Abstract

Leishmaniasis is an important zoonotic parasitic disease in tropical areas. It is a neglected disease and is a great health catastrophe in Iran. Pentavalent antimony compounds are used for its treatment, but they have adverse effects. Therefore, the use of natural herbs with low adverse effects seems necessary for treatment of Leishmaniasis. In this study, we tried to introduce the natural medicines effective against Leishmaniasis. In this review study, keywords searched included natural medicines, herbal medicines, medicinal plants, Leishmaniasis, and treatment in relevant publications published between 1990 and 2017. Searching was on databases including ISI Web of Science, PubMed, PubMed Central, Scopus, ISC, SID, Magiran and some other databases. The relevant articles were reviewed for the review study. The results showed that medicinal plants: Ferula assafoatida (with IC50 of 0.38 mg/ml), Glycyrrhiza glabra (with IC50 of 25mg/ml), Allium sativum (with IC50 of 0.57 mg/ml), Cephalis ipecacuana (with IC50 of 0.01 mg/ml), Artemisia aucheri (with IC50 of 0.46 mg/ml) and Eucalyptus globulus (with IC50 of 0.17 mg/ml) were the natural medicines effective against the disease. Compositions with di-, tri-, tetra-Sulfide, Coumarin derivatives, Camuou-nephrole, Episamarcandine, Amblipernine, Carnephrole, Azafoetidine, Froxolicin, Azafoetidinole, Saradaferine, 1, 8 Cineole, Scopodreniole, Semen, Sabinine, Cineole, Inaleole, Eojenole, Farenzole, Borneol, Allicin, acid Glycerisic, Emetine and Cephalin can have the potential to produce potent drugs against Leishmaniasis. In sum, there are some specific medicinal plants and compounds effective against Leishmaniasis which can be used per se or following changes in their formula to prepare and introduce new drags against this disease.


Introduction

History of consumption of herbal drugs in treatment of diseases goes back to the first human living that has revolted and developed during centuries Fankam Aime and Jules, 2014Rahmatullah et al., 2013. Great tendency of people toward natural treatments, which are harmless, cost-effective, and cultural compatible, has caused extensive use of pharmaceutical plants in Iranian traditional medicine Bahmani et al., 2016Mahomoodally and Fawzi, 2013Mustafa et al., 2017Rouhi-Boroujeni et al., 2017. Although in the past half century, the use of chemical and synthetic drugs has advanced; the adverse effects of these drugs on life have caused a second trend to herbal drugs Li et al., 2011Sarrafchi et al., 2016Tomlinson and Akerele, 2015. Natural substances, extracted from medicinal plants, are reliable sources of procurement of medicines and the original foundation in development of pharmaceutical compounds Ntie-Kang et al., 2013. Herbal drugs have a better general compliance due to low adverse effects Medagama and Bandara, 2014Shayganni et al., 2016. Parasitic diseases infecting humans are important and serious health problems that result in significant effects on individuals and great economic and social costs Akhoundi et al., 2013Belkaid et al., 2002, Conceicao et al., 2016; Gutierrez et al., 2016Mahmoudi et al., 2013Mirzaei et al., 2013Petitdidier et al., 2016Sacks and Perkins, 1984Soares et al., 2017. Various herbal drugs are used for the treatment of parasitic diseases dos Santos Silva, 2014Oliveira et al., 2015Tahir et al., 1998. Leishmaniasis is an important parasitic zoonotic disease in tropical areas, and is considered a neglected disease Ndjonka et al., 2013. Studies and statistics show that about 350 million people worldwide are at risk of being infected with the disease WHO, 2010. Annually, approximately two million new cases of the disease are reported Mohajery et al., 2004. Iran, Algeria, Nicaragua, Colombia, Peru, Bolivia, Afghanistan, Brazil, Syria, and Saudi Arabia are the inhabitant countries of cutaneous leishmaniasis Gramiccia and Gradoni, 2005. Cutaneous Leishmaniasis is the most important parasitic disease in Iran and even in Middle East area Governorate, 1985. Leishmaniasis is a great health catastrophe in Iran Shirazi et al., 2006. In Iran, the regions like Khorasan, Yazd, Bushehr, Fars, Khuzestan, Ilam, and Esfahan have the highest rate of this disease in the country Tabatabaei et al., 2007. Leishmaniasis imposes a great economic burden on the community in developing countries Ashford et al., 2010. Cutaneous Leishmaniasis causes skin lesions with remaining scars. Pentavalent antimonies are used for its treatment, but have high level of adverse effects Mohajery et al., 2004.

