A Systematic Review of the Potential Effects of Nigella sativa on Rheumatoid Arthritis

• Abstract
• Introduction
• Materials and Methods
• Protocol and registration
• Search Strategy and Article Selection
• Data extraction
• Assessment of risk of bias
• Results
• Study characteristics
• Human studies
• Animal studies
• In vitro studies
• Methodological quality and risk of bias
• Discussion
• Contributorsʼ Statement
• References

Abstract

Considering the different untoward effects of the drugs prescribed for the treatment of rheumatoid arthritis (RA), there has been an increasing interest in adjuvant therapies devoid of such unfavorable reactions. Although the beneficial effects of Nigella sativa (N. sativa) on RA have been established, it seems that its mechanisms of action have not still been reviewed. The present review is designed to evaluate the effects of N. sativa on RA systematically. We searched these electronic databases until April 2019: PubMed, Scopus, ISI Web of Science, Cochrane Library, Embase, Ovid, ProQuest, and Google scholar. No restriction was conducted based on language or publication date. We selected all of the related clinical, animal, and in vitro studies. Review papers, abstracts in conferences, book chapters, and papers regarding the effects of N. sativa combined with other herbs, as well as articles regarding the effects of N. sativa on other diseases, were excluded. Each article was assessed critically for the possible risk of bias. Nineteen articles were reviewed. Animal and in vitro investigations supported the favorable effects of N. sativa on clinical, inflammatory, oxidative, and immunologic parameters on RA, whereas results of limited clinical studies did not illustrate any change or improvement of inflammatory and oxidative biomarkers in RA. N. sativa could control RA via multiple ways such as decreasing inflammation, inhibiting oxidative stress, and modulating the immune system. This paper provides persuasive clues to defend the efficacy of N. sativa in RA and justifies the significance of subsequent clinical trials.

Introduction

Rheumatoid arthritis (RA) is a chronic ailment specified with an immune system disturbance and inflammation of the synovium, causing articular pain and stiffness, bone and cartilage destruction, disability, and deformity as well as systemic complications such as cardiovascular, pulmonary, and psychological problems [1]. RA is the most common inflammatory arthritis that is prevalent in 0.5 – 1% of world population with a 3-time greater incident in women than men [2]. This disease significantly leads to diminished quality of life and functional capacity together with increased morbidity and mortality rates and imposes remarkable costs for the health and social care systems [3]. [Fig. 1] presents the pathogenic pathways of RA.

Several pharmaceutical therapies have been suggested and marketed for RA treatment including nonsteroidal anti-inflammatory drugs (NSAIDs), nonbiologic and biologic disease-modifying antirheumatic drugs (DMARDs), immunosuppressants, and corticosteroids. However, as these medications are mostly accompanied by various side effects [4], in recent y, there has been an increasing interest in adjuvant therapies devoid of such unfavorable effects.

Medicinal herbs have gained a lot of attention recently and have been used all over the world to treat various diseases [5]. There is growing evidence in the literature on how some of these medicinal herbs can be effective in the treatment of RA symptoms [6]. One such promising plant is Nigella sativa L. (N. sativa) (family Ranunculaceae), usually known as black seed [7]. N. sativa has been consumed customarily in the Middle and Far East and South Asian countries for the treatment of different disorders [7]. Traditional uses of N. sativa derive from the ancient Egyptians, Greeks, and Romans [8]. The Islamic prophet Mohammed is said to have referred to this herb as having healing capacities for every ailment except death [9]. N. sativa has been favored by Ibn Sina (Avicenna) as a remedy for fever, headache, toothache, and common cold [10]. It is also proposed as a sedative for skin disorders, wounds, and external irritations [10]. In folklore medicine, N. sativa seeds and oil have been regularly prescribed as a natural remedy for various diseases such as fever, cough, nasal congestion, bronchitis, asthma, dyspnea, hypertension, diabetes mellitus, inflammation, eczema, dizziness, gastrointestinal problems, and pain conditions [11], [12]. Furthermore, N. sativa has multiple biological and pharmacological functions including antioxidant [13], [14], [15], anti-inflammatory and analgesic [16], [17], anticancer [18], [19], antimicrobial [20], [21], immune enhancement [22], [23], hypoglycemic [24], hypotensive [25], hypolipidemic and cardioprotective [26], [27], [28], hepato-protective, gastro-protective [29], [30], renal-protective [31], [32], spasmolytic, bronchodilator [33], [34], [35], and increased milk production [36]. Moreover, N. Sativa has been beneficial for convulsion [37], [38], depression [39], menʼs infertility [40], and memory improvement [41]. Most of the therapeutic characteristics of N. sativa are attributable to the thymoquinone (TQ), a major active component and a phytochemical present in the essential oil [42]. Other components of N. sativa seed include carbohydrates, amino acids, proteins, both essential and fixed oil, sterols, alkaloids, saponins, organic acids, crude fiber, vitamins, and minerals [43]. The chemical structures of TQ and other chemical constituents found in N. sativa seed and oil are illustrated in [Fig. 2]. Furthermore, human [44] and animal models [45] have not shown any critical undesirable results.

