Ameer Omar Z. ^{1,2 *}, Salman Ibrahim M. ^1,2, Quek Ko Jin ¹, Asmawi Mohd. Z. ²

Loranthus ferrugineus (L. ferrugineus) from Loranthaceae, a mistletoe, is a medicinal herb used for a variety of human ailments. Traditionally, decoctions of this parasitic shrub have been mainly used to treat high blood pressure (BP) and gastrointestinal complaints; usage which is supported by experimental based pharmacological investigations. Nonetheless, there is still limited data available evaluating this plant’s traditions, and few studies have been scientifically translated toward evidence based phytomedicine. We therefore provide a concise review of the currently available L. ferrugineus literature and discuss potential directions for future areas of investigation.

We surveyed available literature covering ethnopharmacological usage of L. ferrugineus and discussed relevant findings, including important future directions and shortcomings for the medicinal values of this parasitic shrub.

Evidence based pharmacological approaches significantly covered the medicinal application of L. ferrugineus for hypertension and gastrointestinal complaint management, with a particular focus on the active hydrophilic extract of this herb.

Understanding the sites of action of this plant and its beneficial effects will provide justification for its use in old traditional treatments, and potentially lead to the development of therapies. Other medicinal applicative areas of this parasitic shrub, such as wound healing, gerontological effects, and antiviral and anticancer activities, are yet to be researched.

dedalu-api, ethnopharmacology, herbal medicine, Loranthaceae, Loranthus ferrugineus, mistletoe, parasitic shrub

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Medicinal herbs constitute the cornerstone of traditional medicinal practice worldwide. These herbs are relatively cheap and available, and their use depends on ancestral experience [1-3]. Medicinal plants represent a great deal of untapped reservoirs of drugs, and the structural diversity of their components make a valuable source of novel compounds [3, 4]. Thus, there is a growing interest in the utilization of phytoceuticals and natural product scientists are intensifying efforts towards evaluation of these valuable medicinal plants.

One of the various families of herbs that has long been used worldwide in traditional medicine is Loranthaceae [5, 6], which is formed by three distinct families: Loranthaceae (sensu strictu), Viscaceae, and Eremolepidaceae [7, 8]. The members of Loranthaceae are about 75 genera, and most of them are globally known as mistletoes [9, 10].

Historically, the mistletoe, whose name is believed to be derived from the Celtic word for “all-heal”, was used for a variety of treatments. Among the recognized therapeutic properties of Loranthaceae members include antitumor actions [11, 12], cough treatment [13], headache treatment [14], uterus tightening following childbirth [14], and immunomodulatory [15, 16], antioxidant [16-19], antiinflammatory [20, 21], antimicrobial [22-24], antiviral [25], antidiarrhoeal [16, 26], anticancer [23, 27], antinociceptive [21], antipyretic [21], antihyperglycemic, and antidiabetic [16, 18, 28, 29] activities and antihypertensive effects [30-32]. However, despite its wide applicability, mistletoe is mainly used for its blood pressure (BP) lowering and gastrointestinal treatment properties.

Chemical and pharmacological studies of some species of the Loranthaceae family have identified different kinds of constituents, such as flavonoids [15, 16, 21, 28-30, 33-35], alkaloids, lectins, and polypeptides [11, 12, 16, 36, 37], arginine [38], histamine [39], polysaccharides [40, 41], tannins [16, 28, 29], terpenoids and/or steroids [28, 29], acidic compounds [16, 27], glycosides [16, 28], gallic acid [16], and recently discovered, a new flavocoumarin named Loranthin [42].

Loranthus ferrugineus (L. ferrugineus) Roxb., with the synonym Scurrula ferruginea Danser, is a member of the Loranthaceae family. This herb has a unique way of living, being a hemi parasitic shrub that never grows on land but can partially survive on photosynthesis, and is more dependent on the nutrients and water that can access its roots [9]. These roots have modified structure that attaches the herb onto a host plant which is usually a dicotyledonous tree.

The members of the Loranthaceae are widely distributed in many countries like Malaysia, Sumatra, India, Singapore, Australia and New Zealand [9]. Particularly in Malaysia, L. ferrugineus is locally known as “dedalu”, “dalu-dalu”, or “dedalu-api’’ where “api” means “fire” in the Malay language, and probably reflects the rusty appearance of the herb leaves.

L. ferrugineus has been proven to possess antiviral and cytotoxic activities [25]. Other reports have demonstrated that an aqueous extract obtained from L. ferrugineus possesses remarkable capabilities to lower BP in vivo [43]. Moreover, phytochemical investigation of L. ferrugineus has indicated the presence of components like flavonoids and a high concentration of condensed tannins [25]. Three natural flavonol compounds have been isolated from the ethyl acetate fraction of L. ferrugineus: in addition to quercetin and quercitrin, an unusual flavonol glycoside 4”-O-acetylquercitrin was also isolated [44].

In addition to its reputable use for treatment of hypertension and gastrointestinal complaints [43], a decoction of L. ferrugineus is also used as a home remedy for general health maintenance and its gerontological effects, which include the enhancement of memory and well-being in the elderly people. Leaves, fruits and flowers are the most common parts of L. ferrugineus used to treat high BP, while the unique roots attaching the herb to the host plant are employed for other therapeutic uses, such as ulcer and cancer treatment [43]. Other deep rooted uses for the leaves of this plant are snakebites, wounds, fever, malarial infection or women pouch for after childbirth [45, 46].

L. ferrugineus potential antioxidant and anticancer effects represent a relatively unexplored facet of this herb’s knowledge database. Much research has focused on mistletoe’s efficacy as an anticancer treatment [47-50], and thus spurred a variety of pharmaceutical medicines, such as Isorel^®, Eurixor^®, Helixor^®, and Lektinol^® [51]. However, though there seems to be strong evidence suggesting certain constituents, especially the lectins, exhibit anticancer effects, the value of the whole plant in cancer treatment is not fully accepted due to significant discrepancies in research findings [49, 50, 52]. Nonetheless, because L. ferrugineus has been shown to contain some chemical constituents which are believed to have anticancer effects [25, 43, 44], there is a possibility that L. ferrugineus itself, in addition to its supposed antiviral and cytotoxic activities [25], may have anticancer effects too.

Despite L. ferrugineus wide range of medicinal applicability, to date there is little data and limited literature review available. Thus, there is a need to review information that can describe this plant and evaluate its traditions, and survey how it has been scientifically and experimentally translated toward evidence based phytomedicine. Therefore, this poses a necessity to review and analyze all the relevant scientific publications of L. ferrugineus that can add up to our knowledge and understanding of this least explored herb. Furthermore, we aimed to describe the points that remain to be addressed, and thus from this we propose critical future research directions of this herb that could enhance awareness toward evidence based ethnopharmacology.

The taxonomical classification of L. ferrugineus was first described by Bengal [53] as in Table 1.

