Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-08T05:27:37.081Z Has data issue: false hasContentIssue false
  • English
  • Français

Medicinal plants for helminth parasite control: facts and fiction

Published online by Cambridge University Press:  01 October 2007

S. Athanasiadou ,
J. Githiori  and
I. Kyriazakis
S. Athanasiadou*
Affiliation:
Animal Nutrition and Health Department, Scottish Agricultural College, West Mains Road, Edinburgh EH9 3JG, UK
J. Githiori
Affiliation:
International Livestock Research Institute (ILRI), PO Box 30709, 00100 Nairobi, Kenya
I. Kyriazakis
Affiliation:
Animal Nutrition and Health Department, Scottish Agricultural College, West Mains Road, Edinburgh EH9 3JG, UK Faculty of Veterinary Medicine, University of Thessaly, Trikalon 224, 43100 Karditsa, Greece
*
E-mail: [email protected]

Abstract

The use of medicinal plants for the prevention and treatment of gastro-intestinal parasitism has its origin in ethnoveterinary medicine. Although until recently the majority of the evidence on the antiparasitic activity of medicinal plants was anecdotal and lacked scientific validity, there is currently an increasing number of controlled experimental studies that aim to verify and quantify such plant activity. There are indeed a large number of plants whose anthelmintic activity has been demonstrated under controlled experimentation, either through feeding the whole plant or administering plant extracts to parasitised hosts. However, contrary to traditional expectation, there are also a great number of plants with purported antiparasitic properties, which have not been reproduced under experimental conditions. In this paper, we discuss the source of such inconsistencies between ethnoveterinary wisdom and scientific experimentation. We focus on the strengths and weaknesses of the existing methodologies used in the controlled studies to determine the activity of antiparasitic plants. We discuss issues like the seasonal and environmental variability of the plant composition, and how this can affect their antiparasitic properties and highlight the importance of identifying the mechanisms of action of such plants and the target parasite species. In addition to their antiparasitic properties, medicinal plants may also have anti-nutritional properties, which can affect animal performance and behaviour. For this reason, we emphasise the need for considering additional dimensions when evaluating medicinal plants. We also question whether using similar criteria as those used for the evaluation of anthelmintics is the way forward. We propose that a holistic approach is required to evaluate the potential of medicinal plants in parasite control and maximise their benefits on parasitised hosts.

Keywords

bioactive plantsethnoveterinary medicinemedicinal plantsparasitesruminants
Type
Full Paper
Information
animal , Volume 1 , Issue 9 , October 2007 , pp. 1392 - 1400
Copyright
Copyright © The Animal Consortium 2007

Introduction

For centuries, medicinal plants have been used to combat parasitism, and in many parts of the world are still used for this purpose. In ethnoveterinary medicine, which draws inspiration from traditional practice, there seems to be a range of plant/s or plant extract suitable for treating almost every parasitic disease of livestock (International Institute of Rural Reconstruction (IIRR), 1994). For example, seeds of garlic, onion and mint have been used to treat animals that suffer from gastro-intestinal parasitism, whereas extracts of the tobacco plant have been used to treat the skin of livestock afflicted with external parasites (Guarrera, Reference Guarrera1999). Leaves, dried flowers and oil from Chenopodium ambrosioides, a shrub that originated from Central America and has been distributed around the world, have all been used as anthelmintics since the early 1900s (Guarrera, Reference Guarrera1999). Reports from around the world include exhaustive lists of plants that have been reported to have medicinal properties (Hammond et al., Reference Hammond, Fielding and Bishop1997; Akhtar et al., Reference Akhtar, Iqbal, Khan and Lateef2000; Waller et al., Reference Waller, Bernes, Thamsborg, Sukura, Richter, Ingebrigtsen and Hoglund2001; Nundkumar and Ojewole, Reference Nundkumar and Ojewole2002; Athanasiadou and Kyriazakis, Reference Athanasiadou and Kyriazakis2004; Fajimi and Taiwo, Reference Fajimi and Taiwo2005; Githiori et al., Reference Githiori, Athanasiadou and Thamsborg2006).

Although the majority of the evidence on antiparasitic activity of plants has been traditionally based on anecdotal observations, there is currently an increasing number of controlled experimental studies that aim to verify, validate and quantify in a scientific manner such plant activity. Traditionally, there are two approaches that have been employed for this purpose. The first one is through offering plants or plant parts to naturally or experimentally infected animals and quantifying the consequences of their consumption. The second approach is through testing plant extracts and concoctions derived from medicinal plants via in vitro and in vivo systems. Although a number of medicinal plants have been evaluated through these methodologies and have been found to be active against parasites, the purported antiparasitic properties of a large variety of plants have not been reproduced under controlled experimentation. The source of such inconsistencies between ethnoveterinary wisdom and scientific experimentation is discussed in the present review. In the first part of the review, we focus on the weaknesses and strengths of the existing methodologies used to determine the antiparasitic activity of the whole plant. We discuss issues like the seasonal and environmental variability of plant composition and how this can affect their antiparasitic activity, and highlight the importance of identifying the active compounds and mechanisms of such plants and the target parasite species. In the second part, we explore the methodologies used to test the plant extracts for antiparasitic activity and question their value as a tool for this purpose. We discuss how the efficiency of medicinal plant extracts can be compromised by a variety of reasons, which include the interactions between plant secondary metabolites (PSM) and nutrients, host physiology and the site of parasitism. We conclude that in order to explore the full potential of the medicinal plants and progress towards their implementation in parasite control strategies, we need to evaluate their activity in a holistic manner and thus exploit the complementarity of all methodologies available for this purpose.

Studies on the whole plant: strengths and limitations

The emergence of resistance to anthelmintic drugs, which is now a worldwide phenomenon (Jackson and Coop, Reference Jackson and Coop2000), and the increased awareness of consumers about drug residues that potentially enter the food chain have stimulated investigation into alternatives to commercially available anthelmintics, such as medicinal plants. Their persistence in various environments and the wealth of information available from ethnoveterinary sources in many parts of the world has resulted in medicinal plants attracting attention from the scientific community. In an attempt to utilise as effectively as possible the information available from ethnoveterinary and medicinal reports on the anthelmintic activity of plants, there is a current trend to validate such plants under controlled experimental conditions. The variety of methodologies used for this purpose includes the provision of fresh, conserved or dried plants or plant parts to parasitised animals. For example, the consumption of leaves of wormwood in the form of powder (Artemisia brevifolia), one of the bitterest of plants, has been tested in a controlled study for its anthelmintic activity. Iqbal et al. (Reference Iqbal, Lateef, Ashraf and Jabbar2004) demonstrated that the consumption of the whole plant resulted in a 62% reduction of the abomasal nematode Haemonchus contortus egg counts. The consumption of fagara leaves (Zanthoxylum zanthoxyloides), a native tree from Africa, believed to have antiparasitic activity, resulted in reduced egg excretion by the same nematode in sheep, when consumed regularly in small amounts (Hounzangbe-Adote et al., Reference Hounzangbe-Adote, Zinsou, Hounpke, Moutairou and Hoste2005). Similarly, lespedeza (Sericea lespedeza), a grazing perennial legume native of Eastern Asia showed promising anthelmintic activity when offered to goats either fresh (Min et al., Reference Min, Pomroy, Hart and Sahlu2004) or as hay (Shaik et al., Reference Shaik, Terrill, Miller, Kouakou, Kannan, Kallu and Mosjidis2004; Lange et al., Reference Lange, Olcott, Miller, Mosjidis, Terrill, Burke and Kearney2006). Ethnoveterinary sources from south-east Asia report that cassava forage (Manihot esculenta) has been used by traditional healers with success for the control of internal parasitism (Sokerya and Preston, 2003). The consumption of cassava hay resulted in lower faecal egg counts and worm burdens in sheep parasitised with abomasal and intestinal nematodes compared with unsupplemented controls (Sokerya and Preston, 2003; Bunyeth and Preston, 2006).

