Hairworm (Nematomorpha: Gordioidea) parasites of New Zealand wetas (Orthoptera: Stenopelmatidae)

George O. Poinar Jr.

doi:10.1139/z91-223

First report of a gryporhynchid tapeworm (Cestoda: Cyclophyllidea) from New Zealand and from an eleotrid fish, described from metacestodes and in vitro-grown worms

Journal of Helminthology ◽

10.1017/s0022149x11000691 ◽

2011 ◽

Vol 86 (4) ◽

pp. 453-464 ◽

Cited By ~ 6

Author(s):

B. Presswell ◽

R. Poulin ◽

H.S. Randhawa

Keyword(s):

New Zealand ◽

First Record ◽

Small Subunit ◽

Body Cavity ◽

The Body ◽

Species Determination ◽

Fish Family ◽

Rdna Sequences ◽

Stage Of Development

AbstractMetacestodes are often found in the body cavity of the common bully (Gobiomorphus cotidianus McDowall), from freshwater habitats in Otago, New Zealand. Identification of metacestodes relies only on the number, size and shape of the rostellar hooks. To attempt species determination, we cultivated metacestodes in vitro for up to 23 days, during which they matured to at least the male stage of development, although female organs were not discernable. Identified as members of the genus Paradilepis Hsü, 1935 (family Gryporhynchidae), these specimens are compared to previously described species, in particular P. minima (Goss, 1940), from Australia, the closest species, both geographically and morphologically. Although the size of scolex, suckers and proglottids differ significantly from those of P. minima, we are cautious about interpreting ‘adults’ grown in vitro, because we are unsure whether the artificial conditions alter development. For this reason, and because of the lack of female organs, we refrain from erecting a new species, and refer to the specimens as Paradilepis cf. minima until such time as the adults are found in the definitive host. With this proviso we present here a description of the in vitro-grown worms and the metacestodes as a preliminary study of this cestode. A molecular analysis of small subunit (SSU) rDNA sequences, shows the position of P. cf. minima and another gryporhynchid, Neogryporhynchus cheilancristrotus (Wedl, 1855), to be equivocal, but confirms their exclusion from the Dilepididae and Hymenolepididae. This is the first record of a gryporhynchid from New Zealand, and the first from the fish family Eleotridae.

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The free-living and parasitic development of Rhabdias spp. (Nematoda: Rhabdiasidae) in amphibians

Canadian Journal of Zoology ◽

10.1139/z79-014 ◽

1979 ◽

Vol 57 (1) ◽

pp. 161-178 ◽

Cited By ~ 56

Author(s):

M. R. Baker

Keyword(s):

Rana Sylvatica ◽

Skin Penetration ◽

Body Cavity ◽

The Body ◽

Free Living ◽

Infective Larvae ◽

Ecological Barriers ◽

In The Wild ◽

Paratenic Hosts ◽

Similar Growth

Free-living development of Rhabdias americanus and Rhabdias ranae was heterogonic and development of infective larvae was by matricidal endotoky. Both species were experimentally transmitted by skin penetration. Development of R. americanus in Bufo americanus and R. ranae in Rana sylvatica was similar. Growth of third- and fourth-stage larvae occurred in fascia and muscle tissue of the host during migration to the body cavity. Adult worms were recovered only from the body cavity and lungs; larvae were never observed in these locations. Worms probably entered the lungs by direct penetration. Gravid nematodes were observed only in the lungs. Both R. americanus and R. ranae were transmitted to toad and frog tadpoles, respectively, and worms developed to adulthood in tadpoles. Terrestrial snails (Oxyloma decampi Tryon and Discus cronkhitei Newcomb) were demonstrated as possible paratenic hosts for R. americanus. Rhabdias americanus, which does not occur in frogs, and R. ranae, which does not occur in toads in the wild at Guelph, were experimentally cross-transmitted to these amphibians and developed successfully to adults. Infective larvae of these species, however, did not as readily penetrate into the unusual host as the usual host. It is suggested that ecological barriers have prevented cross infections in the wild.