Therefore, using herbal drugs with natural source and low adverse effects seems necessary for the treatment of cutaneous Leishmaniasis. In this study, we introduce natural medicines against Leishmaniasis.

Methods

In this review study, keywords searched included natural medicines, herbal medicines, medicinal plants, Leishmaniasis, and treatment. Searching was on databases including ISI Web of Science, PubMed, PubMed Central, Scopus, ISC, SID, Magiran and some other databases. The relevant articles were reviewed for this review article.

Results

The results of the literature review showed that medicinal plants, including Ferula assafoatida, Glycyrrhiza glabra, Allium sativum, Cephalis ipecacuana, Artemisia aucheri, and Eucalyptus globulus were the herbal medicines effective against the disease. The results of the present study showed that herbal plants such as Ferula assafoatida with IC50 of 0.38 mg/ml, Glycyrrhiza glabra plant with IC50 of 25mg/ml, Allium sativum plant with IC50 of 0.57 of mg/ml, Cephalis ipecacuana plant with IC50 of 0.01 mg/ml, Artemisia aucheri plant with IC50 of 0.46 mg/ml and Eucalyptus globulus herb with IC50 of 0.17 mg/ml were the natural medicines effective against leishmanisis ( Table 1 ).

Table 1.

Discussion

In this study, it was found that herbal medicines, including Ferula assafoatida, Glycyrrhiza glabra, Allium sativum, Cephalis ipecacuana, Artemisia aucheri and Eucalyptus globulus were medicinal plants effective against Leishmaniasis. In traditional medicine, Asafoetida plant is used against seizures, worms, neural diseases, intestinal dysmotility, renal pain, rheumatism, muscular clench, and hypertension, and for elimination of fatty foods’ harms, as well as for enhancing appetite and memory Lee et al., 2009Leung, 1996Mohammadi, 2009Sadraei et al., 2003. Asafoetida has di-, tri-, and tetra-sulfide, coumarin derivatives, camuonephrole, episamarcandine, amblipernine, carnephrole, azafoetidine, froxolicin, azafoetidinole, saradaferine, and foetidine Abd El-Razek et al., 2001Bandyopadhyay, 2006Banerji et al., 1998Fraga, 1999Kajimoto et al., 1989Kojima et al., 2000Nassar et al., 1995. Eucalyptus has antibacterial, antifungal, antioxidan, anti-infectious, and antispasmatic effects. It is also fever palliative and putative, hypoglycemic and anthelmintic plant Ministry of health and medical education, 2004Zargary, 1996. Eucalyptus plant contains a compound called 1, and 8 cineole or Eucalyptole that is the main composition of this plant Mulyaningsih et al., 2010Oyedeji et al., 1996. Artemisia has astringent property, disinfectant activity, antimicrobial, antiparasite, anti-poisoning, and anti-insect effects AliAbadi et al., 2010AzadBakht, 2003. Artemisia contains scopodreniole, semen, sabinine, cineole, inaleole, eojenole, farenzole, and borneol AliAbadi et al., 2010AzadBakht, 2003. Garlic has cardiovascular effects, prevents cancer, has antidiabetic effects, and anti-microbial activity. The main active ingredient of this plant is called allicin Heinrich and Larry, 1996Leistner and Gorris, 1995. Licorice is used to treat bloating, respiratory infections, peptic ulcers and gastritis. It is also used as antitussive, anti-hepatitis, and anti-tumor agent Baba and Shigeta, 1993Lentihet and Nygren, 1997Sato et al., 1996Li et al., 2011Haraguchi et al., 1998Csuk et al., 2010Fukai et al., 2002. The major component of licorice is glycerisic acid Alan Teck et al., 2007Mehravar, 1991Marzi et al., 1993. Cephalis ipecacuana is used in the treatment of cough, children’s bronchitis, and amoebic diarrhea. This plant has active compounds including emetine, and cephaline Vetrichelvan et al., 1996.

