DOCSLIB.ORG

Sylvatic Plague Studies. the Vector Efficiency of Nine Species of Fleas Compared with Xenopsylla Cheopis

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Sylvatic Plague Studies. the Vector Efficiency of Nine Species of Fleas Compared with Xenopsylla Cheopis [ 371 ] SYLVATIC PLAGUE STUDIES THE VECTOR EFFICIENCY OF NINE SPECIES OF FLEAS COMPARED WITH XENOPSYLLA CHEOPIS BY ALBERT LAWRENCE BURROUGHS*, M.S., PH.D. From the George Williams Hooper Foundation, University of California, San Francisco, California (With Plates 4 and 5) CONTENTS PAOE PAGE Introduction .371 Discussion ....... 388 Historical 372 Mass transmissions ..... 388 Individual transmissions .... 389 Materials and methods 376 Estimation of vector efficiency 390 Selection of fleas 376 Method of determining if the variation in the Source of fleas for study .... 376 vector efficiencies obtained in two experi- Rearing the fleas ...... 376 ments is real or due to chance . 390 Maintenance of pure cultures of fleas . 377 Feeding infected fleas 377 Xenopsylla cheopis 390 Infecting the fleas 378 Diamanus montanus . .391 Echidnophaga gallinacea . 379 Malaraeus telchinum ..... 392 Experimental 379 Orchopeas sexdentatus sexdentatus . 392 Nosopsyllus fasciatus ..... 393 Xenopsylla cheopis . .379 Opisodasys nesiotus 393 Determination of the number of organisms Echidnophaga gallinacea .... 393 present in the regurgitant of a blocked flea. 381 Oropsylla idahoensis . .393 Mass transmissions with Xenopsylla cheopis . 383 Pulex irritans ...... 393 Diamanus montanus . .383 Megabothris abantis ..... 393 Nosopsyllus fasciatus . .383 Malaraeus telchinum ..... 384 Orchopeas sexdentatus sexdentatus . 385 Conclusions ....... 394 Opisodasys nesiotus . .385 Echidnophaga gallinacea . 386 Summary ........ 394 Oropsylla idahoensis 386 Pulex irritans 387 Megabothris abanlis ..... 387 References........ 395 INTRODUCTION Russian workers, as well as American, having The discovery of the existence of a large wild-rodent become aware of the widespread existence of reservoir of plague in the western United States sylvatic plague in the steppes, valleys, foothills and during the last forty years stimulated interest in the mountains encompassing thousands upon thousands study of the vectors infecting these rodent popula- of square miles, undertook a study of the vector tions. Since the time that vector studies were first ability of the flea fauna of various rodents known inaugurated, numerous investigators have proved to be subject to periodic plague epizootics. These that fleas are the only important plague vectors— investigations, correlated with ecological research, that although other arthropods may be capable of have helped to explain the seasonal rise and fall of becoming infected, their role in the transmission of epizootics, the carry-over of plague from one season the disease is incidental. And, further, it has been to another, and have disclosed the animal popula- repeatedly illustrated that while some species of tions most susceptible to plague and the species of fleas are particularly efficient vectors, others possess wild rodent-infesting fleas most hazardous to man. few or none of the characteristics of the good vector. The tendency during the past two decades has The greatest amount of work has been done with been to make comparative studies of different fleas of the genus Xenopsylla, particularly with the species of wild-rodent fleas in relation to their species cheopis. ability to transmit plague. Similar work has been * Now with the Division of Entomology and Economic Zoology, University of Minnesota, St Paul, Minnesota. Downloaded from https://www.cambridge.org/core. IP address: 170.106.202.126, on 27 Sep 2021 at 03:44:35, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S0022172400014042 372 Sylvatic plague studies done with rat fleas. Several species of fleas native rats free from parasites were unable to transmit the to North America are now known to possess varying disease to healthy rats kept in the same cage. abilities as vectors. However, if fleas were present, transmission from American •workers have recently presented a sick to healthy rats usually did occur. Simond method which enables one to obtain the vector thought that flea faeces, which he had found to efficiency of a given species (with regard to bio- contain plague organisms, might be a means of logical transmission in contrast to mechanical or percutaneous infection. His early observations faecal transmission) and compare it with the vector even extended to a possible explanation of the efficiency of other species. carry-over of plague from one year to another, for A definite aim has been made in the present he found that fleas could remain infected for a studies to determine the practicability of using this considerable period. method for a comparative