A risk-based detection survey for the predatory mirid Macrolophus pygmaeus in New Zealand

2019 ◽  
Vol 110 (3) ◽  
pp. 370-378
Author(s):  
John M. Kean ◽  
Sarah Mansfield ◽  
Scott Hardwick ◽  
Diane M. Barton
Keyword(s):  
New Zealand ◽  
Host Plants ◽  
Published Data ◽  
Population Densities ◽  
High Confidence ◽  
Greenhouse Whitefly ◽  
Macrolophus Pygmaeus ◽  
Predatory Mirid ◽  
Density Population ◽  
Local Habitat

AbstractMacrolophus pygmaeus, a predatory mirid used to manage greenhouse whitefly, was illegally imported into New Zealand, and for a time was reared and sold to commercial tomato growers. We designed and implemented a risk-based detection survey to determine whether M. pygmaeus was still present in New Zealand a decade later. The survey was designed to have an 80% chance of detecting a single low density (0.05 per lineal metre of host plants) population within 1 km of known points of introduction. The survey was implemented between 8 and 15 March 2018. Local habitat constraints meant that the planned sampling had to be modified but this was accounted for in the subsequent analysis. No M. pygmaeus were found in the samples, but 93 specimens from seven other mirid taxa were detected, validating the sample methods. The survey gives 60% confidence that M. pygmaeus was not present at a mean density of 0.05 per lineal metre of habitat. It gives 80% confidence that a population at 0.1 m−1 was not present and 90% confidence that no population exists at >0.18 m−1. Though there are no published data on typical field population densities of M. pygmaeus, for related species the survey would have had high confidence in detecting any medium to high density population present. Therefore, it is likely that M. pygmaeus is no longer present in New Zealand, but if extant within the sampled areas then we have high certainty that it was at low densities compared to other predaceous mirids.

Ceroplastes sinensis. [Distribution map].

1980 ◽  
Author(s):  
Keyword(s):  
New Zealand ◽  
South America ◽  
Geographical Distribution ◽  
West Indies ◽  
Ivory Coast ◽  
Host Plants ◽  
Distribution Map ◽  
New Distribution ◽  
Distribution In Europe

Abstract A new distribution map is provided for Ceroplastes sinensis Del G. (Hemipt., Coccoidea) (Chinese Wax Scale). Host Plants: Citrus, figs (Ficus), grape, pear. Information is given on the geographical distribution in EUROPE (excl. USSR), Corsica, France, Italy, Portugal, Sardinia, Sicily, Spain, ASIA (excl. USSR), China, Iran, Lebanon, Philippines, Turkey, USSR, AFRICA, Algeria, Benin, Egypt, Ivory Coast, Madeira, Morocco, Mozambique, Togo, Tunisia, AUSTRALASIA, Australia, New Zealand, WEST INDIES, Bermuda, Jamaica, SOUTH AMERICA, Argentina, Brazil, Chile, Ecuador, Uruguay.

Ustilago hypodytes. [Descriptions of Fungi and Bacteria].

1984 ◽  
Author(s):  
J. E. M. Mordue
Keyword(s):  
New Zealand ◽  
North America ◽  
South America ◽  
Root System ◽  
Geographical Distribution ◽  
Host Plants ◽  
Meristematic Tissue ◽  
Wide Range ◽  
Vegetative Multiplication ◽  
Established Infection

Abstract A description is provided for Ustilago hypodytes. Information is included on the disease caused by the organism, its transmission, geographical distribution, and hosts. HOSTS: A wide range of grasses, including species of Agropyron (many), Ammophila, Brachypodium, Bromus, Calamagrostis, Diplachne, Distichlis, Elymus (many), Festuca, Glyceria, Hilaria, Hordeum, Haynaldia, Lygeum, Melica, Orysopsis, Panicum, Phalaris, Phleum, Poa (many), Puccinellia, Secale, Sitanion, Sporobolus, Stipa (many), and Trisetum. DISEASE: Stem smut of grasses. GEOGRAPHICAL DISTRIBUTION: Chiefly a temperate species found in Europe (including Denmark, Finland, France, Germany, Hungary, Italy, Romania, Sweden, Switzerland, UK, USSR, Yugoslavia) and North America (Canada, USA) and extending to central and South America (Argentina, Peru, Uruguay), N. Africa (Libya, Morocco, Tunisia), Japan, Australia and New Zealand. TRANSMISSION: Not fully understood, though inoculation experiments have demonstrated that infection occurs in mature vegetative plants (possibly through meristematic tissue), not seeds or flowers (22, 240; 24, 511). Once established, infection is systemic, probably overwintering in the root system and spreading by vegetative multiplication of host plants as well as from plant to plant (24, 511; 19, 720).

