Anti-inflammatory , analgesic , and immunostimulatory effects of Luehea divaricata Mart . & Zucc . ( Malvaceae ) bark

1Area of Biological and Health Sciences, West University of Santa Catarina, Joaçaba, SC, Brazil, 2Pelé Pequeno Príncipe Research Institute, Curitiba, PR, Brazil, 3Area of Biological and Health Sciences, Pharmacy Graduation, West University of Santa Catarina, Videira, SC, Brazil, 4Chemical-Pharmaceutical Research Center University, Vale do Itajaí University, Itajaí, SC, Brazil, 5Cell Metabolism Laboratory, Department of Physiology, Biological Science Building, Federal University of Parana, Curitiba, PR, Brazil


INTRODUCTION
Luehea divaricata Mart.& Zucc.(Malvaceae) is a plant found in the South Region of Brazil and popularly known as "açoita-cavalo" by the local inhabitants.Its barks have been empirically described by local herbalists in Santa Catarina -Brazil to possess antimicrobial and anti-inflammatory properties, and it has been used in the treatment of respiratory and gastrointestinal infections, arthritis, rheumatism, and leukorrhea, and as vermifuge (data not published).
Despite the consumption of bark infusions by the local population, there is little scientific information about its biological activities.Antifungal properties have been attributed to a dichloromethane extract of L. divaricata barks (25 μg/filter disk), which was able to inhibit polymer synthesis or the assembly of the cell wall of Neurospora crassa (Zacchino et al., 1998).In 2003, Brazilian research characterized two triterpenes (a tormentic acid derivative and maslinic acid), which were obtained from a methanolic extract of L. divaricata leaves (Tanaka, Vidotti, Silva, 2003), but the biological properties of these compounds have not been assessed.The same research group identified a flavonoid, epicatechin, from a methanolic extract of the leaves of L. divaricata, which demonstrated antimicrobial activity against Staphylococcus aureus (250-500 μg/mL) (Tanaka et al., 2005).Coelho de Souza et al. (2004) also verified the antimicrobial activity of a methanolic extract (50 mg/mL) of the aerial parts of L. divaricata.Although previous research suggests that L. divaricata possesses biological activity, no known studies have validated the effectiveness of L. divaricata in the control of inflammatory diseases and pain or investigated the immunomodulatory capacity of this plant.
Inflammation is a complex process involving a network of chemical signals that mediate the actions of the immune system.During inflammation, serum proteins and leukocytes migrate to areas of tissue injury.These inflammatory and activated cells release vasoactive mediators such as nitric oxide, bradykinin, and metabolites of arachidonic acid, all of which increase regional blood flow and promote microvascular permeability (Suffredini et al., 1999).Several inflammatory mediators, mainly bradykinin and metabolites of arachidonic acid, are potent pain-producing agents that can excite and sensitize nociceptive primary afferent neurons (Petho, Reeh, 2012).Several plant extracts have been studied for their anti-inflammatory properties, by using in vitro and in vivo models (Ojewole, 2006;Siriwatanametanon et al., 2010;Areej et al., 2013), and existing data suggest that L. divaricata may also have similar characteristics.
Apart from anti-inflammatory qualities, natural compounds exhibit properties that may interfere with the modulation mechanisms of innate immunity, more specifically, the function of macrophages (Napolitano et al., 2005;Lee et al., 2007;Cruz et al., 2007).Plant derivatives present an exciting opportunity for the discovery of new therapeutic agents and adjuvants that exhibit immunomodulatory properties, potentially representing suitable alternatives for the prevention and treatment of immune-related pathologies (Kalluf, 2008;Tiwari et al., 2004).Plant extracts capable of stimulating the immune system might be useful in the treatment and prevention of infections.Immunostimulatory effects of plant-derived medicines following oral administration could be relevant in the search of new-generation vaccine adjuvants (Licciardi, Underwood, 2011).On the other hand, compounds that exert immunosuppression would be desirable in the treatment of autoimmune and chronic inflammatory diseases.Studies involving macrophages are very significant since they constitute the first line of defense of an organism and are responsible for activating many other processes involved in immune defense.In relation to macrophage functions, plant extracts have been shown to reduce nitric oxide production (Mehrotra et al., 2002;Napolitano et al., 2005), and reduce phagocytosis and expression of plasma membrane proteins (Lee et al., 2007), as well as stimulate phagocytic capacity and production of nitric oxide (Cruz et al., 2007).
To understand the biological potential of L. divaricata, the present study aimed to investigate the anti-inflammatory, analgesic, and immunomodulatory effects of the hydroalcoholic crude extract of L. divaricata (CLD) bark in mice.These data are an important starting point to characterize the potential biological benefits of L. divaricata and define some of its practical therapeutic applications in drug development.