Asafoetida plant with compositions such as di-, tri-, tetra-Sulfide, coumarin derivatives, camuonephrole, episamarcandine, amblipernine, carnephrole, azafoetidine, froxolicin, azafoetidinole, saradaferine, 1, 8 cineole, scopodreniole, semen, sabinine, cineole, inaleole, eojenole, farenzole, borneol, allicin, acid glycerisic, emetine and cephalin has the potential for production of potent drugs against Leishmaniasis.

Other compounds of these plants may also be involved in anti-leishmania activities of these plants. Phenolic compounds are a group of compounds which have been shown to be effective against a wide variety of microbial infections as well as other diseases Hosseinzadeh et al., 2015Lorigooini et al., 2014Lorigooini et al., 2015Ghasemi and Lorigooini, 2016. They should be examined for treatment of Leishmaniasis and for preparation of new drugs.

Conclusion

There are some specific medicinal plants or compounds effective against Leishmaniasis which can be used per se or following changes in their formula to prepare and introduce new drags against Leishmaniasis.

Abbreviations

IC50= The half maximal inhibitory concentration

Author Contribution

All authors contributed to the design of the research. MB, NA, MH and MRK collected the data. MRK write, edited and revised it. All authors reviewed and commented on final draft

References

  1. M. H. Abd El-Razek, S. Ohta, A. A. Ahmed, T. & Hirata. Sesquiterpene coumarins from the roots of Ferula assa-foetida. Phytochemistry. 2001; 58(8) : 1289-1295 .
    View Article    Google Scholar 
  2. M. Akhoundi, M. Mohebali, M. Asadi, M. R. Mahmodi, K. Amraei, A. & Mirzaei. Molecular characterization of Leishmania spp. in reservoir hosts in endemic foci of zoonotic cutaneous leishmaniasis in Iran. Folia Parasitologica. 2013; 60(3) : 218-224 .
  3. W. E. Alan Teck. Evaluation of surfactant assisted pressurized liquid extraction for the determination of glycyrrhizin and ephedrine in medicinal plants. Analytica Chimica Acta. 2007; 583(2) : 289-295 .
    View Article    Google Scholar 
  4. A. Alborzi, F. Namjoian, M. Azadbakht, B. Obodi, M. Panjehshahin, M. Rasoli. Effects of Ferula assa-foetida and its effective fractions on Leishmania (in vitro). Infect Tropic Dis Iran. 2003; 8(12) : 36-40 .
  5. H. AliAbadi, M. Mirshekari Nasri. Effect of Nitrogen Fertilizer and method for its consumption of qualitative and quantitative performance of Artemisia. Journal of Crop Ecophysiology. 2010; 2(3) : 68-175 .
  6. Parasitology Amman Governorate. Am J Trop Med Hyg. Am J Trop Med Hyg. 1985; 79 : 13-46 .
  7. R. W. Ashford, C. Bern, M. Boelaert, A. Bryceson, F. Chappuis, S. Croft. Leishmaniasis control. World Health Organization. 2010 .
  8. M. AzadBakht, Abdollahi Ziaaei. Effect of plant essential oils of Artemisia aucheri, Thymus vulgaris and Myrtus communis on Trichomonas vaginalis. Journal of Medicinal Plant. 2003; 8 : 34-40 .
  9. M. Baba, S. & Shigeta. Antiviral activity glycyrrhizin against varicella zoster virus in vitro. Mund-. 1993; Kiefer- und Gesichtschirurgie : 3(1) .
  10. M. Bahmani, A. Sarrafchi, H. Shirzad, M. & Rafieian-Kopaei. Autism: Pathophysiology and promising herbal remedies. Current Pharmaceutical Design. 2016; 22(3) : 277-285 .
    View Article    Google Scholar 
  11. D. Bandyopadhyay, B. Basak, A. Chatterjee, T.K. Lai, A. Banerji, J. Banerji, A. Prange Neuman. Saradaferin, a new sesquiterpenoid coumarin from Ferula assa foetida. Natural product Res. 2006; 20 (10) : 961: 965 .
