Vaccinium macrocarpon Aiton Extract Ameliorates Inflammation and Hyperalgesia through Oxidative Stress Inhibition in Experimental Acute Pancreatitis

We evaluated the effect of the hydroethanolic extract of fruits of Vaccinium macrocarpon (HEVm) in a model of acute pancreatitis (AP) in mice. AP was induced by two injections of L-arginine and animals were treated with HEVm (50, 100, and 200 mg/kg, p.o.) or vehicle (saline) every 24 h, starting 1 h after the induction of AP. Phytochemical analysis of the extract and measurement of inflammatory and oxidative stress parameters, as well as abdominal hyperalgesia, were performed. Catechin, epicatechin, rutin, and anthocyanins were identified in HEVm. Treatment with HEVm decreased L-arginine-induced abdominal hyperalgesia (from 48 to 72 h). Also, treatment with HEVm decreased L-arginine-induced pancreatic edema, pancreatic and pulmonary neutrophil infiltration, and levels of tumor necrosis factor-α, interleukin-1β, and interleukin-6, after 72 h of induction. L-arginine-induced hyperamylasemia and hyperlipasemia were also reduced by the treatment with HEVm in comparison to vehicle-treated group. Moreover, lipoperoxidation, carbonyl radicals, nonprotein sulfhydryl groups, and activity of catalase and superoxide dismutase, but not glutathione peroxidase, were restored by the treatment with HEVm. These results show that treatment with HEVm decreased hyperalgesia and pancreatic/extrapancreatic inflammation and oxidative damage in L-arginine-induced AP, making this extract attractive for future approaches designed to treat this condition.


Introduction
Acute pancreatitis (AP) is a disease that leads to pancreatic inflammation, related to the premature activation of digestive enzymes. The incidence of this disease has increased in recent years [1] which has contributed to a significant increase in mortality, mainly caused by complications of this condition such as the systemic inflammatory response [2].
The treatment of AP is primarily symptomatic and based on the initial evaluation of disease severity. It is directed to control pain, promote supportive therapy, meet the nutritional needs, treat complications, and prevent pancreatic infection and spread of the inflammatory process to remote organs [3]. The lack of specific therapy for AP along with the high mortality rates observed in severe cases makes experimental studies to find new treatment alternatives of great interest.
Among the sources of new medicinal active principles, natural products with proven antioxidant potential are of interest for the treatment of AP, since the local release 2 Evidence-Based Complementary and Alternative Medicine of reactive oxygen species (ROS) and inflammatory cell infiltration in the pancreas play a key role in the development of AP and complications associated with this condition [4].
The fruit of Vaccinium macrocarpon, Aiton (Ericaceae), is popularly known as cranberry and is used to make juices and sauces throughout North America. Due to promising results, the medicinal use of this plant has spread throughout to the Western world [5]. It contains anthocyanins, flavonoids, proanthocyanidins, condensed tannins, and phenolic acids. Recent studies have shown that an extract of fruits of V. macrocarpon containing approximately 1.82% anthocyanins can attenuate hepatic inflammation in obese mice [6] and inhibit the adhesion of pathogenic E. coli in patients with recurrent urinary tract infection [7]. In addition, treatment with this extract led to decreased intestinal inflammation in obese mice [5]. Clinically, cranberry preparations have been used in the treatment of urinary tract diseases and vascular inflammation, demonstrating high therapeutic potential [8], which may still be underestimated.
The need for new therapeutic options to treat AP along with the potential anti-inflammatory and antioxidant effect presented by cranberry makes it a viable alternative for the treatment pancreatitis. Thus, we investigated the possible effect of a hydroethanolic extract of fruits of Vaccinium macrocarpon (HEVm) in experimental AP in mice.

Plant Material. The hydroethanolic extract of fruits of
Vaccinium macrocarpon (HEVm) was purchased from Fagron BV, lot number 14083757D, with certificate of quality control analysis (HHHC140402).