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Studies on the Life Cycle of Some New Zealand Anisakidae (Nematoda)

10.26686/wgtn.16958437 ◽

2021 ◽

Author(s):

◽

Rosemary Jennifer Hurst

Keyword(s):

Life Cycle ◽

New Zealand ◽

Body Cavity ◽

The Body ◽

In Vitro Cultivation ◽

Free Living ◽

Larval Stages ◽

Factors Influencing ◽

Phocarctos Hookeri

<p>The life cycle of Anisakis simplex in New Zealand waters is described from observations on the morphology, distribution and behaviour of free-living and parasitic stages. Comparison with the life cyles of two other anisakids, Phocanema decipiens Myers 1959 and Thynnascaris adunca Rudolphi 1802 shows differences in distribution, degrees of host specificity, the status of invertebrate hosts, the factors influencing infestation levels of teleost hosts, and the location and pathological effects of infestation. Larval stages occurring in intermediate and paratenic hosts were identified by comparison of larval and adult morphometrics. A. simplex larvae were also positively identified by in vitro cultivation through to adults. Some morphometric variations compared to overseas descriptions are apparent. The ventriculus of A. simplex larvae is shorter relative to body length and the intestinal caecum of P. decipiens is longer relative to ventriculus length. Egg and free-living larval stages were obtained from in vitro cultivation of (A. simplex) and collection of eggs from mature adults from definitive hosts (T. adunca). Eggs of P. decipiens were not obtained. Eggs of A. simplex and T. adunca hatch in 8-11 days at 15 [degrees] C. A. simplex eggs hatch in 6 days at a temperature of 22 [degrees] C and did not hatch in 16 days at 10 [degrees] C. Eggs and free-living stage III larvae of A. simplex and T. adunca are similar in morphology with little differentiation of internal structures. Examination of the stomach contents of pelagic fish infested with anisakids indicated that possible intermediate hosts of A. simplex are the euphausiid Nyctiphanes australis and the decapod Munida gregaria. Possible hosts of T. adunca and M. gregaria are a wide variety of smaller zooplanktonic groups, e.g. decapod larvae and copepods. Larvae of A. simplex were found in one of 8850 N. australis; larvae of T. adunca were found in 69 of 3999 chaetognaths (Sagitta spp.) a medusa and a decapod larva. These larvae are morphologically similar to Stage III larvae from teleosts. No anisakids were found in 3956 Euphausia spp., 1147 M. gregaria and 740 prawns. Twenty five T. adunca larvae and adults were found in 818 freshly eaten M. gregaria in teleost stomachs, indicating that this invertebrate may act as a paratenic and a definitive host. Experimental infection of N. australis and M. gregaria with stage II larvae of A. simplex and T. adunca was unsuccessful. The location of anisakid infestation in three pelagic teleost species, Thyrsites atun, Trachurus novaezelandiae and Trachurus declivis is described. A. simplex larvae are found mainly in the body cavity of all species, at the posterior end of the stomach, with less than one percent occurring in the musculature. Distribution of A. simplex larvae does not change with increasing size of the host or increasing total worm burden. Thyrsites atun have a higher proportion of larvae in the stomach wall (8-13%) compared to Trachurus spp. (< 4%). T. adunca larvae are found infrequently in the body cavity of all three species, on the pyloric caeca and in the stomach wall. Adults and larvae of T. adunca are found more commonly in the alimentary canal, indicating that these teleosts are more important as definitive hosts in the life cycle of this anisakid. P. decipiens larvae are found only in Thyrsites atun and occur mainly in the muscles (98.5%). No quantitative pathogenic effects of anisakid infestation on these teleosts hosts were detected. The main factors influencing the infestation of the three teleost species are age of the host, locality and season. Sex of the host and depth (over the continental shelf, 0-250 m) are not important. A. simplex infestation increased with age in all host species examined, and was higher in Trachurus declivis from the southern-most locality, suggesting the existence of at least two distinct populations of this species. Significant differences in infestation of Thyrsites atun with P. decipiens suggests that this anisakid may be more common in southern localities also. The infestation of Thyrsites atun by larval and adult T. adunca in the alimentary canal is most influenced by season and closely related to diet. Nematode samples were obtained from the marine mammals Arctocephalus forsteri, Kogia breviceps and Phocarctos hookeri. Adult A. simplex were recorded from A. forsteri (a new host record) and Kogia breviceps; preadults from Phocarctos hookeri. Adult P. decipiens were recorded from Phocarctos hookeri; preadults from Arctocephalus forsteri and K. breviceps. Other anisakids found were Anisakis physeteris (Baylis 1923), Contracaecum osculatum Rudolphi 1802 and Pseudoterranova kogiae (Johnston and Mawson 1939) Mosgovoi 1951. These records are all new for the New Zealand region except P. decipiens from P. hookeri and C. osculatum from Arctocephalus forsteri. A. simplex and C. osculatum were found associated with gastric ulcers in Arctocephalus forsteri.</p>

