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Journal of Ethnobiology and Ethnomedicine

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Open Access 01-12-2017 | Review

Therapeutic arthropods and other, largely terrestrial, folk-medicinally important invertebrates: a comparative survey and review

Author: V. Benno Meyer-Rochow

Published in: Journal of Ethnobiology and Ethnomedicine | Issue 1/2017

Abstract

Traditional healing methods involving hundreds of insect and other invertebrate species are reviewed. Some of the uses are based on the tenet of “similia similibus” (let likes be cured by likes), but not all non-conventional health promoting practices should be dismissed as superstition or wishful thinking, for they have stood the test of time. Two questions are addressed: how can totally different organ systems in a human possibly benefit from extracts, potions, powders, secretions, ashes, etc. of a single species and how can different target organs, e.g. bronchi, lungs, the urinary bladder, kidneys, etc. apparently respond to a range of taxonomically not even closely related species? Even though therapeutically used invertebrates are generally small, they nevertheless possess organs for specific functions, e.g. digestion, gas exchange, reproduction. They have a nervous system, endocrine glands, a heart and muscle tissue and they contain a multitude of different molecules like metabolites, enzymes, hormones, neurotransmitters, secretions, etc. that have come under increased scientific scrutiny for pharmacological properties. Bearing that in mind it seems likely that a single species prepared and used in different ways could have a multitude of uses. But how, for example, can there be remedies for breathing and other problems, involving earthworms, molluscs, termites, beetles, cockroaches, bugs, and dragonflies? Since invertebrates themselves can suffer from infections and cancers, common defence reactions are likely to have evolved in all invertebrates, which is why it would be far more surprising to find that each species had evolved its own unique disease fighting system. To obtain a more comprehensive picture, however, we still need information on folk medicinal uses of insects and other invertebrates from a wider range of regions and ethnic groups, but this task is hampered by western-based medicines becoming increasingly dominant and traditional healers being unable and sometimes even unwilling to transmit their knowledge to the younger generation. However, collecting and uncontrolled uses of therapeutic invertebrates can put undue pressure on certain highly sought after species and this is something that has to be borne in mind as well.

Holt V. Why not eat insects? Whitstable: Pryor Publications; 1885.

Bequaert J. Insects as food: How they have augmented the food supply of mankind in early and recent years. Nat Hist J Amer Mus Nat Hist. 1921;21:191–200.

Bergier E. Peuples entomophages et insects comestibles: étude sur les moeurs de l’homme et de l’insecte. Avignon: Imprimérie Rullière Frères; 1941.

Bodenheimer FS. Insects as human food. The Hague: W. Junk Publ; 1951.CrossRef

Meyer-Rochow VB. Can insects help to ease the problem of world food shortage? Search. 1975;6:261–2.

Evans J, Alemu MH, Flore R, Frost MB, Halloran A, Jensen AB, Maciel-Vergara G, Meyer-Rochow VB, Münke-Svendsen C, Olsen SB, Payne C, Roos N, Rozin P, Tans HSG, Van Huis A, Vantomme P, Eilenberg J. ‘Entomophagy’: an evolving terminology in need of review. J Insects Food Feed. 2015;1(4):293–305.CrossRef

Bukkens SGF. Insects in the human diet: nutritional aspects. In: Paoletti MG, editor. Ecological implications of minilivestock potential of insects, rodents, frogs and snails. Enfield: Science Publ; 2005. p. 547–77.

Banjo AD, Lawal OA, Songonuga EA. The nutritional value of 14 species of edible insects in SW Nigeria. Afr J Biotechnol. 2006;5:298–301.

Paoletti MG, Norberto L, Damini R, Musumeci S. Human gastric juice contains chitinase that can degrade chitin. Ann Nutr Metab. 2007;51:244–51.PubMedCrossRef

10.

Oduor PM, Struszczyk MH, Peter MG. Characterization of chitosan from blowfly larvae and some crustacean species from Kenyan marine waters prepared under different conditions. Discov Innovat. 2008;20:129–42.

11.

Osasona AI, Olaofe O. Nutritional and functional properties of Cirina firda larva from Ado/Ekiti, Nigeria. Afr J Food Sci. 2010;4(12):775–7.

12.

Yhoung-Aree J. Edible Insects in Thailand: Nutritional Values and Health Concerns. In: Durst PB, Johnson DV, Leslie RN, Shono K, editors. Edible forest insects: humans bite back. Bangkok: FAO Publ; 2010. p. 201–16.

13.

Chakravorty J, Ghosh S, Jung C, Meyer-Rochow VB. Nutritional composition of Chondacris rosea and Brachytrupes orientalis: Two common insects used as food by tribes of Arunachal Pradesh, India. J Asia-Pacific Entomol. 2014;17:407–15.CrossRef

14.

Chakravorty J, Ghosh S, Megu K, Jung C, Meyer-Rochow VB. Nutritional and anti-nutritional composition of Oecophylla smaragdina (Hymenoptera, Formicidae) and Odontotermes sp. (Isoptera, Termitidae): Two preferred insects of Arunachal Pradesh, India. J Asia-Pacific Entomol. 2016;19:711–20.CrossRef

15.

Ghosh S, Jung S, Meyer-Rochow VB. Nutritional value and chemical composition of larvae, pupae and adults of worker honey bee Apis mellifera ligustica as a sustainable food source. J Asia-Pacific Entomol. 2016;19:487–95.CrossRef

16.

Himan EH. On the use of insects and other arthropods in medicine. J Trop Med Hyg. 1933;35:128–34.

17.

Morge G. Entomology in the western world in antiquity and in medieval times. In: Smith RF, editor. History of entomology. Palo Alto: Annual Reviews, Inc; 1973. p. 37–80.

18.

Mallmann MLW. A farmacopéia do mar: invertebrados marinhos de interesse medico e a etmomedicina alagoana. Monografia (Especialização em Zoologia). Maceió: Universidade Federal de Alagoas; 1996.

19.

Cooper EL, Yao. Diving for drugs: tunicate anticancer compounds. Drug Discov Today. 2012;7(11–12):635–48.

20.

Vetter I, Lewis RJ. Therapeutic potential of cone snail venom peptides (conopeptides). Curr Top Med Chem. 2012;2(14):1546–52.CrossRef

21.

Alves RRN, Oliveiras TPR, Rosa IL, Cunningham AB. Marine invertebrates in traditional medicines. In: Alves RRN, Rosa IL, editors. Animals in traditional folk medicine. Berlin: Springer Verlag; 2013. p. 263–88.CrossRef

22.

Albuquerque UP, Rômulo RNA. Introduction to Ethnobiology. Cham: Springer Intl; 2016.CrossRef

23.

Hider RC. Honeybee venom: a rich source of pharmacologically active peptides. Endeavour. 1988;12(2):60–5.PubMedCrossRef

24.

