* Mendel Z, Lynch SC, Eskalen A, Protasov A, Maymon M, Freeman S (2021) What determines host range and reproductive performance of an invasive ambrosia beetle Euwallacea fornicatus; lessons from Israel and California. Frontiers in Forests and Global Change 4, 654702.
------- Non reproductive host tree in Israel.
* Smith SM, Gomez DF, Beaver RA, Hulcr J, Cognato AI (2019) Reassessment of the species in the Euwallacea fornicatus (Coleoptera: Curculionidae: Scolytinae) complex after the rediscovery of the ‘lost’ type specimen. Insects 10, 261. https://doi.org/10.3390/insects10090261
* Malembic-Maher S, Desqué D, Khalil D, Salar P, Bergey B, Danet J-L, Duret S, (...), Foissac X (2020) When a Palearctic bacterium meets a Nearctic insect vector: Genetic and ecological insights into the emergence of the grapevine Flavescence dorée epidemics in Europe. PLOS Pathogens 16(3), e1007967. https://doi.org/10.1371/journal.ppat.1007967
------- Confirmed host.
* Radonjic S, Hrncic S, Krstic O, Cvrkovic T, Mitrovic M, Jovic J & Tosevski I (2013) First report of Alder yellows phytoplasma infecting common and grey alder (Alnus glutinosa and A. incana) in Montenegro. Plant Disease 97, 686-686.
INTERNET
* Robinson GS, Ackery PR, Kitching I, Beccaloni GW, Hernández LM (2023). HOSTS (from HOSTS - a Database of the World's Lepidopteran Hostplants). Natural History Museum. https://data.nhm.ac.uk/dataset/hosts/resource/877f387a-36a3-486c-a0c1-b8d5fb69f85a
------- Probably feeding host only
* Plant-SyNZ. Landcare Research (NZ). Host plants of a herbivore -Oemona hirta. http://plant-synz.landcareresearch.co.nz/index.asp). Last accessed 2021-06.
* Rizzoli A, Belgeri E, Jermini M, Conedera M, Filippin L, Angelini E (2021) Alnus glutinosa and Orientus ishidae (Matsumura, 1902) share phytoplasma genotypes linked to the ‘Flavescence dorée’ epidemics. Journal of Applied Entomology 145(10), 1015-1028.
------- Confirmed host, O. ishidae can complete its life cycle on A. glutinosa.
* INTERNET
Regione Lombardia. Servizio fitosanitario. Organismi nocivi. Popillia japonica. Specie particolarmente sensibili a Popillia japonica. https://www.regione.lombardia.it/wps/wcm/connect/64dfeeea-c26a-4bf1-995d-660f87136d87/Specie+sensibili+Popillia+japonica+2020.pdf?MOD=AJPERES&CACHEID=ROOTWORKSPACE-64dfeeea-c26a-4bf1-995d-660f87136d87-nbxAUOb
* CAPS (2019) Trichoferus campestris. Cooperative Agricultural Pest Survey pest datasheets. http://download.ceris.purdue.edu/file/3869
* Iwata R & Yamada F (1990) Notes on the biology of Hesperophanes campestris, a drywood borer in Japan. Material und Organismen 25, 305–313.
* Sama G, Fallandhzadeh M, Rapuzzi P (2005) Notes on some Cerambycidae (Coleoptera) from Iran with description of two new species (Insecta Coleoptera Cerambycidae). Quaderno di Studi e Notizie di Storia Naturale della Romagna 20, 123-132.
* Bright DE, Skidmore RE (1997) A catalog of Scolytidae and Platypodidae (Coleoptera): Supplement 1 (1990-1994). NRC Research Press, Ottawa, 635 pp.
* Nikulina T, Mandelshtam M, Petrov A, Nazarenko V, Yunakov N (2015) A survey of the weevils of Ukraine. Bark and ambrosia beetles (Coleoptera: Curculionidae: Platypodinae and Scolytinae). Zootaxa 3912, 61 pp.
* Riba-Flinch JM, Bedós M (2023) Datos sobre la expansión de la especie exótica Xylosandrus compactus (Eichhoff, 1876) (Coleoptera: Curculionidae: Scolytinae) en las provincias de Girona y Barcelona (NE España). Revista gaditana de Entomología, XIV, 117-135.
* Tomoshevich MA, Belomesyatseva D, Banaev EV, Vorob’eva IG, Shabashova T (2023) Comparative Analysis of Foliar Diseases of Some Native and Non-Native Tree Species in Belarus and Siberia. Contemporary Problems of Ecology 16(2), 217-29. https://doi.org/10.1134/S1995425523020166
* Robinson GS, Ackery PR, Kitching IJ, Beccaloni GW, Hernández LM (2010) HOSTS - A Database of the World's Lepidopteran Hostplants. Natural History Museum, London. http://www.nhm.ac.uk/hosts.
* Wallner WE & McManus KA (1989) Proceedings, Lymantriidae: a comparison of features of New and Old World tussock moths; 1988 June 26-July 1; New Haven, CT. Gen. Tech. Rep. NE-123. Broomall, PA: U.S. Department of Agriculture, Forest Service, Northeastern Forest Experiment Station. 554 p. https://doi.org/10.2737/NE-GTR-123
* Brasier CM, Kirk SA, Delcan J, Cooke DEL, Jung T, Man in’t Veld WA (2004) Phytophthora alni sp. nov. and its variants: designation of emerging heteroploid hybrid pathogens spreading on Alnus trees. Mycological Research 108(10), 1172–1184.
* Cerny K, Gregorova B, Strnadova V, Holub V, Tomsovsky M, Cervenka M (2008) Phytophthora alni causing decline of black and grey alders in the Czech Republic Plant Pathology 57(2), 370.
* Zviagintsev V, Prokhоrоva A, Surina T, Belomesyeva D (2023) Global risks of biological invasions of phytopathogenic organisms and improvement of the quarantine monitoring system using computer modeling. Reliability: Theory & Applications 18(75), 569-581.
* Brasier CM, Kirk SA, Delcan J, Cooke DEL, Jung T, Man in’t Veld WA (2004) Phytophthora alni sp. nov. and its variants: designation of emerging heteroploid hybrid pathogens spreading on Alnus trees. Mycological Research 108(10), 1172–1184.
* Zlotina MA (1999) Biology and behavior of Lymantria mathura Moore (Lepidoptera: Lymantriidae). (1999). Doctoral Dissertations 1896 - February 2014. 5673. Accessed 9 June 2023 from: https://scholarworks.umass.edu/dissertations_1/5677
------- Indoor test, not a suitable host (0% larval survival).
* Zlotina MA, Mastro VC, Leonard DE, Elkinton JS (1998) Survival and development of Lymantria mathura on North American, Asian, and European tree species. Journal of Economic Entomology 91, 1162–1166.
------- Indoor test, not a suitable host (0% larval survival),
