Comparison of chemical constituents of Chamomilla recutita (L.) rauschert essential oil and its anti-chemotactic activity

Presibella, Mayra Marinho; Villas-Bôas, Larissa De Biaggi; Belletti, Klézia Morais da Silva; Santos, Cid Aimbiré de Moraes; Weffort-Santos, Almeriane Maria

doi:10.1590/S1516-89132006000600005

Abstracts

Several essential oil samples from dried flower-heads of Chamomilla recutita (L.) Rauschert, grown and commercially available around Curitiba metropolitan area, South of Brazil, were analyzed by GC-MS and the chemical constituents were compared with an Egyptian sample obtained under similar conditions and used as a control. The local grown herbs showed levels of essential oil below the standards recommended by the Brazilian Pharmacopoeia. Also, differences in their composition as well as in the quantity of several components were found such as the unexpected inversion of the relative constitution of the A and B alpha-bisabolol oxides. Of particular interest was the striking effect of the chamomile extracts upon human leukocyte chemotaxis, a biological anti-inflammatory activity not reported before, in which cell migration was in vitro inhibited at the same level as showed by dexamethasone.

Chamomilla recutita; Asteraceae; essential oil; chemotaxis; bisabolol oxide

Óleos essenciais extraídos de amostras de Chamomilla recutita (l.) Rauschert cultivadas e comercializadas na região metropolitana de Curitiba, sul do Brasil, foram analisadas por cromatografia com fase gasosa acoplada à espectrometria de massa e seus constituintes químicos comparados com uma amostra egípcia, usada como controle. A quantidade de óleo essencial obtida das amostras locais foi abaixo do padrão recomendado pela Farmacopéia Brasileira IV. Observou-se, também, diferenças na composição química desses óleos, assim como na quantidade relativa dos constituintes, como os óxidos A e B do alfa-bisabolol. De particular interesse foram os efeitos inibidores dos extratos de camomila sobre a quimiotaxia de leucócitos humanos induzida por caseína, efeito biológico descrito pela primeira vez e semelhante ao promovido pela dexametasona.

HUMAN AND ANIMAL HEALTH

Comparison of chemical constituents of Chamomilla recutita (L.) rauschert essential oil and its anti-chemotactic activity

Mayra Marinho Presibella; Larissa De Biaggi Villas-Bôas; Klézia Morais da Silva Belletti; Cid Aimbiré de Moraes Santos; Almeriane Maria Weffort-Santos^* * Author for correspondence

Programa de Pós-graduação em Ciências Farmacêuticas; Universidade Federal do Paraná; Av. Prefeito Lothário Meissner, 632; Jd. Botânico; 80210-170; almeriane@ufpr.br; Curitiba - PR - Brasil

ABSTRACT

Several essential oil samples from dried flower-heads of Chamomilla recutita (L.) Rauschert, grown and commercially available around Curitiba metropolitan area, South of Brazil, were analyzed by GC-MS and the chemical constituents were compared with an Egyptian sample obtained under similar conditions and used as a control. The local grown herbs showed levels of essential oil below the standards recommended by the Brazilian Pharmacopoeia. Also, differences in their composition as well as in the quantity of several components were found such as the unexpected inversion of the relative constitution of the A and B a-bisabolol oxides. Of particular interest was the striking effect of the chamomile extracts upon human leukocyte chemotaxis, a biological anti-inflammatory activity not reported before, in which cell migration was in vitro inhibited at the same level as showed by dexamethasone.

Key words:Chamomilla recutita, Asteraceae, essential oil, chemotaxis, bisabolol oxide

RESUMO

Óleos essenciais extraídos de amostras de Chamomilla recutita (l.) Rauschert cultivadas e comercializadas na região metropolitana de Curitiba, sul do Brasil, foram analisadas por cromatografia com fase gasosa acoplada à espectrometria de massa e seus constituintes químicos comparados com uma amostra egípcia, usada como controle. A quantidade de óleo essencial obtida das amostras locais foi abaixo do padrão recomendado pela Farmacopéia Brasileira IV. Observou-se, também, diferenças na composição química desses óleos, assim como na quantidade relativa dos constituintes, como os óxidos A e B do a-bisabolol. De particular interesse foram os efeitos inibidores dos extratos de camomila sobre a quimiotaxia de leucócitos humanos induzida por caseína, efeito biológico descrito pela primeira vez e semelhante ao promovido pela dexametasona.

