1. Introduction
Launaea taraxacifolia (Asteraceae), also known as wild lettuce, is found mainly in tropical Africa. The plant over the years has been reported to possess many ethnopharmacological properties on disease conditions such as water retention disorders, conjunctivitis, yaws, improper bone fixation in infants, and diabetes mellitus [1–3]. The World Health Organization (WHO) has reported that between 70% and 95% of individuals in developing countries use traditional medicine also known as “complementary”, “alternative”, or “nonconventional” medicines for disease management [4]. The report added that, in Africa and the Western World, the use of traditional medicine is on the rise.
Despite the increase in patronage of traditional medicines, evidence-based scientific data on plants used as medicines are rather scattered. This emphasizes the need to collate relevant scientific and evidence-based information available to support the medicinal uses of some of these plant medicines to aid further research. Currently no topical review exists on Launaea taraxacifolia, thus necessitating the need to gather data available on the plant. This systematic review aimed to provide a comprehensive and updated information on the botanical aspects, ethnopharmacological uses, nutritional, phytochemistry, pharmacological activities, and toxicological assessment of extracts of Launaea taraxacifolia leaves to explore its therapeutic potential and evaluate future research prospects.
2. Method of Literature Search
An online literature search was performed in January 2018, on ScienceDirect, PubMed, and Google Scholar databases using the keywords Launaea taraxacifolia and Lactuca taraxacifolia with a time limit of papers published from 1985 up to 2018 in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines. The search approach is illustrated in a flow diagram (Figure 1). The article selection was initially based on the following inclusion criteria: articles published in English and articles with keyword in the title, abstract or full text, and studies with isolated compounds from the plant. Articles that were retrieved were manually reviewed with the goal of identifying and excluding works that did not fit the inclusion criteria described, articles with repeated data, and duplication by the search engines.
[figure omitted; refer to PDF]3. Results
3.1. Taxonomy, Ethnic Names, and Ethnopharmacological Importance of Plant
Launaea taraxacifolia belongs to the domain Eukaryota, kingdom Plantae, and subkingdom Viridae Plantae. It is found in the Family Asteraceae or Compositae. It is of the genus Launaea and species taraxacifolia [5]. Table 1 contains various ethnic names by which the plant is called in different dialects in West Africa. Synonyms of the plant names include Lactuca taraxacifolia (Willd.) Schumach. ex Hornem, Lactuca taraxacifolia Schum. & Thonn., and Sonchus taraxacifolius Willd. The plant has several medicinal uses (Table 2). Its ethnomedicinal popularity has necessitated the various biological activities of the plant to be documented in numerous scientific research publications.
Table 1
Ethnic names of Launaea taraxacifolia plant in some African countries.
| People | Ethnic Group | Vernacular names | References |
|---|---|---|---|
| Ghana | Ewe (anlo) | Aŋòto | [5] |
| Asante Twi | Dadedru | ||
| Akuapem Twi | Nne noa | ||
| Hausa | Namijin dayii | ||
| | |||
| Benin | Awonto | Cotafon; Watchi | [13, 14] |
| Holly; Yurouba | Gnanri | ||
| Fon; Machi | Yantotoé | ||
| Tchabè | Katakpa | ||
| Pèda; xwla | Lôto | ||
| Fe; Idaacha; Idasha | Ôdôdô | ||
| Saxwè | Wonto; Lanto | ||
| Adja | Wontou | ||
| | |||
| Nigeria | Yoruba | Efo yanrin | [5] |
| Ibo | Ugu | ||
| | |||
| Sierra Leone | Kissi | Bekuhoa-pomboɛ | [13, 14] |
| Mende | Kipo | ||
| Krio | ɛfo-nyori | ||
| Temne | a-mothsẻra | ||
Table 2
Ethnopharmacological relevance of Launaea taraxacifolia.
| Part of plant | Reported Disease Managed | References |
|---|---|---|
| Leaves | Wound, sore throat, abscess | [1, 11, 14] |
| Leaves | Scorpion/ snake bite | [12, 14, 42] |
| Leaves | Anemia | [14, 43] |
| Leaves | Menstrual Cramps | [1, 14] |
| Leaves | Tetter, tinea, mycosis | [1] |
| Leaves | Typhoid fever | [11, 14] |
| Leaves | Malaria | [1, 11, 14] |
| Leaves | Convulsion attack | [14] |
| Leaves | Hypertension | [11, 13, 14, 44] |
| Leaves | Diabetes mellitus | [1, 11, 13–15, 44] |
| Leaves | Cough | [14] |
| Leaves | Breast milk secretion | [14] |
| Leaves | Indigestion, Constipation | [1, 14] |
| Fresh milky latex | Mosquito repellent | [11] |
| Fresh milky latex | Conjunctivitis | [42] |
| Leaves | Proper bone fixation in infants | [1, 11] |
| Fresh aerial part | Appetite booster | [11] |
| Leaves | Hepatitis | [1, 13, 44, 45] |
| Leaves | Bronchitis | [1] |
| Leaves | Mastitis | [1] |
| Leaves | Atherosclerosis | [1, 44] |
| Leaves | Chronic osteoarthritis | [1] |
| Leaves | Rheumatism | [1] |
| Leaves | Gallstones | [1] |
| Leaves | Pneumonia | [1] |
| Leaves | Cancer / tumors | [38] |
3.2. Botany and Ecological Distribution
Launaea taraxacifolia is a tropical perennial plant that has a creeping root system, with its leaves at the base of an erect stem, which is about 1-3m high. The leaves are arranged in a rosette form of 3-5 and may sometimes be crowned with golden yellow corollas, which produces 7-8 nm air-borne seeds. Launaea taraxacifolia is unique. It is the only species in the Asteraceae family without any trichome. The leaf, stem, and nodes are potential explants for regeneration of Launaea taraxacifolia [6–10]. A picture of the leaves with flowers is shown in Figure 2. The plant is predominant in tropical African countries of Ghana, Nigeria, Senegal, Sierra Leone, Benin, and Tanzania with the Ethiopian highlands being known as its place of origin. It thrives at banks of water bodies, waste dumping places, and backyards [11, 12].