The herb’s (Fig. 1) physical and structural appearance can vary slightly, based on the plant’s tropical natural habitat and age. However, the general description and characterization is more or less the same [2].

Slenders of the bush, young parts, are described to be inflorescences [54]. Branches and twigs of the herb are long, pendulous, and densely clothed with L. ferrugineus down when young, in addition to the underside of the leaves, pedicels, calyxes, and corollas. The rusty colored leaves are opposite in direction, positioned on short petioles, elliptic, obtuse, coriaceous, and glabrous above [55]. These leaves are elliotic, with 4 – 8 cm long inder surfaces densely covered with reddish scurf [54]. Usually, peduncles present as 1 – 4 together in the axils of the leaves. The flowers of L. ferrugineus are: tetrandrous, 2 – 6 most commonly, in axillary cymes; have perianth 1.5 – 2 cm long; are drupe clubshaped; and densely rusty [54]. The flowers are bracteas small, adpressed to the ovaria, and one to each [55], with a tubular and deeply 4 parted flower corolla. For herbs that are native of the East Indies, Pulau-Penang, Singapore and Sumatra, the flowers corolla are densely clothed with rusty hairs, 7 lines long [54]. L. ferrugineus berries are yellowish and ovate in shape, and are an orchard pest that is often parasitic on Melastoma and many other trees [54].

Most traditional productions of L. ferrugineus extract involve a simple water decoction or herbal tea preparation in households, intended for human consumption to treat and alleviate various symptoms. However, this preparation method is not necessarily always implicated for scientific research investigations, because chemically characterizing and isolating constituents from water extracts is laborious. Therefore, as in with all natural product chemists, it is necessary to break down herbal material into many different polarity components to ease their identification, enhance yield or mass product, and to occasionally ensure compound stability [56].

Based on previous published observations, we summarized a general scheme illustrating how L. ferrugineus extractives are usually produced (Fig. 2). We believe that this method can help separate different elements within a plant based on their polarity, potentially purify and optimize yield of active molecules, and most importantly be applied to various bioactive plant constituents.

As per the tradition of the most commonly used portions of the herb, fresh aerial parts of L. ferrugineus, including leaves, young stems, twigs, flowers and berries are usually used. It is important that the plant is collected from the same single host plant to reduce variation between different batches of collection, since chemical composition of the parasitic shrub can be affected by the host plant [57]. Only healthy parts of the plant must be taken, while the diseased portions are discarded. This is because, when contaminated by severe microbial infection, diseased portions may affect healthy portions, and thus eventually alter metabolism of the plant: an effect which may contribute to the formation of large amounts of unexpected products [56, 58]. The plant material is then cleaned of adulterants, chopped into small pieces, dried in an oven at 42℃ for 5 days, ground into a fine powder using a milling machine, and the resultant powder successively treated as per Fig. 2.

As mentioned earlier, various classes of organic compounds described elsewhere have been shown to be present in this herb. These phytochemicals include phenolics, flavonoids, terpenoids, saponins and condensed tannins. The chemical profiling and assays performed thus far on L. ferrugineus and its extractives are summarized in Table 2. On the other hand, constituents such as amino acids, peptides, secondary amines, alkaloids, anthraquinones, sterols and coumarins have been reported to be absent at least in part in L. ferrugineus methanol extract (LFME) [2, 59].

Preliminary thin layer chromatography analysis of LFME and its n-butanol fraction of LFME (NBF-LFME) showed the presence of terpenoids and flavonoids [2], while ultraviolet visible and fourier transform infrared peak spectroscopy analyses of these two extractives were mostly in favoring terpenoids as the major constituents [60].

Few research groups have taken the opportunity to characterize the components of L. ferrugineus; hence there is limited chemical investigation that would possibly identify or isolate the active components in this plant, and thus elucidation of the mechanism by which its bioactive components may exert its cardiovascular effects is largely unexplored. In addition, there have been no investigations of potential chemical composition changes across seasons. Continuing research in this area would considerably enhance our understanding of the natural diversity of this herb, and would definitely open the door for a new era of nutraceuticals. Perhaps future studies may employ DNA barcoding, which allows the identification of species in samples with short reliable DNA regions, or highly degraded DNA. DNA barcoding has been used in many studies to test regions in plant groups, and provides species identification by using standardized DNA regions as tags [61]. In addition, there have been previous studies that have used this method to help identify possible usable DNA sequences in plants for the application of DNA barcoding [51].

Cardiovascular disease is a major public health problem contributing to 17.3 million deaths worldwide, and with over 80% of cardiovascular deaths taking place in the low and middle income countries [62, 63]. By 2030, it has been estimated that 23 million people will die annually from cardiovascular complications [63, 64]. Hypertension is a powerful risk factor for cardiovascular disease and is perhaps one of the most prevalent underlying etiologies of cardiovascular risks [63]. A number of synthetic antihypertensive medications are available in clinical practice; however, these agents do not always provide optimal control of BP, and in many cases are highly associated with adverse effects. This therefore poses a need for alternative therapies that provide better BP control with minimal side effects. Herbal treatments have been successfully utilized to treat patients with congestive heart failure, systolic hypertension, angina pectoris, atherosclerosis, cerebral insufficiency, and arrhythmia [65, 66]. Specific to hypertension, previous and current evidence suggests that L. ferrugineus possesses promising BP lowering activity.

Earlier preliminary investigations conducted by Othman [43] revealed that L. ferrugineus has a remarkable BP lowering activity. Here, it was reported that the water extract of L. ferrugineus, along with other water based herbal extracts, produce BP lowering effects in the anesthetized rat when given as intravenous (i.v.) boluses. Though Othman’s investigation only involved the use of water based extract, subsequent work involved a series of both in vitro and in vivo ethnopharmacological investigations to explain how L. ferrugineus exerts its effects in hypertension management. It is noteworthy mentioning that characterization of L. ferrugineus potential cardiovascular effects can pave the way to a more useful understanding of natural herb remedies. For example, evidence based research has enabled us to obtain fair knowledge of the antihypertensive therapeutic properties of Viscum album [67, 68], a mistletoe herb from Santalaceae which is of close proximity to L. ferrugineus.