study of the different Simond's excellent work was repeatedly confirmed species of fleas which occur in western North in the next few years by various investigators, America. The primary purpose of the studies is an although his theories did not fail to arouse criticism. attempt to cast further light on the epizootiology Thompson (1903) supported Simond, as did Gauthier of sylvatic plague. It is hoped that this purpose & Raybaud (1902—3), who obtained several positive has been realized. results in mass-transmission experiments with rats and rat fleas. HISTORICAL To the problems already presented by the The etiological agent of plague was discovered existence of plague in rats were added questions during an outbreak of the disease at Hongkong at brought about by the discovery of a large wild- the close of the nineteenth century by Yersin (1894), rodent reservoir of plague in Asia, North America, a French scientist, who gave a good description of South America and Africa. Numerous species of the organism. Kitasato (1894), a Japanese worker, wild rodents were known to be involved, and each also announced the discovery of an organism in species was frequently found to harbour one or plague cases, but presented an erroneous descrip- more species of fleas. The ability of the various tion. According to Lagrange (1926), Kitasato is to species of fleas to serve as vectors of plague pre- be honoured for having publicly stated that Yersin sented an important problem. Clemow (1900) alone was the discoverer of the plague bacillus. reported some of the earliest isolations of rodent Roux (1897) first expressed the view that plague plague in animals other than domestic rats. He was primarily a disease of rats. About the same stated that bacteriological proof existed of the time, Ogata (1897) concluded, on epidemiological occurrence of spontaneous plague in monkeys, grounds, that the rat is the principal host and the bandicoots, mice and grey-striped squirrels. The flea the means of dissemination of the causal following corrected list of animals found naturally organism in the rat population. He succeeded in infected with plague was taken from a table producing plague in laboratory animals by inocu- presented by Wu & Pollitzer (1932): lating them with triturated fleas taken from dead Tarabagan (Arctomys [Marmota] sibirica),* Trans- rats. Ogata was suspicious of fleas, as they were baikalia and Mongolia, 1895. frequently the most numerous ectoparasites of rats, Squirrel (Sdurus [Funamhulus] palmarum), and were known to leave dead rats in search of a Ceylon, India, 1898. blood meal. Mole rate (Gunomys [Bandicota] bengalensis), Simond (1898), after having made successful Ceylon, India, 1906. mass-transmission experiments, reported the trans- Striped mouse (Rhabdomyspumilio), South Africa, emission of plague from rat to rat by fleas. He showed 1906. that the cannibalistic and necrophilic habits of rats Hamster rat (Cricetomys gambianus), South rarely resulted in their infection, and that enormous Africa, 1906. numbers of bacteria had to be ingested before such California ground squirrel (Citellus beecheyi), infections could occur. He concluded that the California, 1908. pathology then differed from that of animals Dusky-footed wood rat (Neotomu fuscipes), infected by the cutaneous route. California, 1910. Simond, furthermore, attached significance to the Tree rat (Epimys [Rattus] dolichurus),\ East local reaction which appears in about 5 % of human Africa, 1913. plague cases. This local reaction manifests itself as Small suslik (Citellus pygmaeus), South-east a blister-like eruption and contains many plague Russia, 1913. bacilli. He logically concluded that fleas, which * Wu & Pollitzer listed this as Arctomys bobac. This frequently attack the lower extremities where the species occurs in Poland, while sibirica occurs in reaction was found, were probably responsible. Transbaikalia. Experimentally, Simond found that plague-infected f No reference to this species could be found. Downloaded from https://www.cambridge.org/core. IP address: 170.106.202.126, on 27 Sep 2021 at 03:44:35, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S0022172400014042 ALBERT LAWRENCE BURROUGHS 373 Large suslik (Citellus fulvus), South-east Russia, known to have resulted from contact with wild 1917. animals, usually rodents. De la Barrera (1939) Multimammate mouse (Rattus concha), South reported an outbreak of plague in rural Argentina Africa, 1921. in which the ' cuis' or fence rabbit was incriminated The world-wide sylvatic reservoir of plague as the rodent reservoir. Meyer (1943) states that proved to be of epidemiological significance. Wu domestic rodents are the animals primarily respon- (1934) described an outbreak first reported in 1907 sible for bringing the disease into contact with in south-east Russian Turkestan.