INTRODUCTION

Chamomilla recutita (L.) Rauschert, Asteraceae, or simply chamomile, is one of the most popular and well documented herbal medicine whose flower-heads are used both internally and externally to alleviate or even to cure a vast list of disturbances (Blumenthal, 2000), particularly those related to inflammation conditions (Maiche et al., 1991; Lepley et al., 1996; Birt et al., 1997; Hernández-Ceruelos et al., 2002). Although used in different pharmaceutical preparations (Tubaro et al., 1984; Mann and Staba, 1986; Maiche et al., 1991; Fidler et al., 1996; Li et al., 1996), chamomile is mostly consumed as infusion for sedative and anxiolytic purposes (Viola et al., 1995; Cauffield and Forbes, 1999; Larzelere and Wiseman, 2002), as a digestive aid to treat gastrointestinal disturbances, specially in babies and small children (Weizman et al., 1993; De la Motte et al., 1997; Madisch et al., 2001), and in domestic medicine in wetting cotton pads for topical application with the aim of helping the healing of skin wounds and cuts (Mills and Bone, 2000).

In the last decade, the regional herbal medicine free market has been offering to consumers the possibility of purchasing chamomile dried flower-heads, produced around Curitiba metropolitan area, along with imported and more expensive ones. Because herbal products can have differences in their composition depending on the soil where they grow (Salamon, 1992), and also may carry a variety of potential contaminating agents, such as pesticides, herbicides, heavy metals or even other herbal pharmaceuticals products that can cause toxicity or allergic reactions in sensitive persons (Stingeni et al., 1999), it is important to control all steps of their production to ensure that the final commercial products present the recommended characteristics by the specialized literature for pharmaceutical preparations. Therefore, they must present the potentially active chemical constituents described. In this context, it is worthy to note that formulations prepared from chamomile have been included in pharmacopoeias of at least 26 countries around the world (Salamon, 1992).

Although chamomile flower-heads have been produced in large scale in South of Brazil by several producers, there is no report concerning the compounds present in these marketed products. One of the aims of this work was to investigate and compare the chemical composition of some batches of chamomile produced locally. To achieve this, the essential oil composition of five samples from different producers purchased in the local herbal medicine free market were analyzed and compared with an Egyptian sample, which was used as a control as it had previously fulfilled all the Brazilian Pharmacopoeia recommendations. It was also questioned if these specimens could have potentially distinct biological effects. To address this question, the in vitro influence of the hydroethanolic extracts obtained from some of the final products were investigated on the chemotaxis of human leukocytes, one of the main steps of the body's inflammation response.

MATERIAL AND METHODS

Plant material

Six commercially available samples of dried Chamomilla recutita (L.) Rauschert flower-heads, five of them from plants grown in the metropolitan area of Curitiba, Paraná, Brazil, and one imported from Egypt for comparison, were purchased. Voucher specimens of each sample have been deposited at the Herbarium of the Laboratory of Pharmacognosy, Pharmacy Department, Federal University of Paraná, Brazil.

Essential oil extraction

Each sample (250 g) was subjected to 4 h hydrodistillation using a Clevenger apparatus and the recovered blue colored oils were dried over anhydrous sodium sulphate and kept at 4ºC in sealed brown vials until analysis.

Plant extract preparation

Each sample (50 g) was extracted for 48 h at room temperature in a percolator containing 20% ethanol (200 ml). The obtained extracts were filtered, concentrated under reduced pressure to dryness, re-suspended into Dulbecco's PBS, filter-sterilized (0.22 µm), aliquoted, and kept frozen at temperature -20°C up to their utilization.

Essential oil analysis

GC-MS analyses were carried out with a HP 6890 Hewlett-Packard gas chromatographer coupled with mass spectroscopy (GC-MS), equipped with 5% phenyl/95% methylsiloxane (HP-5MS) capillary column (L: 30 mm x I.D.: 0.25 mm, Ft.: 0.25 µm). The temperature programming condition was 40-250ºC at 4°C/min initial temperature; Helium at 0.8 ml/min was used as a carrier gas; 0.2 µl of oil injection; 280ºC transfer line temperature; 230ºC ion source temperature; 1:200 splitting ratio; 70 eV ionization energy; 50-480 amu scan range; 2 s scan time.