However, not in all cases the evidence on the antiparasitic properties of plants is consistent with the expectations arising from traditional views. The neem tree (Azadirachta indica) is known for its medicinal properties and has been recommended for use against gastro-intestinal nematodes and related problems in many parts of the world (Biswas et al., Reference Biswas, Chattopadhyay, Banerjee and Bandyopadhyay2002; Subapriya and Nagini, Reference Subapriya and Nagini2005). However, when leaves of the neem tree were offered to parasitised sheep, either fresh or dried, no anthelmintic effect was recorded against H. contortus (Githiori et al., Reference Githiori, Hoglund, Waller and Baker2004; Costa et al., Reference Costa, Bevilaqua, Maciel, Camurca-Vasconcelos, Morais, Monteiro, Farias, da Silva and Souza2006). In contrast, in another study, Chandrawathani et al. (Reference Chandrawathani, Chang, Nurulaini, Waller, Adnan, Zaini, Jamnah, Khadijah and Vincent2006) reported the effectiveness of neem in reducing worm numbers of the same nematode in the abomasa of small ruminants fed on fresh neem leaves on a daily basis. Melia azederach, another plant that belongs to the same family as the neem tree, has also been reported to have anthelmintic activity. However, under controlled experiments, no anthelmintic activity has been demonstrated (Hordegen et al., Reference Hordegen, Hertzberg, Heilmann, Langhans and Maurer2003). In addition, there is a large number of grazing forages, including Lotus pedunculatus and Hedysarum coronarium, whose anthelmintic activity has been shown to be rather inconsistent across the various studies around the world (Niezen et al., Reference Niezen, Waghorn and Charleston1998; Garcia et al., Reference Garcia, Leiro, Delgado, Sanmartin and Ubeira2003; Marley et al., Reference Marley, Cook, Keatinge, Barrett and Lampkin2003; Athanasiadou et al., Reference Athanasiadou, Tzamaloukas, Kyriazakis, Jackson and Coop2005; Tzamaloukas et al., Reference Tzamaloukas, Athanasiadou, Kyriazakis, Jackson and Coop2005).

The interpretation of the observed inconsistencies in the activity of medicinal plants when offered to parasitised animals, either as a supplement or single food, is not straightforward. In cases where evidence is anecdotal, one part of the problem seems to be the misinterpretation of facts in various communities, often due to the lack of scientific knowledge. For example, traditional healers are not always familiar with the parasite species that are most pathogenic for livestock. In a participatory study in northern Kenya, traditional healers identified plants as being very effective antiparasitics if they expelled tapeworm segments (Githiori et al., Reference Githiori, Hoglund, Waller and Baker2004). The latter are easy to identify, as they are visible with the naked eye, but not as pathogenic as helminth nematodes, whose both parasitic and non-parasitic stages require specialised knowledge and equipment to be identified. Thus, in some cases, plants may have been mistakenly included in lists with those reported with anthelmintic properties and these mistakes may be justified when controlled experimentation is performed.

In other cases, the inconsistencies observed might be related to methodological limitations while testing the anthelmintic properties of medicinal plants. For example, testing such plants in rodent and other models might not always be appropriate. The majority of ethnoveterinary reports originate from ruminants, as the main livestock species that generate income in poor countries (IIRR, 1994). Consequently, when the antiparasitic activity of such plants is tested in rodent models, for example in the form of dried plant, part of the reported variation may be due to the physiological difference between ruminant and non-ruminant animals (Satrija et al., Reference Satrija, Nansen, Bjorn, Murtini and He1994; Ignacio et al., Reference Ignacio, Ferreira, Almeida and Kubelka2001; Githiori et al., Reference Githiori, Hoglund, Waller and Baker2003a and Reference Githiori, Hoglund, Waller and Baker2003b). Other methodological limitations include the great variation observed in the protocols of collection and storage of the plant material prior to its use, if not grazed or consumed immediately. The latter will result in changes in plant availability in nutrients and metabolites, which may affect the reproducibility of their anthelmintic activity. For example, in the above study by Chandrawathani et al. (Reference Chandrawathani, Chang, Nurulaini, Waller, Adnan, Zaini, Jamnah, Khadijah and Vincent2006) on the neem tree, the leaves were reportedly collected daily and fed fresh to the animals, whereas Githiori et al. (Reference Githiori, Hoglund, Waller and Baker2004) fed conserved leaves. The observed inconsistency on the anthelmintic effects of neem tree in the above studies could be attributed to the method of preservation, which may have affected the plant properties. In most of the cases, the antiparasitic properties of plants are exerted through PSM. These metabolites are unstable molecules and their biological activity will be dependent on their structure and physical and chemical properties (Waterman, Reference Waterman1988 and Reference Waterman1992). Variable conditions of collection and storage of the plants have been shown to affect these properties and likely their anthelmintic activity as well. In addition, seasonal and environmental variability will have an impact on the synthetic pathways of the PSM, which can potentially affect their physical and chemical properties (Mueller-Harvey and McAllan, Reference Mueller-Harvey and McAllan1992).

Prior to considering incorporating medicinal plants in parasite control schemes, the scientific community should provide strong evidence on their benefits on parasitised hosts and address the issue of inconsistency across the studies around the world. We believe that in order to minimise the inconsistencies reported and maximise the repeatability of the results, there is an urgent requirement for the development and utilisation of a standardised methodology for the evaluation of their activity around the world. There is no system currently available to sufficiently characterise the plants in terms of their anthelmintic properties, quantify the latter and finally standardise their use for parasite control in different parts of the world. Such a system could be used as a common currency from scientists around the world to describe the anthelmintic potential of bioactive plants. A first step towards achieving this would be the identification of active compounds in medicinal plants. Subsequently, this information could be used to characterise the medicinal plants by estimating their content in the active compound. This would enable comparisons to be made on the same basis across studies and will also explain the variability of the results. We further exploit this by taking the inconsistency related to neem tree as an example.

