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Spices, herbal xenobiotics and the stomach: Friends or foes?

Ibrahim Abdulkarim Al Mofleh

Abstract

Spices and herbal remedies have been used since ancient times to treat a variety of disorders. It has been experimentally demonstrated that spices, herbs, and their extracts possess antimicrobial, anti-inflammatory, antirheumatic, lipid-lowering, hepatoprotective, nephroprotective, antimutagenic and anticancer activities, besides their gastroprotective and anti-ulcer activities. Despite a number of reports on the toxicity of herbs and spices, they are generally accepted as safer alternatives to conventional therapy against gastric ulcers. To this end, it is also believed, that excessive consumption of spices may favor the pathogenesis of gastric and duodenal ulcer and some studies have substantiated this common perception. Based on various in vivo experiments and clinical studies, on the effects of spices and herbs on gastric ulcers, it has indeed been shown that certain spices do possess remarkable anti-ulcer properties mediated by antisecretory, cytoprotective, antioxidant, and anti-Helicobacter pylori effects and mechanisms regulated by nitric oxide, prostaglandins, non-protein sulfhydryl molecules and epidermal growth factor expression. Accordingly, their consumption may attenuate and help prevent peptic ulcer disease. In the present review, the beneficial effects of spices and herbal nutritive components on the gastric mucosa are discussed against the paradigm of their deleterious potential.
 
© 2010 Baishideng. All rights reserved.
 
Key words: Herbs; Spices; Stomach; Stomach ulcers; Anti-ulcer agents
 
Peer reviewers: Frank I Tovey, OBE, ChM, FRCS, Honorary Research Felllow, Department of Surgery, University College London, London, United Kingdom; Tamara Vorobjova, Senior Researcher in Immunology, Department of Immunology, Institute of General and Molecular Pathology, University of Tartu, Ravila, 19, Tartu, 51014, Estonia
 
Al Mofleh IA. Spices, herbal xenobiotics and the stomach: Friends or foes? World J Gastroenterol 2010; 16(22): 2710-2719  Available from: URL: http://www.wjgnet.com/1007-9327/full/v16/i22/2710.htm  DOI: http://dx.doi.org/10.3748/wjg.v16.i22.2710
  
INTRODUCTION

Herbs and spices are considered as an important additive to food in several parts of the world. They enhance aroma, piquancy, and impart flavor to food. For long, they have been regarded as the essential component of eastern cuisine and have also been adopted into western diets. Since ancient times, spices and herbs have also been used in traditional treatment of a number of diseases. Nowadays, several experimental studies and, to a lesser extent, clinical trials have also emphasized the role of herbs in the treatment of a variety of disorders[1-4]. Several herbs and herbal extracts have been shown to possess antibacterial properties[5-7]. For instance, onion, garlic, ginger, pepper and mustard have demonstrated antimicrobial activity against several types of bacteria[8]. Tayel and El-Tras have recently reported a potent antibacterial activity of cinnamon and clove against several bacterial strains[9]. Some spices possess antifungal activity[10,11]. Beside their antifungal activity, herbs have also shown vermicidal, nematocidal and molluscicidal potential[12-15]. In addition, gingerol, the active ingredient of ginger, and eugenol have shown anti-inflammatory and antirheumatic activity[16]. More recent studies have also demonstrated anti-inflammatory and antirheumatic properties of herbs[17-19]. Furthermore, gingerol and cur cumin have also shown lipid-lowering potential in experimental animals[20-22] as well as in clinical trials[23,24].

In addition, many studies have especially endorsed the experimental evidence of folkloric utilization of spices to treat gastrointestinal disorders, without gastric mucosal toxicity. Also clinical, video-endoscopic studies conducted by Graham et al[25] have shown an adaptive cytoprotection. Furthermore, several experimental studies have also demonstrated cytoprotective activity of herbs[26-29].

On the other hand, some spices are considered to be toxic to the gastric mucosa and may potentiate or induce gastric injuries. Gastric mucosal toxicity induced by some spices in experimental animals is related to their oxidative constituents such as phenylpropenes, safroles, methyl eugenol, 1’-hydroxyestragole, myristicin and elemicin[30,31]. Meyers et al[32] have reported deleterious effect of red pepper and black pepper on the stomach. Both have induced a significant enhancement in parietal secretion, pepsin secretion, and potassium loss, as well as a dose-dependent gastric cell exfoliation and mucosal micro-bleeding, which are comparable to those induced by aspirin. 

Other studies have also reported epigastric pain and dyspepsia. The mechanism of epigastric pain and dyspepsia induced by red and black pepper is not well-defined. However, it is believed to be a consequence of inhibition of gastric surface hydrophobicity, enhancement of surface wettability and activation of intramucosal pain receptors[33]. Some spices may stimulate acid secretion and have deleterious effects on the gastric mucosal lining. Intragastric perfusion of albino rats with aqueous extracts of red pepper, fennel, omum/ajwain, cardamom, black pepper, cumin and coriander have stimulated a cholinergic response, and/or via other mechanism(s) have induced acid secretion with a respectively declining order. In injured stomach, cumin and coriander increase gastric secretion, and red pepper has an inhibitory effect[34].

Herbs in general are believed to be safe, and several studies have found them to be non-detrimental and beneficial to gastric mucosa and have cytoprotective properties[25,28]. In addition to their anti-ulcerogenic activity, it has been reported that spices contain protective factors that possess anticancer potential[35-37]. The ulcerogenic and/or anti-ulcerogenic activity of herbs is likely to be due to the oxidative and anti oxidative action of their different phytoconstituents. The prominent mechanism of protective action is mediated by their antioxidant activity and the ability to scavenge reactive oxygen species (ROS). A variety of herbs such as clove, cinnamon, oregano, black pepper, turmeric, ginger and polygonum species are known to contain phytoconstituents with anti-oxidative potential[38-46]. Antioxidative constituents of herbs are summarized in the Table 1.

The beneficial effects of herbs and plant extracts in the prevention of gastric injury have been indicated in several experimental studies. For example, various extracts of Mammea americana have significantly reduced the ulcer index and demonstrated a cytoprotective effect in experimentally induced ulcers[47]. Further pharmacological and histopathological studies have demonstrated significant protection against ethanol-induced ulcers in rats by extracts of roots of Asphodelus aestivus and Cichorium intybus, herbs of Equisetum palustre and Viscum album ssp. album and fruits of Laurus[48].
 
Clinical studies have also confirmed the gastric pro tection conferred by herbs. In a clinical study of 98 outpatients with chronic gastritis, who were randomly divided into a group treated with herbal pairs and a control group treated with Banxia Xiexin Tang, effectiveness was significantly higher in the treated group. The treatment has improved therapeutic effects, and minimized the adverse effects of gastritis[49]. In another clinical study, 103 patients with duodenal ulcer received phytotherapy in the form of infusions and concoctions of medicinal plants. This resulted in ulcer scarring and a decrease in relapse[50]. Furthermore, in a study of 170 patients with duodenal ulcer and gastroduodenitis treated with herbal combinations alone or with addition of antacids, pain and dyspeptic symptoms disappeared in > 85% of both treatment groups, with a similar rate of endoscopic healing[51]. Hence, agents that possess antioxidative activity are expected to play a major role in the treatment of peptic ulcer disease.
 
EXPERIMENTAL INDUCTION OF ULCERS

Various noxious chemical agents are used to induce acute experimental gastric ulceration. Indomethacin and necrotizing agents including 80% ethanol, 0.2 mol/L NaOH, 25% NaCl are commonly used. Pyloric ligation is applied in antisecretory studies[52-56]. Other universally accepted experimental ulcer models include stress induced by swimming[55], aspirin[56], ethanol/HCl, acetylsalicylic acid, cold-restraint[57] and hypothermic restraint[54]. In addition, gastric ulcers have also been induced by serosal application of acetic acid[58].
 