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Studies on the Life Cycle of Some New Zealand Anisakidae (Nematoda)

10.26686/wgtn.16958437.v1 ◽

2021 ◽

Author(s):

◽

Rosemary Jennifer Hurst

Keyword(s):

Life Cycle ◽

New Zealand ◽

Body Cavity ◽

The Body ◽

In Vitro Cultivation ◽

Free Living ◽

Larval Stages ◽

Factors Influencing ◽

Phocarctos Hookeri

<p>The life cycle of Anisakis simplex in New Zealand waters is described from observations on the morphology, distribution and behaviour of free-living and parasitic stages. Comparison with the life cyles of two other anisakids, Phocanema decipiens Myers 1959 and Thynnascaris adunca Rudolphi 1802 shows differences in distribution, degrees of host specificity, the status of invertebrate hosts, the factors influencing infestation levels of teleost hosts, and the location and pathological effects of infestation. Larval stages occurring in intermediate and paratenic hosts were identified by comparison of larval and adult morphometrics. A. simplex larvae were also positively identified by in vitro cultivation through to adults. Some morphometric variations compared to overseas descriptions are apparent. The ventriculus of A. simplex larvae is shorter relative to body length and the intestinal caecum of P. decipiens is longer relative to ventriculus length. Egg and free-living larval stages were obtained from in vitro cultivation of (A. simplex) and collection of eggs from mature adults from definitive hosts (T. adunca). Eggs of P. decipiens were not obtained. Eggs of A. simplex and T. adunca hatch in 8-11 days at 15 [degrees] C. A. simplex eggs hatch in 6 days at a temperature of 22 [degrees] C and did not hatch in 16 days at 10 [degrees] C. Eggs and free-living stage III larvae of A. simplex and T. adunca are similar in morphology with little differentiation of internal structures. Examination of the stomach contents of pelagic fish infested with anisakids indicated that possible intermediate hosts of A. simplex are the euphausiid Nyctiphanes australis and the decapod Munida gregaria. Possible hosts of T. adunca and M. gregaria are a wide variety of smaller zooplanktonic groups, e.g. decapod larvae and copepods. Larvae of A. simplex were found in one of 8850 N. australis; larvae of T. adunca were found in 69 of 3999 chaetognaths (Sagitta spp.) a medusa and a decapod larva. These larvae are morphologically similar to Stage III larvae from teleosts. No anisakids were found in 3956 Euphausia spp., 1147 M. gregaria and 740 prawns. Twenty five T. adunca larvae and adults were found in 818 freshly eaten M. gregaria in teleost stomachs, indicating that this invertebrate may act as a paratenic and a definitive host. Experimental infection of N. australis and M. gregaria with stage II larvae of A. simplex and T. adunca was unsuccessful. The location of anisakid infestation in three pelagic teleost species, Thyrsites atun, Trachurus novaezelandiae and Trachurus declivis is described. A. simplex larvae are found mainly in the body cavity of all species, at the posterior end of the stomach, with less than one percent occurring in the musculature. Distribution of A. simplex larvae does not change with increasing size of the host or increasing total worm burden. Thyrsites atun have a higher proportion of larvae in the stomach wall (8-13%) compared to Trachurus spp. (< 4%). T. adunca larvae are found infrequently in the body cavity of all three species, on the pyloric caeca and in the stomach wall. Adults and larvae of T. adunca are found more commonly in the alimentary canal, indicating that these teleosts are more important as definitive hosts in the life cycle of this anisakid. P. decipiens larvae are found only in Thyrsites atun and occur mainly in the muscles (98.5%). No quantitative pathogenic effects of anisakid infestation on these teleosts hosts were detected. The main factors influencing the infestation of the three teleost species are age of the host, locality and season. Sex of the host and depth (over the continental shelf, 0-250 m) are not important. A. simplex infestation increased with age in all host species examined, and was higher in Trachurus declivis from the southern-most locality, suggesting the existence of at least two distinct populations of this species. Significant differences in infestation of Thyrsites atun with P. decipiens suggests that this anisakid may be more common in southern localities also. The infestation of Thyrsites atun by larval and adult T. adunca in the alimentary canal is most influenced by season and closely related to diet. Nematode samples were obtained from the marine mammals Arctocephalus forsteri, Kogia breviceps and Phocarctos hookeri. Adult A. simplex were recorded from A. forsteri (a new host record) and Kogia breviceps; preadults from Phocarctos hookeri. Adult P. decipiens were recorded from Phocarctos hookeri; preadults from Arctocephalus forsteri and K. breviceps. Other anisakids found were Anisakis physeteris (Baylis 1923), Contracaecum osculatum Rudolphi 1802 and Pseudoterranova kogiae (Johnston and Mawson 1939) Mosgovoi 1951. These records are all new for the New Zealand region except P. decipiens from P. hookeri and C. osculatum from Arctocephalus forsteri. A. simplex and C. osculatum were found associated with gastric ulcers in Arctocephalus forsteri.</p>