Early experiments conducted by our laboratory group [69] involved utilization of essential extracts of the herb, as shown in Fig. 2. These experiments were conducted by incubation of isolated Sprague-Dawley (SD) rat aortic ring preparations with increasing concentrations of 0.05% – 0.20% (w/v) of petroleum ether extract (LFPEE), chloroform extract (LFCE), ethyl acetate extract (LFEAE), methanol extract (LFME) and water extract (LFWE) in an organ bath chamber, then separately challenging these extracts by cumulative additions of the α-adrenergic agonist norepinephrine. The results showed that LFME possesses a remarkable effect in concentration dependently inhibiting norepinephrine induced vasoconstriction. In addition, further examination showed that LFME can modulate norepinephrine induced aortic ring contraction through a reversible noncompetitive antagonism mechanism [70], suggesting that chemical constituents within LFME modulate vasomotor tone via a non α-receptor mediated action and may likely possess BP lowering properties. To this end, a different set of investigations involved the use of i.v. bolus administration of increasing doses of 25 – 200 mg/kg of L. ferrugineus extracts in in vivo whole animal experimentations. In accordance with in vitro findings, LFME was found to produce the most significant dose dependent yet brief reduction in BP. It was also noted that LFWE had some hypotensive actions; however, these effects were weaker relative to LFME. Although this finding contradicted Othman’s [43] earlier results, where LFWE was purported to be the most potent extract, this discrepancy between findings may be explained by the fact that the earlier study involved only water based extraction of L. ferrugineus, while subsequent investigations, as illustrated in Fig. 2, used increasing polarity solvents for extraction: hence, the active components may be maximally presented in LFME rather than LFWE. Collectively, these findings suggest that relative to the other L. ferrugineus extracts, LFME possesses the most significant vasorelaxant and hypotensive activities in rat models. Additionally, LFME’s promising active constituent(s) is/are of a relatively high polarity, and therefore can justify the herb’s use in the management of hypertension in a form of water based decoction. Thus, perhaps modification of L. ferrugineus chemical structure may yield compounds that present with more sustained antihypertensive effects.

It is well established that BP is a function of cardiac output and total peripheral resistance; two variables that are regulated by two major branches of the autonomic nervous system (sympathetic and parasympathetic) [71]. The autonomic pathways that control the heart and vasculature are primarily sympathetic, targeting both α- and β-adrenoceptors located within these target organs, and hence altering cardiac output and systemic vascular resistance. Parasympathetic autonomic pathways, on the other hand, play an important cardiac effect, modulating both myocardial contractility and heart rate via M2 muscarinic receptors stimulation [72, 73]. Blood vessels mostly lack parasympathetic innervation, yet M3 muscarinic cholinergic receptor subtype is still expressed within the vasculature and responds to circulating acetylcholine (ACh) and other cholinomimetics [73, 74]. Subsequent studies on L. ferrugineus have therefore focused on investigating the role of active constituents contained within its methanol extract in modulating these key BP regulatory pathways in vivo. Thus, the hypotensive mechanisms of L. ferrugineus were characterized by monitoring the extract’s effect on mean arterial pressure, following i.v. bolus injections of several antagonists of the adrenergic and cholinergic pathways, using anesthetized normotensive SD rat preparations [59]. Possible effects on α- and β-adrenergic cardiovascular receptors were investigated using respective agonists and antagonists of these receptors. Here, the ability of prazosin, an α1-adrenergic blocker, and propranolol, a non selective β-adrenoceptor blocker, to alter L. ferrugineus hypotensive effects was investigated with reference to both norepinephrine and isoprenaline, a β-adrenoceptor agonist, as positive controls [69]. Interestingly, the BP lowering activity of the extract was unaffected by either antagonist, suggesting that L. ferrugineus, unlike extracts obtained from Pseuderanthemum palatiferum [75], Artocarpus altilis [76], Solanum torvum [77] and Platycapnos spicata [78], does not exert its hypotensive action via antagonism of cardiovascular α- or β-adrenergic receptors. Indeed, the lack of differences in the hypotensive response to L. ferrugineus following prazosin administration confirmed our previous assertions of a reversible noncompetitive antagonism of norepinephrine mediated vasoconstriction in isolated rat aorta, driven by a non α-adrenoceptor mediated action [2].

The possible action of L. ferrugineus on the cholinergic pathways was subsequently studied, with a particular focus on LFME’s effects on cardiovascular muscarinic receptors and ACh esterase (AChE), an enzyme which metabolizes ACh. In these experiments, L. ferrugineus mean arterial pressur effects were recorded before and after systemic blockade of muscarinic receptors with atropine or AChE inhibition with neostigmine. Data driven from these experiments showed that L. ferrugineus retained a behavior almost similar to the positive control ACh, as L. ferrugineus hypotensive activity was significantly abolished in the presence of atropine. Together, this indicates that L. ferrugineus extract, like extracts derived from Tulbaghia violacea [79], Bidens pilosa [80], Moringa oleifera [80], Cinnamomum zeylanicum [81] and Chenopodium ambrosioides [82], possibly possesses some cholinergic properties, and that its BP lowering effect was most likely driven by stimulation of cardiac and/or vascular muscarinic receptors.

Further exploring the role of the cholinergic pathway, we were able to show that pretreatment with i.v. neostigmine tended to augment the BP lowering effect of L. ferrugineus and the duration of its action: yet, the effect was not as notably significant when compared to the enhancement of ACh action on BP and the action duration. This data suggested that AChE may not be the primary enzyme responsible for termination of the LFME effect in plasma and that other esterases, including butyrylcholinesterase or pseudocholinesterase, which is found in great abundance in plasma as compared to AChE, is likely to hydrolyze esters of plant sources [83]. Importantly, as neostigmine did not block L. ferrugineus action on BP, our study concluded that LFME does not produce its cholinomimetic action through the antagonism of AChE, but rather through direct muscarinic receptor stimulation [2].

The cholinergic pathway exerts a powerful antagonistic influence on the heart by modulating cardiac rate (chronotropy), conduction velocity (dromotropy), contraction (inotropy), and relaxation (lusitropy) [73]. For instance, the cholinergic hypotensive properties of Echinodorus grandiflorus ethanolic extract are associated with powerful reductions in cardiac output and heart rate in spontaneously hypertensive rats [84]. Likewise, Raphanus sativus (radish) seed crude extract produces muscarinic receptor dependent inhibition of cardiac force and rate of contractions in isolated guinea pig atria [85]; however, whether L. ferrugineus exhibits similar direct cardiac effects remains unexplored. Future investigations should therefore consider exploring cardiac activities of L. ferrugineus, investigating not only chronotropic, inotropic and dromotropic responsiveness of the heart but also changes in ventricular pressure, end diastolic volume and coronary blood flow. These experiments will potentially further our understanding of L. ferrugineus cardiovascular properties and provide comprehensive characterization of its therapeutic benefits.

The activity of L. ferrugineus on the autonomic ganglia, which controls cholinergic and preferentially adrenergic cardiovascular targets, were previously studied by monitoring the ability of hexamethonium, a ganglionic blocker, to modulate the hypotensive response evoked by L. ferrugineus extract. It was found that ganglionic blockade did not markedly alter the BP lowering effects of the extract, suggesting L. ferrugineus, unlike dietary soy [86] and Gossypium barbadense [87], does not promote hypotension via ganglionic blockade mechanisms.