Characterization of Hydroethanolic Extract of Fruits of Vaccinium macrocarpon.
Samples were dissolved with methanol : water (70 : 30, v : v), acidified with 5% acetic acid, using an ultrasound bath (Ultrasonic Cleaner 8892E-DTH; Cole-Parmer, Illinois, USA). After 10 min at room temperature, the dissolved extract was centrifuged at 3,500 ×g, for 10 min at 4 ∘ C. This procedure was repeated 3 times and the supernatants were combined. The supernatants were reduced under vacuum at 40 ∘ C in a rotary evaporator (Rotavapor RE 120; Buchi, Flawil, Switzerland) prior to passage through a C-18 extraction column (1 g) (Supelclean LC-18, Supelco, Pennsylvania, USA) previously conditioned with methanol and ultrapure water. The sample was loaded into the column and washed with ultrapure water. The phenolic compounds were eluted with methanol acidified with 0.3% HCl. The eluates were completely dried using a rotary evaporator under vacuum at 40 ∘ C, resuspended in methanol acidified with 5% acetic acid, and filtered through a 0.45 m PVDF filter (Millipore Ltd.) for the quantification of flavonoids by highperformance liquid chromatography-diode array detection (HPLC-DAD) analysis.
Quantification of flavonoids was carried out using an Agilent 1260 Infinity Quaternary LC System (Agilent Technologies, USA) coupled to a diode array detector (DAD). The column used was a 5 m Prodigy ODS3 column (4.60 × 250 mm) (Phenomenex Ltd., UK) with a flow rate of 1 mL/min at 25 ∘ C.
The mobile phase consisted of water/formic acid/acetonitrile (96 : 1 : 3 solvent A, and 58 : 1 : 51 solvent B). The solvent  gradient was 10% B at the beginning, 25% at 10 minutes,  31% at 15 minutes, 40% at 20 minutes, 50% at 30 minutes,  100% at 40 minutes, 10% at 45 minutes, and 10% at 50  minutes. Chromatograms were acquired at 270, 370, and  525 nm. The flavonoids were identified by comparing their retention times, diode array spectral characteristics, and mass spectra, analyzed using LC-ESI-MS/MS, with the standards and the data available in the literature. The quantification was done using a calibration curve of the commercial standards (catechin, epicatechin from Sigma-Aldrich (St. Louis, MO, USA), and cyanidin-3-O-glucoside from Extrasynthese, Genay, France).
The identification of the flavonoids was performed using a Prominence Liquid Chromatograph (Shimadzu, Japan) linked to an AmaZon SL ion trap mass spectrometer (Bruker Daltonics, Bremen, Germany) with an electrospray ionization (ESI) interface. The solvent gradient conditions were the same as those used for the HPLC-DAD analysis. After the sample was passed through the DAD, the flow rate was changed to 0.8 mL/min for examination by the mass spectrometer. The ESI was used in the positive and negative mode. The mass spectrometer operating condition was collision energy of 4,500 V for positive and negative mode. The analysis was carried out using a full scan from / 100 to 1,500. The compounds were identified according to mass spectral characteristics and comparison with literature data.

Animals.
Male adult Swiss mice (30-35 g) were obtained from the Animal Center of Federal University of Sergipe. The animals were maintained at 21 ± 2 ∘ C with free access to food (Nuvilab5) and filtered water under a 12 : 12 h light/dark cycle. All experimental procedures were approved by the Ethics Committee for Animal Use in Research of Federal University of Sergipe (protocol number 09/16) and were conducted in compliance with the Guide for Care and Use of Laboratory Animals (National Institutes of Health). During the experiments, animals were randomly distributed among the experimental groups and the experimenter was unaware of each group's identification.

Experimental Procedure.
Pancreatitis induction was performed by two intraperitoneal (i.p.) injections, 1 h apart, of L-arginine at the dose of 4 g/kg [9]. The solution for injection contained 8% L-arginine in sterile saline with pH adjusted to 7.0. The control group received sterile saline (NaCl, 0.9%). Seventy-two hours after the last injection, the animals were anesthetized (80 mg/kg of ketamine plus 10 mg/kg of xylazine), euthanized by exsanguination, and transcardially perfused with saline plus heparin (5 IU/L), and tissue samples (pancreas and lung) were collected. Blood was centrifuged at 1,000 ×g for 15 min at room temperature to separate serum samples. Aliquots of serum and tissues were stored at −80 ∘ C for proper analysis.