Should immunocontraception be used for wildlife population management?

2004 ◽  
Vol 26 (1) ◽  
pp. 61 ◽  
Author(s):  
DW Cooper
Keyword(s):  
Immune Response ◽  
New Zealand ◽  
Immune Responses ◽  
Fundamental Problem ◽  
Public Perceptions ◽  
Published Data ◽  
Red Foxes ◽  
European Rabbits ◽  
Selection For ◽  
Self Antigens

Immunocontraception involves eliciting an immune response against eggs, sperm or hormones so that successful reproduction is prevented. Work in Australasia is aimed at European rabbits (Oryctolagus cuniculus), red foxes (Vulpes vulpes), house mice (Mus musculus), common brushtail possums (Trichosurus vulpecula), koalas (Phascolartcos cinereus) and kangaroos (Macropus spp.), with the vaccines involved all containing self antigens or their relatives. Two fundamental problems have been inadequately addressed in this research. The first problem is that it is difficult to obtain strong immune responses against self antigens and so the vaccines may be ineffective. Most published data on the effect of immunocontraceptives on reproduction involve the use of an adjuvant of which there are many kinds. The materials enhance the immune response greatly. The most frequently used is Freund?s adjuvant which can cause chronic suffering. Its use on wildlife will lead to very negative public perceptions. There has been no convincing demonstration that successful immunocontraception is possible with any method of vaccination likely to be used in the field, if success is defined as contraception of a proportion of the population high enough for management requirements. If it is assumed that success can be achieved, the second fundamental problem arises with two potential consequences. Even with adjuvant, a substantial minority of the vaccinated animals remains fertile. The first consequence is that since failure to be contracepted is likely to be in part genetic, there is likely to be rapid selection for these non-responders. The method will become ineffective in a few generations. The second problem is that the offspring of the animals which breed will have altered immune responses. Their capacities to respond to their own pathogens or to harbor pathogens of other species in the same ecosystem are likely to be changed. The presence of chlamydia in P. cinereus and bovine tuberculosis in New Zealand T. vulpecula means that responses to these pathogens would have to be studied in offspring of immunocontracepted parents to ensure that the offspring were not more susceptible to them. New Zealand intentions to put an immunocontraceptive into a T. vulpecula gut worm must be viewed with caution by Australia. The eggs of transgenic worms will be easily transplanted either accidentally or deliberately back into Australia, and so infect T. vulpecula in Australia.

scholarly journals The omnivorous predator Macrolophus pygmaeus , a good candidate for the control of both greenhouse whitefly and poinsettia thrips on gerbera plants

2019 ◽  
Vol 27 (3) ◽  
pp. 510-518 ◽  
Author(s):  
Ada Leman ◽  
Barbara L. Ingegno ◽  
Luciana Tavella ◽  
Arne Janssen ◽  
Gerben J. Messelink
Keyword(s):  
Greenhouse Whitefly ◽  
Macrolophus Pygmaeus

scholarly journals The lifecycle and epidemiology of Bactericera cockerelli on three traditional Maori food sources

2010 ◽  
Vol 63 ◽  
pp. 275-275
Author(s):  
A.J. Puketapu
Keyword(s):  
New Zealand ◽  
Ipomoea Batatas ◽  
Host Plants ◽  
Host Preference ◽  
Life Stage ◽  
Food Sources ◽  
Bactericera Cockerelli ◽  
Plant Remains ◽  
Introduced Pest ◽  
Solanum Aviculare

