Physical Properties of Botanical Surfactants

Physical Properties of Botanical Surfactants

Science of the Total Environment 610–611 (2018) 1133–1137 Contents lists available at ScienceDirect Science of the Total Environment journal homepage: www.elsevier.com/locate/scitotenv Physical properties of botanical surfactants Lillian Espíndola Müller a, Gustavo Schiedeck b,⁎ a Departament of Plant Science, Federal University of Pelotas, Pelotas, Brazil b Estação Experimental Cascata, Embrapa Clima Temperado, Pelotas, Brazil HIGHLIGHTS GRAPHICAL ABSTRACT • Botanical surfactants may be suitable to the organic products sprayings. • Some surfactants properties of Q. brasiliensis and A. angustifolia were studied. • Different methods of preparation and concentration were evaluated. • Dry and grind samples resulted in higher foam column height in both species. • Q. brasiliensis was less able to reduce the superficial tension than neutral soap. article info abstract Article history: Some vegetal species have saponins in their composition with great potential to be used as natural surfactants in Received 24 April 2017 organic crops. This work aims to evaluate some surfactants physical properties of Quillaja brasiliensis and Agave Received in revised form 17 August 2017 angustifolia, based on different methods of preparation and concentration. The vegetal samples were prepared Accepted 18 August 2017 by drying and grinding, frozen and after chopped or usedfreshandchopped.Theneutralbarsoapwasusedasa Available online xxxx positive control. The drying and grinding of samples were the preparation method that resulted in higher foam col- Editor: D. Barcelo umnheightinbothspeciesbutQ. brasiliensis was superior to A. angustifolia in all comparisons and foam index was 2756 and 1017 respectively. Critical micelle concentration of Q. brasiliensis was 0.39% with the superficial tension of −1 −1 Keywords: 54.40 mN m while neutral bar soap was 0.15% with 34.96 mN m . Aspects such as genetic characteristics of the Botanical tensoative species, environmental conditions, and analytical methods make it difficult to compare the results with other stud- Foam index ies, but Q. brasiliensis powder has potential to be explored as a natural surfactant in organic farming. Not only the Superficial tension surfactants physical properties of botanical saponins should be taken into account but also its effect on insects and Quillaja brasiliensis diseases control when decided using them. Agave angustifolia © 2017 Elsevier B.V. All rights reserved. Neutral bar soap 1. Introduction expansion of cultivated areas. If on the one hand researchers have de- voted great efforts in searching for effective natural products, the The management of insects and diseases in organic production sys- same can't be said for the formulation of these products. In general, bo- tems is a great problem for farmers yet that, somehow, can limit the tanical extracts and plant protectors are applied directly on crops with- out adjuvants and its efficiency depends on both the bioactivity of the active principle and also its ability to establish an interface with the tar- get organism. The surface of the leaves of most plant species that are in- ⁎ Corresponding author at: Embrapa Clima Temperado, BR 392, km 78, Postal box 403, Pelotas, RS CEP 96010-971, Brazil. teresting for agriculture is formed by a cuticle composed of aliphatic and E-mail address: [email protected] (G. Schiedeck). apolar substances with strong hydrophobic activity which reduce the http://dx.doi.org/10.1016/j.scitotenv.2017.08.193 0048-9697/© 2017 Elsevier B.V. All rights reserved. 1134 L.E. Müller, G. Schiedeck / Science of the Total Environment 610–611 (2018) 1133–1137 level of wetness by the product (Müller and Riederer, 2005). The use of 2.2. Analyzes surfactants (or tensioactives) can help to overcome this barrier since it modifies positively the physicochemical properties of the botanical ex- 2.2.1. Foam height column and foam index (FI) tract to be applied (Iost and Raetano, 2010). The surfactants generally For each plant species and preparation procedure it was developed a enables an uniform product spreading on the surface of the leave, in- sequence of concentrations from 0.2 g to 2 g at intervals of 0.2 g, to which creasing the drop retention, helping the product penetration, it was added 200 mL of distilled water. Then, the samples were submit- preventing the formation of product deposits on the leaves by crystalli- ted to a decoction period of 5 min. After cooling, each decoction was fil- zation and reducing losses caused by rain washing (Baseeth and Sebree, tered through cotton and distributed in test tubes (17 × 182 mm) in 2010; Mendonça et al., 2007; Queiroz et al., 2008). An efficient surfac- successive series of 1, 2, 3, up to 9 mL, adjusting the final volume to tant must have low critical micelle concentration (CMC), which is a 10 mL. The last test tube received 