Banerjee P, Sohoo KN, Biswas TK, Basu SK, Chatterjee J, Hui AK, Chakraborty NC, Debnath PK. Bees make medicine for mankind. Ind J Trad Knowledge. 2003;2(1):22–6.

25.

Al-Waili NS. Mixture of honey, beeswax, and olive oil inhibits growth of Staphylococcus aureus and Candida albicans. Arch Med Res. 2005;36:10–3.PubMedCrossRef

26.

Thomas S, Andrews AM, Hay NP, Bourgoise S. The anti-microbial activity of maggot secretions: results of a preliminary study. J Tiss Viability. 1999;9(4):127–32.CrossRef

27.

Ediriweera ERHSS, Premarathna NYS. Medicinal and cosmetic uses of bee’s honey – A review. Ayurveda. 2012;33(2):178–82.

28.

Gupta RK, Stangaciu S. Apitherapy: holistic healing through the honeybee and bee products in countries with poor healthcare system. In: Gupta RK, Reybroek W, Van Veen JW, Gupta A, editors. Beekeeping for poverty alleviation and livelihood security. Berlin: Springer Verlag; 2014. p. 413–47.

29.

Baer WS. The treatment of chronic osteomyelitis with the maggot (larvae of the blowfly). J Bone Joint Surg. 1931;13:438.

30.

LeClercq M. Utilisation de larves des diptères -maggot therapy- en medicine: historique et actualité. Bull Annls Soc Belge Ent. 1990;126:41–50.

31.

Sherman RA, Hall MJR, Thomas S. Medicinal maggots: an ancient remedy for some contemporary afflictions. Ann Rev Entomol. 2000;45:55–81.CrossRef

32.

Huxtable RJ. The pharmacology of extinction. J Ethnopharmacol. 1992;37:1–11.PubMedCrossRef

33.

Mory RN, Mindell D, Bloom DA. The leech and the physician: biology, etymology, and medical practice with Hirudinea mediicinalis. World J Surg. 2000;24:878–83.PubMedCrossRef

34.

Cherniack EP. Bugs as drugs, Part 2: Worms, leeches, scorpions, snails, ticks, centipedes, and spiders. Altern Med Rev. 2011;16(1):50–8.PubMed

35.

Peng F, Wei YQ, Tian L, Yang L, Zhao X, Lu Y, Mao YQ, Kan B, Lei S, Wang GS, Jiang Y, Wang QR, Luo F, Zou LQ, Liu JY. Induction of apoptosis by norcantharadin in human colorectal carcinoma cell lines: involvement of the CD95 receptor/ligand. J Canc Res Clin Oncol. 2002;128:223–30.CrossRef

36.

Huh JE, Kang KS, Ahn KS, Kim DH, Saiki I, Kim SH. Mylabris phalerata induces apoptosis by caspase activation following cytochrome c release and bid cleavage. Life Sci. 2003;73:2249–62.PubMedCrossRef

37.

Percino-Daniel N, Buckley D, García-París M. Pharmacological properties of blister beetles (Coleoptera: Meloidae) promoted their integration into the cultural heritage of native rural Spain as inferred by vernacular names diversity, traditions, and mitochondrial DNA. J Ethnopharmacol. 2013;147:570–83.PubMedCrossRef

38.

Verma AK, Prasad SB. Antitumor effect of blister beetles: an ethno-medicinal practice in Karbi community and its experimental evaluation against a murine malignant tumor model. J Ethnopharmacol. 2013;148(3):869–79.PubMedCrossRef

39.

Netolitzky F. Käfer als Nahrungs- und Heilmittel. Koleopterol Rundsch. 1918;7(9/10):121–9.

40.

Netolitzky F. Käfer als Nahrungs- und Heilmittel (Schluβ). Koleopterol Rundsch. 1919;8(4/6):47–59.

41.

Lloyd JT. Spiders used in medicine. Am J Pharmacy. 1921;93:18–24.

42.

Schimitschek E. Insekten als Nahrung, in Brauchtum, Kult und Kultur. In: Helmcke J-G, Stark D, Wermuth H, editors. Handbuch der Zoologie – eine Naturgeschichte der Stämme des Tierreichs, Band 4. Berlin: Akademie Verlag; 1968. p. 1–62.

43.

Cherniack EP. Bugs as drugs, Part 1: Insects. The “new” alternative medicine for the 21st century? Altern Med Rev. 2010;15(2):124–35.PubMed

44.

Keferstein A. Über den unmittelbaren Nutzen der Insekten. 1827 (cited in [39]).

45.

Jühling J. Die Tiere in der deutschen Volksmedizin. (cited in [40]); 1900.

46.

Umemura J. Konchu honzo. Nagoya: Shobunkan (Reprinted 1988 by Tokyo Kagaku Shoin Co. Ltd.); 1943.

47.

Weiss HB. Entomological medicaments of the past. J NY Entomol Soc. 1947;55:155–68.

48.

Reid BE. Chinese Materia Medica: Insect drugs, dragon and snake drugs. Chinese Medicine Series 2. Taipei: Materials Center Inc; 1982.

49.

Van Huis A. Medical and stimulating properties ascribed to arthropods and their products in sub-Saharan Africa. In: Motte-Florac E, Thomas JMCP, editors. Les insectes dans la tradition orale - insects in oral literature and traditions. Paris: Peeters Selat (Ethnosciences); 2002. p. 367–82.

50.

Yang JT, Hou FN. The protocol for studying classification and identification of insects used for Chinese medicine. Biol Sci (Taiwan). 2002;45(1):14–9. In Chinese.

51.

Kutalek R, Prinz. Ethnoentomologie Afrikas - Insekten in traditioneller Therapie und Prophylaxe. Denisia. 2004;13:529–39.

52.

Costa-Neto EM. Entomotherapy, or the medicinal use of insects. J Ethnobiol. 2005;25(1):93–114.CrossRef

53.

Costa-Neto EM. Animal-based medicines: biological prospection and the suitable use of zootherapeutic resources. Anais Acad Brasil Ciências. 2005;77(1):33–43.

54.

Ding Z, Zhao Y, Gao X. Medicinal terrestrial arthropods in China. In: Paoletti MG, editor. Ecological implications of minilivestock—potential of insects, rodents, frogs and snails. Enfield: Science Publ; 2005. p. 481–90.

55.

Ding Z, Zhao Y, Gao X. Medicinal insects in China. Ecol Food Nutr. 1997;36:209–20.CrossRef

56.

Pemberton RW. Contempory use of insects and other arthropods in traditional Korean medicine (Hanban) in South Korea and elsewhere. In: Paoletti MG, editor. Ecological implications of minilivestock - potential of insects, rodents, frogs and snails. Enfield: Science Publ; 2005. p. 459–74.

57.

Bonnemain B. Helix and drugs: snails for Western health care from antiquity to the present. Evid-based Compl Alt Med. 2005;2:25–8. doi:10.1093/ecam/neh057.CrossRef

58.