The beneficial effects of N. sativa on RA prevention and treatment have been investigated in recent y, and some hopeful findings have been obtained from experimental investigations [46], [47], [48], [49], [50], [51] and clinical trials [52], [53], [54], [55], [56]. It has been suggested that N. sativa can influence the main traits of RA via various procedures [57]. Even though some review papers have been published regarding the medicinal features of N. sativa [58], [59], [60], to the authorsʼ knowledge, there has not been any review conducted in the area of N. sativa and RA. Therefore, in this research, we aimed to conduct a systematic study on the available literature regarding the effects of N. sativa on RA in clinical, animal and cellular models and possible mechanisms responsible for such effects.

Materials and Methods

Protocol and registration

The current systematic literature search was performed according to the preferred reporting items for systematic reviews and meta‐analysis guidelines [61]. The study protocol can be observed on the international prospective register of systematic reviews (PROSPERO) database (http://www.crd.york.ac.uk/PROSPERO, registration No: CRD42019133047).

Search Strategy and Article Selection

We searched the following electronic databases until April 2019: PubMed, Scopus, ISI Web of Science, Cochrane Library, Embase, Ovid, ProQuest, and Google scholar. The MESH and nonMESH search terms applied were (“Nigella sativa” OR “sativa, Nigella” OR “N. sativa” OR “Black Cumin” OR “Cumin, Black” OR “black seed” OR Kalonji OR “black caraway” OR thymoquinone) AND (“Arthritis, Rheumatoid” OR “Rheumatoid Arthritis” OR RA OR Rheumatoid OR Arthritis). No restriction was conducted based on language or publication date. Two authors (A.KH. and A. M. M.) independently searched, screened, and extracted the data. Duplicated studies were then eliminated. In general, these 2 authors had an agreement on selecting the studies, and possible variations were removed by the third author (Z. J.).

We selected all of the related clinical, animal, and in vitro studies. We also checked the references of selected papers to identify possible novel investigations. In addition, we used search alert services in order to identify any relevant article published after the primary search. Review papers, abstracts in conferences, book chapters, and papers regarding the effects of N. sativa combined with other herbs on RA were not included. Also, papers regarding the effects of N. sativa in other diseases were not included. Considering the specified search terms and the inclusion criteria, 18 papers were assessed. Furthermore, 1 article published after the initial search was identified via search alert services and reviewed. [Fig. 3] presents the flowchart of screening and choosing papers.

Data extraction

Two independent reviewers (A.KH. and A. M. M.) extracted data from the eligible papers. The following information was obtained from the papers: first authorʼs name, publication y, location, subject features, type and dosage of N. sativa supplement, treatment duration, and main results of studies. Any probable controversies were removed with the third reviewer (Z. J.). A summary of the included studies is presented in [Tables 1], [2], [3].

Assessment of risk of bias

Each of the qualified papers was evaluated for the potential risk of bias using Cochrane Collaborationʼs tool [62] for clinical studies, Checklist for Reporting In vitro Studies (CRIS) Guideline [63], for in vitro studies and SYRCLEʼs risk of bias tool [64] for animal studies. The SYRCLEʼs risk of bias tool is based on the Cochrane Rob tool and has been adapted for aspects of bias that have a particular function in animal intervention. Both of the tools have 6 domains ([Fig. 4]), and each domain was evaluated as having a low, unclear, or high risk of bias.