Although the active compound(s) in the neem tree has not yet been isolated, its high content in condensed tannins has led towards hypothesising that these polyphenolic compounds might be responsible for its anthelmintic activity. Possibly due to cost implications and design limitations, condensed tannin content and plant description was not included in any of the studies previously mentioned (Chandrawathani et al., Reference Chandrawathani, Brelin, Nor Fasihah, Adnan, Jamnaah, Sani, Höglund and Waller2002 and Reference Chandrawathani, Chang, Nurulaini, Waller, Adnan, Zaini, Jamnah, Khadijah and Vincent2006; Githiori et al., Reference Githiori, Hoglund, Waller and Baker2004; Costa et al., Reference Costa, Bevilaqua, Maciel, Camurca-Vasconcelos, Morais, Monteiro, Farias, da Silva and Souza2006). This would have helped towards accounting for the potential inconsistencies among the different studies. As the process of isolating the active compounds is long, complex, and often requires specialised equipment, bibliographic evidence on the active compounds and subsequent determination of their concentration in the plant would also be useful. Admittedly, this process can be complicated in cases where the anthelmintic activity of a plant is attributed to more than one compounds. Furthermore, the bioavailability of the active compound in the host is not always directly related to the concentration in the plant, as will be explained in the next part. We still however believe that there is a requirement for the use of a common currency among scientists, in a form of a plant-compound database or index, which will provide a solid reference system used globally. Such a tool, which would need to be the outcome of an interdisciplinary collaboration, should enable scientists to quickly screen medicinal plants by measuring concentrations of the active compound and consequently evaluate its anthelmintic potential.

In the next section, we describe the advantages and pitfalls of the second methodology often used to evaluate the anthelmintic properties of medicinal plants. Although some of the issues raised above apply for this second methodology as well, for the purpose of clarity they will not be further addressed in the next section.

Extracts: is their use the way forward in the validation of medicinal plants?

The effects that parasitised hosts experience as a consequence of plant consumption result from interactions between the nutritional values and the pharmacological/medicinal properties of the plants. In order to facilitate the validation process of the medicinal plants and address some of the methodological drawbacks mentioned in the previous section, there is a concurrent trend towards using plant extracts to assess the anthelmintic activity of medicinal plants. Extraction procedures used for this purpose vary from simple water extractions to very complicated ones, where a series of organic solvents is used (Waterman and Mole, Reference Waterman and Mole1994). The aim is to extract the active compounds from the medicinal plants, and then test their anthelmintic activity, through in vitro and in vivo systems. The anthelmintic properties of several medicinal plant extracts have been evaluated through in vitro systems and their efficiencies have in some cases approached 100% (Satou et al., Reference Satou, Koga, Matsuhashi, Koike, Tada and Nikaido2002; Molan et al., Reference Molan, Duncan, Barry and McNabb2003a; Ademola and Idowu, Reference Ademola and Idowu2006). In addition, in vivo studies have shown that the administration of quebracho extract, a commercially available extract from Schinopsis spp., reduced faecal egg counts and worm numbers in parasitised sheep (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Butter et al., Reference Butter, Dawson, Wakelin and Buttery2001). Similarly, parasitised goats benefited from the inclusion of plant extracts containing high levels of secondary metabolites in their diets (Akhtar and Ahmad, Reference Akhtar and Ahmad1992; Paolini et al., Reference Paolini, Bergeaud, Grisez, Prevot, Dorchies and Hoste2003a and Reference Paolini, Frayssines, De La Farge, Dorchies and Hoste2003b). In some cases, the antiparasitic efficacy of plant extracts has been similar to that of broad-spectrum anthelmintic drugs; Satrija et al. (Reference Satrija, Nansen, Bjorn, Murtini and He1994) almost eliminated intestinal nematodes within 7 days of supplementation with papain extract.

However, not in all cases the alleged anthelmintic activity of certain plant extracts, as reported by ethnoveterinary reports, was confirmed by controlled experimentation. For example, the administration of plant extracts used in Kenya by herbalists in parasitised sheep did not reduce the level of parasitism in controlled experimental studies (Githiori et al., Reference Githiori, Hoglund, Waller and Baker2002). In other cases, although some degree of reduction was observed, this was considered not to be of major importance for their use in parasite control (Githiori et al., Reference Githiori, Hoglund, Waller and Baker2003b). The oil of C. ambrosioides has been known for centuries for its anthelmintic properties. It was included in the British Veterinary Codex until the middle of last century (1953) and is reported for anthelmintic activity in scientific reviews (Tagboto and Townson, Reference Tagboto and Townson2001; Waller et al., Reference Waller, Bernes, Thamsborg, Sukura, Richter, Ingebrigtsen and Hoglund2001). However, when tested under controlled conditions against abomasal nematodes, no anthelmintic activity was reported (Ketzis et al., Reference Ketzis, Taylor, Bowman, Brown, Warnick and Erb2002). Inconsistency is observed not only between ethnoveterinary and scientific reports but also across scientific experiments. The administration of quebracho extract (see above) resulted in a reduction in the abomasal worm burden in one case (Max et al., Reference Max, Wakelin, Dawson, Kimambo, Kassuku, Mtenga, Craigon and Buttery2005), whereas only the intestinal worm burden was affected in another case (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a).

One of the challenges we are faced with, when using plant extracts to assess the anthelmintic activity of medicinal plants, is relating the concentration of the active compound in the extract and that found in the plant. The plant extract, as obtained following the extraction process, will inevitably have a high concentration of the active compounds. In most cases, this will not correspond to the concentration of the active compounds consumed by parasitised hosts when the plant is included in their diets (Molan et al., Reference Molan, Duncan, Barry and McNabb2003a). As a consequence, it is not uncommon to observe high anthelmintic efficacy of medicinal plants when their extracts are tested in vitro (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Ketzis et al., Reference Ketzis, Taylor, Bowman, Brown, Warnick and Erb2002; Paolini et al., Reference Paolini, Fouraste and Hoste2004; Barrau et al., Reference Barrau, Fabre, Fouraste and Hoste2005) or when offered as a medicinal supplement (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Butter et al., Reference Butter, Dawson, Wakelin and Buttery2001). However, efficacy is not near as high when whole plants are offered to parasitised hosts (Niezen et al., Reference Niezen, Waghorn and Charleston1998 and Reference Niezen, Charleston, Robertson, Shelton, Waghorn and Green2002; Tzamaloukas et al., Reference Tzamaloukas, Athanasiadou, Kyriazakis, Jackson and Coop2005). Furthermore, in vitro models are often used to validate plant extracts, without the simultaneous use of in vivo experimentation. Although in vitro testing of the antiparasitic properties plant extracts offers the opportunity to screen large numbers of plant extracts at low cost and rapid turnover, in vitro results are not always verified by in vivo experimentation, and it is often questionable whether the in vitro assays are relevant to in vivo conditions (Athanasiadou and Kyriazakis, Reference Athanasiadou and Kyriazakis2004). The great variety of models and methods available to test the anthelmintic properties of plants and the lack of measures to minimise experimental variability contribute towards an increased apparent conflict of evidence regarding the anthelmintic properties of plant extracts.