[figure omitted; refer to PDF]3.3. Nutraceutical and Phytochemical Composition
The leaf of the plant is consumed by indigenes of Benin, Ghana, Nigeria, Sierra Leone, and other tropical countries [11, 13–15]. It may be eaten as salads, cooked as sauces, and eaten as vegetable soup regularly during pregnancy. The plant, which forms a rich part of the African diet, is endowed with high levels of nutrients. The leaves have been reported to contain substantial amounts of macro- and micronutrients that can compare well with other conventional edible leaves. The leaves of Launaea taraxacifolia are endowed with saponins, terpenoids, cardiac glycosides, steroids, tannins, flavonoids, leucoanthocyanins, phenolic acids, ascorbic acid, lycopene, and β-carotene [16–21]. Ololade et al. [22] have isolated 47 compounds from methanolic extract of the Launaea taraxacifolia leaves. The most abundant chemical components found were palmitic acid, methyl-11-octadecenoate, erythritol, glycerol, linolelaidic acid methyl ester, and phytol. A long chain alcohol, 1-hexacosanol, has also been discovered to be present in the leaves [23]. Some structures of compounds isolated from the leaves of Launaea taraxacifolia are shown on Figure 3.
[figures omitted; refer to PDF]
3.4. Pharmacological Activities
Research over the years has revealed that Launaea taraxacifolia possesses important pharmacological activities. These include antioxidant, hypolipidaemic, antilipid peroxidation, neuroprotective, anticancer, antimalarial, antiarthritic/anti-inflammatory, antibacteria, and cardioprotective and DNA protecting activities [24–36]. Table 3 provides an overview of reported experimental based evidence to support pharmacologic and toxicological activities of Launaea taraxacifolia.
Table 3
A summary of reported pharmacological activities of Launaea taraxacifolia.
| Study Model | Activity | IC50/Effective dosage | Preparation | Reference |
|---|---|---|---|---|
| In vitro | Antioxidant | DPPH(16.18μg/m) | Methanolic | [24] |
| In vivo | Antioxidant | 400mg/kg bwt | Ethanolic | [25] |
| In vitro | Antioxidant | DPPH(6.59mg/ml) | Aqueous | [26] |
| DPPH(3.29mg/ml) | Ethanolic | [26] | ||
| In vitro | Lipid peroxidation | 23μg/ml | Methanolic | [24] |
| In vitro | Hypolipidaemic | 20 μg/μl | Ethanol-aqueous | [27] |
| In vivo | Hypolipidaemic | Cholesterol (500mg/kg) | Ethanol-aqueous | [28] |
| In vivo | Gentamicin protective effect | 300, 500mg/kg | Ethanol-aqueous | [29] |
| In vitro | HepG2 cell viability | 20μg/μl | Ethanol-aqueous | [27] |
| In vivo | Neuroprotective | 400mg/kg | Ethanolic | [25] |
| In vitro | Anti-cancer | - | Aqueous | [30] |
| In vivo | Anti-cisplatin damage | 100, 400mg/kg | Aqueous | [31, 32] |
| In vitro | Anti-arthritic | 0.25mg/ml | Methanolic | [22] |
| In vitro | Anti-bacteria | 250,500,1000μg/ml | Methanolic | [22] |
| In vitro | Antibacteria | 1mg/ml | Methanol-dichloromethane | [23] |
| In vitro | DNA damage protection | 20mg/ml | Methanolic | [24] |
| In vivo | Anti-malaria | 200mg/kg | Methanolic | [33] |
| In vitro | Anti-malaria | 21.55μg/μl | Chloroform | [34] |
| In vivo | Cardioprotective | 200mg/kg | Aqueous | [46] |
Antioxidant Activity. Reactive oxygen species (ROS) and Reactive Nitrogen Species (RNS) are free radicals generated by the body from normal physiological activities in body systems as well as exposure to conditions such as radiations, drugs, and pollutants. Free radicals may alter the generic structure of endogenous lipids, proteins, DNA, and other important molecules that may lead to tissue damage, triggering many diseases in that regard. The body ameliorates the effect of free radicals by synthesizing endogenous molecules, which mop up these radicals [37]. Studies have demonstrated that Launaea taraxacifolia leaf extract has antioxidant power to protect against oxidative stress. A study conducted by Koukoui et al. [27] highlighted that the oxidizing power of phorbol myristic acetate (PMA), an inducer of ROS such as the superoxide radical, was annulled in PLB985 cell lines by Launaea taraxacifolia leaf extract. Studies conducted by Ololade et al. [22], Borokini and Labunmi [26], and Adinortey et al. [24] also confirmed the antioxidant effect of Launaea taraxacifolia against nitric oxide (NO), 2,2-diphenyl-1-picrylhydrazyl (DPPH), and hydroxyl (OH) radicals. These activities were reported to be significant due to the high content of phenolic acids and flavonoids detected in the leaves.