FACTORS INVOLVED IN ULCER HEALING

Acid and other noxious agents such as bile acids, nonsteroidal anti-inflammatory drugs (NSAIDs) and ethanol enhance the presence of mucosal barrier disruption, H+ back diffusion and ulcer susceptibility. Adequate mucosal flow and secretion of bicarbonate with formation of an alkaline buffer layer at the epithelial surface, is considered as a first line of mucosal defense. Prostaglandins (PGs) are involved in the ulcer healing process. Growth factors, some gut hormones (e.g. gastrin and cholecystokinin) and melatonin promote ulcer healing through generation of cyclooxygenase-2 (COX-2) and release of PGE2 in the ulcer margin[59,60]. Similar action is achieved by application of antisecretory doses of exogenous PG[61]. In addition to PGs, many other factors including growth factors, nitric oxide or calcitonin gene-related peptide, as well as some gut hormones such as gastrin and cholecystokinin, leptin, ghrelin and gastrin-releasing peptide, are involved in gastroprotection. The protective action of gut hormones has been attributed to the release of PG or activation of sensory nerves[62].
 
MECHANISMS OF PROTECTION RENDERED BY SPICES AND HERBS

The mechanism of herb-induced gastroprotection varies according to the nature and chemical constituents of the herbs. Three main functions including antisecretory, cytoprotective and antioxidant activities, isolated or in combination, are responsible for gastric mucosal protection.
 
Antisecretory activity

Several herbs and plants extracts have shown an anti-ulcer effect mainly due to their potent antisecretory action, which could be related to their flavonoid content. In experimental animals, Cissus quadrangularis extract and Maytenus ilicifolia have been shown to inhibit gastric secretions and ulcer index[63,64]. Similarly, phytosphingosine hydrochloride has been shown to have antisecretory and anti-ulcer effects in animals with pyloric ligation[65]. Methanolic extract of Momordica charantia prevents development of peptic ulcer and promotes healing of ulcers induced by acetic acid. Antisecretory studies in pylorus-ligated rats have demonstrated a significant reduction in acidity, pepsin content and ulcer index. On the other hand, the extract also amplifies the gastric mucosal content[66]. A variety of herbs and plant extracts including standardized aqueous extract of Cecropia glaziovii Sneth (Cecropiaceae)[67], alkaloid extract and 2-phenylquinoline obtained from the bark of Galipea longiflora (Rutaceae)[68] and Landolphia owariensis extracts[69] have exhibited an anti-ulcer effect.
 
The inhibition of gastric acid and pepsin output in rats with intact or deactivated sensory nerves treated parenterally with capsaicin could contribute to the capsaicin-induced gastroprotection against acid-dependent mucosal lesions[70].
 
Cytoprotective activity

In pylorus-ligated rats, methanolic extract of M. charantia L. fruit protects against peptic ulcer and promotes ulcer healing via enhancing the gastric mucosal content and antisecretory activity in stress-, ethanol-, indomethacin- and cysteamine-induced ulcers[66]. In both ethanol- and indomethacin-induced experimental ulcers, pretreatment with isopulegol, a monoterpene present in essential oils of several aromatic plants, has resulted in significant gastroprotective action, which is apparently mediated through its endogenous PGs and antioxidative properties[71]. More over, Weikang (WK) decoction significantly protects against ethanol-induced gastric mucosal injury. This activity is mediated by enhancement of epidermal growth factor (EGF) content in gastric juice, nitric oxide (NO) in gastric tissue, PGE2 and superoxide dismutase (SOD) in plasma, inhibition of malondialdehyde (MDA) and endothelin in plasma, and an increase in mucosal thickness[72]. In swim- and ethanol-stress-induced ulcers, extract of ginger rhizome (Zingiber officinale) normalizes antioxidant enzymes and protects against oxidative and gastric mucin damage[55]. The gastroprotective effect of Vanillosmopsis arborea bark essential oil is likely mediated by a2-receptor activation[73], whereas the anti-ulcerogenic effect of Solanum torvum Swartz (Solanaceae) aqueous and methanol extracts is probably due to cytoprotective mechanisms[74]. Cytoprotective action of total carotenoid and astaxanthin esters depends on their mucin-related protective action as well as enhancing antioxidants enzymes level and H+, K+-ATPase inhibitory activity[75]. Synthesis of cytoprotective PGs, increased resistance of gastric mucosa, and inhibition of leukotriene synthesis are possibly responsible for gastroprotection induced by boswellic acids (from Boswellia)[57].
In various ulcer models in mice, the gastroprotective activity of G. longiflora (Rutaceae) is related to an increase in gastric mucus content and antisecretory activity. Additionally, NO is involved in mucosal protection, which could be attributed to their alkaloids, particularly 2-phenylquinoline[68]. Pretreatment of albino rats with aqueous extract orally once daily for 2 wk significantly inhibited HCl/ethanol-induced ulcers and enhanced gastric mucus production. Additionally, it displayed antisecretory activity in pylorus-ligated rats. The results indicate that the leaf extracts of Landolphia possess anti-ulcer properties[69].

A new flavonoid derivative, DA-6034, also prevents ulcers induced by ethanol, aspirin, indomethacin, stress, and acetic acid, and enhances endogenous PGE2 synthesis and mucus content in the gel layer of the gastric mucosa. Promotion of the gastric defensive systems is the likely cause of its gastroprotective activities[56].
 
Antioxidative activity

Oxidants are implicated in the pathophysiology of various diseases, including peptic ulcer disease, and antioxidants may therefore contribute to their prevention and treatment. NSAIDs account for some of the most commonly used drugs worldwide and may activate the oxidative process. For instance, treatment with indomethacin induces neutrophil activation with release of ROS and microvascular injuries, which is considered as the prime event in gastric mucosal damage[76]. Therefore, investigators have continued to search for agents with antioxidative properties, which prevent or at least reduce ROS-induced mucosal damage. Such agents include isopulegol, which has shown significant gastroprotective effects in ethanol- and indomethacin-induced ulcer models. Gastroprotective action is probably mediated by its antioxidative properties, synthesis of endogenous PGs and K+ (ATP) channel opening[71]. 

Other herbs with antioxidative actions include carotenoid and astaxanthin esters, the herb collection Korniozil, and ginger rhizome. For instance, total carotenoid and astaxanthin esters have experimentally protected gastric mucin and increased levels of the antioxidant enzymes catalase, SOD, and glutathione peroxidase in gastric homogenate[75]. In addition, Korniozil also protects against experimentally induced stress ulcers, with enhancement of gastric mucous coat regeneration, along with restoration of lipid peroxidation and antioxidative system function[77]. 

Ginger rhizome extract has shown gastroprotective activity in animals with swim- and ethanol-stress-induced ulcers. This activity is based on gastric mucin generation, restoration of antioxidant enzymes and inhibition of Helicobacter pylori (H. pylori) growth[55].

The gastroprotective effect of Cissus sicyoides extract administered orally in rodents treated with various ulcerogenic agents is also due to its antioxidative properties, increase of NO and SH groups, with enhancement of mucosal defense mechanisms and microcirculatory response. Therefore, the authors have supported its use for gastric ulcer treatment[78].

