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Impact of resveratrol and zinc on biomarkers of oxidative stress induced by Trichinella spiralis infection

Published online by Cambridge University Press:  15 December 2023

M.A. Salama*
Affiliation:
Department of Medical Parasitology, Faculty of Medicine, Zagazig University, Egypt
M.A. Alabiad
Affiliation:
Pathology Department, Faculty of Medicine, Zagazig University, Egypt
A.A. Saleh
Affiliation:
Department of Medical Parasitology, Faculty of Medicine, Zagazig University, Egypt
*
Corresponding author: M.A. Salama; Email: [email protected]
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Abstract

Trichinellosis is a re-emerging worldwide foodborne zoonosis. Oxidative stress is one of the most common detrimental effects caused by trichinellosis. In addition, Trichinella infection poses an infinite and major challenge to the host’s immune system. Resistance and side effects limit the efficiency of the existing anti-trichinella medication. Given that concern, this work aimed to investigate the anti-helminthic, antioxidant, anti-inflammatory and immunomodulatory effects of resveratrol and zinc during both phases of Trichinella spiralis infection. Sixty-four Swiss albino mice were divided into four equal groups: non-infected control, infected control, infected and treated with resveratrol, and infected and treated with zinc. Animals were sacrificed on the 7th and 35th days post-infection for intestinal and muscular phase assessments. Drug efficacy was assessed by biochemical, parasitological, histopathological, immunological, and immunohistochemical assays. Resveratrol and zinc can be promising antiparasitic, antioxidant, anti-inflammatory, and immunomodulatory agents, as evidenced by the significant decrease in parasite burden, the significant improvement of liver and kidney function parameters, the increase in total antioxidant capacity (TAC), the reduction of malondialdehyde (MDA) level, the increase in nuclear factor (erythroid-derived 2)-like-2 factor expression, and the improvement in histopathological findings. Moreover, both drugs enhanced the immune system and restored the disturbed immune balance by increasing the interleukin 12 (IL-12) level. In conclusion, resveratrol and zinc provide protection for the host against oxidative harm and the detrimental effects produced by the host’s defense response during Trichinella spiralis infection, making them promising natural alternatives for the treatment of trichinellosis.

Type
Research Paper
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Introduction

Trichinella spiralis (T. spiralis) is a common foodborne parasite that causes trichinellosis (Xu et al. Reference Xu, Bai, Xu, Wang, Dong, Shi, Xu, Li, Liu and Liu2021). It is challenging to estimate the prevalence of trichinellosis worldwide; however, it is possible that 11 million people are affected (Lee et al. Reference Lee, Kim, Lee, Kim and Quan2016). Human infection is acquired by ingestion of insufficiently cooked or uncooked meat (especially pork) harboring T. spiralis larvae (Jiang et al. Reference Jiang, Zhang, Wang, Han, Yang, Duan, Sun, Qi, Liu, Wang and Cui2016). In the stomach, the larvae excapsulate, move to the small intestine, and mature into adults. Adult females of T. spiralis live in the host’s small intestine epithelium, initiating immune-mediated hypersensitivity and inflammatory reactions that provoke the distinct intestinal pathology (Khan Reference Khan2008). The intestinal phase is crucial in trichinellosis since it defines both the progress and consequences of the disease (Ding et al. Reference Ding, Bai, Wang, Shi, Cai, Luo, Liu and Liu2017).

After mating, T. spiralis females release newly born larvae that pass into the blood and invade the striated muscles (Wu et al. Reference Wu, Sofronic-Milosavljevic, Nagano and Takahashi2008). Trichinella infection of the muscles for a long time interacts strongly with the immune system of the host, causing pronounced inflammation of the afflicted muscles (Bruschi and Chiumiento Reference Bruschi and Chiumiento2011).

Tissue damage in trichinellosis is influenced by various factors. The direct devastation triggered by the parasite and the oxidative stress state accompanying Trichinella infection are considered the primary causes of this damage. Additionally, the recruitment of inflammatory cells, when activated, release free radicals, nitrogen species, and an overabundance of reactive oxygen species (ROS) (Chiumiento and Bruschi Reference Chiumiento and Bruschi2009), Therefore, antioxidants and anti-inflammatory medications are anticipated to aid in protecting hosts from these harmful effects (Kazemzadeh et al. Reference Kazemzadeh, Mohammad and Mohammad2014). Chemotherapy is the primary efficient method to combat and control helminth parasites worldwide, although it triggers severe negative effects on hosts (Wang et al. Reference Wang, Rosa, Jasmer and Mitreva2015). Also, resistance against anti-helminthic drug substances is a widespread problem (Gang and Hallem Reference Gang and Hallem2016). Moreover, the frequently prescribed non-steroidal or steroidal anti-inflammatory medications have numerous side effects that restrict their usage (Badri et al. Reference Badri, Miladi, Nazari, Greige-Gerges, Fessi and Elaissari2016). Thus, there is an urgent need for innovative, safe, and effective compounds with anti-inflammatory and antioxidant properties (Kunnumakkara et al. Reference Kunnumakkara, Sailo, Banik, Harsha, Prasad, Gupta, Bharti and Aggarwal2018).

Resveratrol (RSV) is a polyphenolic stilbene ubiquitous in the peels of red fruits like grapes, berries, and nuts (Szkudelska and Szkudelski Reference Szkudelska and Szkudelski2010). It is a phytoalexin that is produced by plants and enhances their resistance to adverse environmental conditions and fungal and microbial infections (Chedea et al. Reference Chedea, Vicas, Sticozzi, Pessina, Frosini, Maioli and Valacchi2017). RSV is a powerful antioxidant. It lowers intracellular ROS production by several mechanisms that offer an antioxidant defense (Leonard et al. Reference Leonard, Xia, Jiang, Stinefelt, Klandorf, Harris and Shi2003; Robb et al. Reference Robb, Page, Wiens and Stuart2008; Tanno et al. Reference Tanno, Kuno, Yano, Miura, Hisahara, Ishikawa, Shimamoto and Horio2010). Furthermore, it has antimicrobial and antiparasitic activities (Wang et al. Reference Wang, Lai, Hsueh, Chiou, Lin and Liaw2006; Soliman et al. Reference Soliman, Ismail, Badr and Nasr2017; Elgendy et al. Reference Elgendy, Othman, Hasby Saad, Soliman and Mwafy2020), anti-inflammatory properties (Donnelly et al. Reference Donnelly, Newton, Kennedy, Fenwick, Leung, Ito, Russell and Barnes2004), as well as cardioprotective (Tanno et al. Reference Tanno, Kuno, Yano, Miura, Hisahara, Ishikawa, Shimamoto and Horio2010) and neuroprotective effects (Sun et al. Reference Sun, Xiao, Cai, Chen, Wei, Liu, Lv and Zou2010).