  12. A. Banerji, B. Mallick, A. Chatterjee, H. Budzikiewicz, M. & Breuer. Assafoetidin and ferocolicin, two sesquiterpenoid coumarins from Ferula assafoetida Regel. Tetrahedron. 1998; 29(13) : 1557-1560 .
    View Article    Google Scholar 
  13. Y. Belkaid, C. A. Piccirillo, S. Mendez, E. M. Shevach, D. L. & Sacks. CD4+ CD25+ regulatory T cells control Leishmania major persistence and immunity. Nature. 2002; 420(6915) : 502-507 .
    View Article    Google Scholar 
  14. M. Chen, S. B. Christensen, J. Blom, E. Lemmich, L. Nadelmann, K. Fich, A. . . . Lichochalcone. A novel antiparasitic agent with potent activity against human pathogenic protozoan species of leishmania. Antimicrobial Agents and Chemotherapy. 1993; 37(12) : 2550-2556 .
    View Article    Google Scholar 
  15. J. Conceição, R. Davis, P. P. Carneiro, A. Giudice, A. C. Muniz, M. E. Wilson, O. . . . Bacellar. Characterization of neutrophil function in human cutaneous leishmaniasis caused by Leishmania braziliensis. PLoS Neglected Tropical Diseases. 2016; 10(5) : e0004715 .
    View Article    Google Scholar 
  16. R. Csuk, S. Schwarz, R. Kluge, D. & Ströhl. Synthesis and biological activity of some anti tumora active deraiveties from glycyrrhetic acid. European Journal of Medicinal Chemistry. 2010; 45(12) : 5718-5723 .
    View Article    Google Scholar 
  17. F. Santos Silva. An ethnopharmacological assessment of the use of plants against parasitic diseases in humans and animals. Journal of Ethnopharmacology. 2014; 155(2) : 1332-1341 .
    View Article    Google Scholar 
  18. G. Fankam Aimé, R. & Jules. Antibacterial activities of Beilschmiedia obscura and six other Cameroonian medicinal plants against multi-drug resistant Gram-negative phenotypes. BMC Complementary and Alternative Medicine. 2014; 14(1) : 241 .
    View Article    Google Scholar 
  19. N. Feasey, M. Wansbrough-Jones, D. C. Mabey, A. W. & Solomon. Neglected tropical diseases. British Medical Bulletin. 2010; 93(1) : 179-200 .
    View Article    Google Scholar 
  20. B. M. Fraga. Natural sesquiterpenoids. Natural Product Reports. 1999; 16(6) : 711-730 .
    View Article    Google Scholar 
  21. T. Fukai, A. Marumoa, K. Kaitou, T. Kanda, S. Terada, T. & Nomura. Anti-Helicobacter pylori flavonoids from licorice extract. Life Sciences. 2002; 71(12) : 1449-1463 .
    View Article    Google Scholar 
  22. S. Ghasemi, Z. & Lorigooini. A review of significant molecular mechanisms of flavonoids in prevention of prostate cancer. Journal of Chemical and Pharmaceutical Sciences. 2016; 9 : 3388-3394 .
  23. T. Ghazonfari, Z. M. Hassani, M. Ebtekar, A. Ahmadiani, G. Naderi, A. & Azar. Garlic induces a shift in a Leishmania major - infected balby mice. Scandinavian Journal of Immunology. 2000; 52 : 491-495 .
    View Article    Google Scholar 
  24. M. Gramiccia, L. & Gradoni. The current status of zoonotic leishmaniases and approaches to disease control. International Journal for Parasitology. 2005; 35(11-12) : 1169-1180 .
    View Article    Google Scholar 
  25. V. Gutiérrez, A. B. Seabra, R. M. Reguera, J. Khandare, M. & Calderón. New approaches from nanomedicine for treating leishmaniasis. Chemical Society Reviews. 2016; 45(1) : 152-168 .
    View Article    Google Scholar 
  26. H. Haraguchi, K. Tanimoto, Y. Tamura, K. Mizutani, T. & Kinoshita. Mode of antibacterial action of retrochalcones from Glycyrrhiza inflate. Phytochemistry. 1998; 48(1) : 125-129 .
    View Article    Google Scholar 