Thomas S. Medicinal use of terrestrial molluscs (slugs and snails) with particular reference to their role in the treatment of wounds and other skin lesions. http://www.worldwidewounds.com/2013/July/Thomas/slug-steve-thomas.html. Accessed 7 Dec 2015.

59.

Costa-Neto EM, Oliveira MVM. Cockroach is good for asthma: zootherapeutic practices in northeastern Brazil. Res Human Ecol. 2000;7(2):41–51.

60.

Costa-Neto EM, Ramos-Elorduy J, Pino JM. Los insectos medicinales de Brasil: primeros resultados. Boletín Socied Entmol Aragonesa. 2006;38(1):395–414.

61.

Senthilkumar N, Barthakur ND, Rao L. Bioprospecting with reference to medicinal insects and tribes in India: an overview. Ind Forester. 2008;12:1575–91.

62.

Hoffmann HJ. Ernstes und Kurioses über Wanzen - ein heteroptologisches Panoptikum. Denisia. 2006;NS 50(19):95–136.

63.

Srivastava SK, Babu N, Pandey H. Traditional insect bioprospecting - as human food and medicine. Ind J Trad Knowl. 2009;8(4):485–94.

64.

Meyer-Rochow VB, Chakravorty J. Notes on entomophagy and entomotherapy generally and information on the situation in India in particular. Appl Entomol Zool. 2013;48:105–12. doi:10.1007/s13355-013-0171-9.CrossRef

65.

Chakravorty J, Ghosh S, Meyer-Rochow VB. Practices of entomophagy and entomotherapy by members of the Nyishi and Galo tribes, two ethnic groups of the state of Arunachal Pradesh (North-East India). J Ethnobiol Ethnomed. 2011;7:5. http://www.ethnobiomed.com/content/7/1/5.PubMedPubMedCentralCrossRef

66.

Chakravorty J, Ghosh S, Meyer-Rochow VB. Comparative survey of entomophagy and entomotherapeutic practices in six tribes of Eastern Arunachal Pradesh (India). J Ethnobiol Ethnomed. 2013;9:50. http://www.ethnobiomed.com/content/9/1/50.PubMedPubMedCentralCrossRef

67.

Alves RRN. Fauna used in popular medicine in NE Brazil. J Ethnobiol Ethnomed. 2009;5:1–30.PubMedPubMedCentralCrossRef

68.

Meyer-Rochow VB. Entomophagy and its impacts on world cultures: the need for a multidisciplinary approach. In: Durst PB, Johnson DV, Leslie RN, Shono K, editors. Forest insects as food: humans bite back. Bangkok: FAO; 2010. p. 23–36.

69.

Pemberton RW. Insects and other arthropods used as drugs in Korean traditional medicine. J Ethnopharmacol. 1999;65:207–16.PubMedCrossRef

70.

Meyer-Rochow VB. Ethnoentomological observations from North Korea (officially known as the “Democratic People’s Republic of Korea”). J Ethnobiol Ethnomed. 2013;9:7. http://www.ethnobiomed.com/content/9/1/7.PubMedPubMedCentralCrossRef

71.

Okamoto H, Muramatsu S. Shokuyou oyobi yakuyo konchu ni kansurus chousa [Research report of edible and medicinal insects in Korea]. Suwon: Kangyo Mohanjo Kenkyo Hokoku No 7; 1922. p. 1–151.

72.

Nonaka K. Mushi ha gochisou! Enjoying insects as food. Tokyo: Komine Shyoten; 2009.

73.

Kakati LN, Doulo V. Indigenous knowledge system of zootherapeutic use of Chakhesang tribe of Nagaland, India. J Hum Ecol. 2002;13(6):419–23.

74.

Solanki GS, Chutia P. Entomotherapy in tribal communities in Arunachal Pradesh. Natl J Life Sci. 2008;5(2):281–4.

75.

Alves RRN, Rosa IL, Albuquerque UP, Cunningham AB. Medicine from the wild: an overview of the use and trade of animal products in traditional medicines. In: Alves RRN, Rosa IL, editors. Animals in traditional folk medicine. Berlin: Springer Verlag; 2013. p. 25–42.CrossRef

76.

Meyer-Rochow VB. Food taboos: their origins and purposes. J Ethnobiol Ethnomed. 2009;5:18. doi:10.1186/1746-4269-5-18.PubMedPubMedCentralCrossRef

77.

Chinlampianga M, Singh RK, Shukla AC. Ethnozoological diversity of northeast India: empirical learning with traditional knowledge holders of Mizoram and Arunachal Pradesh. Ind J Trad Knowledge. 2013;12(1):18–30.

78.

Lev E. Healing with animals in Levant from the 10th to the 18th century. J Ethnobiol Ethnomed. 2006;2:11. doi:10.1186/1746-4269-2-11.PubMedPubMedCentralCrossRef

79.

Oudhia P. Traditional knowledge about medicinal insects, mites and spiders in Chhattisgarh, India. Insect Environment. 1995;4:57–8.

80.

Erren TC, Koch MS, Meyer-Rochow VB. Common sense: folk wisdom that ethnobiological and ethnomedical research cannot afford to ignore. J Ethnobiol Ethnomed. 2013;9:80. http://www.ethnobiomed.com/content/9/1/80.

81.

Meyer-Rochow VB. The diverse uses of insects in traditional societies. Ethnomedizin 1978–79, 5(3/4): 287–300.

82.

Taylor RJ. Butterflies in my stomach. Santa Barbara: Woodbridge Press; 1975.

83.

Finke MD. Nutrient composition of bee brood and its potential as human food. Ecol Food Nutr. 2005;44:257–70.CrossRef

84.

Yoon SY, Kwon YB, Kim HW, Roh DH, Seo HS, Lee HJ, Beitz AJ, Lee JH. Bee venom injection produces a peripheral anti-inflammatory effect by activation of a nitric oxide-dependent spinocoeruleus pathway. Neurosci Lett. 2008;430:163–8.PubMedCrossRef

85.

Son DJ, Kang J, Kim TJ, Siong HS, Sung KJ, YU Do Y, Hong JT. Melittin, a major bioactive component of bee venom toxin, inhibits PDGF receptor beta-tyrosine phosporylation and downstream intracellular signal transduction in rat aortic vascular smooth muscle cells. J Toxicol Environ Health. 2007;A70(15–16):1350–5.CrossRef

86.

Son DJ, Lee JW, Lee YH, Song HS, Lee CK, Hong JT. Therapeutic application of anti-arthritis, pain-releasing, and anti-cancer effects of bee venom and its constituent compounds. Pharmacol Therapeutics. 2007;115(2):246–70.CrossRef

87.

Yamakawa M. Insect antibacterial proteins: regulatory mechanisms of their synthesis and a possibility as new antibiotics. J Seric Sci Jpn. 1998;87(3):163–82.