Animal care
Adult female Swiss mice weighing 25-35 g were supplied by the West University of Santa Catarina.The animals were maintained in a controlled environment at 22 °C ± 2 °C with a 12 h light/dark cycle, with free access to water and food.All animals were acclimatized to the test laboratory 24 h prior to experiments.All procedures were approved by the Institutional Ethics Committee of West University of Santa Catarina (documents numbers: 011/2004, 135/2005 and 001/2010) and are in accordance with NIH Animal Care Guidelines.

Plant material and preparation of crude extract
The barks of L. divaricata were collected in March 2000, in Santa Clara, Joaçaba, Santa Catarina, Brazil (geographic coordinates: 27.1758°S, 51.5662°W).The specimen was identified with the collection documenting number 382.136 at the Municipal Botanical Museum, Curitiba-PR, Brazil, and stored at the same local.The collected barks of L. divaricata was then dried under ventilation in an air-flow chamber and pulverized.The powder was submitted to extraction by maceration (25-30 °C), with ethanol 80° GL for 14 days.The extract was filtered and concentrated in a vacuum with a rotatory evaporator, until completely dry.The dried extract was then stored at -20 °C until use.

Phytochemical analysis
1 g of crude extract of L. divaricata was dissolved in 5 mL of ethyl acetate or chloroform.After 5 min, the solution was filtered and dried to obtain ethyl acetate (SAE) or chloroform (SCHCl 3 ) samples.The yield of SAE and SCHCl 3 was 2.96% and 6.29%, respectively.Both fractions were checked by thin layer chromatography (TLC) according Hostettmann, Marston and Hostettmann (1998).In order to perform TLC, different eluents and systems as mobile phase were used, and silica gel 60 F 254 (Merck) as stationary phase.It was used standards from the bank´s laboratory, stigmasterol, lupeol, α,β-amyrin, vitexin, rutin, quercetin and epicatechin.Some of these compounds were isolated from the plant under study.
The chromatographic SCHCl 3 profile was carried out with two different solvent systems, hexane:acetone 7:3 and 8:2, and the standards used were α,β-amyrin, lupeol and stigmasterol.The SAE profile was performed with chloroform: methanol 8:2, using vitexin, rutin, epicatechin and quercetin as standards.In both cases, the spots were revealed using sulfuric anisaldehyde to 110 °C and ferric chloride.

Paw edema induced by carrageenan test
Experimental animals (n=6-10) were pre-treated with the crude extract of L. divaricata (CLD) at doses of 10-300 mg/kg, orally administered (via oral, v.o.), and control animals (n=10) received a vehicle (distilled water; 0.1 mL/10 g) in place of the CLD.After 1 h, the mice were anesthetized with halothane and were administered carrageenan (300 mg/paw, subcutaneous injection) into the right paw (Morris, 2003).The contralateral paw received the same volume of sterile phosphatebuffered saline (PBS) and served as a control.The paw volume was measured with a plethysmometer (Panlab, Barcelona, Spain) immediately after carrageenan or PBS administration, at specified time points (30, 60, 120, and 240 min after injection of phlogistic agent).The results are expressed as the mean ± standard error of mean (SEM) values of the difference in volume (in mililiters) between the carrageenan-and saline-treated paws.