Studies on piperine have demonstrated an antioxidative effect in vitro, lipid peroxide inhibition in vivo, and enhancement of the bioavailability of phytochemicals. The protective activity of piperine is linked to its antioxidative action and ability to inhibit ROS[40]. Thymoquinone, the active constituent of Nigella sativa, has been shown to protect against gastric mucosal damage induced by ethanol. These effects can be ascribed to improvement in the antioxidant status, increased serum levels of serum glutathione, SOD, inhibition of radical oxygen species, and increased mucin content of the gastric mucosa[29,79].
 
Other activities: PG-herb interaction

PG synthesis is important for gastric mucosal protection. PG has been used as an antisecretory drug to treat peptic ulcer disease. However, the use of a sufficient therapeutic dose is associated with adverse effects, which limits its use, especially after the introduction of antisecretory drugs such as H2-receptor antagonists and proton pump inhibitors. Several studies on herbs and plant extracts that activate PG synthesis have emphasized their role in gastroprotection and healing of gastric mucosal injuries. Silva et al[71] have reported a significant dose-related protective effect of isopulegol, a monoterpene that is obtained from essential oils of several aromatic plants, against indomethacin- and ethanol-induced ulcers. This protective action is probably mediated by endogenous PGs, K+ (ATP) channel opening, and antioxidant properties. Similarly, Alqasoumi et al[54] have reported a PG and/or antisecretory, as well as antioxidant-mediated gastroprotective activity of Rocket extract. Boswellic acid, a triterpenoid used clinically to treat arthritis, has exhibited a mucosal protective action through PG synthesis stimulation and leukotriene synthesis inhibition[57]. Endogenous PGs and PG EP1 receptors have an important role in the adaptive protection and functional responses in mice treated with sodium taurocholate[80]. The active ingredient of chilli, capsaicin, which is believed to be ulcerogenic, on the contrary, prevents ulcer formation through its antisecretory action, as well as stimulation of mucus, alkali secretions and mucosal microcirculation. In addition, capsaicin stimulates afferent neurons in the stomach and transmits signals to the central nervous system, which trigger an anti-inflammatory response and gastroprotection[81]. Treatment with small doses of topical capsaicin protects the gastric mucosa from damage by strong irritants[69].
PGs have been found to reduce enhanced duodenal mucosal permeability induced by hydrochloric acid[82]. In acute injury, small bowel mucosa function recovers with the restitution of epithelium, which is believed to be pivotal for epithelial repair, and occurs only in the presence of PG-mediated paracellular space closure[83]. Hatazawa et al[84] have studied the role of PGs/COX in the healing of indomethacin-induced small-intestinal ulcers in rats. They have reported ulcer healing by endogenous PGs, which is mediated by PG EP4 receptors, and involvement of COX-2 in the early stage and COX-1 in the late stage of healing. Bacterial lipopolysaccharide is involved in gastric mucosal protection in rats, via activation of COX and endogenous PG genes[85]. In rats, Teucrium polium has demonstrated protection against indomethacin-induced gastric ulcer through PG synthesis, EGF receptor (EGFR) expression and modulation of mucin secretion, besides its antioxidative activity, and it lack of toxicity[86].
 
EGF and effect of herbs

Ulcer preventive activity of herbs in experimentally induced gastric injury is thought to be mediated through their antisecretory and antioxidative properties, as well as PG generation. 

Various factors are involved in mucosal defense and repair, including gastrin, parietal cells and tumor necrosis factor (TNF)-a. Gastrin and parietal cells play an important role in the regulation of mucosal proliferation in response to gastric injury and inflammation[87]. Similarly, TNF-a, which is released during gastric mucosal injury, also contributes to epithelial cell repair in the gastric mucosa via its receptor and activation of the PG pathway[88]. EGF and other growth factors are also pivotal for the process of mucosal healing. EGF and transforming growth factor (TGF)-a have a common receptor (EGFR). They promote ulcer healing through enhancement of cell proliferation, overexpression of growth factors, inhibition of gastric secretion and enhancement of blood flow at the ulcer margin[89]. Treatment with EGF significantly induces extracellular signal-regulated kinase (ERK) activity, COX-2 and PGE2 generation, and cell proliferation. The EGF-induced proliferation of gastric epithelial cells is probably mediated by the ERK/COX-2 pathway[90]. Gastric mucosa regeneration, with cell proliferation, migration, tissue injury repair and ulcer healing are controlled by activation of EGFR. Although TGF-a acts under normal circumstances and following acute injury, EGF acts mainly during the healing process of chronic ulcers. Both TGF-a and EGF, and other growth factors including basic fibroblast growth factor (bFGF) and vascular endothelial growth factor (VEGF), promote restoration of connective tissue and angiogenesis in injured gastric mucosa. Further growth factors involved in regeneration include keratinocyte growth factor, hepatocyte growth factor and trefoil peptides[91]. Regeneration of injured human gastric epithelial monolayers has been promoted by EGFR-dependent phosphoinositide 3-kinase activation[92].

Besides its role in gastric inflammation and injury, EGF plays an important role in the regulation of cancer growth. Phosphorylation of EGFR and inhibition of heparin-binding EGF-like growth factor (HB-EGF) carboxyl-terminal fragment (CTF), and HB-EGF-CTF nuclear translocation are considered crucial in inhibitory regulation of cancer cell growth[93]. Overexpression of EGF has often been found in gastric cancer. Growth factors alter the localization of tight-junction-associated proteins such as ZO-1 and occludin[94]. Baek et al[95] have also reported EGF overexpression and urokinase plasminogen activator receptor in human gastric cancers. In epithelial and mesenchymal cells, EGF binds to tyrosine kinase receptor and promotes malignant formation as well as tissue repair[96].

Herb-induced growth factor enhancement may support treatment strategies for gastric ulcer and cancer. Cap saicin-sensitive nerves contribute to healing of acetic-acid-induced chronic gastric ulcer through stimulation of EGF expression in salivary glands, serum and gastric mucosa[97]. Weitongning herb increases EGF and NO content in ulcer scars, which improves ulcer healing and reduces recurrence[98]. Also, in ethanol-induced gastric mucosal injury, WK decoction has shown a significant gastroprotective effect that is mediated by increased levels of NO in gastric tissue, PGI2 and SOD in plasma, and EGF in gastric juice[72]. Mexican tea herb and pilular adina herb have also demonstrated protection of gastric mucosa through stimulation of NO and EGF secretion and enhancement of EGFR expression[99]. Wang et al[100] have also reported increased expression of EGF and EGFR mRNA in experimental gastric ulcer in rats treated with Kuiyangping, with possible promotion of ulcer healing and decreased ulcer recurrence. Angelica and Chuanxiong spices given to rats with myocardial infarction may affect VEGF expression and promote endothelial cell proliferation[101]. This angiogenic effect may also be applied to the formation of new vessels in granulation tissue and restitution of injured gastric mucosa. 

Through their effect on EGF, herbs may prove beneficial in the management of cancer. Constituents of ginger have inhibited EGF-induced cell transformation[102]. Inhibition of EGFR tyrosine kinase proliferation and invasion of gastric cancer cells has also been achieved by curcumin[103]. Molecular therapies that target growth factors EGF and VEGF and their receptors have shown promise against hepatocellular carcinoma in the absence of beneficial effects of chemotherapy[104]. Recent data combining EGFR and VEGF inhibitors have suggested the superiority of targeting multiple pathways rather than a single pathway[105]. The anticancer potential of curcumin has been demonstrated by inhibition of EGF-induced upregulation of aquaporin and ovarian cancer cell migration[106].
 