Nitric oxide (NO) is probably one of the most important molecules produced by the endothelium and is synthesized by the enzyme NO synthase (NOS) from the precursor amino acid L-arginine (L-Arg) [88]. A range of chemical mediators including not only ACh but also bradykinin, serotonin, substance P and adenosine diphosphate trigger NO release from the endothelium by receptor mediated mechanisms [89]. Endothelial derived NO has the capacity to maintain vascular tone and to produce vasodilatation through the activation of guanylate cyclase [70]. Given the relative similarity between L. ferrugineus and ACh pharmacological properties, and the fact that ACh mediated activation of vascular muscarinic receptors triggers a cascade of events that ultimately generate NO, we predicted that inhibition of NOS, as with ACh, would perhaps attenuate the BP lowering effects of L. ferrugineus. Indeed, Nω-Nitro-L-arginine methyl ester hydrochloride (L-NAME), a NOS inhibitor, was shown to attenuate hypotensive responses to L. ferrugineus in vivo, suggesting that BP lowering activity is not only evoked by activation of cardiovascular cholinergic receptors, but also through promoting NO release.

It is common practice to subject crude plant extracts to activity guided fractionation to eliminate various types of complex or antagonistic molecules and derive a more purified and more potent form of the extract. Subsequent studies on L. ferrugineus have therefore aimed to obtain purer derivatives of the active LFME extract for further in vivo and in vitro testing. In one study [2], four chemical fractions including chloroform fraction (CF-LFME), ethyl acetate fraction (EAF-LFME), n-butanol fraction (NBF-LFME) and water fraction (WF-LFME) were derived as shown in Fig. 2 [60]. In vivo data from our laboratory showed that NBF-LFME significantly lowers BP in a dose dependent manner, and has a relatively longer duration of action compared to other fractions. Interestingly, it has been further observed that NBF-LFME has more BP lowering potency relative to its mother crude extract LFME, which indicates that fractionation is able to increase the number of bioactive molecules in the extract [60]. In keeping with our in vivo data, in vitro findings showed that, relative to other fractions, NBF-LFME produces a significant concentration dependent inhibition of aortic ring contraction against the α-agonist phenylephrine and depolarizing signals of potassium chloride [60]. These in vivo and in vitro results compare very closely to research findings on other plants used in hypertensive treatment, in which bioactivity guided fractionation contributes to a more potent pharmacological action. For example, Kane and colleagues [90] investigated an ethanolic extract and fractions of Euphorbia thymifolia for diuretic activity, and found that the dose dependent diuretic effect of this herb was more potent in the fractionated extract. In addition, Ouedraog et al [91] performed a bioassay guided fractionation of ethanolic extract of Agelanthus dodoneifolius, a plant traditionally used as treatment for hypertension, using rat aorta pre-contracted by norepinephrine to monitor the relaxant activity. They found that the vasorelaxant properties of Agelanthus dodoneifolius crude extract were markedly potentiated following column chromatographic separation of its active fractions.

As we found previously, LFME exhibits reversible noncompetitive antagonism of norepinephrine induced aortic ring contraction [59, 70], and NBF-LFME fraction exhibits the greatest BP lowering effect in vivo relative to other LFME fractions [60]. Therefore, we further investigated the effect of the purified NBF-LFME fraction with the aim of finding a more molecular mechanistic explanation to its pharmacological action [92]. The active L. ferrugineus fraction was challenged against vascular endothelium dependent and independent mechanisms, using blockade with various pharmacological interventions including L-NAME, NO-cGMP pathway inhibitor methylene blue, cyclooxygenase inhibitor indomethacin, ATP dependent potassium channel blocker glibenclamide, β-blocker propanolol and α-receptor blocker prazosin. Those experiments revealed that NBF-LFME induced vascular relaxation is primarily driven by endothelium dependent mechanisms, stimulating muscarinic receptors, activating the endothelium derived NO-cGMP-relaxant pathway, promoting prostacyclin release and lengthening the released NO half life through its antioxidant effects [92]. This data therefore provide solid evidence that L. ferrugineus remarkable antihypertensive potentials extend beyond its muscarinic receptor activation, and further involve enhancement of key modulators of vascular function including NO and prostacyclin, and possible vascular protection through its antioxidant and free radical scavenging properties. The effectiveness of L. ferrugineus through its enhancement of NO or its antioxidant properties is of marked importance, as an imbalance between NO and reactive oxygen species production appears to be a common feature of experimental and human hypertension [93]. It is therefore possible that promoting NO release and antioxidant action of L. ferrugineus biologically active principles can potentially influence a range of vascular targets to offer diverse protective cardiovascular properties. For instance, ginsenosides and saponins from Panax ginseng have been shown to protect against myocardial ischaemia/ reperfusion damage and decrease lipid peroxidation, and that those effects are mediated by release of NO from endothelial cells, especially from perivascular nitric oxidergic nerves [94]. Crataegus pinnatifida, a plant which has been used as a decoction for antihypertensive treatment for thousands of years in China, is believed to exert its effects through vasorelaxation resulting from NO stimulation and antioxidant activity [95]. Similarly, other plants such as Theobroma cacao, due to their enriched flavonoid constituents and resulting stimulation of NO formation [96], has been shown to improve endothelial function through mechanisms that enhance NO synthesis or those that decrease NO breakdown [97]. Accordingly, further investigation of L. ferrugineus cardiovascular effects and/or targets is warranted in order to fully understand its cardiovascular protective action.

Herbal medicines could benefit patients suffering from gastrointestinal disorders that cannot be treated using conventional drug therapy, including functional dyspepsia, constipation, and postoperative ileus. As reviewed by Langmead and Rampton, although most indications for the use of such remedies are traditionally derived, controlled research trials suggest some health benefits for ginger in nausea and vomiting, liquorice extracts in peptic ulceration, Chinese herbal medicine in irritable bowel syndrome, opium derivatives in diarrhoea and senna, ispaghula and sterculia in constipation [98].

Following traditional uses of L. ferrugineus for gastrointestinal complaints [43], we aimed to investigate the effect of LFME and NB-LFME on the isolated guinea pig ileal preparation in vitro [69, 99], to test for gut contractility actions. Indeed, this work showed that crude LFME and its NB-LFME retain the ability to dose dependently increase intestinal smooth muscle contractility. Importantly, these effects were significantly reduced upon pre-incubation with atropine, enhanced in the presence of neostigmine, and unchanged in the presence of hexamethonium, suggesting a direct cholinomimetic action via muscarinic receptor activation, and that bioactive constituents within L. ferrugineus serve as a substrate for intestinal AChE. Having previously described a cholinomimetic hypotensive action for L. ferrugineus, our findings in the guinea pig ilium were not counterintuitive. Nonetheless, this data has undoubtedly highlighted a new target organ for L. ferrugineus health benefits, confirmed the ability of the extract’s active constituents to induce a notable peristalsis, and most importantly provided an immense support for its folklore use. Accordingly, L. ferrugineus extracts, like other crude extracts obtained from Carissa carandas [100] and Fumaria parviflora which possess a cholinergic stimulatory action [101], can potentially be formulated to treat constipation disorders.