Writhing test
Writhing is induced by an intraperitoneal (i.p.) injection of acetic acid (0.6%) as an irritant, following which writhing movements are observed and evaluated for 30 min (Koster, Anderson, Debeer, 1959).Experimental animals (n=6-10) were pre-treated with the CLD at doses of 10 -300 mg/kg, orally administered (via oral, v.o.) 1 h prior to injection of acetic acid.Control animals (n=10) received a vehicle (distilled water; 0.1 mL/10 g) in place of the CLD.The results are expressed as the mean ± SEM of the number of times the animal writhed.

Paw formalin and capsaicin tests
Nociceptive behavior was induced by the injection of formalin (Hunskaar, Hole, 1987) or capsaicin (Sakurada et al., 1992) in the ventral surface of the right hind paw.Animals (n=6-10) were pre-treated as specified in the above-described writhing test.After 1 h of pretreatment with CLD or vehicle, the animals received a 20 mL injection of either 2.5% formalin solution (0.92% formaldehyde) or capsaicin (1.6 µg/paw) prepared in PBS.Following formalin or capsaicin injection, the mice were immediately placed in glass chambers, and the time spent licking, flicking, and biting the injected paw was measured with a stopwatch; this time (expressed in seconds) was considered an indication of nociception.This nociceptive behavior is recorded in two phases for the formalin test and only in the one phase for the capsaicin test.The first phase of nociceptive response normally peaks at 0-5 min, and the second phase, 15-30 min after the formalin injection.The results are expressed as the mean ± SEM of nociceptive behavior (in seconds).

Immunostimulatory activity evaluation and macrophage isolation
Animals were randomly separated into three groups, n=5 animals/group: Control Group, animals received only a vehicle (a solution consisting of 10% DMSO and 40% Tween 80 in saline); Treatment Group 100, received 100 mg•kg body weight -1 •day -1 of CLD; Group 200, received 200 mg•kg body weight -1 •day -1 .Body weight was measured immediately before administration.All animals were fed a regular chow diet (Nuvital ® ) and received water ad libitum, and the treatments with CLD or vehicle were performed by gavage daily for 15 days.After this period, the animals were sacrificed in a CO 2 chamber, and the macrophages were collected.This experiment was performed in triplicate such that the total number of animals evaluated per group was 15.
Following euthanasia, the resident macrophages were obtained after i.p. injection of 5 mL of sterile PBS, massaging and opening the peritoneum, and drawing back of the fluid with a Pasteur pipette (~5 mL).Macrophages were collected by centrifugation (290xg, 4 °C for 5 min), the pellet was washed, and then resuspended in PBS after counting in a Neubauer chamber by optical microscopy, using a Trypan blue solution (1%).Adhesion assay and measurement of phagocytic capacity, lysosomal volume, superoxide anion production, and hydrogen peroxide production were performed using macrophage aliquots obtained in this manner.

Adhesion assay
Aliquots (0.1 mL) of macrophage suspension (5×10 6 cells/mL) were added to the wells of a 96-well flat-bottomed tissue culture plate and left to adhere for 1h under controlled temperature (37 °C).After washing with PBS, 0.15 mL of 50% methanol was added to each well, and incubated for 10min at room temperature.The supernatant was discarded, and 0.1 mL of 0.2% Giemsa solution was added.After incubating at room temperature for 40min, washing with distilled water, and incubating with 0.2 mL of 50% methanol at room temperature (Rosen, Gordon, 1987), the absorbance was measured at 550 nm (Microplate Reader 680; Biorad ® ).The mean of adhesion absorbance values of each group (C, 100 and 200) was used to normalize data for phagocytic capacity, lysosomal volume and ROS production assays (normalized value=absorbance value of group x/mean of adhesion absorbance of group x).This normalization was done to adapt results to the actual number of adherent cells on the plate.

Phagocytic capacity
Aliquots (0.1mL) of macrophage suspension (2×10 6 cells/mL) were added to the wells of a 96-well flat-bottomed tissue culture plate and left to adhere for 1h under controlled temperature (37 °C).Then, 10 μL of neutral red-stained zymosan (1×10 8 particles/mL) were added to each well.After incubation for 30 min at 37 °C, the cells were then fixed with Baker´s formol-calcium (4% formaldehyde, 2% sodium chloride, and 1% calcium acetate), 0.1 mL/well, for 30 min.The cells were washed two times and centrifuged, and then, 0.1 mL of acidified alcohol (10% acetic acid, 40% ethanol in distilled water) was added to each well (Bonatto et al., 2004).After 30 min at 37 °C, the absorbance was measured at 550 nm using the microplate reader.