Experimental
Design. Animals were randomly distributed into five groups ( = 5-6 each). In the saline + vehicle group, animals were injected with sterile saline (0.9%, Evidence-Based Complementary and Alternative Medicine 3 5 mL/kg; i.p.; administration for 2 times) and treated with the vehicle (sterile saline; i.p.) at 1, 25, and 49 hours after the last injection of saline. In the L-arginine + vehicle group, animals were injected with L-arginine (4 g/kg; i.p.; administration for 2 times) and treated with the vehicle (i.p.) at 1, 25, and 49 hours after the last injection of L-arginine. In the three AP + HEVm groups, animals were injected with L-arginine (4 g/kg; i.p.; administration for 2 times) and treated with HEVm (50, 100, or 200 mg/kg p.o.) at 1, 25, and 49 hours after the last injection of L-arginine.

Measurement of Abdominal Hyperalgesia.
To evaluate the mechanical hyperalgesia in the abdominal region of mice, we used an electronic von Frey apparatus (Insight, Ribeirão Preto, São Paulo, Brazil), according to Abreu et al. [11], with minor adaptations. On the day of testing, mechanical stimuli were applied to the anterior lateral region of the abdomen of the animals, in triplicate, prior to any manipulation and 24, 48, or 72 h after AP induction. At each time point, an increasing stimulus (in g) was applied to the abdominal region of the mice, with an interval of at least 1 min apart, until any withdrawal behavior was observed and the threshold force (0.1 to 1000 g) value was registered by the equipment.
This test was performed off-stage, so that the examiner did not know the identity of the groups. Data were expressed as variation (Δ) by subtracting the mean value obtained from the three measurements taken at the time point referred to after AP induction from the mean basal value recorded for each animal (prior to pancreatitis).

Evaluation of Locomotor
Activity. The locomotor activity of mice was investigated in a circular open field apparatus (60 cm diameter; Insight, Ribeirão Preto, São Paulo, Brazil) as previously described [12]. The animals ( = 5) were pretreated with HEVm (200 mg/kg) or vehicle (1 h before) or diazepan (1 mg/kg, 30 min before) and were individually placed in the apparatus. After 1 min, the distance traveled (m), mobility time (s), and number of lines crossed were registered over a period of 5 min.

Determination of Inflammatory Markers.
The edema index was calculated as the ratio of wet weight and dry weight of the samples of pancreatic tissue as previously described [10].
To determine myeloperoxidase (MPO) activity, pancreas and lung samples were collected and homogenized with potassium phosphate buffer (50 mM, pH 6.0 containing 0.5% hexadecyltrimethylammonium bromide). Aliquots of the homogenates were centrifuged (2 min, 8,000 ×g, 4 ∘ C) and aliquots of the supernatants were incubated with a solution of o-dianisidine hydrochloride (0.167 mg/mL containing 0.005% H 2 O 2 ). The MPO activity was measured kinetically in a microliter plate scanner (Biotek5) at 460 nm over a period of 5 min. Results were expressed as units of MPO per mg tissue (UMPO/mg tissue). UMPO was considered as the amount of enzyme that degrades 1 mmol of hydrogen peroxide/min [13].
Enzyme-linked immunosorbent assay (ELISA) for interleukin-(IL-) 6, IL-1 , and tumor necrosis factor-(TNF-) was carried out in homogenate samples of pancreas and lung according to the manufacturer's instructions (R&D Systems). The results were corrected by the amount of tissue protein and expressed as pg of each cytokine/mg of protein. The protein content of tissues was determined by the Bradford method using the Bio-Rad5 protein assay reagent.

Determination of Biochemical Parameters in Serum.
Biochemical parameters in serum were assessed for each experimental group by using specific commercial kits for amylase (Katal Biotechnology, Belo Horizonte, MG, Brazil), lipase (Human do Brasil, São Paulo, SP, Brazil), aspartate aminotransferase (AST), and alanine aminotransferase (ALT) (Liquiform Labtest, Lagoa Santa, MG, Brazil), according to each manufacturer's instructions.