  27. P. Heinrich, D.L Larry. Garlic: The science and therapeutic application of Allium Sativum L. and related species. 2 nd ed. Translated to English by: William W. 1996 .
  28. B. Hosseinzadeh, M. Khoshtaghaza, Z. Loriooini, S. Minaei, H. & Zareiforoush. Analysis of the combinative effect of ultrasound and microwave power on Saccharomyces cerevisiae in orange juice processing. Innovative Food Science & Emerging Technologies. 2015; 32 : 110-115 .
    View Article    Google Scholar 
  29. T. Kajimoto, K. Yahiro, T. & Nohara. Sesquiterpenoid and disulphide derivatives from ferula assa-foetida. Phytochemistry. 1989; 28(6) : 1761-1763 .
    View Article    Google Scholar 
  30. Sami A. Khalid. The potential antileishmanial activity of some Sudanese medicinal plants. 2016 .
  31. K. K. Kojima, P. Isaka, O. Ondognii, O. Zevgeegiin, P. Gombosurengyin, K. Davgiin, Y. Ogihara. Sesquiterpenoid derivatives from Ferula ferulaeoides. Chemical & Pharmaceutical Bulletin. 2000; 48(3) : 353-356 .
    View Article    Google Scholar 
  32. C. L. Lee, L. C. Chiang, L. H. Cheng, C. C. Liaw, M. H. Abd El-Razek, F. R. Chang, Y. C. & Wu. Influenza a (H1N1) antiviral and cytotoxic agents from Ferula assa-foetida. Journal of Natural Products. 2009; 30(20) : 1568-1572 .
    View Article    Google Scholar 
  33. L. Leistner, L. & Gorris. Food preservation by hurdle technology. Food Science and Technology (Campinas). 1995; 6(2) : 41-46 .
    View Article    Google Scholar 
  34. M. Lentihet, A. & Nygren. Licorice an old drug and currently a candy with metabolic effects. Journal of Oral Pathology & Medicine. 1997; 26(1) : 36-39 .
  35. AY. Leung, S. Foster. Encyclopedia of common natural ingredient used in food, drugs and cosmetics. 2nd ed.. John willy & sons, inc. new York. 1996; : 44-5 .
  36. Thomas SC. Li. Chinese & Related North American Herbs: Phytopharmacology & Therapeutic Values. CRC press. 2016 .
  37. Y. J. Li, J. Chen, Y. Li, Q. Li, Y. F. Zheng, Y. Fu, P. & Li. Screeing and haracterization of natural antioxidants in four Glycyrrhiza species by liquid chromatography coupied with electrospray ionization quadrupole time of flight tanden mass spectrometry. Journal of Chromatography. 2011; 1218(45) : 8181-8191 .
    View Article    Google Scholar 
  38. Z. Lorigooini, S. A. Ayatollahi, S. Amidi, F. Kobarfard. Evaluation of anti-platelet aggregation effect of some Allium species. Iranian journal of pharmaceutical research (IJPR). 2015; 14(4) : 1225 .
  39. Z. Lorigooini, F. Kobarfard, S. A. & Ayatollahi. Anti-platelet aggregation assay and chemical composition of essential oil from Allium atroviolaceum Boiss growing in Iran. International Journal of Biosciences (IJB). 2014; 5(2) : 151-156 .
  40. M.-R. Mahmoudi, B. Kazemi, A. Mohammadiha, A. Mirzaei, P. & Karanis. Detection of Cryptosporidium and Giardia (oo)cysts by IFA, PCR and LAMP in surface water from Rasht, Iran. Transactions of the Royal Society of Tropical Medicine and Hygiene. 2013; 107(8) : 511-517 .
    View Article    Google Scholar 
  41. M. Mahomoodally, F. & Fawzi. Traditional medicines in Africa: An appraisal of ten potent African medicinal plants. Evidence-Based Complementary and Alternative Medicine. 2013; 2013 : 1-14 .
    View Article    Google Scholar 
  42. V. Marzi, G. Circella, G. M. & Vampa. Effect of soil depth on the rooting system growth in Glycyrrhiza glabra L. ISHS. Acta Horticulturae. 1993; (331) : 71-78 .
  43. A. B. Medagama, R. & Bandara. The use of Complementary and Alternative Medicines (CAMs) in the treatment of diabetes mellitus: Is continued use safe and effective?. Nutrition Journal. 2014; 13(1) : 102 .