Zinc is one of the most precious trace elements in earth’s crust. Many enzymes in plants, people, and animals need it for their cellular and catalytic functions. It can be found in various foods, including eggs, poultry, dairy products, legumes, nuts, red meat, oysters, seafood, and cereals. Additionally, it is crucial for immunological function (Khanam Reference Khanam2018) and has a valuable effect on certain parasitic diseases (Gabrashanska et al. Reference Gabrashanska, Teodorova and Anisimova2008).

Given the above concerns, we attempt to investigate the anti-helminthic effect of RSV and zinc on both phases of Trichinella spiralis infection, besides their role as substances that can diminish unfavorable peroxidation effects. A parasitological, biochemical, histopathological, immunohistochemical, and immunomodulatory assessment will be conducted.

Materials and methods

Experimental animals

Sixty-four parasite-free male Swiss albino mice (~15–20 gm) of 8-week-old age were used. Mice were purchased from Theodor Bilharz Research Institute (TBRI), Giza, Egypt, and acclimated one week before the experiments. Animal maintenance and infection were in accordance with institutional and national guidelines.

Parasites and infection

T. spiralis larvae were obtained from infected pork muscles from Cairo abattoir and maintained in the laboratories of TBRI by consecutive passages in rats. Trichinella isolate used in this study was genotyped as T. spiralis (code: ISS6158) by the European Union Reference Laboratory for Parasites, Superior Institute of Health, Rome, Italy. Each mouse was orally infected with 200 larvae, as described by Dunn and Wright (Reference Dunn and Wright1985).

Experimental design

The current study includes four groups of 16 mice each – Group I: non-infected control (non-infected, non-treated); Group II: infected control (infected, non-treated); Group III: infected, then treated with RSV; Group IV: infected, then treated with zinc. In treated groups, treatment started one day post-infection (dpi) until the day of scarification.

On the 7th day post-infection (dpi), eight mice from each group were euthanized and then sacrificed, and blood samples were collected for biochemical and serological assays. Their small intestine was taken, opened along its entire length, and washed. A small part of each intestinal sample (about 1 cm) was placed in 10% formalin for histopathological and immunohistochemical evaluation, and the remaining part was used for counting T. spiralis adult worms. On the 35th dpi, the remaining eight mice from each group were sacrificed, and blood samples were collected for biochemical and serological assays. Part of the thigh muscles were gently dissected and subjected to histopathological and immunohistochemical studies, and the remaining carcasses were digested for larvae count.

Drug therapy

Resveratrol powder was bought from Sigma-Aldrich Chemie (Steinheim, Germany) and dissolved in distilled water to make a suspension. Each mouse orally received 20 mg/kg once daily (Soliman et al. Reference Soliman, Ismail, Badr and Nasr2017). Zinc: Octozine (Zn) tablets were used (October Pharma SAE). The drug was given orally in the form of an aqueous suspension in distilled water at a dose of 12 mg/kg once daily (Ivanov et al. Reference Ivanov, Dilcheva, Felkova, Nanev, Cabrashanska and Ermakov2014).

Parasitological assessment

Isolation and adult worm counting

The washed intestine was divided into small portions (1 cm) and kept in 10 ml of normal saline for 2 hr at 37°C. The specimens were then shaken and washed with saline several times until the fluid became clear. The collected fluid was centrifuged at 2000 rpm for 2 min, and then the supernatant was discarded. The sediment was reconstituted in 3–5 drops of physiological saline in a petri dish and examined under the dissecting microscope at X10 power to count adult worms (Denham Reference Denham1965; Wakelin and Ltoyd Reference Wakelin and Lloyd1976).

Total larval burden in muscles

On the 35th dpi, mice were euthanized and sacrificed. Muscle larval counts in whole carcasses were determined as described by Dunn and Wright (Reference Dunn and Wright1985). In brief, each mouse was dissected and digested in 1% pepsin hydrochloride in 200 ml of distilled water. The mixture was incubated for 1 hr at 37°C with continuous agitation by an electric stirrer. After being collected using the sedimentation technique, the larvae were thoroughly washed by distilled water then counted under the microscope using the McMaster counting chamber.

Biochemical, serological, and immunological assessments

Blood samples were taken and then allowed to clot at room temperature for 2 hr before being centrifuged at 2000×g for 20 min. The collected serum was separated and kept at −20°C until used.

Biochemical assessment

For biochemical assays, the following parameters were tested: alanine transaminase (ALT), aspartate transaminase (AST), alkaline phosphatase (ALP), L-lactate dehydrogenase (LD), and creatinine phosphokinase (CPK) using commercial kits supplied by TBRI, Giza, Egypt, as illustrated by the manufacturer’s guide.

Assessment of oxidation and antioxidant parameters

The principle for assessment of the antioxidant capacity is based on the reaction of antioxidants in the sample with a predetermined amount of exogenously provided hydrogen peroxide (H2O2). Antioxidants in the sample eliminate a part of the provided hydrogen peroxide, and the remaining H2O2 is measured colorimetrically via an enzymatic reaction that involves the transformation of 3,5-dichloro-2-hydroxybenzensulphonate to a colored product. Total antioxidant capacity (TAC) was spectrophotometrically analysed as described by Koracevic et al. (Reference Koracevic, Koracevic, Djordjevic, Andrejevic and Cosic2001). Malondialdehyde (MDA) level (a marker of oxidative stress) was investigated using a commercial kit supplied by TBRI, Giza, Egypt, as illustrated by the manufacturer’s guide.

Assessment of immunological parameters

Serum levels of interleukin 12 (IL-12) and interleukin 10 (IL-10) were immunoassayed at 7th and 35th dpi using commercial enzyme-linked immunosorbent (ELISA) sets (R & D Systems, Minneapolis, MN, United States) in keeping with the manufacturer’s guidelines.

Histopathological study

All tissue specimens were fixed in 10% formalin for 24 hr and then processed to form paraffin blocks. Five-μm-thick sections were stained using Hematoxylin and eosin (H&E) stain to assess histopathological criteria (Feldman and Wolfe Reference Feldman and Wolfe2014).