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Airbnb and the paradox of the body: The biopolitical management of hosts in four tourist towns in New Zealand

Journal of Sociology ◽

10.1177/14407833211000122 ◽

2021 ◽

pp. 144078332110001

Author(s):

Stella Pennell

Keyword(s):

New Zealand ◽

Business Model ◽

Sharing Economy ◽

The Body ◽

Business Practices ◽

Individual Freedom ◽

Time Work ◽

Part Time ◽

Part Time Work ◽

Low Wages

Airbnb is emblematic of a set of business practices commonly known as ‘the sharing economy’. It is a disruptive business model of homestay accommodation that has exploited conditions of growing precarity of work since 2008. Work precarity is particularly evident in regional tourist areas in New Zealand, which historically experience seasonal, part-time work and low wages. Airbnb draws specifically on the rhetoric of micro-entrepreneurism, with focus on individual freedom and choice: appealing concepts for those experiencing precarity. This article challenges the rhetoric of Airbnb and investigates notions of home, authenticity and hospitality that are reconceptualized under a specific regime of digital biopolitics. Drawing on research conducted in four regional tourist towns in New Zealand this article analyses the biopolitical interpellations that impact hosts’ subjectivities as entities in motion and considers the ways that the rationalities of Airbnb’s algorithms modulate the embodied behaviours of its hosts.