Role of NO mediation by herbs

Tsai et al[107] have evaluated the effect of some spices on NO overproduction generated by inducible NO synthase (iNOS), which is implicated in disease development. Rosemary, tarragon, oregano, basil, marjoram, allspice, and thyme have demonstrated poor to moderate activity. In contrast, cinnamon has excellent ability to scavenge NO. NO-scavenging activity of herbs is probably related to their high content of phenolic compounds, which scavenge NO or suppress iNOS. In another study, pretreatment with NOS inhibitor attenuated the gastroprotective effect induced by polyalthic acid[108]. Moreover, plant-extract-induced gastroprotection is probably related to the enhancing effect on NOS inhibitor expression, gastric microcirculation and release of NO[109]. Participation of NO, PGs and SH compounds may explain the anti-ulcerogenic action of diterpenoid from Croton reflexifolius[108]. 
 
Non-protein-SH compounds and herbal involvement

Non-protein (NP)-SH compounds contribute to gastric mucosal defense. Depletion of NP-SH alters mucosal integrity. Commiphora opobalsamum (L.) Engl. (Balessan) protects against various models of experimental gastric ulcers in rats. It has been shown to protect in a dose-dependent manner against mucus and NP-SH depletion with a large margin of safety[52]. Methanolic C. sicyoides extract given orally to rodents has been shown to inhibit experimental gastric injuries induced by necrotizing agents, via participation of NP-SH compounds and NO, and enhancement of the defense system[78]. Maintaining adequate gastric mucus concentration and NP-SH levels is essential for gastric mucosa integrity and function. Other herbs and plant extracts also have the ability to preserve the defense system of the gastric mucosa. For instance, pretreatment with Ginkgo biloba extract has been shown to inhibit, in a dose-dependent manner, ethanol-induced NP-SH compound production, depletion of gastric wall mucus concentration, and lipid peroxidation, and preserve mucosal function[110]. Similarly, anise aqueous suspension, and rocket and anise have significantly replenished ethanol-induced gastric wall mucus concentration and NP-SH depletion in experimental studies[54,111].
 
H. pylori bactericidal activity of herbs
  
The association between H. pylori and peptic ulcer disease is well-established and eradication is pivotal for ulcer healing and minimizing the relapse rate. Although the eradication rate of currently used regimens ranges between 80% and 90%, the problem of developing resistance is emerging. A number of investigators have evaluated the effect of herbs and plant extracts on H. pylori. Methylene chloride cinnamon extract has also shown an inhibitory effect on the free urease of H. pylori[112]. Also curcumin and its methanolic extract have inhibited the growth of all strains of H. pylori in vitro[113]. In addition, gingerol, a polyphenolic constitute of ginger root, has also demonstrated inhibitory activity on CagA+ strains of H. pylori[114]. Moreover, eugenol and cinnamaldehyde prevented growth of H. pylori obtained from human gastric tissue, and inhibited the growth of all 30 tested H. pylori strains, with a lack of resistance[115]. In a declining order, turmeric, cumin, ginger, chilli, borage, black caraway, oregano and liquorice have demonstrated partial bactericidal activity against H. pylori. H. pylori adhesion to the stomach has been inhibited by extracts of turmeric, borage and parsley[116]. Zaidi et al[117] have reported that > 50% of 50 commonly used Pakistani medicinal plants have inhibited the growth of eight H. pylori strains. Curcuma amada Roxb., Mallotus philippines (Lam) Muell., Myrisctica fragrans Houtt., and Psoralea corylifolia L aqueous-ethanol extracts have demonstrated a potent anti-H. pylori activity and Mal. philippines (Lam) Muell. has exhibited potent bactericidal activity.
 
SAFETY AND TOXICITY OF SPICES

The majority of experimental studies have reported a lack or low levels of toxicity for most spices. However, there are many case reports, and in vivo and in vitro toxicological studies that have demonstrated the toxicity of certain herbs and their constituents[118]. Some investigators have reported hepatotoxicity of curcumin and its derivatives[119], as well as turmeric and its ethanolic extract in vulnerable mice[120]. 

Longer treatment with high turmeric dose has been associated with a significant decline in body weight gain and alterations in liver weight[121]. In contrast, chronic treatment with Foeniculum vulgare ethanolic extracts of fruit and Ruta chalepensis aerial parts have resulted in a significant weight gain in male mice[122]. Changes in liver, spleen, lung or reproductive organs, along with a significant increase in sperm count and motility, and decreased hemoglobin have been reported in Cinnamon zeylanicum, Piper longum and R. chalepensis-treated animals[122,123]. In an experimental model, piperine (10 and 20 mg/kg) decreased mating performance and fertility. Five days post-mating, oral treatment induced considerable anti-implantation activity. In addition, intrauterine injection of piperine has caused loss of implants. However, piperine treatment has not produced any histopathological effect in the ovaries and uterus at the cellular level[124]. Although initial reports on the safety of black pepper and its active ingredient piperine were controversial, the current literature has established its safety in animals. 

Moreover, piperine has shown antimutagenic and antitumor activities. Curcumin administered at higher doses has resulted in nuclear, genome and more extensive mitochondrial damage in human hepatoma G2 cells, mediated by the elevated concentration of ROS and lipid peroxidation. Curcumin also has caused genotoxicity in PC12 cells and has induced suicidal death of normal erythrocytes[125-127]. At elevated concentrations, thymoquinone may be genotoxic and cytotoxic, induce programmed cell death in erythrocytes, and cause glutathione depletion and liver damage[128,129].
 
CONCLUSION

It continues to be debatable whether spices and herbal xenobiotics are beneficial to gastric mucosal damage, and whether their toxicity outweighs any benefits. It is, however, clear that the consumption of certain common spices in food and the intake of herbal supplements may help the fight against peptic ulcer disease in humans. This review provides insights into the future use of herb- and spice-based drugs as alternative treatments for gastric ulcer. Dietary and nutritional practices in the oriental region and the consumption of spices in moderate quantities may be of benefit for the prevention of gastric ulcer. The review suggests the need for further investigations into the benefit of herbal xenobiotics and spices on the gastric mucosa, with in-depth in vivo studies, sustained clinical trials and cohort analyses. There is enough evidence to conclude that spices have a beneficial effect on gastric ulcers, despite various reports of their toxicity.