Furthermore, other issues, such as the bioavailability of the active compounds at different parts of the gastro-intestinal tract, the host–plant interactions and the parasite specificity also increase the degree of variability observed in these studies. It has been shown that it is highly likely that certain plants are more active against specific parasite species than others (Athanasiadou et al., Reference Athanasiadou, Tzamaloukas, Kyriazakis, Jackson and Coop2005; Tzamaloukas et al., Reference Tzamaloukas, Athanasiadou, Kyriazakis, Jackson and Coop2005). This might be related to the parasite niche or the bioavailability of the compound in the different compartments of the gastro-intestinal tract of the parasitised host. Condensed tannins, for example, have been shown to form complexes with macromolecules, such as proteins (Mueller-Harvey, Reference Mueller-Harvey2006). Due to physiological conditions, tannins are expected to be in complexes in the abomasa of parasitised hosts. When in complexes, they are likely unavailable to exert their anthelmintic activity; this could be why abomasal nematodes were not affected in vivo by condensed tannins, whereas they were affected in an in vitro system (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a). The protein–tannin complexes are expected to be disassociated in the small intestine, and thus extracts rich in condensed tannins were effective against intestinal parasites. However, when hosts are offered a diet rich in protein, tannins may remain in complexes with the protein in the small intestine, and thus lower their anthelmintic efficacy (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001b). Compound bioavailability and thus efficacy of medicinal plants may also be related to the host species. For example, although the ingestion of condensed tannins did not affect the abomasal worm burden in sheep, it did in goats (Paolini et al., Reference Paolini, Bergeaud, Grisez, Prevot, Dorchies and Hoste2003a). It is known that a number of physiological adaptations have taken place in the gastro-intestinal tract of goats, in comparison to that of sheep, to counteract the presence of secondary metabolites in the browse material. It has been hypothesised that such differences might be responsible for the host species specificity often observed in the anthelmintic activity of condensed tannins (Hoste et al., Reference Hoste, Jackson, Athanasiadou, Thamsborg and Hoskin2006).

Identifying the active compounds in plant extracts, as described in the previous section, quantifying them in the plant and estimating their bioavailability in the host are essential steps towards strengthening the evidence of the anthelmintic activity of medicinal plants through reducing the inconsistency of the evidence. This is a prerequisite towards achieving the scientific validation of plants for parasite control. It will also contribute towards improving our understanding on host–parasite–compounds interactions in order to consider ways of further increasing the efficacy of such compounds and ensure their best possible use for parasite control. It is imperative that effort is directed towards identifying active plant compounds for another reason: the active compounds contained in the medicinal plants are often responsible for a variety of negative side effects on the parasitised host. We will briefly address this issue below, as it has recently been reviewed elsewhere (Athanasiadou and Kyriazakis, Reference Athanasiadou and Kyriazakis2004; Hutchings et al., Reference Hutchings, Judge, Gordon, Athanasiadou and Kyriazakis2006) and then propose the approach required to exploit medicinal plants to their full potential.

Medicinal plants and parasitised hosts: viewing the whole picture

Although the majority of compounds with anthelmintic properties have yet to be isolated from forages and plants, in most cases such compounds have been identified, they are PSM. For example, lactones, such as santonin isolated from A. maritima, have shown a strong anthelmintic activity towards Ascaris spp., nematode species of livestock and humans (Waller et al., Reference Waller, Bernes, Thamsborg, Sukura, Richter, Ingebrigtsen and Hoglund2001). Alkaloids have also demonstrated strong nematocidal activity towards Strongyloides ratti and S. venezuelensis, two rat nematodes used as models for human nematodes (Satou et al., Reference Satou, Koga, Matsuhashi, Koike, Tada and Nikaido2002). The nematocidal activity of tannin extracts has been reported as early as the 1960s (Taylor and Murant, Reference Taylor and Murant1966), and more recently evidence on the anthelmintic properties of condensed tannins has been supported by a series of in vitro (Dawson et al., Reference Dawson, Buttery, Jenkins, Wood and Gill1999; Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Molan et al., Reference Molan, Meagher, Spencer and Sivakumaran2003b; Ademola and Idowu, Reference Ademola and Idowu2006) and in vivo studies (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2000; Butter et al., Reference Butter, Dawson, Wakelin and Buttery2001; Paolini et al., Reference Paolini, Bergeaud, Grisez, Prevot, Dorchies and Hoste2003a and Reference Paolini, Frayssines, De La Farge, Dorchies and Hoste2003b). However, despite their anthelmintic properties, it is not yet clear whether medicinal plants could actually have a role in controlling parasitism in livestock. This is because the consumption of medicinal plants either in form of plant parts or as extracts has also been related to the demonstration of toxic effects on hosts. These detrimental effects are often attributed to the same plant metabolites that are responsible for the anthelmintic effects. Alkaloids, terpenes, saponins, lactones, glycosides and phenolic compounds are classes of active plant metabolites whose excessive consumption can detrimentally affect herbivore health and in extreme cases, survival. For example, the excessive consumption of tannins, which are polyphenolic compounds, has been associated with a reduction of food intake and food digestibility, impairment of rumen metabolism and mucosal toxicity (Hagerman and Butler, Reference Hagerman and Butler1991; Rittner and Reed, Reference Rittner and Reed1992; Reed, Reference Reed1995; Dawson et al., Reference Dawson, Buttery, Jenkins, Wood and Gill1999). Saponins, which are terpenoids, have been considered responsible for reducing food intake, causing nutritional deficiencies, haemolysis and in extreme cases death of herbivores (Applebaum and Birk, Reference Applebaum and Birk1979; Milgate and Roberts, Reference Milgate and Roberts1995). Excessive consumption of cyanogenic glycosides, terpenes or alkaloids can result in neurological defects (Conn, Reference Conn1979). Cysteine proteinases were highly toxic, despite their obvious anthelmintic activity (De Amorin et al., Reference De Amorin, Borba, Carauta, Lopes and Kaplan1999; Stepek et al., Reference Stepek, Buttle, Duce, Lowe and Behnke2005 and Reference Stepek, Lowe, Buttle, Duce and Behnke2006).

Despite the abundant evidence on the potential negative effects of plant active metabolites in herbivores, to date the majority of the studies investigating the anthelmintic activity of medicinal plants is lacking measurements on the potential negative effects on the host. A small number of studies have monitored host’s performance (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2000 and Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Butter et al., Reference Butter, Dawson, Wakelin and Buttery2001; Githiori et al., Reference Githiori, Hoglund, Waller and Baker2004), and have reported clinical toxicity (Akhtar and Ahmad, Reference Akhtar and Ahmad1992; Satrija et al., Reference Satrija, Nansen, Bjorn, Murtini and He1994; Dawson et al., Reference Dawson, Buttery, Jenkins, Wood and Gill1999; Githiori et al., Reference Githiori, Hoglund, Waller and Baker2003a), which escalate as the concentrations of active compounds increase. In extreme cases, even the death of animals under treatment has been reported (Athanasiadou et al., Reference Athanasiadou, Kyriazakis, Jackson and Coop2001a; Githiori et al., Reference Githiori, Hoglund, Waller and Baker2003a). For parasitised animals to benefit from the anthelmintic properties of the medicinal plants, the antiparasitic effects should outweigh their antinutritional consequences on the performance of the parasitised host. The latter will depend greatly on the severity of the consequences towards the host on the one hand and towards the parasite on the other hand, as it has been discussed in two recent reviews (Houdijk and Athanasiadou, Reference Houdijk and Athanasiadou2003; Athanasiadou and Kyriazakis, Reference Athanasiadou and Kyriazakis2004). Parasitised hosts might even be able to tolerate short-term negative consequences (e.g. toxicity) if they are to attain long-term benefits (e.g. parasite reduction; Kyriazakis and Emmans, Reference Kyriazakis and Emmans1992).