88.

Park HJ, Lee SH, Son DJ, Oh KW, Kim KH, Song SH, Kim GJ, Oh GT, Yoon DY, Hong JT. Antiarthritic effect of bee venom: inhibition of inflammation mediator generation by suppression of NF-kapp B through interaction with the p50 subunit. Arthrit Rheum. 2004;50(11):3504–15.CrossRef

89.

Isidorov VA, Bakler S, Stockl M. GC-MS investigation of the chemical composition of honeybee drone and queen larva homogenate. J Apic Sci. 2016;60(1):111–20.

90.

Beck BF. Bee venom therapy. New York: Appleton-Century Co; 1935.

91.

Bogdanov S. Bee venom: composition, health, medicine: a review. http://www.bee-hexagon.net/venom/biological-therapeutic-properties. Accessed 17 July 2016.

92.

Dutta P, Dey T, Manna P, Kalita J. Antioxidant potential of Vespa affinis L., a traditional edible insect species in North East India. Plos One. 2016;1(5):e0156107. doi:10.1371/journal.pone.0156107. Accessed 17 July 2016.CrossRef

93.

Marques JGW, Costa-Neto EM. Insects as folk medicines in the state of Alagoas, Brazil. In Proceedings of the eighth International Conference on Traditional Medicine and Folklore, vol 4: Scrutinies from Western Medicine. Newfoundland, Canada Sci Soc; 1994:115–119.

94.

Nonaka K, Toms RB. Cultural use of insects in the eastern part of South Africa. In: Nonaka K, editor. Cultural geography of useful insects in southern Africa. Mie: Kenkyu Daihyousha Mie University Press; 2003. p. 13–25.

95.

Chen Y. Ants used as food and medicine in China. Food Insect Newsletter. 1994;7(2):1. 8–10.

96.

Costa-Neto EM, Motta PC. Animal species traded as ethnomedical resources in the federal district, central west region of Brazil. The Open Complement Med J. 2010;2:24–30.CrossRef

97.

Sangma RHC, Pal R, Singh DR. Edible Insects of Northeast India. In: Purkayastha J, editor. Bioprospecting of indigenous bioresources of North-East India. Singapore: Springer Science plus Business Media; 2016. p. 253–67. doi:10.1007/978-981-10-0620-3_15.CrossRef

98.

Meyer-Rochow VB. Traditional food insects and spiders in several ethnic groups of Northeast India, Papua New Guinea, Australia, and New Zealand. In: Paoletti MG, editor. Ecological implications of minilivestock—potential of insects, rodents, frogs and snails. Enfield: Science Publishers; 2005. p. 385–409.

99.

Droege G. Das Imkerbuch. Berlin: VEB Deutscher Lanwirschaftsverlag; 1984.

100.

Lokeshwari RK, Shantibala T. A review on the fascinating world of insect resources: reason for thoughts. Psyche. 2010:ID207570. doi:10.1155/2010/207570.

101.

de Figueirêdo CR, Vasconcellos A, Da Silva P, Alves RRN. Edible and medicinal termites: a global overview. J Ethnobiol Ethnomed. 2015;11:29. doi:10.1186/s13002-015-0016-4102.PubMedPubMedCentralCrossRef

102.

Njiru H, Elchalal U, Paltiel O. Geophagy during pregnancy in Africa: a literature overview. Obstet Gynecol Surv. 2011;66:452–9.PubMedCrossRef

103.

González A, Amich F, Postigo-Mota S, Vallejo JR. Therapeutic and prophylactic uses of invertebrates in contemporary Spanish ethnoveterinary medicine. J Etnobio Ethnomed. 2016;12:36. doi:10.1186/s13002-016-0111-1.

104.

Marie R. Contribution à l’histoire des insects en thérapeutique. PhD dissertation (Pharmacy). Strasbourg: Université de Strasbourg University; 1955. cited in [52].

105.

Van Huis A. The traditional use of arthropods in sub-Saharan Africa. Proc Section Exp Appl Entomol Netherlands Entomol Soc. 1996;7:3–20.

106.

Nonaka K. Ethnoentomology of the central Kalahari San. Afr Stud Monographs, Suppl. 1996;22:29–46.

107.

Anonymous: Central African Republic: proving the worth of a healing art. New York: Time Magazine; 1991.

108.

Dettner K. Gifte und Pharmaka aus Insekten - ihre Herkunft, Wirkung und ökologische Bedeutung. Entomol Heute. 2007;19:3–28.

109.

Luckmann J, Niehuis M. Die Ölkäfer in Rheinland-Pfalz und im Saarland. Landau: GNOR-Verlag; 2009.

110.

Wang GS. Medical uses of Mylabris in ancient China and recent studies. J Ethnopharmacol. 1989;26:147–62.PubMedCrossRef

111.

Wahrendorf MS, Wink. Pharmacologically active natural products in the defence secretion of Palembus ocularis (Tenebrionidae, Coleoptera). J Ethnopharmacol. 2006;106:51–6.PubMedCrossRef

112.

Kutalek R, Kassa A. The use of gyrinids and dytiscids for stimulating breast growth in East Africa. J Ethnobiol. 2005;25:115–28.CrossRef

113.

Dixit AK, Kadavul K, Rajalakshmi S, Shekhavat MS. Ethno-medico-biological studies of South India. Ind J Trad Knowl. 2010;9(1):116–8.

114.

Vallejo JR, González JA. The use of the head louse as a remedy for jaundice in Spanish folk medicine: an overview. J Ethnobiol Ethnomed. 2013;9:52. http://www.ethnobiomed.com/content/9/1/52.PubMedPubMedCentralCrossRef

115.

Chakravorty J, Ghosh S, Meyer-Rochow VB. Chemical composition of Aspongopus nepalensis Westwood 1837 (Hemiptera; Pentatomidae), a common food insect of tribal people in Arunachal Pradesh (India). Int J Vitamin Nutr Res. 2011;8(1):1–14.

116.

Dzerefos CM, Witkowski ETF, Toms R. Comparative ethnoentomology of edible stinkbugs in southern Africa and sustaianable management considerations. J Ethnobiol Ethnomed. 2013;9:20. http://www.ethnobiomed.com/content/9/1/20.

117.

Costa-Neto EM, Melo MN. Entomotherapy in the country of Matinhan dos Pretos, State of Bahia, northeastern Brazil. Food Insects Newslett. 1998;11(2):1–3.

118.

Meyer-Rochow VB, Changkija S. Uses of insects as human food in Papua New Guinea, Australia, and North-East India: cross-cultural considerations and cautious conclusions. Ecol Food Nutr. 1997;36(2–4):159–85.CrossRef

119.

Jamir NS, Lal P. Ethnozoological practices among Naga tribes. Ind J Trad Knowl. 2005;4(1):100–4.