The tomato/potato psyllid Bactericera cockerelli (Sulc) (Hemiptera Triozidae) is an introduced pest of solanaceous crops in New Zealand A range of established plants play host to Bactericera cockerelli including three traditional Maori food sources taewa or Maori potatoes (Solanum tuberosum ssp andigena) kumara (Ipomoea batatas) and poroporo (Solanum aviculare) Taewa and kumara are highly susceptible to summer B cockerelli infestation whilst poroporo an evergreen plant remains susceptible yearround and provides overwintering refuge Extensive monitoring of each host plant was carried out to determine the significance of each host in the lifecycle of B cockerelli in New Zealand Poroporo was monitored from late autumn for 6 months to determine if the plant served as a significant overwintering host for the pest after harvesting summer crops Taewa and kumara plants were monitored throughout the summer growing season on a weekly basis increasing to twice a week as populations proliferated Host plants were monitored both in the natural environment and under laboratory conditions Data collected contributed to tracking population development of B cockerelli on each host including the length of each life stage (ie egg nymph adult) Comparisons between the three hosts revealed host preference host suitability and the significance of each host in the lifecycle progression of B cockerelli

Corollospora gracilis. [Descriptions of Fungi and Bacteria].

2009 ◽  
Author(s):  
D. I. Enríquez
Keyword(s):  
South Africa ◽  
New Zealand ◽  
Dominican Republic ◽  
Geographical Distribution ◽  
Tamil Nadu ◽  
Host Plants ◽  
West Bengal ◽  
Rhizophora Mangle ◽  
Thalassia Testudinum ◽  
Syringodium Filiforme

Abstract A description is provided for Corollospora gracilis. Information on the host plants (Coccoloba uvifera, Rhizophora mangle, Sargassum sp., Syringodium filiforme and Thalassia testudinum), geographical distribution (South Africa, Mexico, Japan, Thailand, Australia, New Zealand, Cuba, Dominican Republic, and Tamil Nadu and West Bengal, India), and dispersal and transmission of the pathogen is presented.

Edwardsiana crataegi. [Distribution map].

1982 ◽  
Author(s):  
Keyword(s):  
New Zealand ◽  
North America ◽  
South America ◽  
Geographical Distribution ◽  
Host Plants ◽  
West Germany ◽  
Distribution Map ◽  
Leaf Hopper ◽  
New Distribution ◽  
Distribution In Europe

Abstract A new distribution map is provided for Edwardsiana crataegi (Douglas) (Edwardsiana austrails(Froggatt), Typhlocyba froggatti Baker (Hem., Cicadellidae) (Apple Leaf-hopper). Host Plants: Apple, cherry, pear, plum, quince. Information is given on the geographical distribution in EUROPE (excl. USSR), Austria, Britain, Czechoslovakia, Denmark, Finland, France, East Germany, West Germany, Hungary, Ireland, Italy, Netherlands, Poland, Romania, Sweden, Switzerland, Yugoslavia, USSR, AUSTRALASIA, Australia, New Zealand, NORTH AMERICA, Canada, USA, SOUTH AMERICA, Argentina, Chile.

‘Quit while you are ahead – and smell the roses!’ A survey of retired Fellows of the Australian and New Zealand College of Anaesthetists

2021 ◽  
pp. 0310057X2110057
Author(s):  
Diana Strange Khursandi ◽  
Victoria Eley
Keyword(s):  
Clinical Practice ◽  
New Zealand ◽  
Standard Deviation ◽  
Response Rate ◽  
Common Factors ◽  
Published Data ◽  
Factors Affecting ◽  
Retirement Decisions ◽  
Zealand College ◽  
The Mean

There are no published data on the age of retirement of anaesthetists in Australia and New Zealand. We surveyed 622 retired Fellows of the Australian and New Zealand College of Anaesthetists to determine their ages of complete retirement from clinical practice, demographics, and whether they had retired at the age they had intended to retire. We also aimed to explore factors affecting the decision to retire, the practice of ‘winding down’, common post-retirement activities, and the arrangement of personal and professional affairs. Responses were received from 371 specialists (response rate 60%). The mean (standard deviation) age of retirement was 65.2 (6.9) years. The mean (standard deviation) retirement ages ranged from 62.0 (7.1) years (those who retired earlier than planned) to 68.0 (4.3) years (those who retired later than they had intended). The mean (standard deviation) age of retirement of the male respondents was 66.0 (6.5) years, and for female respondents was 62.7 (7.7) years. Two hundred and thirty-three respondents (63%) reported winding down their practice prior to retirement, and 360 (97%) had made a will. Poor health and loss of confidence were the two most common factors in the retirement decisions of those who retired earlier than they had planned. Our results may assist current practitioners plan for retirement, and suggest strategies to help health services, departments and private groups accommodate individuals in winding down their practice.

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