In addition to the detrimental effects of plant compounds on the performance, their consequences on behaviour of parasitised hosts is yet another aspect that we believe needs to be considered, in a similar manner as performance. This is an essential issue as there is evidence from rodent models suggesting that the administration of plant extracts may result in a range of either positive (Herrera-Ruiz et al., Reference Herrera-Ruiz, Jimenez-Ferrer, De Lima, Viles-Montes, Perez-Garcia, Gonzalez-Cortazar and Tortoriello2006; Pultrini et al., Reference Pultrini, Galindo and Costa2006) or negative effects (Franco et al., Reference Franco, Morais, Quintans-Junior, Almeida and Antoniolli2005) on the behaviour of parasitised hosts. Changes in the behaviour of hosts, for example the introduction of behaviour that may be considered stereotypic as an outcome of the plant administration, may result in significant costs on the host’s welfare status. Combating parasitism per se, but at the same time introducing behaviours that are considered indicative of poor welfare, would not be a desirable side effect of medicinal plant administration.

However, it is not just the antiparasitic and antinutritional effects of medicinal plants that should be taken into account when considering their use for parasite control. An emerging aspect of the potential benefits of medicinal plants is their contribution towards the development of host resistance to parasites. There is recent evidence suggesting that the consumption of medicinal plants or plant extracts has improved the immune response of parasitised hosts, by increasing the number of specific effector cells (Huffman et al., Reference Huffman, Gotoh, Turner, Hamai and Yoshida1997; Niezen et al., Reference Niezen, Charleston, Robertson, Shelton, Waghorn and Green2002; Tzamaloukas et al., Reference Tzamaloukas, Athanasiadou, Kyriazakis, Huntley and Jackson2006). Consequently, in addition to the antiparasitic and antinutritional effects of medicinal plants on host performance and behaviour, the immunomodulatory effects of plants are another benefit of the consumption of medicinal plants. To date, all such effects of medicinal plants have been mostly described in response to parasites. The possibility that the improvement in the immunity is generic, which would offer an added benefit to the well being of the host, cannot be disregarded and requires further investigation.

There is currently a lot of controversy surrounding the evaluation of the activity and the role of medicinal plants for parasite control. Parasitologists have recommended that threshold points should be established, below which the efficacy of medicinal plants for parasite control should not be considered. It has been suggested that such threshold points should be similar to those set for commercial anthelmintics (Vercruysse and Claerebout, Reference Vercruysse and Claerebout2001). However, because of the various different aspects that need to be considered to justify the use of medicinal plants for parasite control, as these have been discussed above, it is disputable whether we should have the same set of criteria as those used for the evaluation of the anthelmintics. It has recently been suggested that rather than evaluating the anthelmintic efficacy of plant extracts per se, it would be more acceptable to justify their use based on the economic threshold on efficacy (Ketzis et al., Reference Ketzis, Vercruysse, Stromberg, Larsen, Athanasiadou and Houdijk2006). We are in agreement with this view; when considering medicinal plants, it is sensible to estimate the overall benefit or the cost of their use at all different levels, prior of making the evaluation of their applicability. We should be looking for evidence whether the use of medicinal plants can improve the resilience/resistance of hosts, their well-being and the production level. We should also be looking at indicators of sustainability of their anthelmintic activity prior incorporating medicinal plants in parasite control. Currently, there is no published evidence on the development of resistance to any type of medicinal plants. It is possible that due to the lower anthelmintic efficiency of plants compared with the anthelmintic drugs, selection pressure on the resistant parasite population is not strong. Alternatively, anthelmintic drugs seem to be carrying out their anthelmintic activity by influencing a single mechanism in the parasite (Geary, Reference Geary2005), whereas plant compounds may demonstrate a variety of effects, as discussed earlier. Consequently, the expectation would be that resistance will develop at lower rates, compared with anthelmintics, if developed at all. Generation of evidence on the mechanisms of action of specific compounds will contribute towards making safe assumptions on the development of resistance to medicinal plants.

Conclusions

Methodological shortcomings in the various approaches used to describe the anthelmintic properties of medicinal plants have led to the debate about the consistency of their activity and thus their potential use for parasite control. We believe that progress can be achieved by considering the various aspects of medicinal plants together and thus exploit their complementarity. Without a doubt, coordinated effort should be directed towards the experimental validation of plants with medicinal properties deriving from ethnoveterinary sources. Table 1 lists the most common misconceptions and the facts related to the anthelmintic activity of the medicinal plants. Action is required to achieve reproducible evidence on their anthelmintic activity and thus have it appreciated by the worldwide scientific community. We emphasise the need for incorporating additional measurements on ongoing research, such as performance measurements, indicators of immunity and behavioural observations when considering the potential of such plants. This will lead to a more holistic investigation to the properties of plants with antiparasitic properties and influence their potential exploitation in livestock systems.

Table 1 Popular beliefs, facts and action required to exploit the medicinal plants and their anthelmintic properties to their full potential

Acknowledgements

Part of the work presented here has been performed in collaboration with our colleagues from the Parasitology Division at the Moredun Research Institute and was supported by the European Commision, project QLRT-2000-01843, as part of a collaborative programme between Scotland, France, Spain, Sweden and The Netherlands. SAC receives financial support from the Scottish Executive Environment and Rural Affairs Department.