Determination of Antioxidant Activity.
Samples of pancreas and lung were homogenized in phosphate buffer 50 mM pH 7.0, centrifuged at 10,000 ×g, and the supernatant was used for all antioxidant assays.
Lipid peroxidation was determined by the presence of thiobarbituric acid reactive substances in samples of pancreas and lung homogenates by the method previously described by Bose et al. [14], with minor modifications [10]. The results were expressed as pmol of malondialdehyde (MDA) formed per mg of protein.
The determination of oxidized protein content (carbonyl groups) was performed [16] by the reaction of carbonyl groups and 2,4-dinitrophenylhydrazine. The concentration of carbonyl groups was calculated by using 21.5 mM −1 cm −1 as the extinction coefficient for aliphatic hydrazones and the results were expressed as nmol of carbonyls/mg of protein.
Tissue antioxidant status was evaluated in the homogenate of pancreas and lung tissues using the ferric reducing/ antioxidant power (FRAP) assay [17]. Results were plotted against a standard curve of ferrous sulphate (500-1500 mol/ L) and were expressed as mol of ferrous sulphate/mg of protein.
Catalase (CAT) activity was appraised by the decrease in absorption of H 2 O 2 at 240 nm, due to H 2 O 2 consumption by CAT, as previously described [18]. Specific activity was expressed as units of CAT/mg of protein.
The activity of Cu/Zn SOD was assayed by the adrenaline method, based on the capacity of SOD to inhibit autoxidation of adrenaline to adrenochrome. One unit of SOD activity was defined as the amount of protein causing 50% inhibition of the autoxidation of adrenaline at 26 ∘ C [19].
Glutathione peroxidase (GSH-Px) activity was determined as described previously [20]. Enzyme activity was  Table 1.  expressed as mol of glutathione oxidized/mg of protein/min by using the extinction coefficient for NADPH (6220 M −1 cm −1 ).

Effect of HEVm on Inflammatory Parameters.
Pancreatic inflammation induced by L-arginine was characterized by a marked increase of pancreatic MPO activity after 72 h. The treatment with HEVm at 200 mg/kg prevented this effect ( < 0.001) (Figure 2(a)). In addition, the induction of pancreatitis significantly increased MPO activity in the lung tissue compared with the saline group. This effect was also reduced by the treatment with HEVm at 200 mg/kg ( < 0.001, Figure 2(b)). L-arginine administration enhanced pancreatic edema index after injection (5.15 ± 0.05, < 0.001) compared with the saline group (4.39 ± 0.08), and the treatment with HEVm at 200 mg/kg produced a significant inhibition of this effect (4.38 ± 0.08, < 0.001), as did dexamethasone (4.38 ± 0.09, < 0.001). However, the treatment with HEVm at 50 or 100 mg/kg did not alter edema (5.14 ± 0.14, 4.92 ± 0.14, resp.).
In addition to the increase of the above-mentioned inflammatory parameters, the levels of TNF-, IL-1 , and IL-6 were significantly increased in pancreas and lung after AP induction by L-arginine (Figures 3(a)-3(f)) compared with animals injected with saline. The treatment with HEVm strongly modulated the levels of these cytokines. Levels of TNF-were significantly decreased by the treatment with HEVm in the pancreatic ( < 0.01 and < 0.05, resp., at 100 and 200 mg/kg, Figure 3(a)) and lung tissue ( < 0.001 at 50, 100, and 200 mg/kg, Figure 3 with vehicle-treated animals. The amount of IL-1 was also lower in pancreas ( < 0.01 at 50 and 200 mg/kg and < 0.001 at 100 mg/kg, Figure 3(c)) and lung tissues ( < 0.001, Figure 3(d)) in the group treated with HEVm compared to the vehicle-treated animals. A similar effect was observed for IL-6 levels, for which the groups treated with HEVm presented significantly lower levels of this cytokine in pancreas ( < 0.001, Figure 3(e)) and lung ( < 0.001, Figure 3(f)) compared with vehicle-treated animals. As a control, treatment with dexamethasone decreased the levels of these cytokines in both pancreas and lungs tissues ( Figure 3).