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Myiasis in Bufo regularis caused by a Tabanid Larva

Parasitology ◽

10.1017/s0031182000019934 ◽

1924 ◽

Vol 16 (1) ◽

pp. 111-112

Author(s):

Edward Hindle

Keyword(s):

Fibrous Tissue ◽

Dorsal Surface ◽

Body Cavity ◽

The Body ◽

Careful Examination ◽

Large Female ◽

Considerable Time ◽

Ventral Region ◽

Cylindrical Structure ◽

The Right

In December, 1922, whilst dissecting a large female example of Bufo regularis, one of my students noticed a cylindrical structure extending along the ventral region of the body-cavity. A careful examination showed that this structure consisted of an elongated sac-like diverticulum of the right lung, containing an almost full-grown specimen of a dipterous larva, which could be seen through the membraneous wall of the diverticulum. The base of the latter, in addition to its point of origin from the lung, was also connected to the dorsal surface of the liver by strands of fibrous tissue, suggesting that the growth had been in existence some considerable time in order to cause such adhesions. Posteriorly, the diverticulum hung freely in the body cavity and extended to the extreme hinder end. Its dimensions were 5·5 cm. in length, by 0·5 cm. in diameter, but tapering towards each extremity.

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ENCAPSULATION OF RHABDITOID NEMATODES IN MOSQUITOES

Canadian Journal of Zoology ◽

10.1139/z62-103 ◽

1962 ◽

Vol 40 (7) ◽

pp. 1269-1275 ◽

Cited By ~ 41

Author(s):

Joan F. Bronskill

Keyword(s):

Aedes Aegypti ◽

Endemic Species ◽

Body Cavity ◽

Fourth Instar ◽

The Body ◽

Histological Structure ◽

Adult Tissue ◽

Defence Reaction ◽

Blood Sinus

In third and fourth instar larvae of Aedes aegypti (L.), juveniles of the rhabditoid, DD136, penetrate the blood sinus and cardial epithelium of the proventriculus to enter the body cavity of the host, where they complete their development. By 5 hours, a thick capsule developed about many of the ensheathed immature adults of DD136 within the body cavity of A. aegypti larvae. This rapid defence reaction of the mosquito to DD136, which has both a melanin and a cellular manifestation, occurs both in the exotic mosquito A. aegypti and in the two endemic species tested, Aedes stimulans (Walker) and Aedes trichurus (Dyar). The resistance of A. stimulans to an endemic rhabditoid, possibly of the Diplogasteridae, is also similar. The histological structure of the capsule is not affected during metamorphosis in A. aegypti; however, during histogenesis of adult tissue displacement and (or) distortion of some tissues and organs may be caused by the presence of the capsule within the host's body cavity. The activity of the adult A. aegypti is normal when this distortion or displacement is minor. Though usually encapsulated DD136 are retained within the body cavity of A. aegypti during metamorphosis, sometimes they are partially or completely expelled from the host's body cavity at the time of molting.

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Studies on Tapeworm Physiology

Journal of Experimental Biology ◽

10.1242/jeb.26.1.1 ◽

1949 ◽

Vol 26 (1) ◽

pp. 1-15

Author(s):

J. D. SMYTH

Keyword(s):

Bacterial Infections ◽

Detrimental Effect ◽

Horse Serum ◽

Body Cavity ◽

The Body ◽

Nutrient Media ◽

Medium Strength ◽

By Products ◽

Histochemical Examination

1. Plerocercoid larvae of the pseudophyllidean cestode Ligula intestinalis from the body cavity of roach, were cultured in vitro at 40°C. in a variety of saline and nutrient media. About 65% of such cultures were aseptic. 2. During cultivation, larvae produced acid by-products (unidentified) and the pH fell rapidly. 3. The presence of these acid by-products slowed down development, or, if present in sufficient quantity, caused death. 4. In order to obtain development in nutrient media in a period (3 days) comparable to that required in a bird (the normal host) it was necessary to renew the medium 24-hourly. 5. 6% of the eggs produced from a worm cultured in horse serum were fertile. Fertile eggs were never obtained from larvae cultured in any other media. 6. Certain bacterial infections had no apparent detrimental effect on development, but others were toxic. 7. Some larvae underwent development in non-nutrient medium (¾ strength Locke's solution). The exact conditions under which this occurred was not determined. 8. Fragments (3 cm. long), of larvae or larvae with either scolex or posterior half removed, underwent development to the stage of oviposition in nutrient media. 9. Histochemical examination revealed that the plerocercoid larvae were almost fat-free. During cultivation, very large quantities of cytoplasmic fat were produced the quantity being proportional to the duration of cultivation. Fat was produced even under starvation conditions (i.e. during cultivation in saline) and can be considered a metabolic by-product. 10. The fresh plerocercoid contained great quantities of glycogen in the parenchyma and muscle regions. After cultivation in nutrient or saline media, considerable quantities were still present.

