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- BookDomenico Bonamonte, Gianni Angelini, editors.Contents:
Preface
1 Introduction and general principles
2 The aquatic environment and its biotoxins: Toxic aquatic animals
3 The aquatic environment and the function of biotoxins
4 Biochemistry of biotoxins in the aquatic environment
5 Dermatitis caused by Coelenterates: Coelenterates nematocysts
6 Dermatitis caused by Coelenterates: Nematocyst poison
7 Dermatitis caused by Coelenterates: Reactions to jellyfish
8 Dermatitis caused by Coelenterates: Reactions to sea anemones
9 Seabather eruption
10 Dermatitis caused by Coelenterates: Reactions to physaliae (Skin and systemic reactions)
11 Dermatitis caused by Echinoderms
12 Dermatitis caused by Molluscs
13 Lesions caused by Arthropods
14 Dermatitis caused by sponges
15 Dermatitis caused by algae and Bryozoans
16 Dermatitis caused by aquatic worms
17 Dermatitis caused by fish
18 Dermatitis caused by aquatic bacteria
19 Aquatic skin diseases from physical and chemical causes.Digital Access Springer 2016 - ArticleZielke E, Kuhlow F.Tropenmed Parasitol. 1977 Mar;28(1):68-70.From a colony of C.p.fatigans from Monrovia showing 21.6% susceptibility of W. bancrofti a refractory strain could be selected but not a highly susceptible one. Experiments to select a refractory strain out of the highly susceptible colony from Delhi failed. From these results and those of the crossing experiments between the selected refractory strain from Monrovia and the Delhi colony it appears that in the mosquito population from Monrovia susceptibility for W. bancrofti is not dominating refractoriness while this is the case in the population from Delhi. Therefore, it is concluded that there will be at least two genetic factors controlling susceptibility for W. bancrofti in C.p.fatigans.