Histopathological evaluation

The scoring process was performed blindly without knowing the examined group. For small intestinal samples, we evaluated the extent of inflammatory infiltrates within the mucosa and submucosa by evaluating five sections per mouse and ten low-power fields (100×) for each section, to calculate the average score. Inflammatory infiltrate covers of <10% of the examined sections scored as mild infiltrates = (+1); 10–50% scored as moderate = (+2); and more than 50% scored as intense = (+3) (Erben et al. Reference Erben, Loddenkemper, Doerfel, Spieckermann, Haller, Heimesaat, Zeitz, Siegmund and Kühl2014). The mean villus height, the mean crypt depth, and the mean number of goblet cells were also evaluated (Elgendy et al. Reference Elgendy, Othman, Hasby Saad, Soliman and Mwafy2020). For skeletal muscle samples, we evaluated the extent of the inflammatory reaction surrounding the capsule as mild reaction = +1 (1% to 30% increase in inflammatory cellular infiltration), moderate reaction = +2 (31% to 60% increase in inflammatory cellular infiltration), and intense reaction = +3 if (61% to 100% increase in inflammatory cellular infiltration) compared to the control group (Eissa et al. Reference Eissa, Eassa, Zalat, Negm and Elmallawany2022; Shalaby et al. Reference Shalaby, ALbakkosh, Shalaby, ALabiad, ELshamy, ALorini, Jaber and Tawfeek2023).

Immunohistochemistry

The immunohistochemistry staining was performed in accordance with Saber et al. (Reference Saber, Khalil, Abdo, Nassif and El-Ahwany2019). In brief, the serial sections were dewaxed, hydrated, and submerged in an antigen retrieval solution (EDTA solution, PH 8). After that, it was incubated with rabbit anti-Nrf2 polyclonal antibody (Invitrogen, PA5-27882, USA; 1:100 dilution) after being treated with hydrogen peroxide 0.3% and protein block. The slides were washed three times with PBS, incubated with anti-rabbit IgG secondary antibodies (EnVision + System HRP; Dako) for 30 minutes at room temperature, visualized using di-aminobenzidine commercial kits (Liquid DAB + Substrate Chromogen System; Dako), and then counterstained with Mayer’s hematoxylin. The primary antibody was replaced by normal mouse serum as a negative control procedure. The labeling index of Nrf2 was calculated according to the ratio of positive area to the total area in 8 high-power fields.

Statistical analysis

Data were analyzed using IBM SPSS 18.0 for windows (SPSS Inc., Chicago, IL, USA) and NCSS 11 for windows (NCSS LCC., Kaysville, UT, USA). Quantitative data were expressed as mean ± standard deviation (SD). Qualitative data were expressed as frequency and percentage. Data were tested for normality using the Kolmogorov Smirnov test. The following tests were performed: ANOVA (Analysis of Variance) F tests were used for comparing multiple means, LSD was used as a post hoc test for in between groups comparison, and Monte Carlo exact test was used for chi square (for histopathological and immunohistochemistry). A probability (P-value) of <0.05 was considered significant, P-value <0.001 was considered as highly significant, and P-value >0.05 was considered insignificant.

Results

Parasitological assessment

The mean number of adult T. spiralis in the small intestines of the treated groups was significantly reduced compared with the infected control group (P<0.001). Mice that received zinc showed a lower mean (28.5 ± 4.2) than those treated with RSV (59 ± 11.6). Similarly, the muscles of the treated groups showed a significant decrease in the mean larval count compared with the infected control group (P<0.001). The mean larvae count was lower in the muscles of mice that received zinc than in those who received RSV (504.5±122.4 and 885.8±524.98, respectively) (Table 1).

Table 1. Mean adult T. spiralis and larvae count among the studied groups

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III; e, group II vs. IV; f, group III vs. IV

Biochemical findings

Serum enzyme changes

Infection with T. spiralis induced a statistically significant increase in serum levels of ALT, AST, ALP, CPK, and LDH during the enteral and muscle phases of infection compared with the non-infected control group (P<0.001), whereas a significant reduction in their level was noted in the treated groups compared with the infected control group (P<0.001). Mice treated with zinc showed a greater decrease in serum levels than those treated with RSV (Tables 2 and 3).

Table 2. Serum enzyme changes among the studied groups at 7th dpi

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III: e, group II vs. IV; f, group III vs. IV

Table 3. Serum enzyme changes among the studied groups at 35th dpi

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III; e, group II vs. IV; f, group III vs. IV

Redox status parameters

The total antioxidant capacity level (TAC) was significantly reduced in the infected control group compared with the non-infected control group (P<0.001) during both the enteral and muscle phases of infection. Conversely, a significant increase in TAC serum level was noted in both drug-receiving groups as compared to the infected control group (P<0.001). Regarding MDA serum levels, there was a significantly higher serum value in the infected control group compared to the non-infected control group, signifying the oxidative stress during T. spiralis infection. However, its level was decreased in both treated groups with a statistically significant difference compared to the infected control group (P<0.001) during both phases of T. spiralis infection (Table 4).

Table 4. Redox status parameters among the studied groups

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III; e, group II vs. IV; f, group III vs. IV

Changes in serum cytokine levels

To investigate the effect of RSV and zinc on the immune response, we investigated the serum levels of Th1/Th2 cytokines at both the enteral and muscle phases of T. spiralis infection. Th1 cytokine (IL-12) level was significantly increased in the infected control and treated groups on the 7th day of infection and onwards as compared to the non-infected control group. Moreover, its level was higher in the zinc-treated group than in those who received RSV, with a statistically significant difference (P<0.001). Referring to Th2 cytokine (IL-10), a significant increase in its serum level was observed in all groups at both phases of infection compared to the non-infected control group. However, the infected control group showed more elevation than the treated groups. This increase was more evident during the muscle phase of infection. Likewise, the zinc-treated group showed more elevation than the RSV-treated group (Table 5).

Table 5. Changes in serum cytokine levels among the studied groups

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III; e, group II vs. IV; f, group III vs. IV

Histopathological finding

Small intestine

The examined sections of small intestine from the infected control group revealed an intense inflammatory reaction in the mucosa and submucosa, predominantly consisting of eosinophils, neutrophils, and lymphocytes. Also, the intestinal mucosa showed ulceration, sloughing, goblet cell hyperplasia, and marked villous atrophy (Figure 1). Regarding the treated groups, there was a noticeable improvement in histopathological findings noted as a reduction in the inflammatory reaction, decrease in goblet cell hyperplasia, and recovery of intestinal villous length; however, this improvement was remarkable in zinc-treated group (Figures 2, 3, and 4). The extent of inflammatory cellular infiltration is shown in Table 6.