120.

Roepke W. Insecten op Java als menselijk voedsel of als medicijn gebezigt. Entomol Berichten. 1952;14:172–4. cited in [49].

121.

Rudder J. Classification of the natural world of the Yolngu. Ethnomedizin V 3/4 (Abstract of oral presentation at ANZAAS. Auckland: ANZAAS; 1979.

122.

Armstrong DG, Salesn P, Short B, Martin BR, Kimbriel HR, Nixon BP, Boulton AJ. Maggot therapy in “lower extremity hospice” wound care: fewer amputations band more antibiotic-free days. J Am Podiatr Med Assocn. 2005;95(3):254–7.CrossRef

123.

Bell NJ, Thomas S. Use of sterile maggots to treat panniculitis in an aged donkey. Vet Rec. 2001;149(25):768–70.PubMed

124.

Sherman RA, Morrison S, Ng D. Maggot debridement therapy for serious horse wounds - a survey of practitioners. Vet J. 2006;174:86–91.PubMedCrossRef

125.

Fasoranti JO. The place of insects in the traditional medicine of southwestern Nigeria. The Food Insect Newsletter. 1997;10(2):1–5.

126.

Zimmer MM, Frank J, Barker JH, Becker H. Effect of extracts from the Chinese and European mole cricket on wound epithelialisation and neovascularisation: in vivo studies in the hairless mouse ear wound model. Wound Repair Regener. 2006;14:142–51.CrossRef

127.

Alemla Ao M, Singh HK. Utilization of insects as human food in Nagaland. Ind J Entomol. 2004;66(4):308–10.

128.

Chakravorty J, Gogoi M, Meyer-Rochow VB. Cultural attributes and traditional knowledge in connection with the rearing of Muga (Antheraea assama = assamensis) in the Dhemaji District of Assam, North-East India. J Insect Biotech Sericol. 2015;84(1):17–28.

129.

Britton EB. A pointer to a new hallucinogen of insect origin. J Ethnopharmacol. 1984;12:331–3.PubMedCrossRef

130.

Antonio TMF. Insects as remedies for illnesses in Zaire. Food Newslett. 1984;7(3):3–5.

131.

Boyle R. The joy of cooking insects. Audubon. 1992;94(5):100–3.

132.

Xu L, Pan H, Lei Q, Xiao W, Peng Y, Xiao. Insect tea, a wonderful work in the Chinese tea culture. Food Res Int. 2013;53(2):629–35.CrossRef

133.

Molan PC. Why honey is effective as a medicine. I. Its use in modern medicine. Bee World. 1999;80(2):80–92.CrossRef

134.

Meyer-Rochow VB. Local taxonomy and terminology for some terrestrial arthropods in five different ethnic groups of Papua New Guinea and Central Australia. J Roy Soc W Austr. 1975;58(1):15–30.

135.

Meyer-Rochow VB, Nonaka K, Boulidam S. More feared than revered: Insects and their impacts on human societies (with some specific data on the importance of entomophagy in a Laotian setting). Entomologie Heute. 2008;20:3–25.

136.

Moon S-S, Cho N, Shin J, Seo Y, Lee CO, Sang UC. Jineol, a cytotoxic alkaloid from the centipede Scolopendra subspinipes. J Nat Prod. 1996;59(8):777–9.CrossRef

137.

Roheim G. Children of the desert - the western tribes of Central Australia. NewYork: Basic Books Inc Publ; 1974.

138.

Noguchi S, Mori N, Higa H, Kuwahara Y. Identification of mandelonitrite as a major secretary compound of Chamberlinius hualienensis Wang (Polydesmidae, Paradoxosomatidae). Jap J Environ Entomol Zool. 1997;8:208–14.

139.

Enghoff H, Manno N, Tchibozo S, List M, Schwarzinger B, Schoefberger W, Schwarzinger C, Paoletti MG. Millipedes as food for humans: their nutritional and possibly antimalarial value – a first report. Evidence-based Compl Altern Med. 2014:9. Article ID 651768. http://dx.doi.org/10.1155/2014/651768. Accessed 14 Mar 2016.

140.

Bode F, Sachs F, Franz MR. Tarantula peptide inhibits atrial fibrillation. Nature. 2001;409(6816):35–6.PubMedCrossRef

141.

Atakuziev BU, Wright CE, Graudins A, Nicholson GM. Efficacy of Australian red-back spider (Latrodectus hasselti) antivenom in the treatment of cliniucal envenomation by the cupboard spider Staegtoda capensis (Theridiidae). Toxicon. 2014;86:68–78.PubMedCrossRef

142.

Das Gupta S, Debnath A, Saha A, Giri B, Tripathi G, Vedasiromoni JR, Gomes A, Gomes A. Indian black scorpion (Heterometrus bengalensis Koch) venom induced antiproliferative and apoptogenic activity against human leukemic cell lines U937 and K562. Leuk Res. 2007;31:817–25.PubMedCrossRef

143.

Das Gupta SD, Gomes A, Debnath A, Saha A. Apoptosis induction in human leukemic cells by a novel protein Bengalin, isolated from Indian black scorpion venom: through mitochondrial pathway and inhibition of heat shock proteins. Chem Biol Interact. 2010;183:293–303.CrossRef

144.

Gomes A, Haldar S, Giri B, Mishra R, Saha A, Dasgupta S, Gomes A. Experimental osteoporosis induced in female rats and its antagonism by Indian black scorpion (Heterometrus bengalensis C.L. Koch) venom. Toxicon. 2009;53:60–8.PubMedCrossRef

145.

Haldar S, Das Gupta S, Gomes A, Giri B, Dasgupta SC, Biswas A, Mishra R, Gomes A. A high molecular weight protein Bengalin from the Indian black scorpion (Heterometrus bengalensis C.L. Koch) venom having antiosteoporosis activity in female albino rats. Toxicon. 2010;55:455–61.PubMedCrossRef

146.

Mazzuca M, Heurteaux C, Alloui A, Diochot S, Baron A, Voilley N, Blondeau N, Escoubas P, Gélot A, Cupo A, Zimmer A, Zimmer AM, Eschalier A, Lazdunski M. A tarantula peptide against pain via ASIC1a channels and opioid mechanisms. Nat Neurosci. 2007;10(8):943–5.PubMedCrossRef

147.

Park SP, Kim BM, Koo JY, Cho H, Lee CH, Kim M, Na HS, Oh U. A tarantula spider toxin. GsMTx4, reduces mechanical and neuropathic pain. Pain. 2008;137(1):208–17.PubMedCrossRef

148.

Machkour-M’rabet S, Hénaut Y, Winterton P, Rojo R. A case of zootherapy with the tarantula Brachypelma vagans Ausserer, 1875 in traditional medicine of the Chol Mayan ethnic group in Mexico. J Ethnobiol Ethnomed. 2011;7:12. doi:10.1186/1746-4269-7-12.PubMedPubMedCentralCrossRef

149.