Results

Study characteristics

We identified 397 related papers. After removing duplicates, 154 papers remained that were screened by reviewing both titles and abstracts. Of those, 125 papers were excluded after the revision. Eventually, out of 29 potentially relevant publications, 10 studies were removed for the following reasons: N. sativa had been combined with other herbs or components (n = 2), they were protocols or abstracts in conferences (n = 6), and there was no available full-text (n = 2). Finally, 19 papers were entered in the systematic review ([Fig. 3]). The entered studies were classified into clinical (n = 5), animal (n = 13) and in vitro (n = 3) studies. One study included both human and animal models [56], and 1 study included both animal and in vitro models [46]. Characteristics of the investigations are demonstrated in [Tables 1]–[3].

Human studies

The effect of N. sativa consumption on RA cases was assessed in 5 investigations only ([Table 1]). In a research by Hadi et al. [55] on 50 female RA patients, N. sativa oil supplementation (1 g/day) for 8 wk caused a significant decrease in disease activity score 28 (DAS28) compared with the placebo group, while there were no considerable differences in serum interleukin-10 (IL-10), tumor necrosis factor-α (TNF-α), malondialdehyde (MDA), superoxide dismutase (SOD), catalase, total antioxidant capacity (TAC), and nitric oxide (NO) between the groups. Furthermore, in a study by Kheirouri et al. [52] on 50 female RA patients, N. sativa oil supplementation (1 g/day) for 8 wk led to a significant reduction in DAS28 and CD8⁺ percentage and a significant increase in CD4⁺/CD8⁺ ratio and CD4⁺CD25⁺ regulatory T cell percentage compared to the placebo, while there were no considerable differences in percentage of CD4⁺ T cells. In a study by Gheita et al. [54] on 40 female patients with RA, N. sativa oil supplementation (1 g/day) for 4 wk caused a significant decrease in DAS28, number of swollen joints, morning stiffness duration, visual analog scale (VAS) for pain, and white blood cell (WBC) count compared to the placebo. Another study by Mahdy et al. [56] on 36 female RA patients indicated that N. sativa oil supplementation (1 g/day) for 2 wk caused a significant decrease in DAS28, Ritchie articular index (RAI), morning stiffness, and white blood cell cin comparison with the placebo. In a research by Al-Okbi et al. [53] on 56 male RA patients, N. sativa oil supplementation (2 g/day) for 8 wk led to a remarkable reduction in plasma Cu, creatinine, aspartate aminotransferase (AST), and alanine aminotransferase (ALT) and a significant increase in plasma Zn, compared to the other treatment groups, whereas there were no significant changes in erythrocyte sedimentation rate (ESR), C-reactive protein (CRP), rheumatoid factor (RF), prostaglandin E2 (PGE2), SOD, vitamin C, vitamin E, and uric acid compared to the other treatment groups.