References

Ademola, IO, Idowu, SO 2006. Anthelmintic activity of Leucaena leucocephala seed extract on Haemonchus contortus-infective larvae. The Veterinary Record 158, 485486.CrossRefGoogle ScholarPubMed
Akhtar, MS, Ahmad, I 1992. Comparative efficacy of Mallotus Philippinensis fruit (Kamala) or Nilzan (R) drug against gastrointestinal cestodes in beetal goats. Small Ruminant Research 8, 121128.CrossRefGoogle Scholar
Akhtar, MS, Iqbal, Z, Khan, MN, Lateef, M 2000. Anthelmintic activity of medicinal plants with particular reference to their use in animals in the Indo-Pakistan subcontinent. Small Ruminant Research 38, 99107.CrossRefGoogle Scholar
Applebaum, SW, Birk, Y 1979. Saponins. In Herbivores. Their interactions with secondary plant metabolites (ed. GA Rosental and TH Janzen), pp. 539566. Academic Press, London, UK.Google Scholar
Athanasiadou, S, Kyriazakis, I 2004. Plant secondary metabolites: antiparasitic effects and their role in ruminant production systems. Proceedings of the Nutrition Society 63, 631639.CrossRefGoogle ScholarPubMed
Athanasiadou, S, Kyriazakis, I, Jackson, F, Coop, RL 2000. Consequences of long-term feeding with condensed tannins on sheep parasitised with Trichostrongylus colubriformis. International Journal for Parasitology 30, 10251033.CrossRefGoogle ScholarPubMed
Athanasiadou, S, Kyriazakis, I, Jackson, F, Coop, RL 2001a. Direct anthelmintic effects of condensed tannins towards different gastrointestinal nematodes of sheep: in vitro and in vivo studies. Veterinary Parasitology 99, 205219.CrossRefGoogle ScholarPubMed
Athanasiadou, S, Kyriazakis, I, Jackson, F, Coop, RL 2001b. The effects of condensed tannins supplementation of foods with different protein content on parasitism, food intake and performance of sheep infected with Trichostrongylus colubriformis. British Journal of Nutrition 86, 697706.CrossRefGoogle ScholarPubMed
Athanasiadou, S, Tzamaloukas, O, Kyriazakis, I, Jackson, F, Coop, RL 2005. Testing for direct anthelmintic effects of bioactive forages against Trichostrongylus colubriformis in grazing sheep. Veterinary Parasitology 127, 233243.CrossRefGoogle ScholarPubMed
Barrau, E, Fabre, N, Fouraste, I, Hoste, H 2005. Effect of bioactive compounds from Sainfoin (Onobrychis viciifolia Scop.) on the in vitro larval migration of Haemonchus contortus: role of tannins and flavonol glycosides. Parasitology 131, 531538.CrossRefGoogle ScholarPubMed
Biswas, K, Chattopadhyay, I, Banerjee, RK, Bandyopadhyay, U 2002. Biological activities and medicinal properties of neem (Azadirachta indica). Current Science 82, 13361345.Google Scholar
Bunyeth H and Preston TR 2006. Growth performance and parasite infestation of goats given cassava leaf silage, or sun-dried cassava leaves, as supplement to grazing in lowland and upland regions of Cambodia. Livestock Research for Rural Development 18, article #28. Retrieved January 15, 2007, from http://www.cipav.org.co/lrrd/lrrd18/2/buny18028.htm.Google Scholar
Butter, NL, Dawson, JM, Wakelin, D, Buttery, PJ 2001. Effect of dietary condensed tannins on gastrointestinal nematodes. Journal of Agricultural Science 137, 461469.CrossRefGoogle Scholar
Chandrawathani, P, Brelin, D, Nor Fasihah, AS, Adnan, M, Jamnaah, O, Sani, RA, Höglund, J, Waller, P 2002. Evaluation of the neem tree (Azadirachta indica) as a herbal anthelmintic for nematode parasite control in small ruminants in Malaysia. Tropical Biomedicine 19, 4148.Google Scholar
Chandrawathani, P, Chang, KW, Nurulaini, R, Waller, PJ, Adnan, M, Zaini, CM, Jamnah, O, Khadijah, S, Vincent, N 2006. Daily feeding of fresh neem leaves (Azadirachta indica) for worm control in sheep. Tropical Biomedicine 23, 2330.Google ScholarPubMed
Conn, EE 1979. Cyanide and cyanogenic glycosides. In Herbivores. Their interactions with secondary plant metabolites (ed. GA Rosental and TH Janzen), pp. 387412. Academic Press, London, UK.Google Scholar
Costa, CTC, Bevilaqua, CML, Maciel, MV, Camurca-Vasconcelos, ALF, Morais, SM, Monteiro, MVB, Farias, VM, da Silva, MV, Souza, MMC 2006. Anthelmintic activity of Azadirachta indica A. Juss against sheep gastrointestinal nematodes. Veterinary Parasitology 137, 306310.CrossRefGoogle ScholarPubMed
Dawson, JM, Buttery, PJ, Jenkins, D, Wood, CD, Gill, M 1999. Effects of dietary Quebracho tannin on nutrient utilisation and tissue metabolism in sheep and rats. Journal of the Science of Food and Agriculture 79, 14231430.3.0.CO;2-8>CrossRefGoogle Scholar
De Amorin, A, Borba, HR, Carauta, JPP, Lopes, D, Kaplan, MAC 1999. Anthelmintic activity of the latex of Ficus species. Journal of Etnnopharmacology 64, 255258.CrossRefGoogle ScholarPubMed
Fajimi, AK, Taiwo, AA 2005. Herbal remedies in animal parasitic diseases in Nigeria: a review. African Journal of Biotechnology 4, 303307.Google Scholar
Franco, CIF, Morais, LCSL, Quintans-Junior, LJ, Almeida, RN, Antoniolli, AR 2005. CNS pharmacological effects of the hydroalcoholic extract of Sida cordifolia L. leaves. Journal of Ethnopharmacology 98, 275279.CrossRefGoogle ScholarPubMed
Garcia, D, Leiro, J, Delgado, R, Sanmartin, ML, Ubeira, FM 2003. Mangifera indica L. extract (Vimang) and mangiferin modulate mouse humoral immune responses. Phytotherapy Research 17, 11821187.CrossRefGoogle ScholarPubMed
Geary, TG 2005. Ivermectin 20 years on: maturation of a wonder drug. Trends in Parasitology 21, 530532.CrossRefGoogle ScholarPubMed
Githiori, JB, Hoglund, J, Waller, PJ, Baker, RL 2002. Anthelmintic activity of preparations derived from Myrsine africana and Rapanea melanophloeos against the nematode parasite, Haemonchus contortus, of sheep. Journal of Ethnopharmacology 80, 187191.CrossRefGoogle ScholarPubMed
Githiori, JB, Hoglund, J, Waller, PJ, Baker, RL 2003a. The anthelmintic efficacy of the plant, Albizia anthelmintica, against the nematode parasites Haemonchus contortus of sheep and Heligmosomoides polygyrus of mice. Veterinary Parasitology 116, 2334.CrossRefGoogle ScholarPubMed
Githiori, JB, Hoglund, J, Waller, PJ, Baker, RL 2003b. Evaluation of anthelmintic properties of extracts from some plants used as livestock dewormers by pastoralist and smallholder farmers in Kenya against Heligmosomoides polygyrus infections in mice. Veterinary Parasitology 118, 215226.CrossRefGoogle ScholarPubMed