Muscarinic receptors are expressed abundantly throughout gastrointestinal tract. Muscarinic agonists elicit contraction through the M3 receptor present in smooth muscle ranging from the esophagus to ileum [102]. In the ileum, muscarinic agonists are known to have a dual effect on contraction: a direct M3 mediated contraction and an indirect M2 mediated inhibition of relaxation [102, 103]. Activation of gastric acid secretion by endogenous ACh, on the other hand, is triggered by M3 receptor subtype expressed on gastric parietal cells [104]. Despite a cholinomimetic action for L. ferrugineus, it remains undetermined if active constituents within its crude or purified extract would show a muscarinic receptor subtype specificity to elicit their contractile effect, or an ability to modulate acid, mucous or other gastrointestinal secretions.

Alzheimer’s disease is a common neurodegenerative condition that affects the elderly population, primarily resulting in memory loss. The memory dysfunction in Alzheimer’s disease has been associated with cortical cholinergic deficiency and loss of cholinergic neurons within the brain [105]. Furthermore, chronic neuroinflammation and oxidative stress contribute to the neurodegeneration associated with Alzheimer’s disease and represent targets for therapy [106]. L. ferrugineus antioxidant properties and effects on cholinergic pathways are of particular interest, because cholinergic abnormalities may affect memory or play a role in Alzheimer’s disease [107]: perhaps L. ferrugineus action on cholinergic pathways may explain its memory enhancement and gerontological effects that have been observed in elderly people. Though a variety of medicinal plants and their derivatives have been shown to have cholinomimetic activity in conjunction with improvement of memory and learning functions [108, 109], research linking mistletoe and Alzheimer’s disease is limited [110, 111]. Hence, we propose this possible relationship between memory effects and L. ferrugineus cholinergic action tentatively, and emphasize that accurate scientific approach is required to test this hypothesis.

Natural products will continue to be important in three areas of drug discovery: as targets for production by biotechnology; as sources of new lead compounds of novel chemical structure; and as the active ingredients of useful treatments derived from traditional systems of medicine [112].

Though L. ferrugineus possesses a wide range of medicinal applicability, to date there is limited data available that evaluates this plants traditions, and few studies have been scientifically and experimentally translated toward evidence based phytomedicine. Despite the research reviewed, various aspects of L. ferrugineus remain to be addressed: for example, identification of chemical constituents and therapeutic mechanisms. Further studies on the isolation and structural elucidation of the pharmacologically active components of L. ferrugineus are likely to yield interesting results. Perhaps synthetic or chemical modification of functional groups attached to these constituents could be the base for a more desired pharmacologically active component. For example, the production of a compound that has longer NO enhancing properties that would benefit vascular health and serve as a better tool for hypertension control. In addition, to further characterize the BP lowering potential of L. ferrugineus, future investigations may focus on the effects of its extracts both in vivo and in vitro in hypertensive animal models, such as the spontaneously hypertensive rat. The effect of chronic treatment with L. ferrugineus extracts in animal models may also give rise to valuable research outcomes of the herb’s effects in high BP treatment.

Finally, yet another research aspect of L. ferrugineus which remains to be addressed is its toxicology. Presently, no current toxicology studies have been performed to investigate its effect on living organisms, despite that toxicology in particular is an important aspect of herbal medicine, since all substances become toxic under certain conditions, whether it be through contaminated growth environments, contamination incurred during collection of the plant materials, or even unfavorable storage conditions [113].

The findings from L. ferrugineus mistletoe are likely to have important implications for understanding the beneficial actions of L. ferrugineus and for developing therapies for clinical problems involving the sites of action of this plant. More in depth research into L. ferrugineus will provide further justification for the employment of this herb in old traditional treatments, as well as provide greater insight into the underlying mechanisms responsible for its therapeutic effectiveness, and thus enhance awareness toward evidence based phytotherapy.

The authors declare that there are no conflict of interest.