Animal studies

Several animal investigations supported the effect of N. sativa on RA ([Table 2]). According to the inclusion criteria, 13 animal investigations were entered in the current systematic review. Arjumand et al. [48] reported that 10 mg/kg BW TQ caused a considerable reduction in the arthritic score and CRP levels, significant normalization of total leukocyte count (TLC), lymphocytes, neutrophils, and monocytes; significant alleviation of inflammation, pannus formation, and bone erosion; and a significant decrease in mRNA expression levels of toll-like receptor (TLR)2, TLR4, IL-1, nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB), and TNF-α in rats with Freundʼs Complete Adjuvant-induced arthritic compared to the arthritic control group, while there was no significant change in RF compared to the arthritic control group. Nasuti et al. [65] noted that N. sativa oil administration (1596 and 798 mg/kg BW for 25 days) contributed to significant alleviation in paw volume and had significant antinociceptive activity in contralateral hind paw in Freundʼs Complete Adjuvant-induced arthritic rats compared to the arthritic control group; however, reduction in paw volume and the arthritis score was not significant compared to the arthritic control group. Moreover, no considerable change occurred in % of inhibition of arthritis, spontaneous locomotor activity, plasma levels of IL-6, CRP, and albumin compared to the arthritic control group. Additionally, no significant antinociceptive activity was reported in the inoculated hind paw compared to the arthritic control group [65]. Another study in Freundʼs Complete Adjuvant-induced arthritic rats also indicated that TQ (2.5 and 5 mg/kg BW) led to a significant reduction in clinical arthritis, radiological scores, and serum TNF-α and IL-1β levels in comparison with the control group [50]. Faisal et al. [66] reported that administering TQ (2 mg/kg BW) for 15 days to pristine-induced arthritic rats significantly decreased paw weight and score of histopathological parameters (e.g., inflammatory cells, synovial hyperplasia, villous hyperplasia, and pannus formation) compared to the arthritic control group. Furthermore, they showed a considerable decrease in TLC, clinical score of inflammation, and number of inflammatory cells as well as improvement in blood urea and serum creatinine and normalization of differential leukocyte count (DLC) compared to the arthritic control group [49], [67], [68]. Another study in pristine-induced arthritic rats [69] indicated that 2.5 and 5 ml/kg BW black seed oil did not cause significant changes in clinical arthritis severity, ankle joint pathological scores, and plasma NO level compared with the disease group. There was no significant change in mRNA expressions of IL-4, transforming growth factor (TGF)-β, and TNF-α; however, a declining trend in IL-17A mRNA expression was observed compared with the disease group. In a study in collagen-induced arthritic rats, Umar et al. [51] found that 5 ml/kg BW TQ for 21 days lowered the severity and the development of collagen-induced arthritis in a dose-dependent manner and resulted in a significant decrease in articular elastase and myeloperoxidase concentrations, neutrophil activation, and infiltration in the synovial tissues of the joints, as well as a significant decrease in thiobarbituric acid reactive substances (TBARS) level in the cartilage tissue compared with the untreated disease group. In addition, TQ considerably prevented down-regulation of glutathione (GSH) and SOD and replenished catalase activity compared with the untreated disease group [51]. Also, TQ significantly decreased nitrite concentration, suppressed the increase in IL-1β, IL-6, TNF-α, interferon (IFN)-γ, and PGE2 levels, and enhanced IL-10 levels compared with the untreated diseased group. Furthermore, it improved the changes at the histological level and restored the degenerative changes [51]. Another study in collagen-induced arthritic rats showed that the administration of 400 and 500 mg/kg BW N. sativa aqueous methanolic extract led to a significant decrease in myeloperoxidase and elastase activities in the joints as well as a significant suppression of lipid peroxidation and a decrease in MDA in the cartilage tissue in a dose-dependent manner compared with the untreated group [70]. Moreover, N. sativa aqueous methanolic extract significantly restored GSH levels, increased SOD and catalase activities, and decreased articular nitrite content compared with the untreated group. It also improved the changes at histological level [70]. Moreover, Budancamanak et al. [71] stated that giving 10 mg/kg BW TQ by gavage for 3 wk to collagen-induced arthritic rats can cause a significant reduction in the incidence and severity of arthritis, serum NO, urea, and creatinine levels. It can also inhibit kidney dysfunction and histopathologic alterations significantly compared to the control group. In a study in adjuvant-induced arthritic rats, 400 mg/kg BW N. sativa seed oil for 2 wk did not cause a significant change in paw edema, ALT, and AST levels compared to the arthritic control group [56]. TQ administration (5 mg/kg BW) by oral gavage has also been shown to cause a significant reduction in serum H₂O₂-induced 4-hydroxynonenal (HNE), IL-1β, TNF-α, PGE2, and bone turnover markers such as alkaline phosphatase and tartrate-resistant acid phosphatase [46]. TQ was also able to inhibit significantly the arthritis score elevation and paw swelling compared to the arthritic control group [46].