Githiori, JB, Hoglund, J, Waller, PJ, Baker, RL 2004. Evaluation of anthelmintic properties of some plants used as livestock dewormers against Haemonchus contortus infections in sheep. Parasitology 129, 245253.CrossRefGoogle ScholarPubMed
Githiori, JB, Athanasiadou, S, Thamsborg, SM 2006. Use of plants in novel approaches for control of gastrointestinal helminths in livestock with emphasis on small ruminants. Veterinary Parasitology 139, 308320.CrossRefGoogle ScholarPubMed
Guarrera, PM 1999. Traditional antihelmintic, antiparasitic and repellent uses of plants in Central Italy. Journal of Ethnopharmacology 68, 183192.CrossRefGoogle ScholarPubMed
Hagerman, AE, Butler, LG 1991. Tannins and lignins. In Herbivores. Their interaction with secondary plant metabolites (ed. GA Rosental and TH Janzen), pp. 355376. Academic Press, San Diego, USA.CrossRefGoogle Scholar
Hammond, JA, Fielding, D, Bishop, SC 1997. Prospects for plant anthelmintics in tropical veterinary medicine. Veterinary Research Communications 21, 213228.CrossRefGoogle ScholarPubMed
Herrera-Ruiz, M, Jimenez-Ferrer, JE, De Lima, TCM, Viles-Montes, D, Perez-Garcia, D, Gonzalez-Cortazar, M, Tortoriello, J 2006. Anxiolytic and antidepressant-like activity of a standardized extract from Galphimia glauca. Phytomedicine 13, 2328.CrossRefGoogle ScholarPubMed
Hordegen, P, Hertzberg, H, Heilmann, J, Langhans, W, Maurer, V 2003. The anthelmintic efficacy of five plant products against gastrointestinal trichostrongylids in artificially infected lambs. Veterinary Parasitology 117, 5160.CrossRefGoogle ScholarPubMed
Hoste, H, Jackson, F, Athanasiadou, S, Thamsborg, SM, Hoskin, SO 2006. The effects of tannin-rich plants on parasitic nematodes in ruminants. Trends in Parasitology 22, 253261.CrossRefGoogle ScholarPubMed
Houdijk, JGM, Athanasiadou, S 2003. Direct and indirect effects of host nutrition on ruminant gastrointestinal nematodes. In Matching herbivore nutrition to ecosystems biodiversity (ed. L t’Mannetje, L Ramirez-Aviles, Sandoval-Castro and JC Ku-Vera), pp. 213236. Universita Autonoma de Yucatan, Yucatan, Mexico.Google Scholar
Hounzangbe-Adote, MS, Zinsou, FE, Hounpke, V, Moutairou, K, Hoste, H 2005. In vivo effects of Fagara leaves on sheep infected with gastrointestinal nematodes. Tropical Animal Health and Production 37, 205214.CrossRefGoogle ScholarPubMed
Huffman, MA, Gotoh, S, Turner, LA, Hamai, M, Yoshida, K 1997. Seasonal trends in intestinal nematode infection and medicinal plant use among chimpanzees in the Mahale Mountains, Tanzania. Primates 38, 111125.CrossRefGoogle Scholar
Hutchings, MR, Judge, J, Gordon, IJ, Athanasiadou, S, Kyriazakis, I 2006. Use of trade-off theory to advance understanding of herbivore–parasite interactions. Mammal Review 36, 116.CrossRefGoogle Scholar
Ignacio, SRN, Ferreira, JLP, Almeida, MB, Kubelka, CF 2001. Nitric oxide production by murine peritoneal macrophages in vitro and in vivo treated with Phyllanthus tenellus extracts. Journal of Ethnopharmacology 74, 181187.CrossRefGoogle ScholarPubMed
International Institute of Rural Reconstruction 1994. Ethnoveterinary medicine in Asia: an information kit on traditional animal health care practices. International Institute of Rural Reconstruction (IIRR), second edition. Silang, Cavite, Philippines.Google Scholar
Iqbal, Z, Lateef, M, Ashraf, M, Jabbar, A 2004. Anthelmintic activity of Artemisia brevifolia in sheep. Journal of Ethnopharmacology 93, 265268.CrossRefGoogle ScholarPubMed
Jackson, F, Coop, RL 2000. The development of anthelmintic resistance in sheep nematodes. Parasitology 120, S95S107.CrossRefGoogle ScholarPubMed
Ketzis, JK, Taylor, A, Bowman, DD, Brown, DL, Warnick, LD, Erb, HN 2002. Chenopodium ambrosioides and its essential oil as treatments for Haemonchus contortus and mixed adult-nematode infections in goats. Small Ruminant Research 44, 193200.CrossRefGoogle Scholar
Ketzis, JK, Vercruysse, J, Stromberg, BE, Larsen, M, Athanasiadou, S, Houdijk, JGM 2006. Evaluation of efficacy expectations for novel and non-chemical helminth control strategies in ruminants. Veterinary Parasitology 139, 321335.CrossRefGoogle ScholarPubMed
Kyriazakis, I, Emmans, GC 1992. Selection of a diet by growing pigs given choices between foods differing in contents of protein and rapeseed meal. Appetite 19, 121132.CrossRefGoogle ScholarPubMed
Lange, KC, Olcott, DD, Miller, JE, Mosjidis, JA, Terrill, TH, Burke, JM, Kearney, MT 2006. Effect of Sericea lespedeza (Lespedeza cuneata) fed as hay, on natural and experimental Haemonchus contortus infections in lambs. Veterinary Parasitology 141, 273278.CrossRefGoogle ScholarPubMed
Marley, CL, Cook, R, Keatinge, R, Barrett, J, Lampkin, NH 2003. The effect of birdsfoot trefoil (Lotus corniculatus) and chicory (Cichorium intybus) on parasite intensities and performance of lambs naturally infected with helminth parasites. Veterinary Parasitology 112, 147155.CrossRefGoogle ScholarPubMed
Max, RA, Wakelin, D, Dawson, JM, Kimambo, AE, Kassuku, AA, Mtenga, LA, Craigon, J, Buttery, PJ 2005. Effect of quebracho tannin on faecal egg counts and worm burdens of temperate sheep with challenge nematode infections. Journal of Agricultural Science 143, 519527.CrossRefGoogle Scholar
Milgate, J, Roberts, DCK 1995. The nutritional and biological significance of saponins. Nutrition Research 15, 12231249.CrossRefGoogle Scholar
Min, BR, Pomroy, WE, Hart, SP, Sahlu, T 2004. The effect of short-term consumption of a forage containing condensed tannins on gastro-intestinal nematode parasite infections in grazing wether goats. Small Ruminant Research 51, 279283.CrossRefGoogle Scholar
Molan, AL, Duncan, AJ, Barry, TN, McNabb, WC 2003a. Effects of condensed tannins and crude sesquiterpene lactones extracted from chicory on the motility of larvae of deer lungworm and gastrointestinal nematodes. Parasitology International 52, 209218.CrossRefGoogle ScholarPubMed
Molan, AL, Meagher, LP, Spencer, PA, Sivakumaran, S 2003b. Effect of flavan-3-ols on in vitro egg hatching, larval development and viability of infective larvae of Trichostrongylus colubriformis. International Journal for Parasitology 33, 16911698.CrossRefGoogle ScholarPubMed