Patel SB, Bhatt N, Patel KB. Review – traditional zootherapeutic uses of spiders. Life Sci Leaflets. 2012;12:174–80.

150.

Cooke A, Tonks P, Jones FM, O’Shea H, Hutchings P, Fulford AJC, Dunne DW. Infection with Schistosoma mansoni prevents insulin dependent diabetes mellitus in non-obese diabetic mice. Parasite Immunol. 1999;21:169–76.PubMedCrossRef

151.

Reddy A, Fried B. An update on the use of helminthes to treat Crohn’s and other autoimmune diseases. Parasitol Res. 2008;104(8):217–21.PubMed

152.

Cooper EL, Balamurugan M, Huang CY, Tsao CR, Heredia J, Tommaseo-Ponzett M, Paoletti MG. Earthworms dilong: ancient, inexpensive, noncontroversial models may help clarify approaches to integrated medicine emphasizing neuroimmune systems. Evidence-Based Compl Altern Med. 2012, e-CAM Article ID 164152, doi:10.1155/2012/164152.

153.

Borah MP, Prasad SB. Ethnozoological remedial uses by the indigenous inhabitants in adjoining areas of Pobitara wildlife sanctuary, Assam, India. Int J Pharmacy Pharmaceut Sci. 2016;8(4):90–6.

154.

Prakash BM, Gunasekaran BG, Elumala K. Effect of earthworm powder on antioxidant enzymes in alcohol induced hepatotoxic rats. Eur Rev Med Pharmacol Sci. 2008;12:237–43.PubMed

155.

Zhang FX, Guo BZ, Wang HY. The spermatocidal effects of earthworm extract and its effective constituents. Soil Biol Biochem. 1992;24(12):1247–51.CrossRef

156.

Engelmann P, Molnar L, Palinkas L, Cooper EL, Nemeth P. Earthworm leukocyte populations specifically harbour lysosomal enzymes that may respond to bacterial challenge. Cell Tiss Res. 2004;316:391–401.CrossRef

157.

Cooper EL, Hrzenjak TM, Grdiša. Alternative sources of fibrinolytic, anticoagulative, antimicrobial and anticancer molecules. In J Immunopathol Pharmacol. 2004;17(3):237–44.CrossRef

158.

Hrženjak T, Hrženjak M, Kašuba V, Effenburger-Marinculić P, Levanat. A new source of biologically active compounds - earthworm tissue (Eisenia foetida, Lumbricus rubelus). Comp Biochem Physiol. 1992;102A(3):441–7.CrossRef

159.

Li W, Xie L, Chen Z, Zhu Y, Sun Y, Miao Y, XU Z, Han X. Cantharidin, a potent and selective PP2A inhibitor, induces an oxidative stress-independent growth inhibition of pancreatic cancer cells through G2/M cell-cycle arrest and apoptosis. Cancer Sci. 2010;101(5):1226–33.PubMedCrossRef

160.

Stamenova PK, Marchetti T, Simeonov I. Efficacy and safety of tropical hirudin (Hirudex): a double-blind, placebo-controlled study. Eur Rev Med Pharmacol Sci. 2001;5:37–42.PubMed

161.

Hill EA, Hunt CO, Lucarini G, Mutri G, Farr L, Barker G. Land gastropod piercing during late Peistocene and early Holocene in the Haua Fteah, Libya. J Archaeol Sci Rep. 2015;4:320–5.

162.

Schoeninger MJ, Peebles CS. Effect of Mollusc eating on human bone Strontium levels. J Archaeol Sci. 1981;8:391–7.CrossRef

163.

Quave CL, Pieroni A, Bennett BC. Dermatological remedies in the traditional pharmacopoeia of Vulture-Alto Brandano, inland southern Italy. J Ethnobiol Ethnomed. 2008;4:5. doi:10.1186/1746-4269-4-5.PubMedPubMedCentralCrossRef

164.

Pons F, Koenig M, Michelot R, Mayer M, Frossard N. L’effet bronchorelaxant de l’hélicidine, un extrait d’Hélix pomatia, fait intervenir une libération de prostaglandine E2. Pathol Biol. 1999;47:73–80.PubMed

165.

Dwek MV, Ross HA, Streets AJ, Brooks SA, Adam E, Titcomb A, Woodside JV, Schumacher U, Leathe AJ. Helix pomatia agglutinin lectin-binding oligosaccharides of aggressive breast cancer. Int J Cancer. 2001;95:79–85.PubMedCrossRef

166.

Kubota Y, Watanabe Y, Otsuka H, Tamiya T, Tsuchiya T, Matsumoto JJ. Purification and characterization of an antibacterial factor from snail mucus. Comp Biochem Physiol. 1985;82(2):345–8.CrossRef

167.

Brieva A, Philips N, Tejedor R, Guerrero A, Pivel JP, Alonso-Lebrero JL. Molecular basis for the regenerative properties of a secretion of the mollusk Cryptomphalus aspersa. Skin Pharmacol Physiol. 2008;21(1):15–22.PubMedCrossRef

168.

Fabi SG, Cohen JL, Peterson JD, Kiripolsky MG, Goldman MP. The effects of filtrate of the secretion of the Cryptomphalus aspersa on photoaged skin. J Drugs Dermatol. 2013;12(4):453–7.PubMed

169.

Quevauviller A, Mainil J, Garcet S. Le mucus d’Hélix pomatia L. - préparation, composition, propriétés thérapeutiques et pharmacodynamiques. Rev Pathol Gen Comp. 1953;653:1514–38.

170.

Dolashka P. Biologically active components in the garden snail and their applications. Scientific Rep, University of Rousse. 2012;519(Ser 9.2):74–8 (in Bulgarian).

171.

Dolashka P, Kabadzhova P. Garden snail - rich source of active components. https://sites.google.com/site/snailscosmetics/. Accessed 20 Jan 2017.

172.

Mahawar MM, Jaroli DP. Animals and their products utilized as medicines by the inhabitants surrounding the Ranthambhore National Park. India J Ethnobiol Ethnomed. 2006;2:46. doi:10.1186/1746-4269-2-46.PubMedCrossRef

173.

Kunin WE, Lawton JH. Does biodiversity matter? Evaluating the case of conserving species. In: Gaston KJ, editor. Biodiversity: a biology of numbers and differences. Oxford: Blackwell Sci; 1996. p. 283–308.

174.

Dossey AT. Insects and their chemical weaponry: new potential for drug discovery. Nat Prod Rep. 2010;27:1727–32.CrossRef

175.

Andary C, Motte-Florac E, Ramos-Elorduy J, Privat A. Chemical screening: updated methodology applied to medical insects. In The Third European Colloquium on Ethnopharmacology and First International Conferece on Anthropology and History of Health and Disease: Abstracts. Gênova, Erga Edizione; 1996: CD-ROM (cited in [52] and [174]).