Load more

Recommended publications
  • Resource Predictability and Host Specificity in Fleas
    81 Resource predictability and host specificity in fleas: the effect of host body mass B. R. KRASNOV1*, S. MORAND2,D.MOUILLOT3,G.I.SHENBROT1, I. S. KHOKHLOVA4 and R. POULIN5 1 Ramon Science Center and Mitrani Department of Desert Ecology, Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the Negev, P.O. Box 194, Mizpe Ramon 80600, Israel 2 Center for Biology and Management of Populations, Campus International de Baillarguet, CS 30016 34988 Montferrier-sur-Lez cedex, France 3 UMR CNRS-UMII 5119 Ecosystemes Lagunaires, University of Montpellier II, CC093, FR-34095 Montpellier Cedex 5, France 4 Desert Animals Adaptations and Husbandry, Wyler Department of Dryland Agriculture, Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the Negev, Beer Sheva 84105, Israel 5 Department of Zoology, University of Otago, P.O. Box 56, Dunedin, New Zealand (Received 22 November 2005; revised 28 December 2005; accepted 24 January 2006; first published online 28 March 2006) SUMMARY Ecological specialization is hypothesized to result from the exploitation of predictable resource bases. For parasitic organisms, one prediction is that parasites of large-bodied host species, which tend to be long-lived, should specialize on these hosts, whereas parasites of small host species, which represent more ephemeral and less predictable resources, should become generalists. We tested this prediction by quantifying the association between the level of host specificity of fleas and the mean body mass of their mammalian hosts, using published data from 2 large, distinct geographical regions (South Africa and northern North America). In general, we found supporting evidence that flea host specificity, measured either as the number of host species exploited or their taxonomic distinctness, became more pronounced with increasing host body mass.
    [Show full text]
  • Royal Entomological Society
    Royal Entomological Society HANDBOOKS FOR THE IDENTIFICATION OF BRITISH INSECTS To purchase current handbooks and to download out-of-print parts visit: http://www.royensoc.co.uk/publications/index.htm This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 2.0 UK: England & Wales License. Copyright © Royal Entomological Society 2012 ROYAL ENTOMOLOGICAL , SOCIETY OF LONDON Vol. I. Part 1 (). HANDBOOKS FOR THE IDENTIFICATION OF BRITISH INSECTS SIPHONAPTERA 13y F. G. A. M. SMIT LONDON Published by the Society and Sold at its Rooms - 41, Queen's Gate, S.W. 7 21st June, I9S7 Price £1 os. od. ACCESSION NUMBER ....... ................... British Entomological & Natural History Society c/o Dinton Pastures Country Park, Davis Street, Hurst, OTS - Reading, Berkshire RG 10 OTH .•' Presented by Date Librarian R EGULATIONS I.- No member shall be allowed to borrow more than five volumes at a time, or to keep any of tbem longer than three months. 2.-A member shall at any time on demand by the Librarian forthwith return any volumes in his possession. 3.-Members damaging, losing, or destroying any book belonging to the Society shall either provide a new copy or pay such sum as tbe Council shall tbink fit. ) "1' > ) I .. ··•• · ·• "V>--· .•. .t ... -;; ·· · ·- ~~- -~· · · ····· · · { · · · l!i JYt.11'ian, ,( i-es; and - REGU--LATIONS dthougll 1.- Books may b - ~dapted, ; ~ 2 -~ . e borrowed at . !.l :: - --- " . ~ o Member shall b . all Meeflfll(s of the So J t Volumes at a time o; ,IJJowed to borrow more c e y . 3.- An y Mem ber r t '. to keep them lonl{er th than three b.ecorn_e SPecified f e a Jn!ng a \'oJume a n one m on th.