REFERENCES

1      Cai L, Wu CD. Compounds from Syzygium aromaticum possessing growth inhibitory activity against oral pathogens. J Nat Prod 1996; 59: 987-990
2      Nanji AA, Jokelainen K, Tipoe GL, Rahemtulla A, Thomas P, Dannenberg AJ. Curcumin prevents alcohol-induced liver disease in rats by inhibiting the expression of NF-kappa B-dependent genes. Am J Physiol Gastrointest Liver Physiol 2003; 284: G321-G327
3     Bengmark S. Curcumin, an atoxic antioxidant and natural NFkappaB, cyclooxygenase-2, lipooxygenase, and inducible nitric oxide synthase inhibitor: a shield against acute and chronic diseases. JPEN J Parenter Enteral Nutr 2006; 30: 45-51
4      Nicoll R, Henein MY. Ginger (Zingiber officinale Roscoe): a hot remedy for cardiovascular disease? Int J Cardiol 2009; 131: 408-409
5      Weseler A, Saller R, Reichling J. Comparative investigation of the antimicrobial activity of PADMA 28 and selected European herbal drugs. Forsch Komplementarmed Klass Naturheilkd 2002; 9: 346-351
6      Liu CS, Cham TM, Yang CH, Chang HW, Chen CH, Chuang LY. Antibacterial properties of Chinese herbal medicines against nosocomial antibiotic resistant strains of Pseudomonas aeruginosa in Taiwan. Am J Chin Med 2007; 35: 1047-1060
7      Shan B, Cai YZ, Brooks JD, Corke H. Antibacterial properties and major bioactive components of cinnamon stick (Cinnamomum burmannii): activity against foodborne pathogenic bacteria. J Agric Food Chem 2007; 55: 5484-5490
8      Chen HC, Chang MD, Chang TJ. [Antibacterial properties of some spice plants before and after heat treatment] Zhonghua Minguo Weisheng Wujimian Yixue Zazhi 1985; 18: 190-195
9      Tayel AA, El-Tras WF. Possibility of fighting food borne bacteria by egyptian folk medicinal herbs and spices extracts. J Egypt Public Health Assoc 2009; 84: 21-32
10    Sekine T, Sugano M, Majid A, Fujii Y. Antifungal effects of volatile compounds from black zira (Bunium persicum) and other spices and herbs. J Chem Ecol 2007; 33: 2123-2132
11    Seneviratne CJ, Wong RW, Samaranayake LP. Potent anti-microbial activity of traditional Chinese medicine herbs against Candida species. Mycoses 2008; 51: 30-34
12    Hitokoto H, Morozumi S, Wauke T, Sakai S, Kurata H. Inhibitory effects of spices on growth and toxin production of toxigenic fungi. Appl Environ Microbiol 1980; 39: 818-822
13    Karapinar M. Inhibitory effects of anethole and eugenol on the growth and toxin production of Aspergillus parasiticus. Int J Food Microbiol 1990; 10: 193-199
14    El Garhy MF, Mahmoud LH. Anthelminthic efficacy of traditional herbs on Ascaris lumbricoides. J Egypt Soc Parasitol 2002; 32: 893-900
15    Kiuchi F, Goto Y, Sugimoto N, Akao N, Kondo K, Tsuda Y. Nematocidal activity of turmeric: synergistic action of curcuminoids. Chem Pharm Bull (Tokyo) 1993; 41: 1640-1643
16    Sharma JN, Srivastava KC, Gan EK. Suppressive effects of eugenol and ginger oil on arthritic rats. Pharmacology 1994; 49: 314-318
17    Setty AR, Sigal LH. Herbal medications commonly used in the practice of rheumatology: mechanisms of action, efficacy, and side effects. Semin Arthritis Rheum 2005; 34: 773-784
18    Li EK, Tam LS, Wong CK, Li WC, Lam CW, Wachtel-Galor S, Benzie IF, Bao YX, Leung PC, Tomlinson B. Safety and efficacy of Ganoderma lucidum (lingzhi) and San Miao San supplementation in patients with rheumatoid arthritis: a double-blind, randomized, placebo-controlled pilot trial. Arthritis Rheum 2007; 57: 1143-1150
19    Spiller F, Alves MK, Vieira SM, Carvalho TA, Leite CE, Lunardelli A, Poloni JA, Cunha FQ, de Oliveira JR. Anti-inflammatory effects of red pepper (Capsicum baccatum) on carrageenan- and antigen-induced inflammation. J Pharm Pharmacol 2008; 60: 473-478
20    Al-Amin ZM, Thomson M, Al-Qattan KK, Peltonen-Shalaby R, Ali M. Anti-diabetic and hypolipidaemic properties of ginger (Zingiber officinale) in streptozotocin-induced diabetic rats. Br J Nutr 2006; 96: 660-666
21    Ejaz A, Wu D, Kwan P, Meydani M. Curcumin inhibits adipogenesis in 3T3-L1 adipocytes and angiogenesis and obesity in C57/BL mice. J Nutr 2009; 139: 919-925
22    Kang Q, Chen A. Curcumin suppresses expression of low-density lipoprotein (LDL) receptor, leading to the inhibition of LDL-induced activation of hepatic stellate cells. Br J Pharmacol 2009; 157: 1354-1367
23   Alwi I, Santoso T, Suyono S, Sutrisna B, Suyatna FD, Kresno SB, Ernie S. The effect of curcumin on lipid level in patients with acute coronary syndrome. Acta Med Indones 2008; 40: 201-210
24    Alizadeh-Navaei R, Roozbeh F, Saravi M, Pouramir M, Jalali F, Moghadamnia AA. Investigation of the effect of ginger on the lipid levels. A double blind controlled clinical trial. Saudi Med J 2008; 29: 1280-1284
25    Graham DY, Smith JL, Opekun AR. Spicy food and the stomach. Evaluation by videoendoscopy. JAMA 1988; 260: 3473-3475
26    al-Yahya MA, Rafatullah S, Mossa JS, Ageel AM, Parmar NS, Tariq M. Gastroprotective activity of ginger zingiber officinale rosc., in albino rats. Am J Chin Med 1989; 17: 51-56
27   Rafatullah S, Tariq M, Al-Yahya MA, Mossa JS, Ageel AM. Evaluation of turmeric (Curcuma longa) for gastric and duodenal antiulcer activity in rats. J Ethnopharmacol 1990; 29: 25-34
28    Marotta RB, Floch MH. Diet and nutrition in ulcer disease. Med Clin North Am 1991; 75: 967-979
29    Al Mofleh IA, Alhaider AA, Mossa JS, Al-Sohaibani MO, Al-Yahya MA, Rafatullah S, Shaik SA. Gastroprotective effect of an aqueous suspension of black cumin Nigella sativa on necrotizing agents-induced gastric injury in experimental animals. Saudi J Gastroenterol 2008; 14: 128-134
30    Miller EC, Swanson AB, Phillips DH, Fletcher TL, Liem A, Miller JA. Structure-activity studies of the carcinogenicities in the mouse and rat of some naturally occurring and synthetic alkenylbenzene derivatives related to safrole and estragole. Cancer Res 1983; 43: 1124-1134
31    Schiestl RH, Chan WS, Gietz RD, Mehta RD, Hastings PJ. Safrole, eugenol and methyleugenol induce intrachromosomal recombination in yeast. Mutat Res 1989; 224: 427-436
32    Myers BM, Smith JL, Graham DY. Effect of red pepper and black pepper on the stomach. Am J Gastroenterol 1987; 82: 211-214
33    Lichtenberger LM, Romero JJ, Carryl OR, Illich PA, Walters ET. Effect of pepper and bismuth subsalicylate on gastric pain and surface hydrophobicity in the rat. Aliment Pharmacol Ther 1998; 12: 483-490
34    Vasudevan K, Vembar S, Veeraraghavan K, Haranath PS. Influence of intragastric perfusion of aqueous spice extracts on acid secretion in anesthetized albino rats. Indian J Gastroenterol 2000; 19: 53-56