Effect of HEVm on Mechanical Abdominal
Hyperalgesia. L-arginine-induced AP was accompanied by a marked reduction of the intensity of stimulus needed to cause withdrawal behavior in mice after 48 or 72 h, denoting that mice developed abdominal hyperalgesia as a consequence of the pancreatic inflammation. Two-way ANOVA indicated a significant interaction between the time and treatment in this experiment ( < 0.001; F = 3.712). The injection of saline instead of L-arginine did not alter the mice's withdrawal behavior (Figure 4) in comparison to basal evaluation. Figure 4 also demonstrates that the treatment with HEVm clearly reduced the abdominal hyperalgesia of mice submitted to AP after 48 h ( < 0.01 at 50 mg/kg and < 0.05 at 100 mg/kg) or 72 h ( < 0.001 at 50 mg/kg, < 0.01 at 100 mg/kg, and < 0.05 at 200 mg/kg).
Of interest, no difference was observed in the mean basal values of intensity of stimulus needed to induce withdrawal behavior among the groups (saline + vehicle: 25.9 ± 2.0 g; L-arginine + vehicle: 28.2 ± 0.7 g; L-arginine + HEVm
was inhibited by the treatment with HEVm at doses of 50, 100, and 200 mg/kg ( < 0.001; Figure 5(a)) in pancreatic tissue compared with animals treated with the vehicle. In lung tissue, the production of MDA was also reduced by the doses of 50 ( < 0.05), 100, and 200 mg/kg ( < 0.001; Figure 5(b)) compared with animals treated with the vehicle.
In the pancreas and lung tissue of animals with AP, higher amounts of carbonyl radicals were found (Figures 5(c) and 5(d)). This effect was reversed in pancreas ( < 0.05 at 50 mg/kg and < 0.01 at 100 and 200 mg/kg; Figure 5(c)) and lung ( < 0.001 for all doses; Figure 5  Groups of mice (n = 5-6) were submitted to injection of L-arginine or saline, treated with HEVm (50, 100, or 200 mg/kg), dexamethasone (Dexa; 5 mg/kg), or vehicle (saline) and serum was collected after 72 h of induction. a < 0.01 and b < 0.05 versus the respective saline + vehicle group or c < 0.05, b < 0.01, and e < 0.001 versus the respective AP + vehicle group.
In addition, pancreatic and lung nonprotein sulfhydryl groups (NP-SH) were decreased by AP induction (Figures  5(e) and 5(f)). Treatment with HEVm at the doses of 100 and 200 mg/kg maintained the NP-SH content in pancreas ( < 0.05, Figure 5(e)) and lung ( < 0.001, Figure 5(f)) compared with animals treated with the vehicle.
Additionally, tissue antioxidant status was measured in the pancreas and lung through the determination of the total antioxidant activity by the reduction of iron (FRAP). Figures 5(g) and 5(h) demonstrate that tissue antioxidant capacity was significantly reduced in pancreas and lung after AP induction and the treatment with 200 mg/kg of HEVm maintained this capacity near the levels observed in animals from the vehicle + saline group, in both pancreas ( < 0.05; Figure 5(g)) and lung ( < 0.001; Figure 5(h)).
Since the treatment with HEVm produced a marked antioxidant effect in pancreas and lung tissue of animals with pancreatitis, the contribution of some antioxidant enzymes to this action was studied. The induction of AP reduced the activity of CAT, SOD, and GSH-Px enzymes in pancreas and CAT and SOD activities in lung ( Figure 6).  200 mg/kg ( < 0.05). Concomitantly, the activity of SOD significantly increased in the pancreas after treatment with HEVm at doses of 50 ( < 0.05), 100 ( < 0.01), and 200 mg/kg ( < 0.001; Figure 6(c)), which was also observed in lung tissue after treatment with 100 ( < 0.01) and 200 mg/kg ( < 0.05; Figure 6(d)). However, GPx activity was not modified by the treatment with HEVm in both pancreas and lung tissues (Figures 6(e) and 6(f)).