    [Show full text]
  • United States Department of the Interior
    United States Department of the Interior FISH AND WILDLIFE SERVICE South Florida Ecological Services Office 1339 20” Street Vero Beach, Florida 32960 March 25, 2015 Kevin R. Becker Department of the Air Force Detachment 1, 23rd Wing Avon Park Air/Ground Training Complex (ACC) Avon Park Air Force Range, Florida 33825 Service CPA Code: 2013-CPA-0255 Service Consultation Code: 2013-F-0271 Date Received: September 3, 2013 Project: Avon Park AFR, JIFE Counties: Highlands and Polk Dear Lieutenant Colonel Beeker: This document transmits the U. S. Fish and Wildlife Service’s (Service) biological opinion based on our review of the U.S. Air Force’s (USAF) proposed Joint Integrated Fires Exercises (JIFE) at Avon Park Air Force Range (APAFR) in Highlands and Polk Counties, Florida, and its adverse effects on the threatened eastern indigo snake (Drymarchon corals couperi) (indigo snake), threatened Florida scrub-jay (Aphelocoma coerulescens) (scrub-jay), endangered red-cockaded woodpecker (Picoides borealis) (RCW), and endangered Florida bonneted bat (Eumops floridanus) (FBB) in accordance with section 7 of the Endangered Species Act of 1973, as amended (Act) (87 Stat. 884; 16 U.S.C. 1531 etseq.). This Biological Opinion is based on information provided in the USAF’s August 28, 2013, biological assessment (BA), conversations, and other sources of information. A complete administrative record of this consultation is on file in the South Florida Ecological Services Office, Vero Beach, Florida. Consultation History On May 2, 2013, the USAF requested the assistance of the Service with the review of their draft BA for the JIFE. On May 8, 2013, the Service sent the USAF an email with comments on the draft BA.
    [Show full text]
  • Fleas, Hosts and Habitat: What Can We Predict About the Spread of Vector-Borne Zoonotic Diseases?
    2010 Fleas, Hosts and Habitat: What can we predict about the spread of vector-borne zoonotic diseases? Ph.D. Dissertation Megan M. Friggens School of Forestry I I I \, l " FLEAS, HOSTS AND HABITAT: WHAT CAN WE PREDICT ABOUT THE SPREAD OF VECTOR-BORNE ZOONOTIC DISEASES? by Megan M. Friggens A Dissertation Submitted in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy in Forest Science Northern Arizona University May 2010 ?Jii@~-~-u-_- Robert R. Parmenter, Ph. D. ~",l(*~ l.~ Paulette L. Ford, Ph. D. --=z:r-J'l1jU~ David M. Wagner, Ph. D. ABSTRACT FLEAS, HOSTS AND HABITAT: WHAT CAN WE PREDICT ABOUT THE SPREAD OF VECTOR-BORNE ZOONOTIC DISEASES? MEGAN M. FRIGGENS Vector-borne diseases of humans and wildlife are experiencing resurgence across the globe. I examine the dynamics of flea borne diseases through a comparative analysis of flea literature and analyses of field data collected from three sites in New Mexico: The Sevilleta National Wildlife Refuge, the Sandia Mountains and the Valles Caldera National Preserve (VCNP). My objectives were to use these analyses to better predict and manage for the spread of diseases such as plague (Yersinia pestis). To assess the impact of anthropogenic disturbance on flea communities, I compiled and analyzed data from 63 published empirical studies. Anthropogenic disturbance is associated with conditions conducive to increased transmission of flea-borne diseases. Most measures of flea infestation increased with increasing disturbance or peaked at intermediate levels of disturbance. Future trends of habitat and climate change will probably favor the spread of flea-borne disease.