Antilipid Peroxidation Property. Lipid peroxidation is oxidative damage, which is normally initiated by the attack of free radicals in cellular oxidative stress. Phospholipids, lipoproteins, and other lipid-containing molecules are normally prone to peroxidation. It results in the formation of aldehydes, ketones, alkanes, carboxylic acids, and polymerization products. Malondialdehyde (MDA), an example of such reactive aldehydes, is used as a marker to determine lipid peroxidation. It forms a coloured complex with thiobarbituric acid (TBA). This principle has been used in studies conducted by Adinortey et al. [24] which demonstrated that Launaea taraxacifolia inhibits lipid peroxidation by 52 % with an IC50 value of 79 μg/ml. This would imply that Launaea taraxacifolia could be considered as a potential agent for managing lipid peroxidation during cellular oxidative stress.
Hypolipidaemic Activity. Steatosis is a clinical condition characterized by abnormal retention of lipids within a cell due to impairment of normal synthesis and degradation of fats. This abnormal lipid accumulation is often seen in individuals with obesity, hepatitis C, etc. Launaea taraxacifolia leaves have been documented to have hypolipidaemic effects [28]. The investigators showed that lipid accumulation induced with 0.1mM oleic acid in HepG2 cell lines was reversed when the cell lines were treated with 20 μg/μl of 50 % hydroethanolic extract of the plant. An in vivo study with Wistar rats also showed that Launaea taraxacifolia significantly decreased blood cholesterol and triglycerides levels significantly [28].
Neuroprotective Activity. Metals and metallic compounds interfere with functions of the central nervous [25]. Histological and biochemical studies reveal that Launaea taraxacifolia displays brain protective effects against lead acetate and mercuric chloride induced oxidative stress. Lead acetate and mercuric chloride caused significant (p<0.0.05) reduction of behavioural parameters such as reduction in forelimb grip strength. They also induced lipid peroxidation, reduced glutathione (GSH) level, and increased superoxide dismutase (SOD) activity. The metals also altered the microanatomy of the rat regio III cornu ammonis and cerebellum when compared with the control. These changes were significantly ameliorated (p<0.0.05) in rats cotreated with ethanolic extract of L. taraxacifolia when compared with the rats treated with metals only [25, 36].
Anticancer Activity. In the quest to eliminate malignant cells, contemporary medicine and therapies aimed at controlling cancerous cells have yielded undesirable side effects. The need for natural alternative medicines has thus been desirable. Anticancer effect of L. taraxacifolia had been purported in ethnomedicinal reports without concrete scientific data [38]. Thomford et al. [30], in an in vitro study, reported the anticancer effect of L. taraxacifolia. Their study showed that L. taraxacifolia significantly inhibited growth of cancerous cells by downregulating genes that control cell cycle progression of the WHC01 esophageal cancer cells.
Anticisplatin Damage Activity. Cisplatin is a platinum complexed drug that is clinically used as an adjuvant of cancers and is aimed at annihilating tumor cells. Cisplatin destroys tumor cells via apoptosis or interference with transcription and/or DNA replication process. Documented side effects of this platinum complex include kidney and neuronal damage, hearing loss, and bone marrow suppression [39–41]. Aqueous extract of L. taraxacifolia was demonstrated to possess protective potential against cisplatin damage [31]. A study on hepatorenal histological toxicities induced by cisplatin in rats showed that L. taraxacifolia aqueous extracts ameliorated cisplatin-induced toxicities on liver and kidney. Dose-dependent ameliorations of these histopathologies were seen in L. taraxacifolia plus cisplatin-exposed groups whereas extracts-alone-treated rats had normal histoarchitecture. Hepatic (alanine aminotransferase, aspartate aminotransferase, and bilirubin) and renal (blood urea nitrogen, creatinine) parameters, which are markers of organ injury were elevated in cisplatin-exposed groups but with less severity in rats cotreated with L. taraxacifolia and cisplatin. Increased lipid peroxidation and decreased activities of superoxide dismutase, glutathione, and catalase were also observed in cisplatin-exposed groups. These effects were ameliorated with L. taraxacifolia extracts (100 mg and 400 mg). This report suggests that extract of L. taraxacifolia leaves reverses cisplatin-induced damage [31].
Micronuclei are markers that provide information about the integrity of chromosome structure during nuclear division. Adejuwon et al. [32] investigated the antigenotoxic potential of Launaea taraxacifolia (LT) aqueous leaf extract in bone marrow erythrocytes against cisplatin-induced micronuclei production in Wistar rats. Pretreatment of rats with L. taraxacifolia significantly reduced the increase in micronuclei polychromatic erythrocytes (MNPCEs) frequency and a concomitant decrease in polychromatic erythrocytes (PCEs) to normochromatic erythrocytes (NCEs) ratio in cisplatin-exposed groups in an extract dose-dependent fashion. The PCE/NCE ratio is an index of cytoprotection. This suggests that aqueous extract of the plant protects against cisplatin-induced damage.