Lysosomal volume
Lysosomal volume was measured using the method described by Pipe, Coles and Farley (1995).A macrophage suspension (0.1 mL, 1×10 6 cells/mL) was incubated for 1 h at 37 °C, and then, 0.02 mL of 2% neutral red solution in PBS was added, and the samples were incubated for 30 min at 37 °C.The cells were washed twice with PBS and centrifuged.Neutral red was solubilized with 0.1 mL of the extraction solution (1% acetic acid in 50% ethanol) (Bonatto et al., 2004).After 30min of incubation at 37 °C, the absorbance was measured at 550 nm using the microplate reader.

Superoxide anion production
Superoxide production was estimated by the NBT reduction assay (Madhavi, Das, 1994).Macrophages (0.1 mL) suspended in PBS (2×10 6 cells/mL) were incubated for 1 h at 37 °C in the presence of 0.01 mL of 10 μM phorbol myristate acetate (PMA).Subsequently, 0.1 mL of NBT solution (0.25%) was added and the samples were incubated at 37 °C for 30 min.After centrifugation, cells were fixed with 0.1mL of 50% methanol.To assess the amount of superoxide anion production by the cells, the formazan resulting from NBT reduction was solubilized with 0.12 mL of 2 M potassium hydroxide (KOH) and 0.14 mL of DMSO.After 30 min of incubation, the absorbance was measured at 550 nm using the microplate reader.

Hydrogen peroxide production
Hydrogen peroxide production by macrophages was measured as described by Pick and Mizel (1981).This assay is based on horseradish peroxidase-dependent conversion of phenol red into a colored compound by H 2 O 2 .Macrophages (0.1 mL, 2×10 6 cells/mL) were incubated at 37 °C for 1 h and 10 μM PMA (0.01 mL) was added to all the wells.Cells were then incubated in the presence of 0.1 mL of phenol red solution (5 mM glucose, 0.56 mM phenol red, and 8.5 U/mL horseradish peroxidase) in the dark for 1h at 37 °C.The reaction was stopped by adding 0.01 mL of 1 M NaOH, and the absorbance was measured at 655 nm using the microplate reader.

Statistical analysis
Data are presented as mean ± standard error of the mean (SEM).Statistical analysis was performed by one way ANOVA followed by Tukey's post-hoc test.A P value of <0.05 was considered statistically significant.

Phytochemical analysis
Phytochemical analysis by TLC suggested the presence of epicatechin in SAE (Figure 1A), and stigmasterol, lupeol and α and β-amyrin in the SCHCl 3 (Figure 1B).The other compounds investigated were not found.

Anti-inflammatory and analgesic effects
Pretreatment of animals with CLD reduced carrageenan-induced edema formation by 36.8% and 50.2% at the 100 and 300 mg/kg, respectively (Table I, p<0.05).The higher dose of CLD reduced writhing by 64.4% (Table II, p<0.05).Moreover, CLD significantly reduced the second phase of formalin reactivity (inflammatory phase) by 81.2% and 91.6% at 100 and 300 mg/kg, respectively (Table II, p<0.05).Capsaicin reactivity was also reduced; the time spent on painful activities was reduced by 63.9% in animals that received the higher dose of CLD (Table II).

Adhesion capacity
Animals that received 200 mg/kg of CLD (Group 200) significantly reduced macrophage adhesion compared to both the Control Group and Group 100 (~55%, p <0.05).Group 100 showed similar adhesion capacity to the Control Group (p >0.05) (Figure 2).

Phagocytic capacity
Macrophages from Group 200 showed ~3-fold increased phagocytic capacity than the Control Group (p <0.001) and Group 100 (p <0.001).There was no significant difference between the Control Group and Group 100 (p >0.05) (Figure 3).