Discussion
The need for new experimental alternatives to treat AP is still a challenge, since there are no specific treatments for clinical management of this disease [3]. In this study we present data that demonstrates that HEVm can modulate the inflammatory response in pancreas and lung (with the participation of oxidative stress) and abdominal hyperalgesia during L-arginine-induced AP. The finding that HEVm has beneficial effect in experimental pancreatitis is novel for this extract, which is frequently used by people to treat inflammatory conditions of the urinary system [8]. However, the presence of flavonoids in this extract supports the possibility of a beneficial effect on AP. For this reason, we used the hydroethanolic extract of cranberry. Our current data reinforce this hypothesis in the model of pancreatitis induced by L-arginine. The phytochemical analysis of HEVm showed that catechins and epicatechins are its major components. It was possible to identify three flavan-3-ols, one flavonol, and three anthocyanins. Catechin, epicatechins, and cyanidin derivatives were previously described in cranberry preparations [21,22], as was quercetin-3-O-rutinoside (rutin) [23]. These compounds exert various biological effects, including antioxidant and anti-inflammatory effects [11,21].
Treatment with HEVm induced protective effects against pancreatic inflammation. The activity of MPO, edema index, and production of cytokines (TNF-, IL-1 , and IL-6) were reduced by this extract. Along with the lower pancreatic damage in animals treated with HEVm, the levels of serum amylase and lipase were lower, which corroborates the reduction of pancreatic damage. Neutrophil infiltration is a hallmark of AP [24] and our data show that HEVm can interfere with the presence of these cells in the pancreas. This agrees with previous findings that cranberry extract reduces the MPO activity in mice paws injected with carrageenan [23]. Similarly, treatment with 1.5% dried whole cranberry powder (incorporated in the diet) reduced MPO activity in the colon of mice submitted to dextran sulphate sodiuminduced colitis [25]. Altogether, these results highlight the anti-inflammatory effect of the extract of fruits of V. macrocarpon. In accordance with this effect, treatment with HEVm produced antiedematogenic effect. Corroborating this finding, [23] showed that the extract of V. macrocarpon fruits reduces the production of prostaglandins in vitro, possesses antioxidant activity, and inhibits carrageenan-induced mice paw edema. The reduction of neutrophil migration to the pancreas and edema formation induced by HEVm certainly are dependent on the inhibitory activity of proinflammatory cytokines. Our results demonstrate that pancreatic contents of TNF-, IL-1 , and IL-6 were reduced by the treatment with HEVm. Other studies have also demonstrated that the extract of cranberry inhibited IL-6, IL-8, and prostaglandin E 2 production by gingival fibroblasts stimulated with lipopolysaccharide in vitro [26] and that serum IL-1 and interferonconcentrations and TNF-and IL-1 mRNA expression in colon were reduced by treatment with cranberry in mice submitted to dextran sulphate sodium-induced colitis [25].
Besides pancreatic inflammation, abdominal hyperalgesia was observed 48 and 72 hours after pancreatitis induction. Similar results were described by Abreu et al. [11] in the model of L-arginine-induced pancreatitis and we believe that this mimics the abdominal pain observed in humans after an AP attack. The reduction of AP-induced abdominal hyperalgesia by the treatment with HEVm may be a consequence of the decrease of pancreatic inflammatory mediators, such as TNF-, IL-1 , and IL-6. However, we cannot discard the possibility that substances present in HEVm blocked the stimulation of nociceptive pathways. Since HEVm administration did not alter the locomotor activity of mice, we can exclude the possibility of muscular relaxation or central nervous system depression that could bias the nociceptive measurement. Few studies have focused on the possible analgesic effect of V. macrocarpon fruits. A randomized clinical study demonstrated that men receiving radiation therapy for prostate cancer and taking cranberry capsules presented lower incidence of pain and burning [27]. The presence of flavonoids could also contribute to this antihyperalgesic effect. A previous study showed that the extract of grapefruit rich in proanthocyanidin (a class of flavonoids) reduced nociception caused by sciatic nerve ligation-induced neuropathic pain in rats [28]. In addition, the grapefruit extract reduced the nociception induced by formalin in mice, by mechanisms involving the participation of opioid receptor activation [29]. Concordantly, a previous study by our group showed that rutin reduced abdominal hyperalgesia in L-arginine-induced pancreatitis in mice [11].