Antimalaria Activity. Launaea taraxacifolia has been reported to be used as an antimalarial agent [1, 14]. The antiplasmodial value of L. taraxacifolia against Plasmodium berghei and the chloroquine-sensitive (D6) strain Plasmodium falciparum was investigated. The methanolic extract of L. taraxacifolia leaves administered to different groups of Swiss mice at 200 mg/kg per body weight significantly (p < 0.05) inhibited parasitemia and improved survival time as well as some haematological parameters in P. berghei-infected mice. Bello et al. [34], in an in vitro study, also showed that the chloroform extract of Launaea taraxacifolia produced 52% growth inhibition to P. falciparum yielding an IC50 value of 21.55μg/mL.
Antibacterial Activity. The bactericidal potential of Launaea taraxacifolia was investigated by Ololade et al. [22] and Tayman et al. [23]. Tayman and colleagues showed that three compounds isolated from L. taraxacifolia significantly inhibited the growth of Staphylococcus aureus. Their results were confirmed by Ololade et al. who showed that, in addition to Staphylococcus aureus, the plant extract also inhibits Escherichia coli, Enterococcus faecalis, Micrococcus varians, and Streptococcus agalactiae. Implicitly there is evidence to support the fact that Launaea taraxacifolia is a potential inhibitor of both gram positive and gram negative bacteria.
DNA Protective Ability. Electrophoresis has been used as a tool by researchers to determine distortions in native conformational structure of genetic materials such as DNA, RNA, and proteins. Adinortey and colleagues in 2018 [24] demonstrated that Launaea taraxacifolia leaf extract has DNA protective ability. In the study, it was observed that electrophoretic mobility was a function of DNA conformational structure. Using the UV-H2O2 model, the investigators showed that structurally damaged DNA without protection from Launaea taraxacifolia leaf extract had the slowest mobility on the gel compared to native supercoiled circular DNA. However, when 20mg/ml of Launaea taraxacifolia methanolic extract was incubated with DNA samples before UV irradiation, the electrophoretic mobility of the sample was faster and further compared to irradiated DNA sample with no extract. Cellular DNA damage had been associated with action of free radicals. UV-photolysis of H2O2 produces OH- radical which is responsible for damage of genetic materials as suggested by Guha et al. [47] who had documented that OH- radical binding to DNA leads to strand breakage and opening, deoxyribose sugar fragmentation, and nitrogenous base modification. The result of this study suggests that Launaea taraxacifolia confers protection on DNA against OH- radical induced by radiation and allows less distortion in the DNA structure upon irradiation.
Antiarthritic and Anti-Inflammatory Activities. Denaturation of proteins has been suggested by various researchers to be the cause of inflammation and rheumatoid arthritis. Evidence suggesting the role of ROS in rheumatoid arthritis has been on the rise. Research using Nrf2-knockout mouse has indicated that ROS are important factors in the breakdown of collagen in experimental arthritis [48–51]. Studies by Ololade et al. [22] suggested that methanolic extract of Launaea taraxacifolia leaves has antiarthritic/anti-inflammatory properties by preventing the denaturation of bovine serum albumin (BSA). The mechanism of denaturation involves alteration in electrostatic, hydrogen, hydrophobic, and disulphide bonding holding the globular structure of proteins in definite conformation. This activity has been associated with biologically active compounds and may be useful in drug development.
Cardioprotective Activity. Cardiovascular diseases (CVD) are estimated to be the leading causes of mortality and morbidity throughout the world. According to the World Heart Federation [52], more than 17.1 million lives are lost each year from cardiovascular diseases. Dyslipidemia, lack of physical activities, smoking, high levels of low-density lipoprotein (LDL) cholesterol, oxidative stress, and excessive alcohol consumption are some causes of CVDs. Natural products play a significant role in drug discovery process and are useful agents for mitigating the prevalence of CVDs. Green leafy vegetables, consumed all over the world, play a vital role after maintaining the wellbeing of humans due to myriads of their phytoconstituents and nutrients [44]. The cardioprotective effect of aqueous extracts of L. taraxacifolia (wild lettuce) was evaluated in male Wistar rats using the isoproterenol (ISO) model of myocardial infarction. Histopathologic examination of the rats showed degeneration of myocytes with slendering of fibre, loss of nuclei, loss of cross striation of the cardiac muscles, and an increase in interfibre space (oedema). These conditions were significantly corrected in rats that were treated with L. taraxacifolia extract [46], thus demonstrating the protective effects of L. taraxacifolia extract on the cardiovascular system. A summary of the pharmacological effects of the L. taraxacifolia leaves is shown in Figure 4.
[figure omitted; refer to PDF]Toxicological Activities. Toxicity studies are important in ascertaining the safety of substances to humans, especially in cases where the substances serve as food or medicines. In this regard, a number of safety studies have been conducted on L. taraxacifolia extracts. In an in vivo toxicity study by Kuatsienu et al. [29] L. taraxacifolia administered at a maximum dose of 1000 mg/kg per body weight of rats was found to be nontoxic in a 14-day study. They rather showed the ability of the plant to protect against gentamicin-induced kidney damage in rats. Histological studies of kidney tissues showed an insignificant change in tubular epithelium in L. taraxacifolia plus gentamicin treated groups compared to L. taraxacifolia treated only. Koukoui et al. (2017) [28] have also reported that Launaea taraxacifolia is nontoxic to rats at a maximum dose of 500mg/kg body weight. However, Koukoui et al. (2015) [27] have shown that the plant extract decreases HepG2 cell viability at concentrations higher than 20μg/μl in an in vitro 3-(4, 5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium (MTS) test. This is to be expected, as HepG2 cell lines are immortalized human carcinoma cells. Although, in general, there have not been negative reports from individuals who incorporate the leaves of Launaea taraxacifolia in their meals, there is the need, therefore, for further research to be conducted in this area to determine the most effective, yet nontoxic, dose of the plant extract.