    [Show full text]
  • Fleas and Flea-Borne Diseases
    International Journal of Infectious Diseases 14 (2010) e667–e676 Contents lists available at ScienceDirect International Journal of Infectious Diseases journal homepage: www.elsevier.com/locate/ijid Review Fleas and flea-borne diseases Idir Bitam a, Katharina Dittmar b, Philippe Parola a, Michael F. Whiting c, Didier Raoult a,* a Unite´ de Recherche en Maladies Infectieuses Tropicales Emergentes, CNRS-IRD UMR 6236, Faculte´ de Me´decine, Universite´ de la Me´diterrane´e, 27 Bd Jean Moulin, 13385 Marseille Cedex 5, France b Department of Biological Sciences, SUNY at Buffalo, Buffalo, NY, USA c Department of Biology, Brigham Young University, Provo, Utah, USA ARTICLE INFO SUMMARY Article history: Flea-borne infections are emerging or re-emerging throughout the world, and their incidence is on the Received 3 February 2009 rise. Furthermore, their distribution and that of their vectors is shifting and expanding. This publication Received in revised form 2 June 2009 reviews general flea biology and the distribution of the flea-borne diseases of public health importance Accepted 4 November 2009 throughout the world, their principal flea vectors, and the extent of their public health burden. Such an Corresponding Editor: William Cameron, overall review is necessary to understand the importance of this group of infections and the resources Ottawa, Canada that must be allocated to their control by public health authorities to ensure their timely diagnosis and treatment. Keywords: ß 2010 International Society for Infectious Diseases. Published by Elsevier Ltd. All rights reserved. Flea Siphonaptera Plague Yersinia pestis Rickettsia Bartonella Introduction to 16 families and 238 genera have been described, but only a minority is synanthropic, that is they live in close association with The past decades have seen a dramatic change in the geographic humans (Table 1).4,5 and host ranges of many vector-borne pathogens, and their diseases.
    [Show full text]
  • Echidnophaga Gallinacea) in Dog
    Journal of Applied Animal Science Vol.2 No.3 September-December 2009 43 Case Report Heavy Infestation of the Sticktight Flea (Echidnophaga gallinacea) in Dog Thekhawet Weluwanarak, Siriporn Tangsudjai, Seni Ngamloephochit and Tanasak Changbunjong* The Monitoring and Surveillance Center for Zoonotic Diseases in Wildlife and Exotic Animals, Faculty of Veterinary Science, Mahidol University, Salaya, Nakhon Pathom 73170, Thailand. *Corresponding author, E-mail address: [email protected] ∫∑§—¥¬Õà A 6-month-old female dog in Kanchanaburi province was heavily infested with the sticktight flea (Echidnophaga gallinacea). The dog showed the signs of weakness, emaciation, as well as pale mucus membranes and mild dehydration. Hematological analysis revealed moderate anemia, with 28.7% packed cell volume (normal range 35-55%) and a 4.94 x 106μl-1 erythrocyte count (normal range 5-9 x 106μl-1). However, hemoparasites and other ectoparasites such as ticks and lice were not found. The finding of this investigation is valuable for control of the fleas in order to prevent adverse effects on animal health. Keywords: Ectoparasite, Echidnophaga gallinacea, Flea, Dog 44 Journal of Applied Animal Science Vol.2 No.3 September-December 2009 °“√μ‘¥¢ÕßÀ¡—¥ Echidnophaga gallinacea Õ¬à“ß√ÿπ·√ß„π ÿπ—¢ ∑‘¶‡«∑ ‡«Ãÿ«π“√—°…å »‘√‘æ√ μ—Èß ÿ¥„® ‡ π’¬å ß“¡‡≈‘»æÕ®‘μ ·≈– ∏π»—°¥‘Ï ™à“ß∫√√®ß* »Ÿπ¬å‡ΩÑ“√–«—ß·≈–μ‘¥μ“¡‚√§®“° —μ«åªÉ“ —μ«åμà“ß∂‘Ëπ·≈– —μ«åÕæ¬æ §≥– —μ«·æ∑¬»“ μ√å ¡À“«‘∑¬“≈—¬¡À‘¥≈ »“≈“¬“ π§√ª∞¡ 73170 *ºŸâ√—∫º‘¥™Õ∫∫∑§«“¡ E-mail address: [email protected] ∫∑§—¥¬Õà
    [Show full text]