Figure 1. Section in the small intestine of (a) the non-infected control group showing the normal histological structure formed of mucosa (M), submucosa (S), and musculosa (MS) (H&E,×100), (b) a higher magnification of the previous image demonstrating finger-like villi with a core of lamina propria covered by simple columnar epithelium (green arrow) and goblet cells (yellow arrow) (H&E, ×400), (c) the infected control group showing marked histopathological damage (H&E, ×100), (d) a higher magnification of the previous image demonstrating intense inflammatory reaction infiltrating the mucosa, submucosa, and musclosa (red arrows), increase goblet cell number (yellow arrows), and short, broad villi with increased crypt depth (green arrows) (H&E, ×400).

Figure 2. Section in the small intestine of (a) RSV-treated group, (b) zinc-treated group showing marked reduction in the inflammatory infiltrates (red arrow), decreased number of goblet cells (yellow arrows), and marked improvement in the villous lengths (green arrow) (H&E, ×100).

Figure 3. Bar chart showing the mean number of goblet cells among studied groups, *significant vs. control, ^significant vs. positive control group, •significant vs. RSV-treated group.

Figure 4. Bar chart showing the means of villus height and crypt depth among studied groups, *significant vs. control, ^significant vs. positive control group, •significant vs. RSV-treated group.

Table 6. The extent of the inflammatory cellular infiltrates in the small intestine of the studied groups

Chi-square test was used to compare the treated groups with the infected control group.

Skeletal muscle

Microscopic examination of skeletal muscle sections of the infected control group exhibited numerous encroachment larvae of T. spiralis encysted in the skeletal muscle fibers, surrounded by an intense inflammatory reaction. Compared to the treated groups, there was a significant reduction in inflammatory infiltration and the number of infested larvae, with a greater improvement within the zinc-treated group (Figure 5). The extent of the inflammatory infiltrate is shown in Table 7.

Figure 5. Section in the skeletal muscle of (a) the non-infected control group showing the normal histological structure (H&E, ×100), (b) the infected control group with numerous larvae within the muscle fibers enclosed by an intense inflammatory reaction (green arrows) (H&E, x100), (c) the RSV-treated group reveals decrease in number of encysted larvae within the muscles and moderate inflammatory reaction (H&E, 100×), (d) the zinc-treated group shows marked reduction in number of deposited larvae with atrophic changes and mild inflammatory infiltrates (H&E, 100×).

Table 7. The extent of the inflammation infiltrates within the skeletal muscle of the studied groups

Chi-square test was used to compare the treated groups with the infected control group.

Immunohistochemical assessment

Nrf2 expression in the intestine

In the non-infected control group, a scanty expression of Nrf2 was detected within the intestinal epithelial lining. However, there was a mild increase in Nrf2 expression in the infected control group. This immunoreactivity was observed within the intestinal epithelial lining and was associated with parasitic intestinal invasion. A significant increase in Nrf2 expression was observed in both treated groups; moreover, the zinc-treated group showed a marked expression that was more evident within the intestinal epithelial lining and within the interstitial inflammatory cells (Figure 6).

Figure 6. Immunohistochemical staining of Nrf2 in small intestine sections of (a) the non-infected control group with a scanty expression of Nrf2 within intestinal epithelial lining (arrowheads), (b) the infected control group showing a mild increase of Nrf2 expression within intestinal epithelial lining (arrowheads) associated with parasitic intestinal invasion (P), (c) the RSV-treated group showing a moderate increase of Nrf2 expression within intestinal epithelial lining (white arrowheads) and within the interstitial inflammatory cells (black arrowhead) and parasitic invasion (P), (d) the zinc-treated group displaying a marked increase of Nrf2 expression of within intestinal epithelial lining (white arrowhead) and within the interstitial inflammatory cells (black arrowhead), X200.

Nrf2 expression in muscles

The immunohistochemical expression of Nrf2 in skeletal muscle sections of the non-infected control group was low; however, the infected control group revealed a moderate increase in Nrf2 expression within the skeletal muscle fibers infected with Trichinella parasites. A significant increase in immunoreactivity of Nrf2 was observed in both treated groups compared to the infected control group, with marked expression in zinc-treated group compared to RSV-treated group (Figure 7). Nrf2 expression within the experimental groups is summarized in Table 8.

Figure 7. Immunohistochemical staining of Nrf2 in skeletal muscle of (a) the non-infected control group showing a low level of Nrf2 expression within the skeletal muscle fibers (arrowhead) (b) the infected control showing a moderate increase of Nrf2 expression within the skeletal muscle fibers infected with Trichinella parasites (arrowhead), (c) the RSV-treated group displaying an increase of Nrf2 expression within the skeletal muscle fibers (arrowhead), (d) the zinc-treated group showing a marked increase of Nrf2 expression within the skeletal muscle fibers (arrowhead), X200.

Table 8. Nrf2 among the studied groups

There is a significant difference between the following groups: a, group I vs. II; b, group I vs. III; c, group I vs. IV; d, group II vs. III; e, group II vs. IV; f, group III vs. IV

Discussion

The management of T. spiralis is a challenge because of the variety of tissue involvement, immune response mechanisms, and effector cells during the various stages of infection (Hamed et al. Reference Hamed, Abdel-Shafi, Elsayed, Mahfoz, Tawfeek and Abdeltawab2022).

Nutritional immunity is the manner used by the host to manage its availability of micronutrients in order to limit the advancement and severity of infections (Hood and Skaar Reference Hood and Skaar2012). In hosts with balanced micronutrient status, nutritional immunity is an intensely regulated response. Zinc deficiency may disrupt this balance, impairing the body’s ability to fight off infections (Fançony et al. Reference Fançony, Soares, Lavinha and Brito2022). Natural foodstuffs have always been an excellent source for bioactive compounds (Bruno et al. Reference Bruno, Castelli, Vitale, Catanzaro, Badaco, Roberti, Colomba, Cascio and Tolomeo2021). One of these constituents is resveratrol (RSV), which is a natural plant extract with an antioxidant effect (Malaguarnera Reference Malaguarnera2019). The biologically active components of this substance enable it to act against numerous medically important protozoa, including leishmania (Ferreira et al. Reference Ferreira, Soares, do Nascimento, Pinto-da-Silva, Sarzedas, Tinoco and Saraiva2014), Amoeba (Pais-Morales et al. Reference Pais-Morales, Betanzos, García-Rivera, Chávez-Munguía, Shibayama and Orozco2016), Toxoplasma gondii (Chen et al. Reference Chen, Dong, Qin, Yang, He, Li, Zheng, Chen and Chen2019), and Trypanosoma cruzi (Bruno et al. Reference Bruno, Castelli, Vitale, Catanzaro, Badaco, Roberti, Colomba, Cascio and Tolomeo2021; Isabela et al. Reference Isabela, Ana, Anne, Giulia, Isabella, Maria, Nathalia Del Vecchio, Yasmin and Silva2022) as well. Given these facts, there is a reason to be optimistic about the potential role of resveratrol and zinc in the management and prevention of a wide range of chronic and infectious diseases.