Launaea taraxacifolia Interactions with Drugs. Traditional medicine is gaining prominence due to its therapeutic benefits. Some patients take orthodox drug such as antihypertensive drugs, hypoglycaemics, and antiretroviral therapy (HAART) in conjunction with traditional medicines. The combined use of traditional herbal medicines with orthodox drugs could potentially cause herb-drug interactions (HDI). These interactions may influence the bioavailability and efficacy and cause undesirable effects.
Efavirenz (EFV) and nevirapine (NVP) are main constituents of HAART and are both biotransformed by the enzyme CYP2B6 during metabolism. This drug-metabolizing enzyme may be susceptible to induction or inhibition by medicinal plant extracts. Thomford and colleagues reported in 2016 [30, 53] a study they carried out to evaluate the effect of Launaea taraxacifolia extract on recombinant human CYP2B6 enzyme activity on the potential of L. taraxacifolia extract to cause HDI and its ability to act as a reversible time-dependent inhibitor (TDI), using EVF and NVP as target drugs. The extract inhibited CYP2B6 with an IC50 value of 33.87 ± 1.54μg/mL and a TDI of 3.17. Similar reversible time-dependent inhibitions have been reported for CYP1A2, CYP2C9, and CYP2C19. These findings show that drugs metabolized by cytochrome enzymes may be toxic to patients who use L. taraxacifolia concurrently with HAART. Significant levels of these drugs may accumulate in plasma thereby causing toxicity.
4. Conclusion
The nutritional, medicinal/pharmacological properties of Launaea taraxacifolia reported make it a desirable plant for development as a plant-based drug. Data presented up to date demonstrate that there is evidence that support the ethnopharmacological uses of Launaea taraxacifolia. The pharmacological activities reported by various researchers may be due to specific phytoconstituents. Though several compounds have been isolated from this plant, not much is known about their bioactivities. It is therefore necessary for bioactivity-guided fractionation experiment to identify specific constituents that are responsible for the desired medicinal/pharmacological effects. In silico molecular docking studies of the isolated compounds should be done to screen for potential inhibitors of various ailment target sites. Further studies on the structure-activity relationships of the inhibition of recombinant human cytochromes P450 by some bioactive compounds isolated from Launaea taraxacifolia leaves and their analogues are also recommended. The plant does not show any overt toxicity in in vivo and in vitro safety studies. However, there is evidence of its potential to cause herb-drug interactions through inhibition of CYP enzymes. Users should therefore exercise caution in view of potential long-term toxicity and teratogenic effects as well as harmful effects that could result from herb-herb and/or herb-drug interactions.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
[1] H. M. Burkill, "The useful plants of west tropical Africa. Edition 2. Vol. 1: families AD," Kew, Royal Botanic Gardens, vol. 1, 1985.
[2] A. A. Adebisi, "Launaea taraxacifolia (Willd.) Amin ex C. Jeffrey," Plant Resources of Tropical Africa, vol. 2, pp. 362-364, 2004.
[3] F. O. A. Laleye, S. Mensah, A. E. Assogbadjo, H. Ahissou, "Diversity, knowledge, and use of plants in traditional treatment of diabetes in the Republic of Benin," Ethnobotany Research and Applications, vol. 14, pp. 231-258, DOI: 10.17348/era.14.0.231-257, 2015.
[4] "," .
[5] L. E. Kuatsienu, Safety Assessment of the Ethanolic Leaf Extract of LaunaeaTaraxacifolia (Willd) of the Family Asteraceae in Rodents [Masters, thesis], 2012.
[6] C. W. Agyakwa, I. O. Akobundu, A handbook of West African weeds, 1987.
[7] O. Adedeji, O. A. Jewoola, "Importance of leaf epidermal characters in the Asteraceae family," Notulae Botanicae Horti Agrobotanici Cluj-Napoca, vol. 36 no. 2, 2008.
[8] A. M. A. Sakpere, O. A. Aremu, "The growth of Launaea taraxacifolia (Asteraceae) and its response to shading," Research Journal of Botany, vol. 3 no. 2, pp. 90-96, DOI: 10.3923/rjb.2008.90.96, 2008.
[9] A. M. Sakpere, E. R. Ayisire, O. I. Abioye, "Potential of Launaea taraxacifolia (Willd) Amin Ex. C. Jeffrey for in Vitro Regeneration," Notulae Scientia Biologicae, vol. 3 no. 3, 2011.
[10] O. O. Obembe, O. A. Bello, O. S. Aworunse, J. O. Popoola, O. Akposibruke, B. I. Olukanmi, M. N. Olayode, "In vitro multiple shoots formation in wild lettuce (Launaea taraxacifolia) (Willd.) Amin ex C. Jeffrey," Annual Research & Review in Biology, vol. 19 no. 6, 2017.
[11] A. A. Adebisi, D. O. Ladipo, "Popularization of neglected indigenous leafy vegetables among the Yoruba tribe of SouthWest Nigeria," Popularization of neglected indigenous leafy vegetables among the Yoruba tribe of South–West Nigeria, 2000.
[12] H. J. Beentje, Flora of Tropical East Africa: Compositae (part 1), .