Lysosomal volume
Neutral red uptake by the macrophages in Group 200 was ~50% greater than that observed to the Control Group (p <0.001), which was in contrast to the macrophages from Group 100, which showed a reduction of uptake capacity by ~20%.Group 200 presented ~90% higher uptake capacity than Group 100 (p <0.001, Figure 4).

Reactive oxygen species (ROS) production
Superoxide anion (Figure 5) and hydrogen peroxide (Figure 6) production was ~90% greater in the macrophages from Group 200 than those from the Control Group (p <0.001).The macrophages from Group 100 produced half the concentration of ROS compared to that of Group 200 (p <0.001).No statistical difference was observed between the Control Group and Group 100.

DISCUSSION
Bioactive compounds found in medicinal plants may present anti-inflammatory and analgesic capacities, in addition to immunomodulation properties.Indeed, many compounds isolated from plant extracts have demonstrated anti-inflammatory properties as well as immunostimulatory activities (da Silva, Parente, 2001;Biella et al., 2008;Halder et al., 2009).The current study characterizes the biological activity of L. divaricata bark for the first time, specifically showing that CLD reduced inflammation in all assays performed and that it stimulated macrophage activity.
Thin layer chromatography (Figure 1) revealed the presence of epicatechin in the SAE, and stigmasterol, lupeol and α and β-amyrin in the SCHCl 3 .Whereas some flavonoids and triterpenes exhibit immunomodulatory and anti-inflammatory activities (Saleem, 2009;Sabeva et al., 2011;Ahmad et al., 2013;Rosenblat, Volkova, Aviram, 2013), it is possible that they may be partly responsible for the activities found in the present study.
Carrageenan-induced paw edema is a wellcharacterized experimental model of inflammation, and it has been widely used to investigate the efficacy of natural compounds (Nardi et al., 2003;Wang et al., 2013).The acute inflammatory reaction elicited by carrageenan is characterized by sequential liberation of inflammatory mediators, promoting marked accumulation of exudate and intense migration of polymorphonuclear leukocytes in the affected paw (Morris, 2003).In the present study, we clearly show the anti-inflammatory properties of CLD, as demonstrated by a dose-dependent reduction in paw edema in mice (Table I).This effect was evident 30 min after the oral administration of CLD, and was maintained throughout the evaluation period.
The writhing test is an experimental model used to screen investigational drugs for analgesic activity.This is evaluated by the irritation caused by the i.p. injection of acetic acid, which causes the release of mediators such as bradykinin, prostaglandins, histamine, and 5-hydroxytryptamine (Whittle, 1964).Different of writhing test, in formalin test is possible to identify two phases of nociception.The first phase is characterized by direct activation of primary afferent fibers, followed by the second phase, which is characterized by the release of several inflammatory mediators in the immediate area of formalin injection (Hunskaar, Hole, 1987;Corrêa, Calixto, 1993;Choi, Lee, Suh, 2001).The CLD effectively reduced writhing behavior that suggests a level of pain in animals (Table II).This reduction in pain by CLD is further supported by the reduction in pain, as demonstrated in the   second phase of formalin test for CLD-treated animals (Table II).The lack of effect of CLD in the first phase of the formalin test supports our hypothesis that antiinflammatory substances are responsible for the analgesic effect of CLD, rather than a direct excitation of the primary afferents.
Capsaicin is known to directly activate the vanilloid receptor (TRPV-1) in the primary afferent fibers, which transmits the nociceptive stimulus to the central nervous system, promoting the release of pro-inflammatory neuropeptides such as substance P, neurokinins, nitric oxide, and prostaglandins.These substances are responsible for producing the sensation of pain and inflammatory process (Holzer, 1991;Wu et al., 1998;Palazzo, Rossi, Malone, 2008).The data on formalin test paired with the reduction in capsaicin-induced pain behavior suggests that CLD activity is due to the modulation of inflammatory mediators.Together with the reduction in edema in the carrageenan model, these data suggest that CLD contains anti-inflammatory substances, which act to reduce the sensation of pain by reducing inflammatory excitation of nociceptors in the primary afferent fibers.
Indigenous populations who use crude extract of L. divaricata to treat various conditions prepare infusions of the barks that are often administered orally.To simulate the effects of oral intake and evaluate the potential immunomodulatory activity of CLD, we orally administered CLD to animals for 15 days.According to Gertsch, Viveros-Paredes and Taylor (2011), the activity of the immune system can only unambiguously be evaluated in vivo, and the most ethnopharmacologically relevant way to test plant products is by oral administration.Here, we show that oral administration of a minimum of 200 mg/kg CLD produced an overall stimulatory effect on the peritoneal macrophages from mice.