  • Investigations on the Abundance of Ectoparasites and Vector-Borne Pathogens in Southwest Madagascar
    Investigations on the abundance of ectoparasites and vector-borne pathogens in southwest Madagascar Dissertation with the aim of achieving a doctoral degree at the Faculty of Mathematics, Informatics and Natural Sciences Department of Biology University of Hamburg submitted by Julian Ehlers Hamburg, 2020 Reviewers: Prof. Dr. Jörg Ganzhorn, Universität Hamburg PD Dr. Andreas Krüger, Centers for Disease Control and Prevention Date of oral defense: 19.06.2020 TABLE OF CONTENTS Table of contents Summary 1 Zusammenfassung 3 Chapter 1: General introduction 5 Chapter 2: Ectoparasites of endemic and domestic animals in 33 southwest Madagascar Chapter 3: Molecular detection of Rickettsia spp., Borrelia spp., 63 Bartonella spp. and Yersinia pestis in ectoparasites of endemic and domestic animals in southwest Madagascar Chapter 4: General discussion 97 SUMMARY Summary Human encroachment on natural habitats is steadily increasing due to the rapid growth of the worldwide population. The consequent expansion of agricultural land and livestock husbandry, accompanied by spreading of commensal animals, create new interspecific contact zones that are major regions of risk of the emergence of diseases and their transmission between livestock, humans and wildlife. Among the emerging diseases of the recent years those that originate from wildlife reservoirs are of outstanding importance. Many vector-borne diseases are still underrecognized causes of fever throughout the world and tend to be treated as undifferentiated illnesses. The lack of human and animal health facilities, common in rural areas, bears the risk that vector-borne infections remain unseen, especially if they are not among the most common. Ectoparasites represent an important route for disease transmission besides direct contact to infected individuals.
    [Show full text]
  • (Siphonaptera: Pulicidae) Recorded in Canada for the First Time
    Echidnophaga gallinacea (Siphonaptera: Pulicidae) recorded in Canada for the first time Terry D. Galloway1,*, Andrea Andruschak2 and Robyn M. Underwood1 1Department of Entomology, University of Manitoba, Winnipeg, Manitoba, Canada R3T 2N2 247 Silverfox Place, East St. Paul, Manitoba, Canada R2E 0G4 Echidnophaga gallinacea (Westwood, 1875) is a cosmopolitan sticktight flea which parasitizes a wide variety of birds and mam- mals. In North America, this ectoparasite is found primarily in the southern United States. This species is reported here from a Brown-headed Cowbird, Molothrus ater (Boddaert), from the University Field Station at Delta Marsh, Manitoba, and this is its first record in Canada. INTRODUCTION The genus Echidnophaga Olliff, 1886 includes 21 species all of which are distrib- uted in the Palaearctic, Ethiopian and Autralasian Regions (Lewis 1998), except for the hen flea, Echidnophaga gallinacea (Westwood, 1875). This species is now cos- mopolitan, and the only species in the genus found in North America, a result of accidental introduction by humans along with their domestic animals (Lewis 1998). Females of these sticktight fleas attach and feed at one site on their hosts for pro- longed periods (4-19 days), during which time the surrounding tissue becomes swol- len and ulcerated. Males feed for shorter periods, interspersed with mate-seeking behaviour (Harwood and James 1979; Parman 1923). Mating and oviposition occur on the host (Parman 1923). Echidnophaga gallinacea has an extremely wide host range, including many species of mammals and birds. It may be a serious pest of poultry and cause irritation to cats, dogs, rabbits, horses and humans (Harwood and James 1979).