[13] A. Dansi, A. Adjatin, H. Adoukonou-Sagbadja, V. Faladé, H. Yedomonhan, D. Odou, B. Dossou, "Traditional leafy vegetables and their use in the Benin Republic," Genetic Resources and Crop Evolution, vol. 55 no. 8, pp. 1239-1256, DOI: 10.1007/s10722-008-9324-z, 2008.
[14] F. Sanoussi, H. Ahissou, M. Dansi, "Ethnobotanical investigation of three traditional leafy vegetables [Alternanthera sessilis (L.) DC. Bidens pilosa L. Launaeataraxacifolia Willd.] widely consumed in southern and central Benin," Journal of Biodiversity and Environmental Sciences, vol. 6 no. 2, pp. 187-198, 2015.
[15] A. Asase, D. T. Yohonu, "Ethnobotanical study of herbal medicines for management of diabetes mellitus in Dangme West District of southern Ghana," Journal of Herbal Medicine, vol. 6 no. 4, pp. 204-209, DOI: 10.1016/j.hermed.2016.07.002, 2016.
[16] M. B. Adinortey, J. K. Sarfo, E. T. Quayson, A. Weremfo, C. A. Adinortey, W. Ekloh, J. Ocran, "Phytochemical screening, proximate and mineral composition of Launaea taraxacifolia leaves," Research Journal of Medicinal Plant, vol. 6 no. 2, pp. 171-179, DOI: 10.3923/rjmp.2012.171.179, 2012.
[17] S. Darkwa, A. A. Darkwa, "The use of indigenous green leafy vegetables in the preparation of Ghanaian dishes," Journal of Food Processing and Technology, vol. 4 no. 12, 2013.
[18] J. O. Arawande, I. A. Amoo, L. Lajide, "Chemical and phytochemical composition of wild lettuce Launaea taraxacifolia," Journal of Applied Phytotechnology in Environmental Sanitation, vol. 2 no. 1, pp. 25-30, 2013.
[19] R. A. Dickson, K. Annan, T. C. Fleischer, I. K. Amponsah, K. Nsiah, J. A. Oteng, "Phytochemical investigations and nutritive potential of eight selected plants from Ghana," Journal of Pharmacy and Nutrition Sciences, vol. 2 no. 2, pp. 172-177, 2012.
[20] D. J. Olugbenga, R. U. Ukpanukpong, U. R. Ngozi, "Phytochemical Screening, Proximate Analysis and Acute Toxicity Study of Launaea Taraxacifolia Ethanolic Extract on Albino Rats," The International Journal of Science and Technoledge, vol. 3 no. 6, 2015.
[21] B. A. Salau, K. T. Odufuwa, O. D. Olukanni, A. K. Atunnise, G. G. Daramola, "Increase in tannin content of some selected Nigerian vegetables during blanching and juicing," Journal of Scientific Research Reports, vol. 5 no. 2, pp. 152-160, DOI: 10.9734/JSRR/2015/14245, 2015.
[22] Z. S. Ololade, S. E. Kuyooro, O. O. Ogunmola, O. O. Abiona, "Phytochemical, Antioxidant, Anti-Arthritic, Anti-Inflammatory and Bactericidal Potentials of the Leaf Extract of Lactuca teraxacifolia," Global Journal of Medical Research, 2017.
[23] F. K. Tayman, J. P. Adotey, F. A. Armah, "Isolation, identification and biological activity of 1-Hexacosanol from the leaves of Launaeataraxacifolia (Willd) Jeffery," Asteraceae. Journal of basic and applied sciences, vol. 1 no. 1, 2013.
[24] M. B. Adinortey, C. Ansah, A. Weremfo, C. A. Adinortey, G. E. Adukpo, E. O. Ameyaw, A. K. Nyarko, "DNA damage protecting activity and antioxidant potential of Launaeataraxacifolia leaves extract," Journal of Natural Science, Biology, and Medicine, vol. 9 no. 1, 2018.
[25] O. Owoeye, S. K. Onwuka, "Lead Toxicity: Effect of Launaeataraxacifolia on the Histological and Oxidative alterations in Rat Regio III Cornu ammonis and Cerebellum," Anatomy Journal of Africa, vol. 5 no. 1, pp. 783-794, 2016.
[26] F. B. Borokini, L. Labunmi, "In vitro investigation of antioxidant activities of Launeataraxacifolia and Crassocephalum rubens," International Journal of Food Studies, vol. 6 no. 1, 2017.
[27] O. Koukoui, P. Agbangnan, S. Boucherie, "Phytochemical study and evaluation of cytotoxicity, antioxidant and hypolipidemic properties of Launaea taraxacifolia leaves extracts on cell lines HepG2 and PLB985," American Journal of Plant Sciences, vol. 6 no. 11,DOI: 10.4236/ajps.2015.611177, 2015.
[28] O. Koukoui, M. Senou, P. Agbangnan, S. Seton, F. Koumayo, S. Azonbakin, A. Sezan, "Effective in vivo cholesterol and triglycerides lowering activities of hydroethanolic extract of Launaea taraxacifolia leaves," International Journal of Pharmaceutical Sciences and Research, vol. 8 no. 5, 2017.
[29] L. E. Kuatsienu, C. Ansah, M. B. Adinortey, "Toxicological evaluation and protective effect of ethanolic leaf extract of Launaea taraxacifolia on gentamicin induced rat kidney injury," Asian Pacific Journal of Tropical Biomedicine, vol. 7 no. 7, pp. 640-646, DOI: 10.1016/j.apjtb.2017.06.011, 2017.