  44. M. Mehravar. Extraction of licorice from licorice roots by pure water and one percent aqueous ammonia solution. M.Sc. Thesis. Shiraz University, Shiraz, Iran, 107. 1991 .
  45. Ministry of health medical education. Iran herbal farmacoope. 2004; : 84-93 .
  46. A. Mirzaei, S. Rouhani, P. A. Kazerooni, M. Farahmand, P. & Parvizi. Molecular detection and conventional identification of Leishmania species in reservoir hosts of zoonotic cutaneous Leishmaniasis in Fars province. South of Iran. Iranian Journal of Parasitology. 2013; 8(2) : 280-288 .
  47. M Mohajeri, A. Shamsian. Medical protozoology. 2nd ed. Mashhad: Academic Center for Education, Culture and Research (ACECR) Publishers. 2010 .
  48. M. Mohajery, G. R. Hatam, A. A. Shamsian, A. & Javaheri. Isoenzyme identification Of L.Major. Journal of Medicine. 2004; 47 : 19-27 .
  49. R Mohammadi, A. Sepahvand, S. Roodbar Mohammadi, Mirsafaei H. Noor Shargh ShadziSh. Antifungal activity of Ferula assa - foetida against clinical agents of Mucormycosis. Majallah-i Danishkadah-i Pizishki-i Isfahan. 2009; 27(100) : 582-587 .
  50. S. Mulyaningsih, F. Sporer, S. Zimmermann, J. Reichling, M. & Wink. Synergistic properties of the terpenoids aromadendrene and 1,8-cineole from the essential oil of Eucalyptus globulus against antibiotic-susceptible and antibioticresistant pathogens. Phytomedicine. 2010; 17(13) : 1061-1066 .
    View Article    Google Scholar 
  51. G. H. Mustafa, R. Arif, A. Atta, S. Sharif, A. & Jamil. Bioactive compounds from medicinal plants and their importance in drug discovery in Pakistan. Matrix Science Pharma. 2017; 1(1) : 17-26 .
    View Article    Google Scholar 
  52. M. I. Nassar, E. A. Abu-Mustafa, A. A. & Ahmed. Sesquiterpene coumarins from Ferula assafoetida L. Die Pharmazie. 1995; 50(11) : 766-767 .
  53. D. Ndjonka, L. Rapado, A. Silber, E. Liebau, C. & Wrenger. Natural products as a source for treating neglected parasitic diseases. International Journal of Molecular Sciences. 2013; 14(2) : 3395-3439 .
    View Article    Google Scholar 
  54. R. A. Neal. Effect of emetine and related compounds on experimental cutaneous leishmaniasis. Annals of Tropical Medicine and Parasitology. 1970; 64(2) : 159-165 .
    View Article    Google Scholar 
  55. F. Ntie-Kang, L. L. Lifongo, L. M. Mbaze, N. Ekwelle, L. C. Owono Owono, E. Megnassan, S. M. N. . . . Efange. Cameroonian medicinal plants: A bioactivity versus ethnobotanical survey and chemotaxonomic classification. BMC Complementary and Alternative Medicine. 2013; 13(1) : 147 .
    View Article    Google Scholar 
  56. D. R. Oliveira, A. U. Krettli, A. C. C. Aguiar, G. G. Leitão, M. N. Vieira, K. S. Martins, S. G. & Leitão. Ethnopharmacological evaluation of medicinal plants used against malaria by quilombola communities from Oriximiná, Brazil. Journal of Ethnopharmacology. 2015; 173 : 424-434 .
    View Article    Google Scholar 
  57. A. Oyedeji, O. Ekundayo, O. Olawore, B. Adeniyi, W. & Koenig. Antimicrobial activity of the essential oils of five Eucalyptus species growing in Nigeria. Fitoterapia. 1996; 70(5) : 526-528 .
    View Article    Google Scholar 
  58. E. Petitdidier, J. Pagniez, G. Papierok, P. Vincendeau, J.-L. Lemesre, R. & Bras-Gonçalves. Recombinant forms of Leishmania amazonensis excreted/secreted promastigote surface antigen (PSA) induce protective immune responses in dogs. PLoS Neglected Tropical Diseases. 2016; 10(5) : e0004614 .