35    Tanida N, Kawaura A, Takahashi A, Sawada K, Shimoyama T. Suppressive effect of wasabi (pungent Japanese spice) on gastric carcinogenesis induced by MNNG in rats. Nutr Cancer 1991; 16: 53-58
36     Lo YC, Yang YC, Wu IC, Kuo FC, Liu CM, Wang HW, Kuo CH, Wu JY, Wu DC. Capsaicin-induced cell death in a human gastric adenocarcinoma cell line. World J Gastroenterol 2005; 11: 6254-6257
37    Mothana RA, Gruenert R, Bednarski PJ, Lindequist U. Evaluation of the in vitro anticancer, antimicrobial and antioxidant activities of some Yemeni plants used in folk medicine. Pharmazie 2009; 64: 260-268
38    Oya T, Osawa T, Kawakishi S. Spice constituents scavenging free radicals and inhibiting pentosidine formation in a model system. Biosci Biotechnol Biochem 1997; 61: 263-266
39    Shan B, Cai YZ, Sun M, Corke H. Antioxidant capacity of 26 spice extracts and characterization of their phenolic constituents. J Agric Food Chem 2005; 53: 7749-7759
40    Srinivasan K. Black pepper and its pungent principle-piperine: a review of diverse physiological effects. Crit Rev Food Sci Nutr 2007; 47: 735-748
41    Adhikari S, Indira Priyadarsini K, Mukherjee T. Physico-chemical studies on the evaluation of the antioxidant activity of herbal extracts and active principles of some Indian medicinal plants. J Clin Biochem Nutr 2007; 40: 174-183
42    Huang WY, Cai YZ, Xing J, Corke H, Sun M. Comparative analysis of bioactivities of four Polygonum species. Planta Med 2008; 74: 43-49
43    Schwarz K, Ternes W. Antioxidative constituents of Rosmarinus officinalis and Salvia officinalis. I. Determination of phenolic diterpenes with antioxidative activity amongst tocochromanols using HPLC. Z Lebensm Unters Forsch 1992; 195: 95-98
44    Cheel J, Schmeda-Hirschmann G, Jordan M, Theoduloz C, Rodríguez JA, Gerth A, Wilken D. Free radical scavenging activity and secondary metabolites from in vitro cultures of Sanicula graveolens. Z Naturforsch C 2007; 62: 555-562
45    Korkina LG. Phenylpropanoids as naturally occurring antioxidants: from plant defense to human health. Cell Mol Biol (Noisy-le-grand) 2007; 53: 15-25
46    Agbor GA, Vinson JA, Oben JE, Ngogang JY. In vitro antioxidant activity of three Piper species. J Herb Pharmacother 2007; 7: 49-64
47    Toma W, Hiruma-Lima CA, Guerrero RO, Brito AR. Preliminary studies of Mammea americana L. (Guttiferae) bark/latex extract point to an effective antiulcer effect on gastric ulcer models in mice. Phytomedicine 2005; 12: 345-350
48    Gürbüz I, Ustün O, Yeşilada E, Sezik E, Akyürek N. In vivo gastroprotective effects of five Turkish folk remedies against ethanol-induced lesions. J Ethnopharmacol 2002; 83: 241-244
49    Xia J. Medicinal herbs used in pairs for treatment of 98 cases of chronic gastritis. J Tradit Chin Med 2004; 24: 208-209
50    Chernomorets NN, Seleznev AV, Revutskiĭ BI, Alifanova RE, Kravchenko ZV, Cherkasskaia EP. [The differentiated phytotherapy of patients with duodenal peptic ulcer] Lik Sprava 1992; 112-115
51    Chakŭrski I, Matev M, Stefanov G, Koĭchev A, Angelova I. [Treanntment of duodenal ulcers and gastroduodenitis with a herbal combination of Symphitum officinalis and Calendula officinalis with and without antacids] Vutr Boles 1981; 20: 44-47
52    Al-Howiriny T, Al-Sohaibani M, Al-Said M, Al-Yahya M, El-Tahir K, Rafatullah S. Effect of Commiphora opobalsamum (L.) Engl. (Balessan) on experimental gastric ulcers and secretion in rats. J Ethnopharmacol 2005; 98: 287-294
53    AI-Mofleh IA, Alhaider AA, Mossa lS, Al-Sohaibani MO, Rafatullah S, Qureshi S.  Protection of gastric mucosal damage by Coriandrum sativum L. pretreatment in Wistar albino rats. Environmental Toxicol Pharmacol 2006; 22: 64-69.
54   Alqasoumi S, Al-Sohaibani M, Al-Howiriny T, Al-Yahya M, Rafatullah S. Rocket “Eruca sativa”: a salad herb with potential gastric anti-ulcer activity. World J Gastroenterol 2009; 15: 1958-1965
55    Nanjundaiah SM, Annaiah HN, M Dharmesh S. Gastroprotective Effect of Ginger Rhizome (Zingiber officinale) Extract: Role of Gallic Acid and Cinnamic Acid in H+, K+-ATPase/H. pylori Inhibition and Anti-oxidative Mechanism. Evid Based Complement Alternat Med 2009; Epub ahead of print
56    Choi SM, Shin JH, Kang KK, Ahn BO, Yoo M. Gastroprotective effects of DA-6034, a new flavonoid derivative, in various gastric mucosal damage models. Dig Dis Sci 2007; 52: 3075-3080
57    Singh S, Khajuria A, Taneja SC, Khajuria RK, Singh J, Johri RK, Qazi GN. The gastric ulcer protective effect of boswellic acids, a leukotriene inhibitor from Boswellia serrata, in rats. Phytomedicine 2008; 15: 408-415
58    Qian Y, Si JM, Wu JG, Chen SJ, Zhu YF, Sun KK, Deng YY, Chen K, Wang LJ, Liu WL. [Effect of mucosal protective on the quality of gastric ulcer healing] Zhejiang Daxue Xuebao Yixueban 2007; 36: 71-77
59    Kivilaakso E. Pathogenetic mechanisms in experimental gastric stress ulceration. Scand J Gastroenterol Suppl 1985; 110: 57-62
60    Nayeb-Hashemi H, Kaunitz JD. Gastroduodenal mucosal defense. Curr Opin Gastroenterol 2009; 25: 537-543
61    Konturek SJ, Konturek PC, Brzozowski T. Prostaglandins and ulcer healing. J Physiol Pharmacol 2005; 56 Suppl 5: 5-31
62    Brzozowski T, Konturek PC, Konturek SJ, Brzozowska I, Pawlik T. Role of prostaglandins in gastroprotection and gastric adaptation. J Physiol Pharmacol 2005; 56 Suppl 5: 33-55
63    Jainu M, Vijai Mohan K, Shyamala Devi CS. Gastroprotective effect of Cissus quadrangularis extract in rats with experimentally induced ulcer. Indian J Med Res 2006; 123: 799-806
64    Baggio CH, Freitas CS, Otofuji Gde M, Cipriani TR, Souza LM, Sassaki GL, Iacomini M, Marques MC, Mesia-Vela S. Flavonoid-rich fraction of Maytenus ilicifolia Mart. ex. Reiss protects the gastric mucosa of rodents through inhibition of both H+,K+ -ATPase activity and formation of nitric oxide. J Ethnopharmacol 2007; 113: 433-440
65    Baek SW, Kim NK, Jin HJ, Koh CW, Kim CK, Kwon OH, Kim JS, Cho MH, Park CK. Anti-ulcer actions of phytosphingosine hydrochloride in different experimental rat ulcer models. Arzneimittelforschung 2005; 55: 461-465
66    Alam S, Asad M, Asdaq SM, Prasad VS. Antiulcer activity of methanolic extract of Momordica charantia L. in rats. J Ethnopharmacol 2009; 123: 464-469
67    Souccar C, Cysneiros RM, Tanae MM, Torres LM, Lima-Landman MT, Lapa AJ. Inhibition of gastric acid secretion by a standardized aqueous extract of Cecropia glaziovii Sneth and underlying mechanism. Phytomedicine 2008; 15: 462-469