In vitro studies

Findings from in vitro studies supported the effect of N. sativa on RA via showing moderate antiproliferative and strong anti-inflammatory and antioxidant features of TQ ([Table 3]). These results indicate that the treatment of human RA synovial fibroblasts with 1 – 5 µM TQ can induce apoptosis by blocking myeloid cell leukemia (Mcl)-1 expression and inhibit TNF-α-induced IL-6 and IL-8 generation in a dose-dependent style. TQ treatment can additionally decrease levels of TNF-α-induced intercellular adhesion molecule (ICAM)-1 and vascular cell adhesion molecule (VCAM)-1, reduce the expression of cadherin (Cad)-11, and inhibit TNF-α-induced phosphorylation of p38 and c-Jun N-terminal kinase (JNK) in a dose-dependent style. TQ treatment has also been illustrated to prevent the phosphorylation and the subsequent activation of TNF-α-induced apoptosis-regulated signaling kinase (ASK)-1 to decelerate TNF-α signaling and to suppress the expression of p38/JNK-mediated phospho-c-Jun [47]. Vaillancourt et al. [46] suggested that treatment with 0 – 10 µM TQ in human RA fibroblast-like synoviocytes can inhibit the lipopolysaccharides (LPS)-induced mRNA expression of IL-1β and TNF-α, PGE2 release, and cyclooxygenase (COX)-2 expression and prevent LPS-induced matrix metalloproteinase (MMP)-13 expression at the protein and mRNA levels in a dose-dependent style. The authors further reported the inhibition of LPS-induced p38 mitogen-activated protein kinase (MAPK), extracellular-signal-regulated kinase (ERK½) and NF-κB-p65 phosphorylation and their signaling pathways [46]. In a study by May et al. [72] in HTB-93 female RA Cell Line, TQ treatment (10, 50, and 100 µM) caused a significant reduction in cell proliferation, cell number, and NO levels compared to the controls. A significant decrease and/or increase in total cellular protein levels, and a significant increase in GSH levels compared to the controls were also reported; while no significant change in MDA levels and NO production were shown [72].

Methodological quality and risk of bias

The risk of bias was evaluated for all of the above-mentioned types of investigations. An unclear risk of selection bias (owing to lack of information regarding the randomization procedure, n = 19 and concealment, n = 21), performance bias (owing to lack of information regarding blinding of participants and personnel, n = 18) and detection bias (blinding of outcome evaluation, n = 21) was noticed. The risk of bias for the studies was low for reporting bias and attrition bias ([Fig. 4]).

Discussion

This is the first systematic review assessing the available literature on the effects of N. sativa on RA in in vitro, animal, and clinical studies. In vitro studies have noted the desirable effects of N. sativa in improving the inflammatory and oxidative status of RA [46], [47], [72]. Furthermore, almost all animal studies [46], [48], [49], [50], [51], [65], [66], [67], [68], [70], [71] have shown that N. sativa and its active component TQ can have beneficial effects on clinical, inflammatory, oxidative, and immunologic parameters in RA. However, 2 studies in animal models [56], [69] did not report any significant effect of N. sativa in RA. In addition, human studies [52], [53], [54], [55], [56] have suggested favorable effects of N. sativa on clinical and immunologic parameters of RA; however, no change or improvement of inflammatory and oxidative biomarkers was declared in the clinical trials [53], [55]. The controversy in findings between clinical and experimental investigations may be attributed to the differences in the measures of inflammatory, oxidative, and anti-oxidative markers in vivo or in vitro, as well as intensity and the type of stimulators of inflammation and oxidative stress. Furthermore, different preparations used in various studies may also affect the results. In clinical trials studied in this review, N. sativa oil was administered in capsules, whereas in a majority of experimental studies, the active component TQ was used. It seems that concentration of the principal compounds within N. sativa, namely TQ, varies greatly depending on the storage and preparation of N. sativa products, which can cause significant differences in bioactive compounds between studies. A primary limitation of the reviewed studies is the lack of information regarding quantification or standardization of bioactive compounds in the N. sativa preparations used. Standardization of herbal formulations is necessary in order to evaluate quality of drugs, based on the concentration of their active principles, physical, chemical, phytochemical, in vitro, and in vivo parameters [73]. Standardization of herbal medicines is the process of prescribing a set of standards or inherent features, constant parameters, and qualitative and quantitative values that carry an assurance of quality, efficacy, safety, and reproducibility [74]. However, among clinical trials and animal investigations reviewed here, only 1 study [70] discussed standardization of N. sativa preparation used. As mentioned above, TQ is the most bioactive component of N. sativa seeds and the oil that exists in tautomeric forms including the enol, keto and mixtures. Comprising the major fraction (~ 90%), the keto form is responsible for the pharmacological features of TQ [75]. TQ is a hydrophobic molecule, so its solubility can affect its bioavailability and cause limitations in drug formulation. In addition, its solubility depends on time as it ranges from 549 – 669 µg/ml in 24 h elevating to 665 – 740 µg/ml [76] in 72 h. TQ can be consumed via various methods including oral, intravenous, and intraperitoneal. Oral administration of TQ can cause biotransformation due to the metabolizing liver enzymes that catalyzes TQ into a hydroquinone [75]. Not many reports are detectable regarding its oral pharmacokinetics, which can be due to its poor solubility and low oral bioavailability [77]. The clearance of TQ following intravenous administration is 7.19 ml/kg/min, and the estimated volume of distribution at steady state (VSS) is 700.90 ml/kg. After oral administration, the apparent clearance value is 12.30 ml/min/kg, and VSS is 5109.46 ml/kg. The absorption half-life (T1/2) of TQ is calculated about 217 min, and it is rapidly removed from plasma [78]. The lack of bioavailability and pharmacokinetic parameters, as well as formulation problems, delayed the usage of TQ in the clinical phase. Thus, more investigations are required for a better understanding of TQ pharmacological properties meant for future clinical development.