    View Article    Google Scholar 
  59. M. Rahmatullah, S. R. Pk, M. Al-Imran, R. & Jahan. The Khasia tribe of Sylhet district, Bangladesh, and their fast-disappearing knowledge of medicinal plants. Journal of Alternative and Complementary Medicine (New York; N.Y.). 2013; 19(7) : 599-606 .
  60. H. Rouhi-Boroujeni, E. Heidarian, H. Rouhi-Boroujeni, F. Deris, M. & Rafieian-Kopaei. Medicinal Plants with multiple effects on cardiovascular diseases: A systematic review. Current Pharmaceutical Design. 2017; 23(7) : 999-1015 .
    View Article    Google Scholar 
  61. D. L. Sacks, P. V. & Perkins. Identification of an infective state of Leishmania promastigotes. Science. 1984; 223(4643) : 1417-1420 .
    View Article    Google Scholar 
  62. H. Sadraei, A. Ghannadi, K. & Malekshahi. Composition of the essential oil of assa foetida and its spasmolytic action. Saudi Pharmaceutical Journal. 2003; 11(3) : 136-140 .
  63. A. Sarrafchi, M. Bahmani, H. Shirzad, M. & Rafieian-Kopaei. Oxidative stress and Parkinson’s disease: New, hopes in treatment with herbal antioxidants. Current Pharmaceutical Design. 2016; 22 (2) : 238-246 .
    View Article    Google Scholar 
  64. H. Sato, W. Goto, J. Yamamura, M. Kurokawa, S. Kageyama, T. Takahara, K. Shirak. Therapeutic basis of glycyrrhizin on chronic hepatitis B. Antiviral Research. 1996; 30(2-3) : 171-177 .
    View Article    Google Scholar 
  65. M. Sharif, H. Ziaei, M. Azadbakht, A. Daryani, A. Ebadattalb, M. & Rostami. Effeet of methanolic extract of Artemisia auchori and Camellia sinansis on Leishmania major (in vitro). Turk Sci. 2006; 36(6) : 365-369 .
  66. E. Shayganni, M. Bahmani, S. Asgary, M. & Rafieian-Kopaei. Inflammaging and cardiovascular disease: Management by medicinal plants. Phytomedicine. 2016; 23(11) : 1119-1126 .
    View Article    Google Scholar 
  67. M. Shirazi, R. Ranjbar, K. & Khansari. Secondary bacterial infections of skin lesions suspicious for cutaneous leishmaniasis. Iranian Journal of Infectious Diseases and Tropical Medicine. 2006; 12(38) : 55-58 .
  68. R. R. Soares, L. M. R. Antinarelli, C. Abramo, G. C. Macedo, E. S. Coimbra, K. K. G. & Scopel. What do we know about the role of regulatory B cells (Breg) during the course of infection of two major parasitic diseases, malaria and leishmaniasis?. Pathogens and Global Health. 2017; 111(3) : 107-115 .
  69. S. Tabatabaei, M. Zahraei, H. Ahmadnia, M. Ghotbi, F. & Rahimi. Principles of disease prevention and surveillance (2nd ed.). Tehran: Roohe Ghalam Publishers. 2007 .
  70. A. E. Tahir, A. M. Ibrahim, G. M. H. Satti, T. G. Theander, A. Kharazmi, A. S. & Khslid. The potential antileishmanial activity of some Sudanse medicinal plants. Phytotherapy Research. 1998; 12(8) : 576-579 .
    View Article    Google Scholar 
  71. T. R. Tomlinson, O. Eds. & Akerele. Medicinal plants: their role in health and biodiversity. University of Pennsylvania press. 2015 .
  72. T. Vetrichelvan, S. Kavimani, R. Elango, B. & Jaykar. Effect of l-dopa and l-methionine supplementation on bioproduction of ementine in callus cultures of cephaelis ipecacuanha. Ancient Science of Life. 1996; 16(1) : 74-78 .
  73. Geneva: WHO World Health Organization. Packages of Interventions. 2010.; Available at: http://www.who.int/whr/1996/media_centre/executive_summary1/en/index9.html. 2010 .
  74. A. Zargary. Herbal druges. Vol2. 6th edit. Univearcity publication.. 1996; : 312 .

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