Following AP induction, many extrapancreatic responses were observed in animals injected with L-arginine, such as the increased MPO activity in lung and increased markers of hepatic injury. Although the mechanisms underlying these alterations are not well understood in this model of pancreatitis, the beneficial effect of HEVm is supported by these results. Serum ALT and AST levels were used as markers of extrapancreatic alterations in the present study. The increase in ALT, but not AST, is usually predictive of biliary pancreatitis [30]. However, in the model of Larginine-induced AP in rats, other authors have shown that both AST and ALT are increased [31], but no study has previously measured these enzymes in mice. Interestingly, this increase in hepatic enzymes was partially reduced by the administration of HEVm, which may in part be due to the reduction of pancreatic lesions, as observed by the decrease of pancreatic inflammatory markers and enzymes (amylase and lipase).
Lung injury is the secondary effect of pancreatitis most related to mortality in patients [32]. In the model of L-arginine-induced pancreatitis, lung MPO activity was increased 72 h after induction, corroborating previous findings [9]. The fact that the treatment with HEVm reduced lung MPO activity is complementary to the above-mentioned extrapancreatic protective effects, which might be a consequence of the reduction of pancreatic damage. Pancreatitisrelated lung injury is multifactorial and is associated with many factors, such as the presence of activated enzymes, destruction of the lung surfactant, low lung perfusion rates, and increased cytokine in lung tissue [33]. Interestingly, in agreement with the decrease in lung MPO activity, we detected lower TNF-, IL-1 , and IL-6 levels in lungs of animals treated with HEVm in comparison to the vehicletreated group.
Since the HEVm is rich in flavanols and other polyphenols and these compounds have antioxidant effects [11,34,35], we speculated that the beneficial actions observed in pancreatic and extrapancreatic parameters could take place with the involvement of antioxidant activity. In fact, increased TBARS and carbonyl groups in parallel with decreased NP-SH and total antioxidant capacity (FRAP) in both pancreas and lung indicated that oxidative stress plays a significant role in this model, as previously shown [11,36]. Treatment with HEVm maintained antioxidant capacity of the tissue (NP-SH and FRAP) and consequently reduced the oxidation markers (MDA and carbonyl), which can be attributed to the direct antioxidant effect of polyphenols found in HEVm [11,22,23,34,37]. Another reasonable possibility of explaining the antioxidant effect of HEVm is modulation of the activity of endogenous antioxidant enzymes. Pancreatitis induction was characterized by reduction of the activity of CAT, SOD, and GPx in pancreas and lung, corroborating previous findings [11]. The CAT and SOD activities were markedly altered by the treatment with HEVm, indicating that HEVm strongly modulates oxidative stress. Interestingly, CAT and SOD activities seemed to be more susceptible to reversion in pancreas than in lung, which agrees with the idea that the reduction of pancreatic damage was important to the modulation of extrapancreatic effects. The beneficial modulation of CAT and SOD activities in animals treated with HEVm was more evident than GPx activity, which was not altered by treatment with HEVm. Indeed, HEVm countered the L-arginine-induced increase in oxidation and decrease in antioxidative capacity.
The antioxidant effects observed in the treatment with HEVm can be caused by the compounds present in this extract. The phenolic compounds found in HEVm, like anthocyanins, rutin, catechin and epicatechins, and other phenolic compounds (e.g., quercetin, kaempferol, ellagic acid, and p-coumaric acid), are present in cranberries (for review, see [21,22]) and certainly contributed to the reduction of oxidative stress, which in turn decreased the pancreatic lesions and resulted in less severe extrapancreatic alterations in mice.
An important concern about cranberry extracts is regarding their safety. Many studies have found no toxicity after treatment with cranberry extracts for 6-10 weeks in experimental animals [5,6,38] or in humans [39,40], but a recent study found small differences in the spleen and kidney function of the progeny of mice treated with cranberry extract during pregnancy [41]. Thus, more specific studies are needed to assure the safety of cranberry extracts.
Altogether, our results indicate a protective role of HEVm in the model of AP induced by L-arginine, by reducing pancreatic damage, hyperalgesia, and remote alterations through the key participation of the antioxidant capacity of this extract. These findings provide insights into the possible use of this extract in the treatment of this disease.