176.

Alves RRN, Albuquerque UP. Animals as a source of drugs: bioprospecting and biodiversity conservation. In: Alves RRN, Rosa IL, editors. Animals in traditional folk medicine. Berlin: Springer; 2013. p. 67–90.CrossRef

177.

Eloff JN, Teffo LS, Toms RB, Aderogba AM. The possible interaction between an edible insect and five antibacterial kaempferol methyl ethers isolated from Dodoaea viscose Jacq. var. angustifolia (Sapindaceae) leaf extracts. Planta Med. 2007;73:SL014.CrossRef

178.

Lee JA, Son MJ, Choi J, Jun JH, Kim JI, Lee MS. Bee venom acupuncture for rheumatoid arthritis: a systematic review of randomised clinical trials. London. BMJ Open. 2014;4:e006140. doi:10.1136/bmjopen-2014-006140.PubMedPubMedCentralCrossRef

179.

Bisset NG. One man’s poison, another man’s medicine? J Ethnopharmacol. 1991;32:71–81.PubMedCrossRef

180.

Prakash S, Bhargava HR. Apis cerana bee venom: its anti-diabetic and anti-dandruff activity against Malassezia furfur. World Appl Sci J. 2014;32(3):343–8.

181.

Diamond G. Nature’s antibiotics: the potential of antimicrobial peptides as new drugs. Biologist. 2001;48:209–12.PubMed

182.

Jones D. The neglected saliva: medically important toxins in the saliva of human lice. Parasitol. 1998;116:973–81.CrossRef

183.

Wolff H, Hansson C. Larval therapy for a leg ulcer with methicillin-resistant Staphylococcus aureus. Acta Derm Venereol. 1999;79(4):320–1.PubMedCrossRef

184.

Steenvoorde P, Jukema GN. The antimicrobial activity of maggots: in-vivo results. J Tiss Viability. 2004;14(3):97–101.CrossRef

185.

Aili SR, Touchard A, Escoubas P, Padula MP, Orivel J, Dejean A, Nicholson GM. Diversity of peptide toxins from stinging ant venoms. Toxicon. 2014;92:166–78.PubMedCrossRef

186.

Veal DA, Trimble JE, Beattie AJ. Antimicrobial properties of secretions from the metapleural glands of Myrmecina gulosa (the Australian bull ant). J Appl Microbiol. 1992;72(3):188–94.

187.

Nikbakhtzadeh MR, Tirgari S. Medically important beetles (Insecta: Coleoptera) in Iran. J Venom Anim Toxins Incl Trop Dis. 2008;14(4):597–618.CrossRef

188.

Frank JH, Kanamitsu K. Paederus sensu lato (Coleoptera, Staphylinidae): natural history and medical importance. J Med Entomol. 1987;24:155–91.PubMedCrossRef

189.

Knapp J, Bokník P, Lüss I, Huke S, Linck B, Lüss H, Müller FU, Müller T, Nacke P, Noll T, Piper HM. The protein phosphatase inhibitor cantharidin alters vascular endothelial cell permeability. J Pharmacol Exp Therap. 1999;289(3):1480–6.

190.

Ghaffarifar F. Leishmania major: in vitro and in vivo anti-leishmania effect of cantharidin. Exp Parasitol. 2010;126(2):126–9.PubMedCrossRef

191.

Dorn DC, Kou CA, Png KJ, Moore MAS. The effect of cantharidin on leukemic stem cells. Int J Cancer. 2009;124(9):2189–99.CrossRef

192.

Yu T, Hou F, Liu M, Zhou L, Li D, Liu J, Fan Z, Li Q. Norcantharidin anti-angiogenesis activity possibly through an endothelial cell pathway in human colorectal cancer. Asian Pacific J Cancer Prevent. 2012;13:499–503.CrossRef

193.

Rai PK, Singh AK, Singh OP, Rai NP, Dwivedi AK. Efficacy of leech therapy in the management of osteoarthritis. Ayu. 2011;32(2):213–7.PubMedPubMedCentralCrossRef

194.

Zaidi SMA, Jameel SS, Zaman F, Jilani S, Sultana A, Khan SA. A systematic overview of the medicinal importance of sanguivorous leeches. Altern Med Rev. 2011;16(1):59–65.PubMed

195.

Ingole AR, Dhabarde DM, Kamble MA, Potnis VV. Modern touch to traditional leech therapy: a review. Res J Pharmaceut Biol Chem Sci. 2013;4(3):557–63.

196.

Li GQ, Wang KY, Li DH, Wang N, Liu DH. Cloning, expression and characterization of a gene from earthworm Eisenia foetida encoding a blood-clot dissolving protein. PLoS One. 2012;7(12):e53110. doi:10.371/journal.pone0053110.PubMedPubMedCentralCrossRef

197.

Meyer-Rochow VB. New observations - with older ones reviewed- on mass migrations in millipedes based on a recent outbreak on Hachijojima Izu Islands) of the polydesmid diplopod Chanberlinius hualienensis, Wang 1956: Nothing appears to make much sense. Zool Res. 2015;35(1):119–32.

198.

Francischetti IM, Mather TN, Ribeiro JM. Tick saliva is a potent inhibitor of endothelial cell proliferation and angiogenesis. Thromb Haemost. 2005;94:167–74.PubMedPubMedCentral

199.

Cameiro-Lobo TC, Schaffner F, Disse J, Ostergaard H, Francischetti IM, Monteiro RQ, Ruf W. The tick-derived inhibitor Ixolaris prevents tissue factor signalling on tumor cells. J Thromb Haemost. 2012;10(9):1849–58.CrossRef

200.

Ribeiro JMC, Arca B. From sialomes to the sialoverse: an insight into salivary potion of blood-feeding insects. Adv Insect Physiol. 2009;37:59–118.CrossRef

201.

Lee CG, Silva CAD, Lee J-Y, Harti D, Elias JA. Chitin regulation of immune responses: an old molecule with new roles. Curr Opinion Immunol. 2008;20:684–9.CrossRef

202.

Reese TA, Liang H-E, Tager AM, Luster AD, Rooijen NV, Voehringer D, Locksley RM. Chitin induces accumulation in tissue of innate immune cells associated with allergy. Nature. 2007;447:92–6.PubMedPubMedCentralCrossRef

203.

Muzzarelli RAA. Chitins and chitosans as immunoadjuvants and non-allergic drug carriers. Mar Drugs. 2010;8:292–312.PubMedPubMedCentralCrossRef

204.

Lopez-Levers L. Traditional healing as indigenous knowledge: its relevance to HIV/AIDS in southern Africa and the implications for counsellors. J Psychol Afr. 2006;1:87–100.

205.

Cooper JE, Cunningham AA. Pathological investigation of captive invertebrates. Int Zool Ybk. 1991;30:137–43.CrossRef

206.