1. The ABC clinical guide to herbs [internet]. USA: American Botanical Council; 2002. Available from: http://cms.herbalgram.org/ABCGuide/ProprietaryProducts/ProprietaryProductReferences.html.
2. Ameer OZ. Characterization of Loranthus ferrugineus cardiovascular activites. an ethnopharmacological and phytochemical investigation. Germany: LAP LAMBERT Academic Publishing; 2011. 288 p.
3. Amos S, Akah PA, Binda L, Enwerem NM, Ogundaini A, Wambebe C, et al. Hypotensive activity of the ethanol extract of pavetta crassipes leaves. Biol Pharm Bull. 2003;26(12):1674-80.
4. Harvey AL. Medicines from nature: are natural products still relevant to drug discovery?. Trends Pharm Sci. 1999;20(5):196-8.
5. Ratera EL, Ratera MO. [Plantas de la flora argentina empleadas en medicina popular]. Spain: Hemisferio Sur Editorial; 1997. p. 1-189. Spanish.
6. Tian WX, Li LC, Wu XD, Chen CC. Weight reduction by Chinese medicinal herbs may be related to inhibition of fatty acid synthase. Life Sci. 2004;74(19):2389-99.
7. Barlow BA. Classification of the Loranthaceae and viscaceae. Proc Linn Soc New South Wales. 1965;89:268-72.
8. Kuijt J. Monograph of the Eremolepidaceae. Systematic Botany Monographs. USA: Amer Society of Plant Taxonomists; 1988. p. 1-60.
9. Barlow B. Provisional key to the genera of Loranthaceae and viscaceae of the flora malesiana region. Flora Malesiana Bull. 1991;10:335-8.
10. Calvin CL, Wilson CA. Comparative morphology of epicortical roots in old and new world Loranthaceae with reference to root types, origin, patterns of longitudinal extension and potential for clonal growth. Flora-Morphology, Distribution, Functional Ecology of Plants. 2006;201(1):51-64.
11. Park JH, Hyun CK, Shin HK. Cytotoxicity of heat-treated Korean mistletoe. Cancer Lett. 1998;126(1):43-8.
12. Park JH, Hyun CK, Shin HK. Cytotoxic effects of the components in heat-treated mistletoe (Viscum album). Cancer Lett. 1999;139(2):207-13.
13. Wiart C. Medicinal plants of asia and the pacific. USA: CRC Press; 2006. p. 295.
14. Kwanda N, Noikotr K, Sudmoon R, Tanee T, Chaveerach A. Medicinal parasitic plants on diverse hosts with their usages and barcodes. J Nat Med. 2013;67(3):438- 45.
15. Fernández T, Wagner ML, Varela BG, Ricco RA, Hajos SE, Gurni AA, et al. Study of an argentine mistletoe, the hemiparasite ligaria cuneifolia (R. et P.) tiegh. (Loranthaceae). J Ethnopharmacol. 1998;62(1):25-34.
16. Moghadamtousi SZ, Hajrezaei M, Abdul Kadir H, Zandi K. Loranthus micranthus linn.: biological activities and phytochemistry. Evid Based Complement Alternat Med. 2013(2013):9.
17. Katsarou A, Rhizopoulou S, Kefalas P. Antioxidant potential of the aerial tissues of the mistletoe loranthus europaeus jacq. Records Nat Products. 2012;6(4):394-7.
18. Onunogbo C, Ohaeri OC, Eleazu CO, Eleazu KC. Chemical composition of mistletoe extract (loranthus micranthus) and its effect on the protein, lipid metabolism and the antioxidant status of alloxan induced diabetic rats. J Med Res. 2012;1(4):57-62.
19. Wong DZH, Kadir HA, Lee CL, Goh BH. Neuroprotective properties of loranthus parasiticus aqueous fraction against oxidative stress-induced damage in NG108-15 cells. J Nat Med. 2012;66(3):544-51.
20. Hostanska K, Hajto T, Spagnoli G, Fischer J, Lentzen H, Herrmann R. A plant lectin derived from Viscum album induces cytokine gene expression and protein production in cultures of human peripheral blood mononuclear cells. Nat Immun. 1995;14(5-6):295-304.
21. Mothana RA, Al-Said MS, Al-Rehaily AJ, Thabet TM, Awad NA, Lalk M, et al. Anti-inflammatory, antinociceptive, antipyretic and antioxidant activities and phenolic constituents from Loranthus regularis steud. ex sprague. Food Chem. 2012;130(2):344-9.
22. Amabeoku GJ, Leng MJ, Syce JA. Antimicrobial and anticonvulsant activities of viscum capense. J Ethnopharmacol. 1998;61(3):237-41.
23. Deeni Y, Sadiq N. Antimicrobial properties and phytochemical constituents of the leaves of african mistletoe (tapinanthus dodoneifolius (DC) danser) (Loranthaceae): an ethnomedicinal plant of hausaland, northern nigeria. J Ethnopharmacol. 2002;83(3):235-40.
24. Cemaluk EAC, Nwankwo NE. Phytochemical properties of some solvent fractions of petroleum ether extract of the african mistletoe (Loranthus micranthus linn) leaves and their antimicrobial activity. AFR J Biotechnol. 2012;11(62):12595-9.
25. Lohézic-Le Dévéhat F, Bakhtiar A, Bézivin C, Amoros M, Boustie J. Antiviral and cytotoxic activities of some indonesian plants. Fitoterapia. 2002;73(5):400-5.
26. Osadebe PO, Abba CC, Agbo MO. Antimotility effects of extracts and fractions of eastern Nigeria mistletoe (Loranthus micranthus linn). Asian Pac J Trop Med. 2012;5(7):556-60.
27. Ohashi K, Winarno H, Mukai M, Shibuya H. Preparation and cancer cell invasion inhibitory effects of C16-alkynic fatty acids. Chem Pharm Bull. 2003;51(4):463-6.
28. Tarfa FD, Amos S, Temple VJ, Ochekpe NA, Gamaniel KS. Hypoglycemic effects of the aqueous extract of African mistletoe, tapinanthus sesselifolius (P. beauv) van tiegh (Loranthaceae). Int J Biol Chem Sci. 2012;6(1):408-14.
29. Waly NM, Ali AEED, Jrais RN. Botanical and biological studies of six parasitic species of family Loranthaceae growing in Kingdom of Saudi Arabia. Int J Environ Sci. 2010;1(4):196-205.
30. Fukunaga T, Nishiya K, Kajikawa I, Takeya K, Itokawa H. Studies on the constituents of Japanese mistletoes from different host trees, and their antimicrobial and hypotensive properties. Chem Pharm Bull. 1989;37(6):1543- 6.
31. Tara CA, Wagner ML, Horacio MA, Roberto P, Gurni AA. Estudio farmacológico de un agente vasoactivo presente en Ligaria cuneifolia var, cuneifolia. Acta Farm Bonaerense. 1994;13(2):91-5.
32. Iwalokun BA, Hodonu SA, Nwoke S, Ojo O, Agomo PU. Evaluation of the possible mechanisms of antihypertensive activity of loranthus micranthus: an african mistletoe. Biochem Res Int. 2011;2011.
33. Graziano M, Widmer G, Coussio J, Juliani R. Isolation of tyramine from five Argentine species of Loranthaceae. Lloydia. 1967;30(3):242-4.
34. Graziano M, Widmer G, Juliani R, Coussio J. Flavonoids from the Argentine mistletoe, psittacanthus cuneifolius. Phytochem. 1967;6(12):1709-11.
35. Numan IT, Hamad MN, Hassan A. Hematopoietic toxicity of loranthus europaeus: in vivo study. Asian J Pharm Clin Res. 2013;6(1):117-20.
36. Wagner H, Jordan E, Feil B. Studies on the standardization of mistletoe preparations. Oncology. 1986;43(S1):16-22.
37. Winterferld K, Dorle E. The active material of mistletoe (Viscum album L.) II. Archives of Pharmacy. 1942;280:23-36.