Mueller-Harvey, I 2006. Unravelling the conundrum of tannins in animal nutrition and health. Journal of the Science of Food and Agriculture 86, 20102037.CrossRefGoogle Scholar
Mueller-Harvey, I, McAllan, AB 1992. Tannins: their biochemistry and nutritional properties. Advances in Plant Cell Biochemistry and Biotechnology 1, 151217.Google Scholar
Nundkumar, N, Ojewole, JAO 2002. Studies on the antiplasmodial properties of some South African medicinal plants used as antimalarial remedies in Zulu folk medicine. Methods and Findings in Experimental and Clinical Pharmacology 24, 397401.CrossRefGoogle ScholarPubMed
Niezen, JH, Waghorn, GC, Charleston, WAG 1998. Establishment and fecundity of Ostertagia circumcincta and Trichostrongylus colubriformis in lambs fed lotus (Lotus pedunculatus) or perennial ryegrass (Lolium perenne). Veterinary Parasitology 78, 1321.CrossRefGoogle ScholarPubMed
Niezen, JH, Charleston, WAG, Robertson, HA, Shelton, D, Waghorn, GC, Green, R 2002. The effect of feeding sulla (Hedysarum coronarium) or lucerne (Medicago sativa) on lamb parasite burdens and development of immunity to gastrointestinal nematodes. Veterinary Parasitology 105, 229245.CrossRefGoogle ScholarPubMed
Paolini, V, Bergeaud, JP, Grisez, C, Prevot, F, Dorchies, P, Hoste, H 2003a. Effects of condensed tannins on goats experimentally infected with Haemonchus contortus. Veterinary Parasitology 113, 253261.CrossRefGoogle ScholarPubMed
Paolini, V, Frayssines, A, De La Farge, F, Dorchies, P, Hoste, H 2003b. Effects of condensed tannins on established populations and on incoming larvae of Trichostrongylus colubriformis and Teladorsagia circumcincta in goats. Veterinary Research 34, 331339.CrossRefGoogle ScholarPubMed
Paolini, V, Fouraste, I, Hoste, H 2004. In vitro effects of three woody plant and sainfoin extracts on 3rd stage larvae and adult worms of three gastrointestinal nematodes. Parasitology 129, 6977.CrossRefGoogle ScholarPubMed
Pultrini, ADM, Galindo, LA, Costa, M 2006. Effects of the essential oil from Citrus aurantium L. in experimental anxiety models in mice. Life Sciences 78, 17201725.CrossRefGoogle ScholarPubMed
Reed, JD 1995. Nutritional toxicology of tannins and related polyphenols in forage legumes. Journal of Animal Science 73, 15161528.CrossRefGoogle ScholarPubMed
Rittner, U, Reed, JD 1992. Phenolics and in vitro degradability of protein and fibre in west African Browse. Journal of the Science of Food and Agriculture 58, 2128.CrossRefGoogle Scholar
Satou, T, Koga, M, Matsuhashi, R, Koike, K, Tada, I, Nikaido, T 2002. Assay of nematocidal activity of isoquinoline alkaloids using third stage larvae of Strongyloides ratti and S. venezuelensis. Veterinary Parasitology 104, 131138.CrossRefGoogle ScholarPubMed
Satrija, F, Nansen, P, Bjorn, H, Murtini, S, He, S 1994. Effect of papaya latex against Ascaris suum in naturally infected pigs. Journal of Helminthology 68, 343346.CrossRefGoogle ScholarPubMed
Shaik, SA, Terrill, TH, Miller, JE, Kouakou, B, Kannan, G, Kallu, RK, Mosjidis, JA 2004. Effects of feeding Sericea lespedeza hay to goats infected with Haemonchus contortus. South African Journal of Animal Science 34, 248250.Google Scholar
Sokerya S and Preston TR 2003. Effect of grass or cassava foliage on growth and nematode parasite infestation in goats fed low or high protein diets in confinement. Livestock Research for Rural Development 15 (8). Retrieved January 15, 2007, from http://www.cipav.org.co/lrrd/lrrd15/8/kery158.htm.Google Scholar
Subapriya, R, Nagini, S 2005. Medicinal properties of neem leaves: a review. Current Medical Chemical – Anti-cancer Agents 5, 149156.CrossRefGoogle ScholarPubMed
Stepek, G, Buttle, DJ, Duce, IR, Lowe, A, Behnke, JM 2005. Assessment of the anthelmintic effect of natural plant cysteine proteinases against the gastrointestinal nematode, Heligmosomoides polygyrus, in vitro. Parasitology 130, 203211.CrossRefGoogle ScholarPubMed
Stepek, G, Lowe, AE, Buttle, DJ, Duce, IR, Behnke, JM 2006. In vitro and in vivo anthelmintic efficacy of plant cysteine proteinases against the rodent gastrointestinal nematode, Trichuris muris. Parasitology 132, 681689.CrossRefGoogle ScholarPubMed
Tagboto, S, Townson, S 2001. Antiparasitic properties of medicinal plants and other natural occurring products. Advances in Parasitology 50, 199295.CrossRefGoogle ScholarPubMed
Taylor, CE, Murant, AF 1966. Nematicidal activity of aqueous extracts from raspberry canes and roots. Nematologica 12, 488494.Google Scholar
Tzamaloukas, O, Athanasiadou, S, Kyriazakis, I, Jackson, F, Coop, RL 2005. The consequences of short-term grazing of bioactive forages on established adult and incoming larvae populations of Teladorsagia circumcincta in lambs. International Journal for Parasitology 35, 329335.CrossRefGoogle ScholarPubMed
Tzamaloukas, O, Athanasiadou, S, Kyriazakis, I, Huntley, JF, Jackson, F 2006. The effect of chicory (Cichorium intybus ) and sulla (Hedysarum coronarium) on larval development and mucosal cell responses of growing lambs challenged with Teladorsagia circumcincta. Parasitology 132, 419426.CrossRefGoogle ScholarPubMed
Vercruysse, J, Claerebout, E 2001. Treatment vs non-treatment of helminth infections in cattle: defining the threshold. Veterinary Parasitology 98, 195214.CrossRefGoogle ScholarPubMed
Waller, PJ, Bernes, G, Thamsborg, SM, Sukura, A, Richter, SH, Ingebrigtsen, K, Hoglund, J 2001. Plants as de-worming agents of livestock in the Nordic Countries: Historical perspective, popular beliefs and prospects for the future. Acta Veterinaria Scandinavica 42, 3144.CrossRefGoogle ScholarPubMed
Waterman, PG 1988. Tannins – chemical ecology in action. Phytochemistry 12, R12R13.Google Scholar
Waterman, PG 1992. Roles for secondary metabolites in plants. Ciba Foundation Symposia 171, 255275.Google ScholarPubMed
Waterman, PG, Mole, S 1994. Extraction and chemical quantification. In Analysis of Phenolic Plant Metabolites (ed. JH Lawton and GE Likens), pp. 66103. Blackwell Scientific Publication, Oxford, UK.Google Scholar
Figure 0

Table 1 Popular beliefs, facts and action required to exploit the medicinal plants and their anthelmintic properties to their full potential