68    Zanatta F, Gandolfi RB, Lemos M, Ticona JC, Gimenez A, Clasen BK, Cechinel Filho V, de Andrade SF. Gastroprotective activity of alkaloid extract and 2-phenylquinoline obtained from the bark of Galipea longiflora Krause (Rutaceae). Chem Biol Interact 2009; 180: 312-317
69    Olaleye SB, Owoyele VB, Odukanmi AO. Antiulcer and gastric antisecretory effects of Landolphia owariensis extracts in rats. Niger J Physiol Sci 2008; 23: 23-26
70    Brzozowski T, Konturek SJ, Sliwowski Z, Pytko-Polończyk J, Szlachcic A, Drozdowicz D. Role of capsaicin-sensitive sensory nerves in gastroprotection against acid-independent and acid-dependent ulcerogens. Digestion 1996; 57: 424-432
71    Silva MI, Moura BA, Neto MR, Tomé Ada R, Rocha NF, de Carvalho AM, Macêdo DS, Vasconcelos SM, de Sousa DP, Viana GS, de Sousa FC. Gastroprotective activity of isopulegol on experimentally induced gastric lesions in mice: investigation of possible mechanisms of action. Naunyn Schmiedebergs Arch Pharmacol 2009; 380: 233-245
72    Fan TY, Feng QQ, Jia CR, Fan Q, Li CA, Bai XL. Protective effect of Weikang decoction and partial ingredients on model rat with gastric mucosa ulcer. World J Gastroenterol 2005; 11: 1204-1209
73    de O Leite G, da Penha AR, Fernandes CN, Souza HH, da Costa JG, Campos AR. Gastroprotective mechanism of Vanillosmopsis arborea bark essential oil. Fitoterapia 2009; 80: 77-80
74    Nguelefack TB, Feumebo CB, Ateufack G, Watcho P, Tatsimo S, Atsamo AD, Tane P, Kamanyi A. Anti-ulcerogenic properties of the aqueous and methanol extracts from the leaves of Solanum torvum Swartz (Solanaceae) in rats. J Ethnopharmacol 2008; 119: 135-140
75    Kamath BS, Srikanta BM, Dharmesh SM, Sarada R, Ravishankar GA. Ulcer preventive and antioxidative properties of astaxanthin from Haematococcus pluvialis. Eur J Pharmacol 2008; 590: 387-395
76    Naito Y, Yoshikawa T. Oxidative stress involvement and gene expression in indomethacin-induced gastropathy. Redox Rep 2006; 11: 243-253
77    Bogdarin IuA, Potekhin PP, Kozlov DV, Shirokova NIu. [Efficacy of the new collection of herbs at stressful experimental sharp ulcer defects of the gastroduodenal zone] Eksp Klin Gastroenterol 2005; 74-78, 102
78    de Paula Ferreira M, Nishijima CM, Seito LN, Dokkedal AL, Lopes-Ferreira M, Di Stasi LC, Vilegas W, Hiruma-Lima CA. Gastroprotective effect of Cissus sicyoides (Vitaceae): involvement of microcirculation, endogenous sulfhydryls and nitric oxide. J Ethnopharmacol 2008; 117: 170-174
79    Kanter M, Demir H, Karakaya C, Ozbek H. Gastroprotective activity of Nigella sativa L oil and its constituent, thymoquinone against acute alcohol-induced gastric mucosal injury in rats. World J Gastroenterol 2005; 11: 6662-6666
80    Komoike Y, Nakashima M, Nakagiri A, Takeuchi K. Prostaglandin E receptor EP1 subtype but not prostacyclin IP receptor involved in mucosal blood flow response of mouse stomachs following barrier disruption. Digestion 2003; 67: 186-194
81    Satyanarayana MN. Capsaicin and gastric ulcers. Crit Rev Food Sci Nutr 2006; 46: 275-328
82    Nylander O, Andersson H, Wilander E, Sababi M. Prostaglandins reduce hydrochloric acid-induced increase in duodenal mucosal permeability by a mechanism not related to stimulation of alkaline secretion. Acta Physiol Scand 1995; 153: 365-374
83    Gookin JL, Galanko JA, Blikslager AT, Argenzio RA. PG-mediated closure of paracellular pathway and not restitution is the primary determinant of barrier recovery in acutely injured porcine ileum. Am J Physiol Gastrointest Liver Physiol 2003; 285: G967-G979
84    Hatazawa R, Ohno R, Tanigami M, Tanaka A, Takeuchi K. Roles of endogenous prostaglandins and cyclooxygenase isozymes in healing of indomethacin-induced small intestinal lesions in rats. J Pharmacol Exp Ther 2006; 318: 691-699
85    Konturek PC, Brzozowski T, Konturek SJ, Taut A, Kwiecien S, Pajdo R, Sliwowski Z, Hahn EG. Bacterial lipopolysaccharide protects gastric mucosa against acute injury in rats by activation of genes for cyclooxygenases and endogenous prostaglandins. Digestion 1998; 59: 284-297
86    Mehrabani D, Rezaee A, Azarpira N, Fattahi MR, Amini M, Tanideh N, Panjehshahin MR, Saberi-Firouzi M. The healing effects of Teucrium polium in the repair of indomethacin-induced gastric ulcer in rats. Saudi Med J 2009; 30: 494-499
87    Beales IL. Gastrin and interleukin-1beta stimulate growth factor secretion from cultured rabbit gastric parietal cells. Life Sci 2004; 75: 2983-2995
88    Luo JC, Shin VY, Yang YH, Wu WK, Ye YN, So WH, Chang FY, Cho CH. Tumor necrosis factor-alpha stimulates gastric epithelial cell proliferation. Am J Physiol Gastrointest Liver Physiol 2005; 288: G32-G38
89    Konturek PC, Brzozowski T, Konturek SJ, Ernst H, Drozdowicz D, Pajdo R, Hahn EG. Expression of epidermal growth factor and transforming growth factor alpha during ulcer healing. Time sequence study. Scand J Gastroenterol 1997; 32: 6-15
90    Sasaki E, Tominaga K, Watanabe T, Fujiwara Y, Oshitani N, Matsumoto T, Higuchi K, Tarnawski AS, Arakawa T. COX-2 is essential for EGF induction of cell proliferation in gastric RGM1 cells. Dig Dis Sci 2003; 48: 2257-2262
91    Jones MK, Tomikawa M, Mohajer B, Tarnawski AS. Gastro intestinal mucosal regeneration: role of growth factors. Front Biosci 1999; 4: D303-D309
92    Tétreault MP, Chailler P, Beaulieu JF, Rivard N, Ménard D. Specific signaling cascades involved in cell spreading during healing of micro-wounded gastric epithelial monolayers. J Cell Biochem 2008; 105: 1240-1249
93    Shimura T, Kataoka H, Ogasawara N, Kubota E, Sasaki M, Tanida S, Joh T. Suppression of proHB-EGF carboxy-terminal fragment nuclear translocation: a new molecular target therapy for gastric cancer. Clin Cancer Res 2008; 14: 3956-3965
94    Yoshida K, Kanaoka S, Takai T, Uezato T, Miura N, Kajimura M, Hishida A. EGF rapidly translocates tight junction proteins from the cytoplasm to the cell-cell contact via protein kinase C activation in TMK-1 gastric cancer cells. Exp Cell Res 2005; 309: 397-409
95    Baek MK, Kim MH, Jang HJ, Park JS, Chung IJ, Shin BA, Ahn BW, Jung YD. EGF stimulates uPAR expression and cell invasiveness through ERK, AP-1, and NF-kappaB signaling in human gastric carcinoma cells. Oncol Rep 2008; 20: 1569-1575