In the current study, the effectiveness of RSV and zinc on adult and larva stages of Trichinella spiralis was observed, as evidenced by the significant decrease in the mean parasite burden in the small intestines and muscles, improvement in histopathological findings, and enhancement of the immune status of the targeted treatment groups as compared to the infected control group. However, this improvement was more evident in zinc-treated group.

In agreement with our results were those of Ozkoc et al. (Reference Ozkoc, Tuncay, Delibas and Akisu2009) and Elgendy et al. (Reference Elgendy, Othman, Hasby Saad, Soliman and Mwafy2020). Both reported the direct harmful effect of RSV on larvae and adult stages of T. spiralis. RSV can induce marked morphological changes by acting on neuromotor activity, affecting the parasite’s motility and impairing its ability to migrate and acquire nutrients. Furthermore, it can affect the tegument, causing vacuolations, disruption, and extensive lysis of sub-tegumental regions, with subsequent fading of the immunological concealment of the parasite, which, in turn, exposes immunogens and immunogenic epitopes. So, it induced a dual action by both harming the parasite and enhancing host oxidative stress against it as well (Gouveia et al. Reference Gouveia, Brindley, Azevedo, Gärtner, da Costa and Vale2019).

Several mechanisms were proposed to justify the parasiticidal effect of RSV. Earlier studies suggested that RSV inhibits polyamine metabolism, terminates tubulin polymerization, blocks calcium channels, and limits oxygen consumption by the parasites (Stadler et al. Reference Stadler, Dagne and Anke1994; Leiro et al. Reference Leiro, Cano, Ubeira, Orallo and Sanmartín2004; Kedzierski et al. Reference Kedzierski, Curtis, Kaminska, Jodynis-Liebert and Murias2007; Lamas et al. Reference Lamas, Morais, Arranz, Sanmartín, Orallo and and Leiro2009). Furthermore, RSV was reported to reduce the activity of acetylcholinesterase (AChE), resulting in paralysis of the worms with subsequent detachment and expulsion from the host (Giri and Roy Reference Giri and Roy2015). In addition, it exerts indirect harm to parasites through the activation of macrophages with the subsequent release of TNF, which promotes parasite killing (Chen et al. Reference Chen, Dong, Qin, Yang, He, Li, Zheng, Chen and Chen2019).

Regarding zinc, it was a remarkable finding that the zinc-treated group showed the highest reduction in parasite burden. To our knowledge, previous studies investigating the direct effect of zinc on trichinellosis are lacking. Effective immune responses, mainly intestinal immunity, against gastrointestinal nematodes greatly depend on zinc status and zinc nutrition (Hughes and Kelly, Reference Hughes and Kelly2006). So, the parasiticidal effect obtained may be due to its role as an ‘immune booster’, enhancing the body’s immunity by decreasing oxidative stress markers and generating inflammatory cytokines (Khanam Reference Khanam2018). This is in agreement with Khan et al. (Reference Khan, Singh, Ullah, Shoeb, Naqvi and Abidi2015) and Dorostkar et al. (Reference Dorostkar, Ghalavand, Nazarizadeh, Tat and Hashemzadeh2017), who stated that the anti-helminthic effect of zinc can be attributed to its ability to induce oxidative/nitrosative stress with subsequent membrane damage, observed as a damage to the parasite’s integument, erosion in the superficial papillae, and rupture of superficial annulments. It has been suggested that oxidative stress can result in structural damage and destroy subcellular architecture, including mitochondria, which in turn overwhelms the synthesis of ATP and ultimately results in the paralysis of the worm (Wolstenholme et al. Reference Wolstenholme, Fairweather, Prichard, von Samson Himmelstjerna and Sangster2004). The antiparasitic effect of zinc has previously been a point of concern for many researchers. Exposure to ZnO or ZnONPs has been reported to affect the parasite’s ultrastructure, causing sloughing, disruption, and loss of cuticular spines, bursting and disruption in surface annulations, disruption in the arrangement and erosion in male pre- and postanal papillae (Morsy et al. Reference Morsy, Fahmy, Mohamed, Ali, El–Garhy and Shazly2019; Hassan et al. Reference Hassan, Ramdan, SFA and Elkabawy2021b). However, a possible explanation was attributed to the ability of NPs to generate ROS and cause changes in macromolecules such as proteins, nucleic acids, and lipids (Khashan et al. Reference Khashan, Sulaiman, Hussain, Marzoog and Jabir2020). Oxidation of proteins and peroxidation of lipids lead to damaging the hardness of the cell membrane, changing fluid permeability and ion transport and inhibiting metabolic processes (Akhtar et al. Reference Akhtar, Alhadlaq, Alshamsan, Majeed Khan and Ahamed2015).

In trichinellosis, the invasion of muscle tissue by T. spiralis larvae coincides with an increase in cellular permeability, leakage of fluid into the adjacent tissue, and an increase in serum aspartate transaminase (AST), alanine transaminase (ALT), creatine phosphokinase (CPK), and lactate dehydrogenase (LDH) (Kociecka Reference Kociecka2000).

AST is present in most cells, but it is used as a marker to evaluate hepatocellular and muscular injuries because it is highly active in these tissues. However, ALT is almost exclusively associated with hepatocellular injury, and its increased serum levels reflect the severity of hepatocellular damage (Aulbach and Amuzie Reference Aulbach, Amuzie and Faqi2017). Also, the abnormal increase in plasma CPK and LDH levels usually reflects disruption of the function and permeability of the muscle cell membrane and is used as an indicator of muscle damage (Brancaccio et al. Reference Brancaccio, Maffulli and Limongelli2007).

In the present work, the levels of ALT and AST were significantly elevated in the infected groups compared to the non-infected control group. These findings agreed with Hassan et al. (Reference Hassan, Abd El-Rahman, Abd El-Hamed, Abdel Fattah, Harb, Mohamed and Sarhan2021a), Basyoni and Elsabah (Reference Basyoni and El-Sabaa2013), and Swilam et al. (Reference Swilam, Nasreldin, Abd-Elrahman and Nasr2022), who reported elevation in serum ALT and AST in mice infected with T. spiralis due to liver damage by migrating larvae.

