. ramiflora leaf infusions and bark decoctions have been evaluated for their activity as free radical scavengers by FRAP assay. The presence of antioxidant molecules in plant samples brings about the reduction of the Fe3+ complex to the ferrous form: in this assay, the yellow color of the test solution changes to different shades of green and blue depending on the reducing power of antioxidant samples. The antioxidant compounds, present in analyzed extracts, reduced the Fe3+ complex to the Fe2+ form in different way depen- ding on extraction method: the antioxidant capacity ranged from 1.07±0.03 mmol Fe2+/kg (infusions) to 6.42±0.08 mmol Fe2+/kg (decoctions) (Tab. 3), according to similar studies (kaRimi et al., 2010). Most of the identified compounds possess hydroxyl groups which have the ability of formation complexes with iron metal: the hydroxyl groups of the molecules donate electron pairs to the iron metal with a coordinate covalent bond to form metal complexes. The antioxidant activity of B. ramiflora leaves and bark could be attributed to the hydroxyl groups of the molecules that donate electron pairs to the metal, as also reported by ERenleR et al. (2016). The high Pearson’s correlation coefficients between the polypheno- lic content and antioxidant activity (Rinfusions = 0.99 and Rdecoctions = 0.62) confirmed a strong positive linear relationship between these two variables according to similar researches (majiC et al., 2015). Conclusions Folk medicine represents an important tool to spot plants of pharma- cological interest, since it can indicate potential sources of bioactive compounds. It can be inferred that the forest of Maromizaha is a source of important raw materials for plant-derived pharmaceuticals. Medicinal plant exploitation have a link with biodiversity conser- vation. The valorization of medicinal plants may increase local in- centives to preserve and manage the habitat. It is hoped that further studies will generate an interest in the proper sustainable produc- tion, processing, and commercialization of B. ramiflora for medici- nal purposes. Indeed, according to the results of this study, it may be concluded that B. ramiflora could be considered as a promising source of natural antioxidants that may contribute to health benefits: the analyzed preparations revealed an important polyphenol content, in particular flavonoids and tannins, and the decoctions presented the highest levels. The phytochemical profile was also characterized by the presence of monoterpenes, organic acids and vitamin C. Furthermore, agreements between local institutions and pharmaceu- tical companies may encourage a further development of prospective medicines and natural remedies based on B. ramiflora and other lo- cal medicinal plants. As the quantity of wild growing plant species is continuously decli- ning, a major effort should be done to strengthen conservation poli- cies and strategies. In this perspective, this preliminary survey would give a contribute to the knowledge of Malagasy flora: the outcomes of this preliminary phytochemical investigation may provide a con- tribution to the identification and quantification of lead compounds responsible for traditional therapeutic claims, but a further quantita- tive evaluation on the basis of their chemical structures with HPLC coupled to mass spectrometry is necessary. Finally, further studies providing more ecophysiological and phar- macological information are necessary to have a more complete pic- ture on B. ramiflora, highlighting the importance of biodiversity on the health and wellbeing of local communities. 212 D. Donno, D. Randriamampionona, H. Andriamaniraka, V. Torti, M.G. Mellano, C. Giacoma, G.L. Beccaro Declaration of interest The authors declare that they have no conflict of interest. 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This is an Open Access article distributed under the terms of the Creative Commons Attribution Share-Alike License (http://creative- commons.org/licenses/by-sa/4.0/). I Supplementary material     Gallic acid Chemical Formula: C7H6O5 Molecular Weight: 170,12 m/z: 170.02 (100.0%), 171.02 (7.6%), 172.03 (1.3%)       γ-Terpinene Chemical Formula: C10H16 Molecular Weight: 136,23 m/z: 136.13 (100.0%), 137.13 (11.0%)         Fig. S1: Mass spectrometry data of some selected phytochemicals in B. ramiflora decoctions and infusions Supplementary material II     Terpinolene Chemical Formula: C10H16 Molecular Weight: 136,23 m/z: 136.13 (100.0%), 137.13 (11.0%)       Citric acid Chemical Formula: C6H8O7 Molecular Weight: 192,12 m/z: 192.03 (100.0%), 193.03 (6.8%), 194.03 (1.6%)           Oxalic acid Chemical Formula: C2H2O4 Molecular Weight: 90,03 m/z: 90.00 (100.0%), 91.00 (2.3%)       Tartaric acid Chemical Formula: C4H6O6 Molecular Weight: 150,09 m/z: 150.02 (100.0%), 151.02 (4.6%), 152.02 (1.3%)       Fig.  S1:  Mass  spectrometry  data  of  some  selected  phytochemicals  in  B.  ramiflora  decoctions  and  infusions III Supplementary material