Components identification

The identification of each compound in the analyzed oils was performed by comparison of the relative retention time (RT) and the mass spectral data were obtained from the literature (Jakovlev et al., 1979; Adams, 1995; Hernández-Ceruelos et al., 2002) along with the NIST 98 computerized MS-data bank.

Human leukocytes isolation

The protocol used in this work for human peripheral blood collection has been approved by the Clinical Hospital Ethical Committee of the Federal University of Paraná, CEP-HC No. 066EXT020/2002-11. Peripheral blood samples (10 ml) in EDTA-K₃ were obtained by venipuncture from healthy volunteers after consent. Buffy coats were obtained after spinning the samples at 800 g for 25 min at room temperature and collecting the upper, leukocyte-rich fraction. Contaminating erythrocytes were removed by osmotic lysis with Gey's buffer (solution A: NH₄Cl 654.20 mM/l, KCl 24.83 mM/l, Na₂HPO₄.H₂O 6.53 mM, KH₂PO₄ 0.88 mM/l, glucose 27.77 mM, phenol red 0.05 g/l; solution B: MgCl₂.6H₂O 2.06 mM, MgSO₄.7H₂O 0.56 mM, CaCl₂ 3.42 mM; solution C: NaHCO₃ 26.78 mM, all at pH 7.2-7.4; just before use, 4:1:1 parts of solutions A, B, and C were, respectively, added to 14 parts of H₂0, filter-sterilized, and kept at room temperature). After washing twice in PBS, the remaining leukocytes were resuspended into PBS supplemented (PBSS) with glucose (0.1% w/v), BSA (0.25% w/v), CaCl₂ (0.90 mM), and MgCl₂ (0.5 mM), and the cell concentration was adjusted to 10⁶/ml. All cell preparations used contained > 95% viable cells as estimated by the trypan blue exclusion test. Granulocytes (neutrophils, eosinophils, and basophils) constituted the major leukocyte population (> 73%), followed by mononuclear cells (lymphocytes and monocytes).

Extracts and drugs' cytotoxicity

Primary screening tests upon leukocytes measured with all tested concentrations of chamomile extracts and dexamethasone using the trypan blue exclusion test did not show any signs of cytotoxicity to the human leukocytes and their viability was always higher than 95%, before and after the migration experiments.

Leukocyte migration

Leukocytes were incubated with increasing extract concentrations (0.1-10³ µg/ml) for 30 min at 37°C, washed twice with PBS, and resuspended into PBSS. Thereafter, migration of the treated cells towards casein was measured using a modified Boyden technique (Boyden, 1962). Briefly, the upper chamber was separated from the lower one by a 5 µm pore size, PVP free polycarbonate filter (NeuroProbe) and loaded with 2x10⁵ human leukocytes, which were stimulated to migrate towards 1% (w/v) casein gradient placed into the lower chamber for 90 min at 37°C. In some experiments, the cells were first pre-treated with dexamethasone (Decadron-Prodome; 10^-5M) or with increasing concentrations (0.1 10³ µg/ml) of chamomile extracts, both at room temperature for 30 min, before chemotaxis. Cell migration was expressed as a percentage of the control, i.e., the number of cells, which had not been treated with any plant extract, migrating towards chemoattractant under similar conditions. It is important to note that the experimental protocol used allowed only the migration of granulocytes, and cytospun preparations stained with May-Grunwald-Giemsa showed that > 95% of the migrated cells were neutrophils.

Statistical evaluation

The results are expressed as the mean % ± SEM of migrated cells. Statistical significance was calculated by the t test and differences were considered significant when p < 0.05.