Several potential mechanisms can be proposed for the observed ameliorating influences of N. sativa on RA. [Fig. 5] summarizes the potential mechanisms and pharmacological properties of N. sativa in RA. The major bioactive component of N. sativa is the phytochemical TQ, which has been illustrated to convey anti-inflammatory, antioxidant, and immunomodulatory properties [48]. As noted previously, inflammation, oxidative damage, and immune system activation are major players in the development and progression of RA. Increased generation and activity of proinflammatory cytokines, specifically TNF-α, IL-1, and IL-6, leads to the uncontrolled inflammation, which destructs the bone and cartilage and causes RA manifestations [79]. It has been suggested that the TQ in N. sativa can be involved in anti-inflammatory processes by preventing the production of eicosanoids such as thromboxane B2 and leukotriene B4 via suppressing COX and 5-lipoxygenase [80]. Furthermore, TQ can significantly inhibit the leukotriene C4 synthase activity [81]. In vitro treatment of stimulated neutrophils with TQ has shown to inhibit the generation of 5-lipoxygenase products and 5-hydroxy eicosatetraenoic acid [82]. TQ treatment in human blood cells can also inhibit the transformation of arachidonic acid to 5-hydroxy eicosatetraenoic acid [81].

In addition to the inhibitory effects of TQ on eicosanoid production, TQ has been proposed to retain its anti-inflammatory effects via inhibiting various pro-inflammatory transcription factors such as NF-κB/STAT3, by inducing several stimuli including cytokines, free radicals, etc. [83]. NF-κB activation triggers multiple cascades that cause inflammatory and immune responses [79]. According to animal studies of inflammatory arthritis, NF-κB had a predominant function in expansion of arthritis [84]. Furthermore, NF-κB activation has been seen in RA synovial tissue in early as well as later phases [79]. Therefore, NF-κB inhibitors are supposed to have therapeutic effects and are appropriate for RA treatment [85]. TQ can decrease pro-inflammatory responses predominantly by modulating NF-κB activity and suppressing IL-1β, IL-6, TNF-α, and IFN-γ production [86], [87], [88].

Anti-inflammatory properties of N. sativa in RA are further supported by studies showing the preventive effects of TQ on the generation of NO [51]. NO is a pro-inflammatory mediator produced from activated macrophages as part of the inflammatory response [89]. Inflammatory cytokines in chondrocytes can upregulate the activity of inducible nitric oxide synthase (iNOS) with the subsequent production of NO. The iNOS activity and plasma NO levels have been declared to be higher in RA cases compared with the normal controls [90], [91]. Excessive NO production has been proposed in the induction of apoptosis in chondrocytes [92]. Thus, agents that prevent extra NO production may have helpful therapeutic influences on arthritis by blocking cartilage destruction [93].