Regarding the treated groups, our results showed a significant decrease in ALT and AST serum levels. The effects of RSV and zinc could be attributed to their ability to protect hepatocytes from primary damage induced by oxidative stress. Likewise, several studies have reported the hepatoprotective effect of RSV (Rubiolo et al. Reference Rubiolo, Mithieux and Vega2008; Sahin et al. Reference Sahin, Orhan, Akdemir, Tuzcu, Iben and Sahin2012; Jia et al. Reference Jia, Li, Cao, Du, Zheng, Qian, Gu, Jeney, Xu and Yin2019). They suggested that RSV protects hepatocytes from injury through Nrf2 activation and suppression of toll-like receptor-2 (TLR2)-Myd88-NF-κB activation. Also, Hosui et al. (Reference Hosui, Kimura, Abe, Tanimoto, Onishi, Kusumoto, Sueyoshi, Matsumoto, Hirao, Yamada and Hiramatsu2018) reported that zinc supplementation improved liver function and decreased AST and ALT levels in patients with chronic liver disease. The precise mechanism by which zinc exerts its effect on the liver is still unidentified; however, we proposed that the improvement of liver injury is due to the role of zinc in restoring SOD activity to the basal level and reducing ROS levels (Hosui et al. Reference Hosui, Kimura, Abe, Tanimoto, Onishi, Kusumoto, Sueyoshi, Matsumoto, Hirao, Yamada and Hiramatsu2018).

In this work, a significant decrease in CPK and LDH serum levels was noticed in both treated groups compared to the infected control group. Our results were consistent with those obtained by Xiao (Reference Xiao2015), Hsu et al. (Reference Hsu, Ho, Lee, Ho, Huang and Kan2020), and Huang et al. (Reference Huang, Lee, Ho, Hsu, Ho and Kan2021), who revealed the protective effect of RSV against induced oxidative muscle damage and lipid peroxidation and observed a reduction in CPK and LDH levels, decreased muscle damage, and regeneration of muscle satellite cells after RSV supplementation. Also, Malyar et al. (Reference Malyar, Li, Liu, Abdulrahim, Farid, Gan and Chen2020) reported a decrease in serum levels of CPK and LDH in rats upon zinc supplementation. Zinc is known to be important for maintaining cell membrane integrity. It binds to thiol groups of biomolecules, protecting them from oxidation, reduces the activities of oxidant-promoting enzymes, boosts the activities of antioxidant enzymes, and prevents the generation of lipid peroxidation products (Prasad Reference Prasad2009).

Given that tissue damage in T. spiralis infection is most likely contributed to an oxidative stress state mediated by ROS and produced by the parasite and the host defense reaction (Gabrashanska et al. Reference Gabrashanska, Petkova and Teodorova2019), as well as membrane lipid peroxidation (Mido et al. Reference Mido, Fath, Farid, Nonaka, Oku and Horii2012), we investigated redox status parameters and observed an increase in MDA level and a decrease in TAC in the infected control group compared with the non-infected control group. A similar increase in serum MDA level was verified by Tolstoj et al. (Reference Tolstoj, Lytvynets and Langrova2007), Ivanov et al. (Reference Ivanov, Dilcheva, Felkova, Nanev, Cabrashanska and Ermakov2014), Gabrashanska et al. (Reference Gabrashanska, Petkova and Teodorova2019), and Hamed et al. (Reference Hamed, Abdel-Shafi, Elsayed, Mahfoz, Tawfeek and Abdeltawab2022). The increased MDA concentration (a sign of lipid peroxidation extent) in T. spiralis infection is an indicator of radical-induced damage in the host (Ivanov et al. Reference Ivanov, Dilcheva, Felkova, Nanev, Cabrashanska and Ermakov 2014) and may signify that the infected organism does not have enough antioxidant enzymes to cope with the increased oxidative stress (Xu et al. Reference Xu, Wang and Wang2007). It is recognized that parasitic nematodes need antioxidant enzymes to survive the ROS generated during cellular metabolism (Dorostkar et al. Reference Dorostkar, Ghalavand, Nazarizadeh, Tat and Hashemzadeh2017). Moreover, there was a predominance of antioxidant status in the targeted treatment groups, as evidenced by a significant increase in serum TAC and a significant decrease in MDA levels. The alterations in serum TAC and MDA levels clearly show the development of an antioxidant imbalance in the infected host. This finding was in accordance with previous studies (Soliman et al. Reference Soliman, Ismail, Badr and Nasr2017; Chen et al. Reference Chen, Dong, Qin, Yang, He, Li, Zheng, Chen and Chen2019; Turkmen et al. Reference Turkmen, Birdane, Demirel, Kabu and Ince2019; Elgendy et al. Reference Elgendy, Othman, Hasby Saad, Soliman and Mwafy2020) that reported the antioxidant efficiency of RSV and its ability to destroy the oxidant-antioxidant homeostasis elaborated by the parasite, and Isabela et al. (Reference Isabela, Ana, Anne, Giulia, Isabella, Maria, Nathalia Del Vecchio, Yasmin and Silva2022), who reported that RSV can directly activate Sirtuin 1 (SIRT-1), which is an enzyme that performs histone deacetylase and is responsible for increasing the number of antioxidant enzymes via balancing the effects of ROS on Nrf2 (Maldonado et al. Reference Maldonado, Rojas, Morales, Miralles and Solari2020). Concerning the zinc-treated group, our finding was in line with several studies (Ivanov et al. Reference Ivanov, Dilcheva, Felkova, Nanev, Cabrashanska and Ermakov2014; Pivoto et al. Reference Pivoto, Torbitz, Aires, da Rocha, Severo, Grando, Peiter, Moresco, da Rocha and Leal2015; Jarosz et al. Reference Jarosz, Olbert, Wyszogrodzka, Młyniec and Librowski2017; Marreiro et al. Reference Marreiro, Cruz, Morais, Besserra, Severo and de Oliveira2017; Váradyová et al. Reference Váradyová, Mravčáková, Babják, Bryszak, Grešáková, Čobanová, Kišidayová, Plachá, Königová, Cieslak, Slusarczyk, Pecio, Kowalczyk and Várady2018) that confirmed the potent antioxidant effect of zinc and suggested that it could possibly be a natural antioxidant minimizing the oxidative stress in nematode infection.