RESULTS

The percentage of essential oil found for the Brazilian samples varied from 0.2 to 0.3% (v/w), and it was 0.5% (v/w) for the Egyptian control, showing that the local specimens were not in accordance with the standards required by the Brazilian Pharmacopoeia, which is at least 0.4% (v/w) (Farmacopéia, 1996). Table 1 shows the retention time (RT) and relative abundance (%) of the essential oil constituents included in this study (only those in amounts higher than 0.1%). The profile of the control sample was similar to those described in the literature (Jakolev et al., 1983; Scalia et al., 1999; Hernández-Ceruelos et al., 2002), and was used for comparison. Most of the known chamomile essential oil components such as b-farnesene (RT: 24.95), spathulenol (RT: 28.60), b-eudesmol (RT: 30.66), a-bisabolol oxide B (RT: 30.81), a-bisabolol (RT: 31.59) or a-bisabolol oxide A (RT: 33.42), could be identified in all samples, although broad variation in their relative abundance was observed. Interestingly, chamazulene (RT: 32.79), one of the most important constituents of chamomile essential oil, was not detected in Sample 5 under the used experimental conditions.

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The compounds n-hexadecanoic acid (RT: 38.85), n-hexadecanoic acid ethyl ester (RT: 39.38), and hexatriacontane (RT: 50.07), which have been reported as wax by Scalia and co-workers (Scalia et al., 1999), could be identified in the majority of the samples. On the other hand, p-cimene (RT: 10.35), n-decanoic acid ethyl ester (RT: 23.06), and trans-en-in-dicycloether (RT: 37.08) were detected only in the control, while the artemisia ketone (RT: 11.67) was present only in Sample 1.

One of the most intriguing results of this work was related to the quantitative profile of the a-bisabolol oxides A and B, in which a clear inversion was found, with the Brazilian samples presenting higher amounts of the B oxide, and lower amounts of A oxide, in relevant contrast with the values found for the control, which was in agreement with the literature (Scalia et al., 1999; Hernández-Ceruelos et al., 2002).

The effects of exposing human leukocytes from peripheral blood to increasing concentrations of a national (Sample 1) and the Egyptian chamomile extracts before inducing them to migrate towards a casein gradient are shown in Fig. 1.

The Brazilian plant extract resulted in an unexpected increased dose-related number of cells retained in the upper chamber compartment in comparison with untreated controls up to 10 µg/ml, the best result concentration, with only 65.8 ± 5.3% of the cells recovered from the lower chamber (n = 15; p < 0.005). When similar treatment was performed with the control sample, a significant inhibitory effect was also observed but it showed a different dose-response profile, in which a dose-related decreasing effect was observed. The maximum significant effect was at the concentration of 0.1 µg/ml of extract, the lowest dose tested, with only 65.9 ± 4.3% of the cells recovered from the lower compartment (n = 8; p < 0.005). For DEXA (10^-5M), which had the ability to inhibit the migration properties of leukocytes in vitro (Lomas et al., 1991; Zentay et al., 1999), and had been considered a model for this purpose, the value found using similar conditions was 69.1 ± 6.2% (n = 17; p < 0.005).

DISCUSSION

Chamomile dried flower-heads are worldwide used to treat an extensive list of conditions (Blumenthal, 2000), varying from skin inflammation (Tubaro et al., 1984; Rekka et al., 1996; Brown and Dattner, 1998; Leung and Foster, 1998) to cancer (Maiche et al., 1991; Lepley et al., 1996; Birt et al., 1997; Hernández-Ceruelos et al., 2002), and several of its potentially biologicaly active chemical constituents have been isolated, specially those from its essential oil (Habersang et al., 1979; Jakolev et al., 1979; Jakolev et al., 1983; Safayhi et al., 1994; Gerritsen et al., 1995; Miller et al., 1996; Rekka et al., 1996; Avallone et al., 2000). The terpenoid chamazulene has been reported to affect the levels of protein up-regulation at transcriptional level (Gerritsen et al., 1995; Rekka et al., 1996; Liang et al., 1999). Bisabolol, one of the most abundant components of the essential oil, apart from its spasmolytic effects on intestinal smooth muscle (Achterrath-Tuckermann et al., 1980; Forster et al., 1980), has been reported to have anti-inflammatory, antibacterial, antipyretic, antifungal properties (Berry, 1995; Blumenthal, 2000) as well as ulcer-protective effect (Isaac, 1979).