Lewbart GA. Invertebrate medicine. Chichester: Wiley-Blackwell; 2006.CrossRef

207.

Solter L. Invertebrate pathology. http://arwh.org/sites/default/files/files-uploads/09%20Invertebrate%20Pathology.pdf. Accessed 14 Oct 2016.

208.

Oldfield ML. The value of conserving genetic resources. Washington, DC: Natl Park Service; 1989 (cited in [59]).

209.

Harshbarger JC, Taylor RL. Neoplasms of insects. Ann Rev Entomol. 1968;13:159–90.CrossRef

210.

Vogt G. How to minimize formation and growth of tumours: potential benefits of decapods crustaceans for cancer research. Int J Cancer. 2008;123:2727–34.PubMedCrossRef

211.

Tascedda F, Ottaviani E. Tumors in invertebrates. Invert Surviv J. 2014;11:197–203.

212.

Alves RRN, Alves HN. The faunal drugstore: animal-based remedies used in traditional medicines in Latin America. J Ethnobiol Ethnomed. 2011;7:9.

213.

Oliveira ES, Torres DF, Brooks SE, Alves RRN. The medicinal animal markets in the metropolitan region of Natal City, Northeastern Brazil. J Ethnopharmacol. 2010;130(1):54–60.PubMedCrossRef

214.

Martinez GJ. Use of fauna in the traditional medicine of native Toba (qom) from the Argentine Gran Chaco region: an ethnozoological and conservationist approach. Ethnobiol Conserv. 2013;2(2):1–43.

215.

Ferreira FS, Albuquerque UP, Coutinho HDM, Almeida WO, Alves RRN. The trade in medicinal animals of Northeastern Brazil. Evidence-based Compl Alt Med. 2012;2012:1–20.CrossRef

216.

Chakravorty J, Meyer-Rochow VB, Ghosh S. Vertebrates used for medicinal purposes by members of the Nyishi and Galo tribes in Arunachal Pradesh (North-East India). J Ethnobiol Ethnomed. 2011;7:13.PubMedPubMedCentralCrossRef

217.

Anonymous: Medicinal animal use (zootherapy) amongst the KhoeSan of Namibia, South Africa and Botswana. https://s3-eu-west-1.amazonaws.com/esrc-files/…/Knoa39lCqEWoOZDa1TfKiQ. Accessed 20 Jan 2017.

218.

Soewa DA. Zootherapy and biodiversity conservation in Nigeria. In: Alves RRN, Rosa IL, editors. Animals in traditional folk medicine. Berlin: Springer Verlag; 2013. p. 347–65.CrossRef

219.

Alves RRN, Dias TLP. Usos de invertebrados na medicina popular no Brasil e suas implicações para conservação. Trop Conserv Sci. 2010;3(2):159–74.CrossRef

220.

Ferreira FS, Fernandes-Ferreira H, Leo Negto N, Brito SV, Alves RRN. The trade of medicinal animals in Brazil: current status and perspectives. Biodivers Conserv. 2013;22:839–70.CrossRef

221.

Ferreira FS, Brito SV, Almeida WO, Alves RRN. Conservation of animals traded for medicinal purposes in Brazil: can products derived from plants or domestic animals replace products of wild animals? Reg Environm Change. 2016;16:543–51.CrossRef

222.

Hamilton W. The hygiene hypothesis unravelled: gut-dwelling parasites may protect us against potentially deadly diseases. Science Articles 2013, University of Cambridge: http://www.thenakedscientists.com/HTML/articles/article/the-hygiene-hypothesis-unraveled/. Accessed 21 Nov 2016.

223.

Anonymous: Helminthic therapy in Science and the media. http://www.foodsmatter.com/natural_medicine_comp_therapies/helminthic_therapy/articles/helminthic-therapy-in-science-and-the-media.pdf. Accessed 21 Nov 2016.

224.

Roberts D. Are worms vital to human health? BBC News, 2009, http://news.bbc.co.uk/2/hi/health/7856095.stm. Accessed 14 Oct 2016.

225.

Rook GAW. The hygiene hypothesis and Darwinian medicine. Basel: Birkhäuser Verlag; 2009.CrossRef

226.

Wu D, Molofsky AB, Liang H-E, Ricardo-Gonzalez RR, Jouihan HA, Bando, Chawla A, Locksley RM. Eosinophils sustain adipose alternatively activated macrophages associated with glucose homeostatsis. Science. 2011;332:243–7.PubMedPubMedCentralCrossRef

227.

Eldor A, Orevi M, Rigbi M. The role of leeches in medical therapeutics. Blood Rev. 1996;10(4):201–9.PubMedCrossRef

228.

Costa-Neto EM. Zootherapy based medicinal traditions in Brazil. Honey Bee. 2000;11(2):4–6.

229.

Cremati J. Sensitized Slug Slime Recipe. University of Saskatchewan 2007; Available from URL: http://www.usask.ca/lists/alt-photo-process-l/200712/msg00196.html. Accessed 20 July 2016.

230.

Richardson H. Slug on a thorn. Pitt Rivers Museum Website 2013; Available from URL: http://england.prm.ox.ac.uk/englishness-slug-on-a-thorn.html. Accessed 20 Jul 2016.

231.

Kim H, Song M-J. Ethnomedical practices for treating liver disorders of local communities in the southern regions of Korea. Evid-based Compl Altern Med Article ID, 2013;869176:11. doi:10.1155/2013/869176.

232.

Finkl CW. Os medicamentos do mar. In: Cousteau JY, editor. Encyclopédia dos mares, vol. 1. Rio-de-Janeiro: Salvat; 1984. p. 74–5. (cited in [210]).

233.

Peng K, Kong Y, Zhai L, Wu X, Jia P, Liu J, Yu H. Two novel antimicrobial peptides from centipede venoms. Toxicon. 2010;55(2–3):274–9.PubMedCrossRef

234.

Lee JE, Kim IW, Kim MA, Ahn MY, Yun EY, Hwang JS. Antimicrobial activity of the scolopendrasin V-peptide identified from the centipede, Scolopendra subspinis mutilans. J Microbiol Biotechnol. 2016. doi:10.4014/jmb.1609.09057. [Epub ahead of print].

Title: Therapeutic arthropods and other, largely terrestrial, folk-medicinally important invertebrates: a comparative survey and review
Author: V. Benno Meyer-Rochow
Publication date: 01-12-2017
Publisher: BioMed Central
Published in: Journal of Ethnobiology and Ethnomedicine / Issue 1/2017
Electronic ISSN: 1746-4269
DOI: https://doi.org/10.1186/s13002-017-0136-0

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Therapeutic arthropods and other, largely terrestrial, folk-medicinally important invertebrates: a comparative survey and review

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Keynote webinar | Spotlight on medication adherence

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Abstract

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