Inflammation is the primary response evolved by the host to infection or injury. Although it helps to preserve tissue homeostasis, limit further tissue damage, and stimulate repair mechanisms (Munn Reference Munn 2017 ; Kunnumakkara et al. Reference Kunnumakkara, Sailo, Banik, Harsha, Prasad, Gupta, Bharti and Aggarwal2018), uncontrolled inflammation is well established to be deleterious and causes progressive tissue damage (de Sá Coutinho et al. Reference De Sá Coutinho, Pacheco, Frozza and Bernardi2018). It was reported that T. spiralis infection can alleviate inflammation by enhancing nuclear factor (erythroid-derived 2)-like-2 factor (Nrf2) expression (Chu et al. Reference Chu, Lee, Kang, Moon and Quan2020). Nrf2 is a crucial regulatory transcription factor in antioxidant response element-dependent genes (Wei et al. Reference Wei, Gupta, Kao, Almudallal, Letterio and Pareek2018).

In the current study, RSV and zinc reduced the severe inflammatory reaction provoked by T. spiralis infection, as demonstrated by the improvement in histopathological alterations and increased Nrf2 expression in the intestine and muscle tissues. Our results agreed with Chu et al. (Reference Chu, Lee, Kang, Moon and Quan2020) and Jin et al. (Reference Jin, Bai, Zhao, Dong, Pang, Liu and Liu2021), who reported that Nrf2 production was provoked by T. spiralis muscle larval excretory/secretory (ES) products. These excretory-secretory (ES) proteins trigger regulatory network components to decrease host immune attacks as a survival strategy (Li et al. Reference Li, Qiu, Yuan, Wang, Wu, Yang, Wang, Ma, Qian, Zhan and Yang2022). Likewise, Ungvari et al. (Reference Ungvari, Bagi, Recchia, Sonntag, Pearson, de Cabo and Csiszar2010) and Farkhondeh et al. (Reference Farkhondeh, Folgado, Pourbagher-Shahri, Ashrafizadeh and Samarghandian2020) reported that resveratrol exerts its effect through upregulating Nrf2 expression. In addition, Nrf2 is a known zinc finger protein (Prasad and Bao Reference Prasad and Bao2019), and it has been proven to be upregulated by zinc (Jarosz et al. Reference Jarosz, Olbert, Wyszogrodzka, Młyniec and Librowski2017). Our finding showed that the highest Nrf2 expression was observed in the zinc-treated group; this was consistent with Zhao et al. (Reference Zhao, Tan, Dai, Li, Guo, Cui, Wang, Shi, Zhang, Mellen, Li and Cai2010), who reported a significant increase in oxidative damage and reduced Nrf2 expression in zinc-deficient mice, and Cortese et al. (Reference Cortese, Suschek, Wetzel, Kröncke and Kolb-Bachofen2008), who stated that zinc can protect endothelial cells from hydrogen peroxide by promoting glutathione production in a Nrf2-dependent manner.

Pointing to the immune response, it is recognized that T. spiralis induces a complex Th1/Th2 immune response (Ding et al. Reference Ding, Bai, Wang, Shi, Cai, Luo, Liu and Liu2017), with upregulation of IFN-γ and IL-12 at the early stage of infection, as well as IL-4, IL-10, and IL-13 through the muscle stage (Yu et al. Reference Yu, Deng, Lu, Jia, Wu and Qi2013). Nevertheless, T. spiralis can suppress Th1 cells and direct the immune response toward Th2 cells, or Tregs (Sofronic et al. Reference Sofronic-Milosavljevic, Ilic, Pinelli and Gruden-Movsesijan2015; Wang et al. Reference Wang, Bai, Tang, Yang, Wang, Zhu, Luo, Yan, Jia, Liu and Liu2020), which are essential for the parasite and the host’s survival (Everts et al. Reference Everts, Smits, Hokke and Yazdanbakhsh2010).

Concerning the present work, serum cytokine assays revealed an increase in Th1 (IL12) and Th2 (IL-10) cytokines levels in the infected control group at days 7 and 35 dpi compared to the non-infected control group, in harmony with the intestinal and muscular phases of infection, respectively. Similar findings were reported by Aranzamendi et al. (Reference Aranzamendi, Fransen, Langelaar, Franssen, van der Ley, van Putten, Rutten and Pinelli2012), Kang et al. (Reference Kang, Cho, Park, Kim, Hong, Lee, Cha, Ock and Yu2012), and Ding et al. (Reference Ding, Bai, Wang, Shi, Cai, Luo, Liu and Liu2017).

Regarding the treated groups, a significantly higher level of IL-12 and lower levels of IL-10 were noted when compared to the infected control group. However, zinc seemed to be a more potent stimulator of Th1 cytokines in both phases of infection than RSV, in which Th1 stimulation was more evident during the muscle phase. Since Th1 and Th2 lymphocytes perform different functions to maintain a balanced immune response (Baltaci and Mogulkoc Reference Baltaci and Mogulkoc2012; Koyasu and Moro Reference Koyasu and Moro2011), our result denotes that both RSV and zinc have restored this disrupted balance.

The immunomodulatory effects of RSV, both in vivo and in vitro, had previously been emphasized. Resveratrol maintains a balanced immunity through the regulation of immune cells and pro-inflammatory cytokines, and the synthesis and expression of immune cells genes (Isabela et al. Reference Isabela, Ana, Anne, Giulia, Isabella, Maria, Nathalia Del Vecchio, Yasmin and Silva2022). Furthermore, RSV was reported to inhibit nod-like receptor pyrin domain-containing 3 (NLRP-3) activation (Chang et al. Reference Chang, Ka, Hsu, Chen, Chao, Lin, Hsieh, Chen, Chiu, Ho, Chiu, Liu and Hua2014). Jin et al. (Reference Jin, Bai, Yang, Ding, Shi, Fu, Boireau, Liu and Liu2020) reported that IL-10 was significantly decreased in the absence of NLRP3, suggesting that these molecules play an important role in host defenses against T. spiralis by promoting the Th2 and Treg responses. Also, our findings are consistent with several studies that reported the crucial role of zinc in maintaining the balance between different T-cell subsets and in driving the immune response towards the Th1 type (Fraker et al. Reference Fraker, King, Laakko and Vollmer2000; Foster and Samman Reference Foster and Samman2012; Haase and Rink Reference Haase and Rink2014; Bonaventura et al. Reference Bonaventura, Benedetti, Albarede and Miossec2015).