38. Yataro O. The components of Viscum album. I. searching for nitrogenous compound; isolation of arginin. Eur J Agron. 1941;17:219-21.
39. Sajner J, Veris O. Occurrence of histamine in Viscum album. Die Pharmazie. 1958;13(3):170.
40. Jordan E, Wagner H. Structure and properties of polysaccharides from Viscum album (L.). Oncology. 1986;43(S1):8-15.
41. Sinha A, Taylor WH, Khan IH, McDaniel ST, Esko JD. Glycoside primers of psittacanthus cucullaris. J Nat Prod. 1999;62(7):1036-8.
42. Badr JM, Shaala LA, Youssef DT. Loranthin: a new polyhydroxylated flavanocoumarin from plicosepalus acacia with significant free radical scavenging and antimicrobial activity. Phytochem Lett. 2013;6(1):113-7.
43. Othman S. Cardiovascular effect of Loranthus ferrugineus roxb (a local mistletoe). [master’s thesis]. Malaysia: Universiti Sains Malaysia; 1988.
44. Lohézic-Le-Dévéhat F, Tomasi S, Fontanel D, Boustie J. Flavonols from scurrula ferruginea danser (Loranthaceae). Z Naturforsch C Biosci. 2002;57:1092-5.
45. Danser BH. Vernacular names of Loranthaceae in the Malay peninsula and the Netherlands Indies. Bull Jard Bot Buitenz. 1933;3(13):487-96.
46. Quisumbing E. Medicinal plants of the Philippines. Tech Bull. 1951;16:126.
47. Bantel H, Engels IH, Voelter W, Schulze-Osthoff K, Wesselborg S. Mistletoe lectin activates caspase-8/ FLICE independently of death receptor signaling and enhances anticancer drug-induced apoptosis. Cancer Res. 1999;59(9):2083-90.
48. Ernst E, Schmidt K, Steuer-Vogt MK. Mistletoe for cancer? a systematic review of randomised clinical trials. Int J Cancer. 2003;107(2):262-7.
49. Rostock M, Huber R, Greiner T, Fritz P, Scheer R, Schueler J, et al. Anticancer activity of a lectin-rich mistletoe extract injected intratumorally into human pancreatic cancer xenografts. Anticancer Res. 2005;25(3B):1969- 75.
50. Stauder H, Kreuser ED. Mistletoe extracts standardised in terms of mistletoe lectins (MLI) in oncology: current state of clinical research. Onkologie. 2002;25(4):374-80.
51. Kress WJ, Wurdack KJ, Zimmer EA, Weigt LA, Janzen DH. Use of DNA barcodes to identify flowering plants. Proc Natl Acad Sci USA. 2005;102(23):8369-74.
52. Kienle GS, Berrino F, Büssing A, Portalupi E, Rosenzweig S, Kiene H. Mistletoe in cancer-a systematic review on controlled clinical trials. Eur J Med Res. 2003;8(3):109-19.
53. Hooker WJ. Botanical miscellany: Containing figures and descriptions of such plants as themselves. London: Forgotten Books; 1830. p. 279.
54. Keng H. The concise flora of Singapore: gymnosperms and dicotyledons. Singapore: NUS Press; 1990. p. 222.
55. Don G. A general history of the dichlamydeous plants. London: JG and F Rivington; 1834. p. 1-818.
56. Harborne AJ. Phytochemical methods, a guide to modern techniques of plant analysis. Netherlands: Springer Netherlands; 1998. p. 1-221.
57. Narayanasamy C, Sampathkumar R. Host parasite relationships of dendrophthoe falcata (linn. f.) bettingh. (Loranthus longiflorus desr). J Bombay nat Hist Soc.1981;78(1):192-3.
58. Misra PC. Regionalization of the physiological effect of mistletoe infection. Ind J Exp Biol. 1970;8(4):324-5.
59. Ameer OZ, Salman IM, Yam MF, Abd Allah HH, Abdulla MH, Shah AM, et al. Vasorelaxant properties of Loranthus ferrugineus roxb. methanolic extract. Int J Pharmacol. 2009;5(1):44-50.
60. Ameer OZ, Salman IM, Siddiqui MJ, Yam MF, Sriramaneni RN, Sadikun A, et al. Cardiovascular activity of the n-butanol fraction of the methanol extract of Loranthus ferrugineus roxb. Braz J Med Biol Res. 2010;43(2):186- 94.
61. Hebert PD, Gregory TR. The promise of DNA barcoding for taxonomy. Syst Biol. 2005;54(5):852-9.
62. Laslett LJ, Alagona P, Clark BA, Drozda JP, Saldivar F, Wilson SR, et al. The worldwide environment of cardiovascular disease: prevalence, diagnosis, therapy, and policy issues: a report from the American College of Cardiology. J Am Coll Cardiol. 2012;60(S25):1-49.
63. Global status report on noncommunicable diseases 2010 [Internet]. Geneva: World Health Organization; 2011. Available from: http://apps.who.int/iris/handle/10665/44579.
64. Mathers CD, Loncar D. Projections of global mortality and burden of disease from 2002 to 2030. Plos Med. 2006;3(11):e442.
65. Mashour NH, Lin GI, Frishman WH. Herbal medicine for the treatment of cardiovascular disease: clinical considerations. Arch Intern Med. 1998;158(20):2225- 34.
66. Winslow LC, Kroll DJ. Herbs as medicines. Archives of internal medicine. 1998;158(20):2192-9.
67. Ben EE, Eno AE, Ofem OE, Aidem U, Itam EH. Increased plasma total cholesterol and high density lipoprotein levels produced by the crude extract from the leaves of Viscum album (mistletoe). Niger J Physiol Sci. 2006;21(1-2):55-60.
68. Ofem OE, Eno AE, Imoru J, Nkanu E, Unoh F, Ibu JO. Effect of crude aqueous leaf extract of Viscum album (mistletoe) in hypertensive rats. Indian J Pharmacol. 2007;39(1):15-9.
69. Ameer OZ, Salman IM, Siddiqui MJA, Yam MF, Sriramaneni RN, Sadikun A, et al. Characterization of the possible mechanisms underlying the hypotensive and spasmogenic effects of Loranthus ferrugineus methanolic extract. Am J Chin Med. 2009;37(5):991-1008.
70. Ameer OZ, Salman IM, Najim HS, Abdullah GZ, Abdulkarim MF, Yam MF, et al. In vitro pharmacodynamic profile of Loranthus ferrugineus: evidence for noncompetitive antagonism of norepinephrine-induced vascular contraction. J Acupunct Meridian Stud. 2010;3(4):272-82.
71. Guyenet PG. The sympathetic control of blood pressure. Nat Rev Neurosci. 2006;7(5):335-46.
72. Loewy AD, Spyer KM. Central regulation of autonomic functions. USA: Oxford University Press; 1990. p. 88- 103.
73. Thomas GD. Neural control of the circulation. Adv Physiol Educ. 2011;35(1):28-32.
74. Walch L, Brink C, Norel X. The muscarinic receptor subtypes in human blood vessels. Therapie. 2001;56(3):223-6.
75. Khonsung P, Panthong A, Chiranthanut N, Intahphuak S. Hypotensive effect of the water extract of the leaves of pseuderanthemum palatiferum. J Nat Med. 2011;65(3- 4):551-8.
76. Nwokocha CR, Owu DU, McLaren M, Murray J, Delgoda R, Thaxter K, et al. Possible mechanisms of action of the aqueous extract of Artocarpus altilis (breadfruit) leaves in producing hypotension in normotensive sprague-dawley rats. Pharm Biol. 2012;50(9):1096-102.
77. Nguelefack TB, Mekhfi H, Dongmo AB, Dimo T, Watcho P, Zoheir J, et al. Hypertensive effects of oral administration of the aqueous extract of solanum torvum fruits in L-NAME treated rats: evidence from in vivo and in vitro studies. J Ethnopharmacol. 2009;124(3):592-9.
78. Orallo F. Acute cardiovascular effects of (+)-nantenine, an alkaloid isolated from platycapnos spicata, in anaesthetised normotensive rats. Planta Med. 2004;70(2):117-26.