[30] N. E. Thomford, B. Mkhize, K. Dzobo, K. Mpye, A. Rowe, M. I. Parker, A. Wonkam, M. Skelton, A. V. September, C. Dandara, "African Lettuce (Launaea taraxacifolia) Displays Possible Anticancer Effects and Herb-Drug Interaction Potential by CYP1A2, CYP2C9, and CYP2C19 Inhibition," OMICS: A Journal of Integrative Biology, vol. 20 no. 9, pp. 528-537, DOI: 10.1089/omi.2016.0117, 2016.
[31] A. Adejuwon, O. Femi-Akinlosotu, J. Omirinde, "Launaea taraxacifolia Ameliorates Cisplatin-Induced Hepato-renal Injury," European Journal of Medicinal Plants, vol. 4 no. 5, pp. 528-541, DOI: 10.9734/EJMP/2014/7314, 2014.
[32] S. A. Adejuwon, O. O. Aina, O. M. Femi-Akinlosotu, J. O. Omirinde, "Anti-clastogenic effects of launaea taraxacifolia leaf extract on cisplatin-induced micronuclei in bone marrow erythrocytes," Journal of Bio Innovation, vol. 3 no. 2, pp. 86-92, 2014.
[33] A. Adetutu, O. S. Olorunnisola, A. O. Owoade, P. Adegbola, Inhibition of in Vivo growth of Plasmodium berghei by Launaeataraxacifolia and Amaranthusviridis in Mice, 2016.
[34] O. M. Bello, A. A. Zaki, S. I. Khan, P. S. Fasinu, Z. Ali, I. A. Khan, L. A. Usman, O. S. Oguntoye, "Assessment of selected medicinal plants indigenous to West Africa for antiprotozoal activity," South African Journal of Botany, vol. 113, pp. 200-211, DOI: 10.1016/j.sajb.2017.08.002, 2017.
[35] F. M. Oloyede, F. A. Oloyede, E. M. Obuotor, S. I. Ibironke, "Antioxidant activities and food value of five underutilized green leafy vegetables in south western Nigeria," Nigerian Journal of Nutritional Sciences, vol. 32 no. 1, pp. 13-18, 2011.
[36] O. Owoeye, G. O. Arinola, "A Vegetable, Launaea taraxacifolia, Mitigated Mercuric Chloride Alteration of the Microanatomy of Rat Brain," Journal of Dietary Supplements, vol. 14 no. 6, pp. 613-625, DOI: 10.1080/19390211.2017.1288194, 2017.
[37] J. P. Kehrer, L.-O. Klotz, "Free radicals and related reactive species as mediators of tissue injury and disease: Implications for Health," Critical Reviews in Toxicology, vol. 45 no. 9, pp. 765-798, DOI: 10.3109/10408444.2015.1074159, 2015.
[38] D. Dafam, A. Agunu, H. Ibrahim, U. Ajima, T. Ohemu, V. Okwori, D. Kagaru, N. Ilyas, "A Preliminary Ethno-medical Survey of Plants Used in the Traditional Management of Cancer and Related Diseases amongst Tarok People of Plateau State, North-Central Nigeria," European Journal of Medicinal Plants, vol. 16 no. 4,DOI: 10.9734/EJMP/2016/29281, 2016.
[39] J. Zhang, L. Wang, Z. Xing, D. Liu, J. Sun, X. Li, Y. Zhang, "Status of bi-and multi-nuclear platinum anticancer drug development," Anti-Cancer Agents in Medicinal Chemistry (Formerly Current Medicinal Chemistry-Anti-Cancer Agents), vol. 10 no. 4, pp. 272-282, 2010.
[40] U. Olszewski, G. Hamilton, "A better platinum-based anticancer drug yet to come?," Anti-Cancer Agents in Medicinal Chemistry, vol. 10 no. 4, pp. 293-301, DOI: 10.2174/187152010791162306, 2010.
[41] N. Shah, D. S. Dizon, "New-generation platinum agents for solid tumors," Future Oncology, vol. 5 no. 1, pp. 33-42, DOI: 10.2217/14796694.5.1.33, 2009.
[42] M. Ogunlesi, W. Okiei, M. Ademoye, "Medicinal plants used in treating eye infections in Nigeria," A Textbook of Medicinal plants from Nigeria, pp. 299-317, 2008.
[43] I. T. Gbadamosi, E. R. Otobo, "Assessment of the nutritional qualities of ten botanicals used in pregnancy and child delivery in Ibadan, Nigeria," International Journal of Phytomedicine, vol. 6 no. 1, pp. 16-22, 2014.
[44] C. Larbie, D. A. Mensah, "Botanicals for managing cardiovascular disorders: a review of medicinal weeds on KNUST campus," Global Journal of Research on Medicinal Plants Indigenous Medicine, vol. 3 no. 9, 2014.
[45] R. K. Obi, I. I. Iroagba, O. A. Ojiako, "Virucidal potential of some edible Nigerian vegetables," African Journal of Biotechnology, vol. 5 no. 19, pp. 1785-1788, 2006.
[46] T. F. Salisu, B. Ottu, J. Okpuzor, "Histopathologic studies of aqueous extracts of five selected local edible vegetables in isoproterenol-induced myocardial infarction in male Wistar albino rats," Planta Medica, vol. 80 no. 16, 2014.