10 mL of the undiluted integral decoc- characteristic directly related to the amount of surfactant required to re- tion. It was measured the pH of each decoction with an indicator strip duce the superficial tension of the product to the lowest value and, when it was necessary, there was a correction to 7.0 with calcium (Mulligan, 2005). carbonate. Test tubes were shaked by hand for 15 s and remained resting The saponins are secondary metabolites glycosylated which are for 15 min, when it was measured the height of persistent foam column found in a wide range of plant species that have great use in food, cos- in each treatment. The determination of foam index was made adapting metic and pharmaceutical industries (Cheok et al., 2014; Sparg et al., the methodology described in Brazilian Pharmacopoeia (Brasil, 2010a) 2004), since they are considered efficient, low cost and safe for the en- and it was calculated by the equation: vironment and health (Basu et al., 2015; Böttcher and Drusch, 2016; Muntaha and Khan, 2015). Among the saponins physicochemical fea- FI ¼ 10=½ðÞM Á Ddv =200 ð1Þ tures their ability to form persistent foam in aqueous solutions and with high interfacial activity is one of the most important resources where M (g) is the plant mass for each treatment and Ddv (mL) is the de- for developing surfactants (Böttcher and Drusch, 2016; Ribeiro et al., coction-diluted volume used in each test tube. The 10 and 200 values 2013), especially for botanical extracts application (Chapagain and represent the total volume in the test tube and the volume used in decoc- Wiesman, 2006). tion, respectively. FI is an index presented without any unit of magnitude However, the content and the composition of saponins in plants, and and represents the highest dilution in which a given mass of plant is able therefore their own bioactivity, are determined both by its botanical or- to form 1 cm column of foam under specific conditions, thus enabling igin (Böttger et al., 2012; Mert-Türk, 2006) and the biotic and abiotic their comparison with different saponins solutions. factors involved, such as herbivory, development stage, cultivation tech- niques and environmental variables (Costa et al., 2013; Szakiel et al., 2.2.2. Superficial tension and critical micelle concentration (CMC) 2011). From the FI results it was determined the static superficial tension Some species in southern Brazil have saponins in their composition only for Q. brasiliensis in the decoction concentrations of 0.25% and with great potential to be used as natural surfactants for spraying organic 0.5%. As elements of comparison, it was also evaluated the decoction at crops. Quillaja brasiliensis (A. St.-Hill. & Tul.) Mart. (Quillajaceae) is a na- 2.5% and neutral bar soap (NBS) at 0.25%. It was used the drop weight tive tree also known as soldier-soap or soap-dish due to its leaves and method, adapting the procedure described by Lee et al. (2008).Froma bark that produce persistent foam in water (Carvalho, 2006; Yendo et burette, it was gathered 20 drops of each dilution decoction, in triplicate, al., 2015). Agave angustifolia Haw. (Agavaceae), in turn, is native from and it was measured the average value of the mass and drop volume. The Mexico, where other species of this kind have economic importance in superficial tension was calculated by Tate Law and it was added a correc- beverage industry and folk medicine (Ahumada-Santos et al., 2013; tion factor concerning to the remaining fraction of liquid at the burette Good-Avila et al., 2006) and that is used mainly as ornamental specie tip (Lee et al., 2008): in Brazil. hi = This work aims to evaluate some surfactants physical properties of γ ¼ ðÞm:g = 2 Á π Á r Á Ψ r=V1 3 ð2Þ Quillaja brasiliensis and Agave angustifolia, based on different methods of preparation and concentration. where γ is the superficial tension (mN m−1), m is the average mass (g) of each drop, g is the gravity acceleration (980 cm s−2), r is the radius of the burette tip (0.175 cm) and Ψ(r/V1/3) is the correction factor, calculat- 2. Material and methods ed by equation: 2.1. Site, collection and preparation of botanical material = = = 2 Ψ r=V1 3 ¼ 1:000–0:9121 r=V1 3 –2:109 r=V1 3 = 3 = 4 The study was conducted at the Estação Experimental Cascata (EEC), þ 13:38 r=V1 3 −27; 29 r=V1 3 Embrapa Clima Temperado, Pelotas, Brazil. The plants were collected 5− 6 7 þ : = 1=3 : = 1=3 þ : = 1=3 ð Þ from September 2014 to March 2015. The Agave angustifolia sample 27 53 r V 13 58 r V 2 593 r V 3 was collected at Universidade Federal de Pelotas area in full sun, Capão do Leão county (31°48′ S, 052°24′ W, 13 m a.s.l.), and the Quillaja where V is the average volume (cm3)ofeachdrop. brasiliensis sample was taken on the forest extract edge, in the EEC area The critical micelle concentration (CMC) is the concentration from (31°37′ S, 052°31 W, 180 m a.s.l.).

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