96    Berlanga-Acosta J, Gavilondo-Cowley J, López-Saura P, González-López T, Castro-Santana MD, López-Mola E, Guillén-Nieto G, Herrera-Martinez L. Epidermal growth factor in clinical practice - a review of its biological actions, clinical indications and safety implications. Int Wound J 2009; 6: 331-346
97    Ma L, Chow JY, Wong BC, Cho CH. Role of capsaicin sensory nerves and EGF in the healing of gastric ulcer in rats. Life Sci 2000; 66: PL213-PL220
98    Zheng XG, Zhang JJ, Huang YC. [Study on the effect of weitongning on epidermal growth factor and nitric oxide contents in tissue of stomach of rats with gastric ulcer] Zhongguo Zhongxiyi Jiehe Zazhi 2004; 24: 549-551
99    Cao MB, Dong L, Chang XM, Zou BC, Qin B. Effect of Mexican tea herb and pilular adina herb on concrescence of gastric mucosa in experimental gastric ulcer rats. Chin J Integr Med 2007; 13: 132-136
100  Wang B, Zhao HY, Zhou L, Wang YF, Cao J. Effect of Kuiyangping on expressions of EGF and EGFR mRNA in gastric mucosa in rats with experimental gastric ulcer. Beijing Zhongyiyao Daxue Xuebao 2008; 31: Abstract
101  Meng H, Guo J, Sun JY, Pei JM, Wang YM, Zhu MZ, Huang C. Angiogenic effects of the extracts from Chinese herbs: Angelica and Chuanxiong. Am J Chin Med 2008; 36: 541-554
102  Bode AM, Ma WY, Surh YJ, Dong Z. Inhibition of epidermal growth factor-induced cell transformation and activator protein 1 activation by [6]-gingerol. Cancer Res 2001; 61: 850-853
103  Cai XZ, Wang J, Li XD, Wang GL, Liu FN, Cheng MS, Li F. Curcumin suppresses proliferation and invasion in human gastric cancer cells by downregulation of PAK1 activity and cyclin D1 expression. Cancer Biol Ther 2009; 8: 1360-1368
104  Marijon H, Faivre S, Raymond E. [Targeted therapies in hepatocellular carcinomas: recent results and future development] Bull Cancer 2009; 96: 553-561
105  Kelly K, Huang C. Biological agents in non-small cell lung cancer: a review of recent advances and clinical results with a focus on epidermal growth factor receptor and vascular endothelial growth factor. J Thorac Oncol 2008; 3: 664-673
106  Ji C, Cao C, Lu S, Kivlin R, Amaral A, Kouttab N, Yang H, Chu W, Bi Z, Di W, Wan Y. Curcumin attenuates EGF-induced AQP3 up-regulation and cell migration in human ovarian cancer cells. Cancer Chemother Pharmacol 2008; 62: 857-865
107  Tsai PJ, Tsai TH, Yu CH, Ho SC. Evaluation of NO-suppressing activity of several Mediterranean culinary spices. Food Chem Toxicol 2007; 45: 440-447
108  Reyes-Trejo B, Sánchez-Mendoza ME, Becerra-García AA, Cedillo-Portugal E, Castillo-Henkel C, Arrieta J. Bioassay-guided isolation of an anti-ulcer diterpenoid from Croton reflexifolius: role of nitric oxide, prostaglandins and sulfhydryls. J Pharm Pharmacol 2008; 60: 931-936
109  Zayachkivska OS, Konturek SJ, Drozdowicz D, Brzozowski T, Gzhegotsky MR. Influence of plant-originated gastroproteciive and antiulcer substances on gastric mucosal repair. Fiziol Zh 2004; 50: 118-127
110  Chen SH, Liang YC, Chao JC, Tsai LH, Chang CC, Wang CC, Pan S. Protective effects of Ginkgo biloba extract on the ethanol-induced gastric ulcer in rats. World J Gastroenterol 2005; 11: 3746-3750
111  Al Mofleh IA, Alhaider AA, Mossa JS, Al-Soohaibani MO, Rafatullah S. Aqueous suspension of anise “Pimpinella anisum” protects rats against chemically induced gastric ulcers. World J Gastroenterol 2007; 13: 1112-1118
112  Tabak M, Armon R, Neeman I. Cinnamon extracts’ inhibitory effect on Helicobacter pylori. J Ethnopharmacol 1999; 67: 269-277
113  Mahady GB, Pendland SL, Yun G, Lu ZZ. Turmeric (Curcuma longa) and curcumin inhibit the growth of Helicobacter pylori, a group 1 carcinogen. Anticancer Res 2002; 22: 4179-4181
114  Mahady GB, Pendland SL, Stoia A, Hamill FA, Fabricant D, Dietz BM, Chadwick LR. In vitro susceptibility of Helicobacter pylori to botanical extracts used traditionally for the treatment of gastrointestinal disorders. Phytother Res 2005; 19: 988-991
115  Ali SM, Khan AA, Ahmed I, Musaddiq M, Ahmed KS, Polasa H, Rao LV, Habibullah CM, Sechi LA, Ahmed N. Antimicrobial activities of Eugenol and Cinnamaldehyde against the human gastric pathogen Helicobacter pylori. Ann Clin Microbiol Antimicrob 2005; 4: 20
116  O’Mahony R, Al-Khtheeri H, Weerasekera D, Fernando N, Vaira D, Holton J, Basset C. Bactericidal and anti-adhesive properties of culinary and medicinal plants against Helicobacter pylori. World J Gastroenterol 2005; 11: 7499-7507
117  Zaidi SF, Yamada K, Kadowaki M, Usmanghani K, Sugiyama T. Bactericidal activity of medicinal plants, employed for the treatment of gastrointestinal ailments, against Helicobacter pylori. J Ethnopharmacol 2009; 121: 286-291
118  Asiri Y, Al-Dhawailie A, AlQasoumi S, Al-Yahya M, Rafatullah S. Pharmacovigilance in Herbal Medicine: A Paradigm to Drug Toxicity Monitoring In Conventional Health Care. Hung Med J 2008; 2: 351-363
119  Balaji S, Chempakam B. Pharmacokinetics prediction and drugability assessment of diphenylheptanoids from turmeric (Curcuma longa L). Med Chem 2009; 5: 130-138
120  Kandarkar SV, Sawant SS, Ingle AD, Deshpande SS, Maru GB. Subchronic oral hepatotoxicity of turmeric in mice--histopathological and ultrastructural studies. Indian J Exp Biol 1998; 36: 675-679
121  Deshpande SS, Lalitha VS, Ingle AD, Raste AS, Gadre SG, Maru GB. Subchronic oral toxicity of turmeric and ethanolic turmeric extract in female mice and rats. Toxicol Lett 1998; 95: 183-193
122  Shah AH, Qureshi S, Ageel AM. Toxicity studies in mice of ethanol extracts of Foeniculum vulgare fruit and Ruta chalepensis aerial parts. J Ethnopharmacol 1991; 34: 167-172
123  Shah AH, Al-Shareef AH, Ageel AM, Qureshi S. Toxicity studies in mice of common spices, Cinnamomum zeylanicum bark and Piper longum fruits. Plant Foods Hum Nutr 1998; 52: 231-239
124  Daware MB, Mujumdar AM, Ghaskadbi S. Reproductive toxicity of piperine in Swiss albino mice. Planta Med 2000; 66: 231-236
125  Cao J, Jia L, Zhou HM, Liu Y, Zhong LF. Mitochondrial and nuclear DNA damage induced by curcumin in human hepatoma G2 cells. Toxicol Sci 2006; 91: 476-483
126  Mendonça LM, Dos Santos GC, Antonucci GA, Dos Santos AC, Bianchi Mde L, Antunes LM. Evaluation of the cytotoxicity and genotoxicity of curcumin in PC12 cells. Mutat Res 2009; 675: 29-34
127  Bentzen PJ, Lang E, Lang F. Curcumin induced suicidal erythrocyte death. Cell Physiol Biochem 2007; 19: 153-164
128  Khader M, Bresgen N, Eckl PM. In vitro toxicological properties of thymoquinone. Food Chem Toxicol 2009; 47: 129-133
129  Qadri SM, Mahmud H, Föller M, Lang F. Thymoquinone-induced suicidal erythrocyte death. Food Chem Toxicol 2009; 47: 1545-1549