The adhesion capacity of the macrophages from Group 200 was reduced by ~50% in comparison to those from both the Control Group and Group 100 (Figure 2).Modifications in the adhesion capacity of cells can be derived from changes in either the membrane fluidity (Calder et al., 1990;Noudeh et al., 2010) or in the distribution of adhesion molecules within the plasma membrane (KyungSeop et al., 2000;Kim et al., 2011).For example, there are reports showing that polyphenols and tannins contained in plant extracts are able to modify the properties of the plasma membrane, thereby affecting adhesion capacity (Cyboran, Oszmianski, Lkeszczynska, 2012;Olchowik et al., 2012).Interestingly, the phagocytic capacity observed in Group 200 was 3-fold greater than that observed for Control Group (p<0.001) (Figure 3).This measurement was normalized by adhesion capacity, and although the adhesion capacity of the cells in Group 200 was 50% lower than that observed for the Control Group, the phagocytic capacity of adherent cells was still 3-fold greater.Together, these data indicate that the substances present in the barks of L. divaricata are able to stimulate a significant macrophage-mediated response, contributing to the body of evidence demonstrating that plant components influence immunomodulation by altering the phagocytic capacity of macrophages (Bin-Hafeez et al., 2003;Lee et al., 2007;Cruz et al., 2007) and other phagocytic cells (Nudo, Catap, 2011).However, a dose of 100 mg/kg did not elicit an impact on the adhesion and phagocytic capacity of isolated macrophages, suggesting an insufficient concentration of bioactive molecules to provide immunomodulation.Notwithstanding the lack of response in Group 100, the results obtained in the current study, particularly in relation to phagocytosis modulation, suggest that CLD is able to strongly stimulate the innate immune system at sufficient concentrations.
Cellular digestion of agents contained in phagosomes is controlled by fusion to hydrolase-containing lysosomal vesicles.Neutral red uptake by macrophages in Group 200 was greater than that observed in Group 100 and the Control Group (Figure 4).This supports the dose-dependent response observed in phagocytic capacity (Figure 3), indicating that the cells were able to both phagocytose the cationic dye neutral red and process it.However, the lysosomal volume of Group 200 did not show a proportional increase in neutral red uptake with respect to phagocytic capacity.This mismatch between phagocytosis and dye uptake has also been observed by other research groups (Bonatto et al., 2004).Swanson and Baer (1995) report that several events enable fusion between the lysosomal vacuolar membrane and phagosomes, which together form a phagolysosome.The rate of phagosome-lysosome fusion can vary dramatically depending on the nature of the encapsulated particles, suggesting that not all particles phagocytized stimulate a large change in lysosomal volume.This may partly explain the disparity between the results obtained for phagocytic capacity (Figure 3) and lysosomal volume (Figure 4) in Group 200.
Resting macrophages consume little oxygen, although activation by an appropriate stimulus leads to increased production of reactive oxygen species (ROS).ROS are produced by macrophages (superoxide anions and hydrogen peroxide) by a non-mitochondrial respiratory burst, which greatly increases consumption of oxygen and conversion to superoxide anions (Babior, 1984).The nicotinamide adenine dinucleotide phosphateoxidase (NADPH oxidase) enzyme that resides in the plasma membrane of phagocytes is responsible for this conversion, and it is activated by phagocytosis as well as by compounds such as PMA via activation of kinase C proteins (Lunardi, Lima, 2006).Superoxide anions and hydrogen peroxide that are immediate products of this respiratory burst lead to the generation of hypochlorite and chloramines, which are potent microbicidal oxidized halogens, in addition to hydroxyl radicals, an oxidizing radical that can damage all types of macromolecules (Babior, 1984).Our results show an increase in the concentrations of superoxide anion and hydrogen peroxide produced by the activated macrophages from Group 200 in comparison to those from Control Group (Figure 5 and Figure 6).These data are consistent with the increased phagocytic capacity of the macrophages from Group 200 animals.In these experiments, the cells of all groups were treated with PMA, but a greater concentration of superoxide anions and hydrogen peroxides were observed in Group 200 compared to Group C, suggesting that the crude extract at 200 mg/kg was able to stimulate the production of these ROS by macrophages.Studying the molecular mechanisms by which the compounds from CLD stimulate ROS production in macrophages was not the aim of this study, but we found that the crude extracts from medicinal plants are able to interact directly on the NADPH oxidase enzyme (Mahomoodally et al., 2012), suggesting that this action of the extract on this enzyme cannot be ruled out.Physiologically, the activation of phagocytic NADPH oxidase can be induced by microbial products such as bacterial lipopolysaccharide, by lipoproteins, or by cytokines such as interferon-γ, interleukin-1β, or interleukin-8 (Bonizzi et al., 2000).In addition to exerting an important role as microbicidal agents, superoxides and related ROS contribute to signal transduction via various membrane receptors, and thus, to overall immunological function (Drogë, 2002).
Taken together, these results indicate that the CLD contains substances with both anti-inflammatory and analgesic effects, as well as immunomodulatory bioactive compounds capable of stimulating macrophage activity.These findings support the empirical use of this plant to combat different types of inflammatory diseases and infections.Further studies are necessary to elucidate the chemical compounds within CLD that contribute to these properties, and to evaluate the therapeutic effects exerted by these compounds on adaptive immune cells and their products.
1 a n.d.Each group represents the mean ± SEM for 6 to 10 animals.Significantly different from control group: a p <0.05.n.d., not determined.The time in seconds indicates time spent licking, flicking, and biting the injected paw.