79. Raji I, Mugabo P, Obikeze K. The contributions of muscarinic receptors and changes in plasma aldosterone levels to the anti-hypertensive effect of Tulbaghia violacea. BMC Complement Altern Med. 2013;13:13.
80. Abrogoua DP, Dano DS, Manda P, Adepo AJ, Kablan BJ, Goze NB, et al. Effect on blood pressure of a dietary supplement containing traditional medicinal plants of cote d’ivoire. J Ethnopharmacol. 2012;141(3):840-7.
81. Nyadjeu P, Dongmo A, Nguelefack TB, Kamanyi A. Antihypertensive and vasorelaxant effects of Cinnamomum zeylanicum stem bark aqueous extract in rats. J Complement Integr Med. 2011;8(1):1-18.
82. Assaidi A, Legssyer A, Berrichi A, Aziz M, Mekhfi H, Bnouham M, et al. Hypotensive property of chenopodium ambrosioides in anesthetized normotensive rats. J Complement Integr Med. 2014;11(1):1-7.
83. Brunton L, Chabner BA, Knollmann B. Goodman and gilman’s the pharmacological basis of therapeutics. China: McGraw-Hill Professional; 2011. p. 1808.
84. Lessa MA, Araújo CV, Kaplan MA, Pimenta D, Figueiredo MR, Tibiriçá E. Antihypertensive effects of crude extracts from leaves of Echinodorus grandiflorus. Fundam Clin Pharmacol. 2008;22(2):161-8.
85. Ghayur MN, Gilani AH. Radish seed extract mediates its cardiovascular inhibitory effects via muscarinic receptor activation. Fundam Clin Pharmacol. 2006;20(1):57- 63.
86. Martin DS, Breitkopf NP, Eyster KM, Williams JL. Dietary soy exerts an antihypertensive effect in spontaneously hypertensive female rats. Am J Physiol Regul Integr Comp Physiol. 2001;281(2):553-60.
87. Hasrat JA, Pieters L, Vlietinck AJ. Medicinal plants in suriname: hypotensive effect of gossypium barbadense. J Pharmacol Pharmacother. 2004;56(3):381-7.
88. Lüscher TF, Vanhoutte PM, The endothelium: modulator of cardiovascular function. London: CRC press; 1990. p. 248.
89. Bruno RM, Taddei S. Nitric oxide. in: encyclopedia of exercise medicine in health and disease. Berlin: Springer- Verlag; 2011. p. 645-8.
90. Kane SR, Apte VA, Todkar SS, Mohite SK. Diuretic and laxative activity of ethanolic extract and its fractions of euphorbia thymifolia linn. Int J ChemTech Res. 2009;1(2):149-52.
91. Ouedraogo M, Ruiz M, Vardelle E, Carreyre H, Coustard JM, Potreau D, et al. From the vasodilator and hypotensive effects of an extract fraction from Agelanthus dodoneifolius (DC) danser (Loranthaceae) to the active compound dodoneine. J Ethnopharmacol. 2011;133(2):345-52.
92. Ameer OZ, Salman IM, Siddiqui MJ, Yam MF, Sriramaneni RN, Mohamed AJ, et al. Pharmacological mechanisms underlying the vascular activities of Loranthus ferrugineus roxb. in rat thoracic aorta. J Ethnopharmacol. 2010;127(1):19-25.
93. Kojsová S, Jendekova L, Zicha J, Kune? J, Andriantsitohaina R, Pechánová O. The effect of different antioxidants on nitric oxide production in hypertensive rats. Physiol Res. 2006;55(S1):3-16.
94. Chen X. Cardiovascular protection by ginsenosides and their nitric oxide releasing action. Clin Exp Pharmacol Physiol. 1996;23(8):728-32.
95. Brixius K, Willms S, Napp A, Tossios P, Ladage D, Bloch W, et al. Crataegus special extract WS 1442 induces an endothelium-dependent, NO-mediated vasorelaxation via eNOS-phosphorylation at serine 1177. Cardiovasc Drug Ther. 2006;20(3):177-84.
96. Taubert D, Berkels R, Roesen R, Klaus W. Chocolate and blood pressure in elderly individuals with isolated systolic hypertension. JAMA. 2003;290(8):1029-30.
97. Grassi D, Desideri G, Ferri C. Protective effects of dark chocolate on endothelial function and diabetes. Curr Opin Clin Nutr Metab Care. 2013;16(6):662-8.
98. Langmead L, Rampton D. Review article: herbal treatment in gastrointestinal and liver disease-benefits and dangers. Aliment Pharmacol Ther. 2001;15(9):1239-52.
99. Ameer OZ, Salman IM, Siddiqui MJ, Yam MF, Sriramaneni RN, Sadikun A, et al. In vitro cholinomimetic effect of Loranthus ferrugineus in isolated guinea pig ileum. J Acupunct Meridian Stud. 2009;2(4):288-93.
100. Mehmood MH, Anila N, Begum S, Syed SA, Siddiqui BS, Gilani AH. Pharmacological basis for the medicinal use of carissa carandas in constipation and diarrhea. J Ethnopharmacol. 2014;153(2):359-67.
101. Rehman N, Mehmood MH, Al-Rehaily AJ, Mothana RA, Gilani AH. Species and tissue-specificity of prokinetic, laxative and spasmodic effects of fumaria parviflora. BMC Complement Altern Med. 2012;12(1):16.
102. Ehlert FJ, Sawyer GW, Esqueda EE. Contractile role of M2 and M3 muscarinic receptors in gastrointestinal smooth muscle. Life Sci. 1999;64(6):387-94.
103. Sawyer GW, Ehlert FJ. Contractile roles of the M2 and M3 muscarinic receptors in the guinea pig colon. J Pharmacol Exp Ther. 1998;284(1):269-77.
104. Samuelson LC, Hinkle KL. Insights into the regulation of gastric acid secretion through analysis of genetically engineered mice. Annu Rev Physiol. 2003;65(1):383- 400.
105. Rabiei Z, Rafieian-kopaei M, Heidarian E, Saghaei E, Mokhtari S. Effects of zizyphus jujube extract on memory and learning impairment induced by bilateral electric lesions of the nucleus basalis of meynert in rat. Neurochem Res. 2014;39(2):353-60.
106. Wenk GL, McGann-Gramling K, Hauss-Wegrzyniak B, Ronchetti D, Maucci R, Rosi S, et al. Attenuation of chronic neuroinflammation by a nitric oxide-releasing derivative of the antioxidant ferulic acid. J Neurochem. 2004;89(2):484-93.
107. Terry AV, Buccafusco JJ. The cholinergic hypothesis of age and alzheimer’s disease-related cognitive deficits: recent challenges and their implications for novel drug development. J Pharmacol Exp Ther. 2003;306(3):821- 7.
108. Khalili M, Roghani M, Ekhlasi M. The effect of aqueous crocus sativus l. extract on intracerebroventricular streptozotocin-induced cognitive deficits in rat: a behavioral analysis. Iran J Pharm Res. 2009;8(3):185-91.
109. Kim JH, Hahm DH, Lee HJ, Pyun KH, Shim I. Acori graminei rhizoma ameliorated ibotenic acid-induced amnesia in rats. Evid Based Complement Alternat Med. 2009;6(4):457-64.
110. Schumacher U, Kretzschmar H, Pfüller U. Staining of cerebral amyloid plaque glycoproteins in patients with alzheimer’s disease with the microglia-specific lectin from mistletoe. Acta Neuropathol. 1994;87(4):422-4.
111. Schumacher U, Adam E, Kretzschmar H, Pfüller U. Binding patterns of mistletoe lectins I, II and III to microglia and alzheimer plaque glycoproteins in human brains. Acta Histochem. 1994;96(4):399-403.
112. Harvey AL. Drugs from natural products. England: Ellis Horwood; 1993. p. 450.
113. Chan K. Some aspects of toxic contaminants in herbal medicines. Chemosphere. 2003;52(9):1361-71.