The data obtained from the GC-MS analysis showed clear and relevant differences in the chemical composition of the local samples when compared with the control. It was hypothesized whether these differences could affect the anti-inflammatory properties of these herbal plants. To address this question, a modified Boyden chamber system (Boyden, 1962) was used to test the ability of human leukocytes to migrate actively towards casein through a membrane in response to casein after their exposure to chamomile hydroethanolic extracts instead of using the essential oil. This approach was taken because, first, most if not all, essential oil constituents were present in the extract, and, second, because chamomile in this country has been largely consumed as a tea or infusion, and the extract would be the closest form to this traditional medicine use in the treatment of inflammatory conditions. Also, it would be worthy to note that this methodology has been extensively used as a model for investigating specific effects of plant extracts upon leukocyte locomotion (Muller et al., 1999; Hofbauer et al., 2000, 2001; Shen et al., 2001).

The biological data showed an unexpected and significant inhibition of the casein-induced polymorphonuclear leukocytes migration for both national and imported chamomile extracts tested. However, the intensity of such activity was distinct according to the dose and sample tested. For the local chamomile extract, the maximum inhibition effect observed was at the concentration of at least one hundred times higher than the value found for the imported sample under the experimental conditions used. Moreover, both effects were very close to the significant effects caused by DEXA, an anti-inflammatory drug commonly used in this system as a negative regulator of leukocyte chemotaxis (Lomas et al., 1991; Zentay et al., 1999).

These results could reflect the differences in their composition, some of which were revealed by the GC-MS analysis performed in this work. Moreover, they might be associated with the conditions in which these plants were produced, including all steps from the quality and preparation of the soil through the growing period, harvesting time, drying conditions to its presentation to the consumers at the free market, suggesting that surveillance on the quality control procedures must be taken when producing herbs, particularly for medicinal purposes.

Worthy of note in the present investigation was the significant inhibition of casein-induced human leukocyte chemotaxis by the chamomile extracts, suggesting that exposure of human leukocytes to chamomile was associated with impairment of leukocyte functions. Although the influence of chamomile or its compounds have been extensively investigated for inflammation processes using in vivo and in vitro approaches, to our knowledge there were no reports concerning to their influence on the chemotactic activity of human leukocytes, one of the most important steps of the body's inflammatory response.

While the cellular and molecular mechanisms involved remain obscure, the biological findings described in this study could be of particular relevance in clinical practice as at least a novel attractive hypothesis that could support the popular usage of chamomile infusions for combating inflammatory processes was revealed. By inhibiting the exacerbated leukocyte migration to the inflammation injury sites, chamomile could alleviate the symptoms and cope with wound healing produced by the inflammation process. Also, the intensity of such activity could be somewhat dependent on the quality of the medicinal plant used. Further analysis would be needed to clarify whether one or more of the known chamomile compounds were responsible for the inhibitory migration activity described in this work, or whether these effects were the result of the interaction of several compounds present in the extract, favoring the use of phytotherapic preparations.

ACKNOWLEDGEMENTS

One of us (L.D.B.V-B.) thanks CNPq for PIBIC scholarship.

Received: December 20, 2004;

Revised: July 04, 2005;

Accepted: March 30, 2006.

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*

Author for correspondence

Publication Dates

Publication in this collection
26 Feb 2007
Date of issue
Sept 2006

History

Received
20 Dec 2004
Reviewed
04 July 2005
Accepted
30 Mar 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Achterrath-Tuckermann, U.; Kunde, R.; Flaskamp, E., Isaac; O. and Thiemer, K. (1980), Pharmacological investigations with compounds of chamomile. V. Investigations on the spasmolytic effect of compounds of chamomile and Kamillosan on the isolated guinea pig ileum. Planta Medica, 39, 38-50.

[2] Adams, R. P. (1995), Identification of essential oil components by Gas Chromatography/Mass Spectroscopy. Illinois, Allured Publishing Corporation.

[3] Avallone, R. P. Z.; Puia, G.; Kleinschnitz. M.; Schreier, P. and Baraldi, M. (2000), Pharmacological profile of apigenin, a flavonoid isolated from Matricaria chamomilla. Biochemical Pharmacology, 59, 1387-1394.

[4] Berry, M. (1995), Herbal Products. Part 6. Chamomiles. Pharmacology Journal, 254, 191-193.

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