[47] G. Guha, V. Rajkumar, L. Mathew, R. A. Kumar, "The antioxidant and DNA protection potential of Indian tribal medicinal plants," Turkish Journal of Biology, vol. 35 no. 2, pp. 233-242, 2011.
[48] S. Datta, S. Kundu, P. Ghosh, S. De, A. Ghosh, M. Chatterjee, "Correlation of oxidant status with oxidative tissue damage in patients with rheumatoid arthritis," Clinical Rheumatology, vol. 33 no. 11, pp. 1557-1564, DOI: 10.1007/s10067-014-2597-z, 2014.
[49] C. J. Wruck, A. Fragoulis, A. Gurzynski, L. Brandenburg, Y. W. Kan, K. Chan, J. Hassenpflug, S. Freitag-Wolf, D. Varoga, S. Lippross, T. Pufe, "Role of oxidative stress in rheumatoid arthritis: insights from the Nrf2-knockout mice," Annals of the Rheumatic Diseases, vol. 70 no. 5, pp. 844-850, DOI: 10.1136/ard.2010.132720, 2011.
[50] D. Arya, M. Meena, N. Grover, V. Patni, "In vitro anti-inflammatory and anti-arthritic activity in methanolic extract of Cocculushirsutus (l.) diels. in vivo and in vitro," International Journal of Pharmaceutical Sciences and Research, vol. 5 no. 5, 1957.
[51] I. L. Elisha, J.-P. Dzoyem, L. J. McGaw, F. S. Botha, J. N. Eloff, "The anti-arthritic, anti-inflammatory, antioxidant activity and relationships with total phenolics and total flavonoids of nine South African plants used traditionally to treat arthritis," BMC Complementary and Alternative Medicine, vol. 16 no. 1,DOI: 10.1186/s12906-016-1301-z, 2016.
[52] C. Deaton, E. S. Froelicher, L. H. Wu, C. Ho, K. Shishani, T. Jaarsma, "The global burden of cardiovascular disease," European Journal of Cardiovascular Nursing, vol. 10 no. 2, pp. S5-S13, DOI: 10.1016/S1474-5151(11)00111-3, 2011.
[53] N. E. Thomford, C. Awortwe, K. Dzobo, F. Adu, D. Chopera, A. Wonkam, M. Skelton, D. Blackhurst, C. Dandara, "Inhibition of CYP2B6 by medicinal plant extracts: Implication for use of efavirenz and nevirapine based highly active anti-retroviral therapy (HAART) in resource-limited settings," Molecules, vol. 21 no. 2,DOI: 10.3390/molecules21020211, 2016.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Copyright © 2018 Michael Buenor Adinortey et al. This is an open access article distributed under the Creative Commons Attribution License (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. https://creativecommons.org/licenses/by/4.0/
Abstract
Launaea taraxacifolia (Willd.) Amin ex C. Jeffrey is a herb found mostly in tropical Africa. The plant, commonly found in West Africa, is used in the management of many diseases including cardiovascular, respiratory, haematological, endocrine, and metabolic diseases in Ghana, Nigeria, Benin, Serra Leone, and Senegal. This piece provides comprehensive and updated information on the traditional uses, phytochemical constituents, and pharmacological and toxicological information available on Launaea taraxacifolia to support its medicinal uses and also unearth knowledge gaps for future studies. An electronic literature search using search engines, namely, Google Scholar, ScienceDirect, and PubMed, was carried out to obtain information on the plant. Both common and scientific names of the plant were used as keywords for the search process. This paper captured information on Launaea taraxacifolia from 1985 to 2018. The search revealed that the leaves of the plant possess nutritional/pharmacological effects on diseases such as diabetes mellitus, hypertension, cancer, malaria, bacterial infections, and arthritis. The leaf has been shown to be a rich source of phytoconstituents such as flavonoids, phenolic acids, tannins, alkaloids, glycosides, coumarins, triterpenoids, ascorbic acid, lycopene, and β-carotene. Also, isolated phytoconstituents as well as the safety profile of the plant have been documented. This review on Launaea taraxacifolia has provided a one-stop documentation of information in support of the several purported ethnopharmacological uses of the plant. It also reveals information gaps such as the need to research into its pharmacokinetics, interactions with drugs of importance, and its development into a plant-based drug in order to expand its clinical use.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
; Sarfo, Justice Kwabena 1 ; Kwarteng, Jeffery 1
; Adinortey, Cynthia Ayefoumi 2
; Ekloh, William 3 ; Kuatsienu, Lydia Enyonam 4 ; Alexander Kwadwo Nyarko 5 1 Department of Biochemistry, School of Biological Sciences, College of Agriculture and Natural Sciences, University of Cape Coast, Cape Coast, Ghana
2 Department of Molecular Biology and Biotechnology, School of Biological Sciences, College of Agriculture and Natural Sciences, University of Cape Coast, Cape Coast, Ghana
3 Department of Biochemistry, School of Biological Sciences, College of Agriculture and Natural Sciences, University of Cape Coast, Cape Coast, Ghana; West African Centre for Cell Biology of Infectious Pathogens (WACCBIP), Department of Biochemistry, Cell and Molecular Biology, College of Basic and Applied Sciences, University of Ghana, Legon, Ghana
4 Department of Pharmacology, School of Pharmacy, Princefield University College, Ho, Ghana
5 Department of Pharmacology and Toxicology, School of Pharmacy, University of Ghana, Legon, Ghana