    [Show full text]
  • The Sticktight Flea (Echidnophaga Gallinacea)
    Close enCounters With the environment What’s Eating You? The Sticktight Flea (Echidnophaga gallinacea) Roger Kapoor, MD, MBA; Dirk M. Elston, MD aterally compressed bodies and large hind legs characterize all fleas. Unlike the dog and cat L fleas, the sticktight flea (Echidnophaga gallinacea) (Figures 1 and 2) lacks genal (mustache area) and pronotal (back of head) ctenidia (combs) and is less than half the size of the cat flea (Figure 3). Unlike the Xenopsylla flea, the sticktight flea has no pleural rod (a vertical rod visible within the mesopleuron above the second pair of legs). Additional features include a head that is flattened anteriorly and 2 pairs of setae (hairs) found behind the antennae. TrueCUTIS to its name, the sticktight flea has the ability to tightly stick to its host through broad and serrated laciniae (stiletto- shaped cutting extensors of the maxilla). Echidnophaga gallinacea infests a wide variety of birds and mammals worldwide,Do and while Not it is mainly Figure Copy 1. The sticktight flea (Echidnophaga gallinacea). a poultry flea, it is becoming more common on dogs.1-3 It has a predilection to attach to bare spots on the skin (eg, eyes, anus). It is the only species in the genus found in North America, especially in the an intermediate host of the dog tapeworm. Because southern and western United States, and has been this flea is increasingly recognized as a common flea noted to be the most common flea on dogs in areas on wild animals and domestic pets, it represents an of South Africa. It also is becoming more common important disease vector.
    [Show full text]
  • The Flea (Siphonaptera) Fauna of Georgia, Usa
    THE FLEA (SIPHONAPTERA) FAUNA OF GEORGIA, USA Lance A. Durden Department of Biology Georgia Southern University Statesboro, GA Introduction • Some flea species can transmit zoonotic pathogens (e.g., Rickettsia typhi, R. felis, R. prowazekii, Bartonella quintana). • Some are intermediate hosts of rodent & canine tapeworms (which can be zoonotic). • Some are nuisance biters (e.g., Ctenocephalides felis, Echidnophaga gallinacea) – some can cause flea-bite dermatitis. • Pathogen transmission or ecological importance for fleas parasitizing wild mammals or birds is poorly understood. • Faunal studies have been completed for fleas of AL (Sanford & Hays 1974), FL (Layne 1971), SC (Durden et al. 1999) & TN (Pfitzer, 1950; Durden & Kollars 1997) but not for GA. Previous records of GA fleas • Data from surveys of rat fleas in association w. murine typhus studies (e.g., Fox 1931; Cole & Koepke 1947; Ludwig & Nicholson 1947; Morlan 1947, 1952; Harkema & Kartman 1948; Hill & Morlan 1948; Hill et al. 1951; Mohr 1951; Morlan & Hines 1951; Morlan & Utterback 1952; Mohr & Smith 1957; Love & Smith 1960). • Data from a Catalog of Smithsonian (USNM) flea types (Adams & Lewis 1995). • Data from flea specimens in the Natural History Museum, London (Hopkins & Rothschild 1953, 1962, 1966; Hopkins 1954; Smit 1987). • Atlas of fleas of eastern N. America (Benton 1980). • Data from numerous flea surveys of wild & domestic mammals (& a few birds) in GA. Sources of new GA flea Records • Flea collections from southern GA from 100s of live- trapped or roadkill mammals & a few birds from 1992-2010 (Durden, unpublished). • Collections from live-trapped mammals in N. GA mountains by Ralph Eckerlin from 1986-1992. • Collections from live-trapped mammals (esp.