Another possible mechanism for the observed positive effects of N. sativa in RA is its free radicals scavenging properties. TQ is a potent antioxidant scavenging reactive oxygen species (ROS) such as superoxide anion, hydroxyl radical, and singlet molecular oxygen [28], [94]. The antioxidant activity of TQ may be attributed to the redox characteristics of its quinone structure and the capability of TQ to pass physiological barriers and easily reach the subcellular sections, all of which assist the radical cleaning function [95], [96]. Moreover, it can increase the activity of several antioxidant enzymes such as catalase, SOD, glutathione transferase, glutathione peroxidase, glutathione reductase, and GSH [97]. TQ may enhance the activation of Nrf2, and thus increase the heme oxygenase-1 (HO-1) expression [98].

The immunomodulatory activity of N. sativa is another possible mechanism through which it can influence RA. It has been indicated that N. sativa can enhance the immune response, particularly T lymphocytes [99], [100], increase the proportion of helper T cells to suppressor T cells, and increase the activity of natural killer cells [101]. N. sativa has also been shown to modulate Th1/Th2 pattern, and partially inhibit the Th2 [102]. Furthermore, a reduction in B cell-mediated immunity has been reported in vitro [103]. The immunomodulatory features of N. sativa and TQ have also been observed in mixed lymphocyte cultures, where it reduced IL-1β and IL-8 secretion [104]. Additionally, it has been announced that N. sativa can stimulate interleukin-3 secretion by T cells [105].

The first limitation of our study is the limited number of relevant clinical trials while the number of experimental studies is great and the majority of them have similar procedures. Due to lack of clinical trials and incomparable experimental information, we were not able to carry out meta-analysis on clinical, animal, and cellular studies. Furthermore, according to the risk of bias assessment, all experimental studies showed unclear risk of bias regarding randomization, allocation concealment, and masking ways because of the lack of reporting. Since the clinical investigations are often justified based on the findings from animal studies, this systematic review illustrated the need for randomization, allocation concealment, and masking outcome assessment of animal studies to reduce the risk of bias [106]. The strength of the present study was to systematically review all of the related human, animal, and in vitro studies. Furthermore, there was no limitation for time and language in our systematic review.

In this systematic review article, we tried to give persuasive clues on the efficacy of N. sativa in RA management and its mechanisms of function. Generally, there is an agreement regarding the impressive effects of N. sativa on clinical, inflammatory, oxidative, and immunologic parameters in animal models of RA, while the findings of the existing clinical investigations did not declare any change or improvement of inflammatory and oxidative biomarkers in RA subjects. Nevertheless, it should be noted that the majority of the animal research used N. sativa extract or its bioactive compound in high doses compared to N. sativa powder in clinical studies. In general, given the absence of sufficient clinical information, further randomized controlled clinical trials are warranted to confirm the promising effects of N. sativa on RA.

Contributorsʼ Statement

Conception and design of the work: A. Khabbazi, Z. Javadivala, N. Seyedsadjadi, A. Malek Mahdavi; data collection: A. Khabbazi, Z. Javadivala, N. Seyedsadjadi, A. Malek Mahdavi; analysis and interpretation of the data: A. Khabbazi, Z. Javadivala, N. Seyedsadjadi, A. Malek Mahdavi; drafting the manuscript: A. Khabbazi, Z. Javadivala, N. Seyedsadjadi, A. Malek Mahdavi; critical revision of the manuscript: A. Khabbazi, Z. Javadivala, N. Seyedsadjadi, A. Malek Mahdavi.

Conflict of Interest

The authors declare that they have no conflict of interest.

Acknowledgements

The authors wish to thank the Connective Tissue Diseases Research Center of Tabriz University of Medical Sciences, Tabriz, Iran. We are also thankful to Dr. Ashraf Fakhari who helped us in drawing chemical structures.

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