FIGURE 2 -
FIGURE 2 -Adhesion capacity of resident macrophages from mice fed regular chow (Control Group), treated with 100 mg/kg b.w. of CLD (Group 100), and 200 mg/kg b.w.(Group 200).a p<0.05 compared to Control.b p<0.05 compared to Group 100.Results are presented as % relative to Control.

FIGURE 3 -
FIGURE 3 -Phagocytic capacity of resident macrophages from mice fed regular chow (Control Group), treated with 100 mg/kg b.w. of CLD (Group 100), and 200 mg/kg b.w.(Group 200).a p<0.001 compared to Control.b p<0.001 compared to Group 100.Results are presented as % relative to Control.

FIGURE 4 -
FIGURE 4 -Lysosomal volume of resident macrophages from mice fed regular chow (Control Group), treated with 100 mg/kg b.w. of CLD (Group 100), and 200 mg/kg b.w.(Group 200).a p<0.001 compared to Control.b p<0.001 compared to 100.Results are presented as % relative to control.

FIGURE 5 -
FIGURE 5 -Superoxide anion production of resident macrophages from mice fed regular chow (Control Group), treated with 100 mg/kg b.w. of CLD (Group 100), and 200mg/kg b.w.(Group 200).a p<0.001 compared to Control.b p<0.001 compared to 100.Results are presented as % relative to control.

FIGURE 6 -
FIGURE 6 -Hydrogen peroxide production of resident macrophages from mice fed regular chow (Control Group), treated with 100 mg/kg b.w. of CLD (Group 100), and 200 mg/kg b.w.(Group 200).a p<0.001 compared to Control.b p<0.001 compared to 100.Results are presented as % relative to control.

TABLE I -
Anti-inflammatory effect of crude extract of L. divaricata (CLD) on the paw edema induced by carrageenan test in mice Each group represents the mean for 6 to 10 animals.Significantly different from control group: a p <0.05.Results are presented as mean ± EPM values of the difference in volume (mL) between the carrageenan-and saline-treated paws.The edema inhibition was determined by calculating the area under curve.

TABLE II -
Analgesic effect of crude extract of L. divaricata (CLD) on the writhing test, paw formalin test and paw capsaicin test in mice