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Ka mura ka muri: understandings of organ donation and transplantation in Aotearoa New Zealand

Medical Humanities ◽

10.1136/medhum-2020-012038 ◽

2021 ◽

pp. medhum-2020-012038

Author(s):

Rhonda Shaw ◽

Robert Webb

Keyword(s):

New Zealand ◽

Organ Donation ◽

Well Being ◽

The Body ◽

Cultural Meanings ◽

Aotearoa New Zealand ◽

Values And Beliefs ◽

History Of ◽

Research Findings ◽

Interview Studies

In this article, we refer to the separation of solid organs from the body as bio-objects. We suggest that the transfer of these bio-objects is connected to emotions and affects that carry a range of different social and cultural meanings specific to the context of Aotearoa New Zealand. The discussion draws on research findings from a series of qualitative indepth interview studies conducted from 2008 to 2013 with Māori (the Indigenous people of Aotearoa New Zealand) and Pākehā (European settler New Zealanders) concerning their views on organ donation and transplantation. Our findings show both differences and similarities between Māori and Pākehā understandings of transplantation. Nevertheless, while many Māori draw on traditional principles, values and beliefs to reflect on their experiences in relation to embodiment, gift-giving, identity and well-being, Pākehā tend to subscribe to more Western understandings of identity in terms of health and well-being, in line with international literature on the topic. Rather than reflecting individualistic notions of the body and transplantation as the endpoint of healthcare as do Pākehā, Māori views are linked to wider conceptions of family, ancestry and belonging, demonstrating how different rationalities and ontologies affect practices and understandings surrounding organ transfer technology. In the article, we focus predominantly on Māori perspectives of organ transfer, contextualising the accounts and experiences of our research participants against the backdrop of a long history of settler colonialism and health inequalities in Aotearoa New Zealand.

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The occurrence of Contracaecum sp. larvae (Nematoda : Anisakidae) in the catfishClarias gariepinus (Burchell) from Lake Chivero, Zimbabwe

Onderstepoort Journal of Veterinary Research ◽

10.4102/ojvr.v71i1.283 ◽

2004 ◽

Vol 71 (1) ◽

Cited By ~ 15

Author(s):

M. Barson

Keyword(s):

Significant Relationship ◽

Condition Factor ◽

Clarias Gariepinus ◽

Parasite Prevalence ◽

Body Cavity ◽

The Body ◽

Nematode Parasites ◽

Significant Difference ◽

Third Stage ◽

Males And Females

Clarias gariepinus were collected from Lake Chivero, Zimbabwe, and examined for nematode parasites from November 2000 to May 2002. Of the 202 specimens collected, 42.6 % were infected with third-stage larvae of Contracaecum sp. in the body cavity. The intensity of the infection was 1-7 worms per fish (mean intensity = 2.2). Seasonal variation in the prevalence of the parasite was not obvious and there was no significant difference in the prevalence of infection between males and females (c2 = 2.228; P > 0.05). No significant relationship between host size and prevalence was established. There was also no significant relationship between intensity and the body condition factor (r = 0.11; P > 0.05). The low parasite prevalence may have been caused by the disruption of the infection cycle since piscivorous birds, which are the final hosts of the parasite, do not feed on C. gariepinus in Lake Chivero.

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