It was reported that zinc deficiency disturbs cellular immunity via decreased production of Th1 cytokines and decreased DNA-binding activity of T-bet, which is a key transcription factor for Th1 cytokine gene expression (Bao et al. Reference Bao, Prasad, Beck, Bao, Singh, Ali and Sarkar2011). Additionally, zinc supplementation enhances the release of IFN-ℽ, which is the main Th1-stimulating factor (Schroder et al. Reference Schroder, Hertzog, Ravasi and Hume2004). Th1 cytokines such as IL-12 and IFN- ℽ have a significant role in the immunity against T. spiralis infection owing to their role in DC maturation (Venturiello et al. Reference Venturiello, Verzoletti, Costantino, Forastiero and Roux2007). In trichinellosis, during the enteral phase, the host boosts a Th1 immune response mediated by signals from DC and directed at eliminating the parasite (Munoz-Carrillo et al. Reference Munoz-Carrillo, Contreras-Cordero, Munoz-Lopez, Maldonado-Tapia, Munoz-Escobedo and Moreno-Garcia2017); however, Trichinella-derived molecules can down-regulate the host immune response by interfering with dendritic cell (DC) maturation and signaling (Bella et al. Reference Bella, Benagiano, Gennaro, Gomez-Morales, Ludovisi, D’Elios, Luchi, Pozio, D’Elios and Bruschi2017). DC are believed to be one of the main antigen-presenting cells in the intestine (Ding et al. Reference Ding, Bai, Wang, Shi, Cai, Luo, Liu and Liu2017), essential for eliminating infection, mediating tissue healing against the invading nematode parasites, and maintaining balanced Th1 and Th2 responses as well (Neubert et al. Reference Neubert, Lehmann, Heger, Baranska, Staedtler, Buchholz, Yamazaki, Heidkamp, Eissing, Zebroski, Nussenzweig, Nimmerjahn and Dudziak2014 ; Gazzinelli-Guimaraes and Nutman Reference Gazzinelli-Guimaraes and Nutman2018; Sorobetea et al. Reference Sorobetea, Svensson-Frej and Grencis2018).

Conclusion

We concluded that RSV and zinc can exert a protective effect against oxidant-mediated damage and the destructive impacts of substances elaborated due to the host’s defense response during T. spiralis infection. They also displayed nematocidal activity in addition to their anti-inflammatory efficacy. Further studies are needed before employing them as a possible natural alternative for trichinellosis treatment.

Financial support

No agency provided a specific grant for the current work.

Competing interest

No conflict of interest.

Ethical standard

The protocol of the current work was accredited by the ethics committee of Faculty of Medicine, Zagazig University (approval number: ZU-IACUC/3/F/341/2022).

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Figure 0

Table 1. Mean adult T. spiralis and larvae count among the studied groups

Figure 1

Table 2. Serum enzyme changes among the studied groups at 7th dpi

Figure 2

Table 3. Serum enzyme changes among the studied groups at 35th dpi

Figure 3

Table 4. Redox status parameters among the studied groups

Figure 4

Table 5. Changes in serum cytokine levels among the studied groups

Figure 5

Figure 1. Section in the small intestine of (a) the non-infected control group showing the normal histological structure formed of mucosa (M), submucosa (S), and musculosa (MS) (H&E,×100), (b) a higher magnification of the previous image demonstrating finger-like villi with a core of lamina propria covered by simple columnar epithelium (green arrow) and goblet cells (yellow arrow) (H&E, ×400), (c) the infected control group showing marked histopathological damage (H&E, ×100), (d) a higher magnification of the previous image demonstrating intense inflammatory reaction infiltrating the mucosa, submucosa, and musclosa (red arrows), increase goblet cell number (yellow arrows), and short, broad villi with increased crypt depth (green arrows) (H&E, ×400).

Figure 6

Figure 2. Section in the small intestine of (a) RSV-treated group, (b) zinc-treated group showing marked reduction in the inflammatory infiltrates (red arrow), decreased number of goblet cells (yellow arrows), and marked improvement in the villous lengths (green arrow) (H&E, ×100).

Figure 7

Figure 3. Bar chart showing the mean number of goblet cells among studied groups, *significant vs. control, ^significant vs. positive control group, •significant vs. RSV-treated group.

Figure 8

Figure 4. Bar chart showing the means of villus height and crypt depth among studied groups, *significant vs. control, ^significant vs. positive control group, •significant vs. RSV-treated group.

Figure 9

Table 6. The extent of the inflammatory cellular infiltrates in the small intestine of the studied groups

Figure 10

Figure 5. Section in the skeletal muscle of (a) the non-infected control group showing the normal histological structure (H&E, ×100), (b) the infected control group with numerous larvae within the muscle fibers enclosed by an intense inflammatory reaction (green arrows) (H&E, x100), (c) the RSV-treated group reveals decrease in number of encysted larvae within the muscles and moderate inflammatory reaction (H&E, 100×), (d) the zinc-treated group shows marked reduction in number of deposited larvae with atrophic changes and mild inflammatory infiltrates (H&E, 100×).

Figure 11

Table 7. The extent of the inflammation infiltrates within the skeletal muscle of the studied groups

Figure 12

Figure 6. Immunohistochemical staining of Nrf2 in small intestine sections of (a) the non-infected control group with a scanty expression of Nrf2 within intestinal epithelial lining (arrowheads), (b) the infected control group showing a mild increase of Nrf2 expression within intestinal epithelial lining (arrowheads) associated with parasitic intestinal invasion (P), (c) the RSV-treated group showing a moderate increase of Nrf2 expression within intestinal epithelial lining (white arrowheads) and within the interstitial inflammatory cells (black arrowhead) and parasitic invasion (P), (d) the zinc-treated group displaying a marked increase of Nrf2 expression of within intestinal epithelial lining (white arrowhead) and within the interstitial inflammatory cells (black arrowhead), X200.

Figure 13

Figure 7. Immunohistochemical staining of Nrf2 in skeletal muscle of (a) the non-infected control group showing a low level of Nrf2 expression within the skeletal muscle fibers (arrowhead) (b) the infected control showing a moderate increase of Nrf2 expression within the skeletal muscle fibers infected with Trichinella parasites (arrowhead), (c) the RSV-treated group displaying an increase of Nrf2 expression within the skeletal muscle fibers (arrowhead), (d) the zinc-treated group showing a marked increase of Nrf2 expression within the skeletal muscle fibers (arrowhead), X200.

Figure 14

Table 8. Nrf2 among the studied groups