    [Show full text]
  • Flea Diversity and Prevalence on Arid-Adapted Rodents in the Oriental Basin
    Available online at www.sciencedirect.com Revista Mexicana de Biodiversidad Revista Mexicana de Biodiversidad 86 (2015) 981–988 www.ib.unam.mx/revista/ Ecology Flea diversity and prevalence on arid-adapted rodents in the Oriental Basin, Mexico Diversidad de pulgas y prevalencia en roedores de zonas áridas en la Cuenca Oriental, México a,∗ b Roxana Acosta , Jesús A. Fernández a Museo de Zoología “Alfonso L. Herrera”, Departamento de Biología Evolutiva, Facultad de Ciencias, Universidad Nacional Autónoma de México, Apartado Postal 70-399, 04510 México, D.F., Mexico b Departamento de Recursos Naturales, Facultad de Zootecnia y Ecología, Universidad Autónoma de Chihuahua, Periférico Francisco R. Almada Km. 1, 31453 Chihuahua, Chihuahua, Mexico Received 31 July 2015; accepted 28 August 2015 Available online 6 November 2015 Abstract Inventorying biodiversity is basic for conservation and natural resources management because constant loss of natural areas increases the need for fast biodiversity inventories. Desert flea diversity and associations are not well known in Mexican deserts, especially in the Oriental Basin (OB). Rodents were trapped in the Oriental Basin through June 2007, 2009, and 2010, and July 2008, in 10 localities. A total of 144 rodents belonging to 10 species were trapped, of which 133 were parasitized by 350 fleas belonging to 18 species. Peromyscus difficilis had the highest parasite richness with 9 species, followed by P. maniculatus with 8. The most abundant fleas in the OB were Polygenis vazquezi, Plusaetis parus, Meringis altipecten, and Plusaetis mathesoni. Seven species were found representing new records for 3 states. All Rights Reserved © 2015 Universidad Nacional Autónoma de México, Instituto de Biología.
    [Show full text]
  • FELINE ARTHROPODS ARTICLE Lindsay Starkey, DVM Jay Stewart, DVM Oklahoma State University Aumsville Animal Clinic, Aumsville, Oregon
    PARASITE PROTOCOLS FOR YOUR PRACTICE Peer Reviewed Recommendations from the Companion Animal Parasite Council FELINE FRIENDLY FELINE ARTHROPODS ARTICLE Lindsay Starkey, DVM Jay Stewart, DVM Oklahoma State University Aumsville Animal Clinic, Aumsville, Oregon The mission of the Companion Animal Parasite Council (CAPC) is to foster animal and human health, while preserving the human–animal bond, through recommendations for the diagnosis, treatment, prevention, and control of parasitic infections. For more information, including detailed parasite control recommendations, please visit capcvet.org. Ectoparasites—in addition to being a nuisance— 4. Adults quickly fi nd a host after emerging, and are associated with allergies, skin infections, and begin feeding within minutes.1 self-induced traumatic injury in pets. They are also • Egg production begins around 24 hours after vectors of infectious and zoonotic disease-causing initiation of feeding.1 agents, some of which can prove fatal.1–6 Fleas, • Adults account for only about 5% of the total ticks, mites, and lice are common ectoparasites flea population in an infestation.12 seen on cats in the United States. Completion of the life cycle typically takes 3 to 8 weeks, and depends on relative humidity and FLEAS temperature; a moist, warm environment is ideal.4 The most common ectoparasite that infests cats (and dogs) in North America is the cat fl ea, Signi cance of Infestation Ctenocephalides felis ( ). Other fl eas also Figure 1 Fleas can cause irritation and pruritus, and certain infest cats, including Echidnophaga gallinacea, Pulex cats may develop fl ea allergy dermatitis. Heavy irritans, and P simulans.1,7,8 infestations can lead to anemia and, if not managed appropriately, can be fatal.1 Life Cycle Fleas are also important vectors of disease- Fleas have 4 life stages: causing agents.
    [Show full text]