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C Programme Components: Objectives, Preferred Option and Issues to Resolve
1 North IslandD Phase III Development Process
Appendix 1. Options paper for North Island active surveillance
Appendix 2. Draft terms of reference for diagnostic laboratories participating in Phase II varroa surveillance
Appendix 3. Terms of reference for a mediation process between beekeepers affected by the movement control line
Appendix 4. Recommendations for movement control permitting conditions for Phase II (04/09/00)
Appendix 5. Options paper for South Island active surveillance
Appendix 6. Draft terms of reference for an analysis of the risks to non-target species associated with a feral bee poisoning programme
Appendix 7. Draft terms of reference for an assessment of the risk to public health associated with a feral bee poisoning programme
Appendix 8. Draft terms of reference for an analysis of the risks of varroa introduction into the South Island by non-beekeeper pathways (cut-flowers, logs, cars, freight, bumblebees)
Appendix 9. Draft terms of reference for development and approval of a standardised delivery method for formic acid solutions for the treatment of varroa
Appendix 10. Funding arrangements for North Island treatments
Appendix 11. Terms of reference for a varroa control booklet contract
Appendix 12. Draft terms of reference for the delivery of a programme of beekeeper workshops to develop skills for varroa management
Appendix 13. Terms of reference for the Varroa Management Group
On 12 July 2000, the Cabinet agreed to a three-stage Government response to the incursion of Varroa destructor (varroa). The first stage of this response is already underway and progressing well. It involves immediate assisted treatment of infected hives with approved products at the Crown's expense, upon consent of the beekeeper.
Arrangements for the long-term management of varroa will be considered over the next two years using the framework for pest management provided by the Biosecurity Act 1993. A programme co-ordinator has been employed within MAF to facilitate the development of a national pest management strategy (NPMS) proposal in accordance with Part V of the Act. This may or may not result in a decision to proceed with a NPMS. Developing the NPMS proposal will involve extensive industry consultation, and if the industry indicates it does not require statutory powers to manage varroa long term, then a NPMS is probably not warranted. One advantage of a NPMS, however, is that it provides an opportunity to formalise sustainable industry funding arrangements.
For the period until long-term arrangements can be put in place, the Cabinet has agreed to support a two-year management programme to assist the transition into long-term control. The objectives of this programme are to ensure the South Island remains varroa free for as long as possible, and that impacts in the North Island are mitigated. The Cabinet has directed MAF to work with beekeepers and other interested industries to finalise an operational plan, and report back with a:
MAF has discussed the development of the transitional two-year Government supported management programme at 14 regional meetings throughout the country. These meetings were convened by branches of the National Beekeepers' Association (NBA), and other interested industry groups were also in attendance. MAF has consolidated the feedback from these regional meetings.
This document contains a two-year management proposal intended to be finalised during a meeting in Wellington on 20 September 2000. Attendees at this meeting will include:
Subsequent to this meeting, MAF will present the proposed two-year management plan to the Cabinet for its consideration. Final decisions on the programme will be subject to available resources and based on cost benefit analysis.
The development of the transitional (two year) varroa management plan will be undertaken by MAF in consultation with beekeepers and other affected stakeholders. The development process subsequent to the Cabinet decision on 12 July 2000 is described below.
Primary objective
Mechanisms to achieve objective
Passive surveillance
Active surveillance
(Note: A discussion and analysis of North Island active surveillance strategies developed by MAF National Centre for Disease Investigation appears as Appendix 1)
Primary objective
Primary objective
Means of achieving the objective
(Note: A discussion and analysis of North Island active surveillance strategies developed by MAF National Centre for Disease Investigation appears as Appendix 4)
Primary objective
Mechanisms to achieve the objective
Primary objective
Mechanisms to achieve the objective
Primary objectives
Mechanisms for achieving the objective
(N.B. One synthetic pyrethroid is already approved and another is in the approval process. A further product from a separate chemical family is also already in the approval process. The distributor of a thymol product has indicated intention to progress through the approval process.)
Mechanisms to achieve the objective
Primary objective
Mechanisms to achieve the objective
The draft control plan suggested a research fund of $1.4M. MAF's experience to date suggests this sum would purchase between 15-25 pieces of original research of varying size.
Primary objectives
Mechanisms to achieve the objective
N.B. These figures are derived from the indicative cost section of each programme component, with rounding of figures upwards.
Totals
First year costs: $1,659,630
Second year costs: $1,557,630
Combined costs of two-year programme: $3,217,260
N.B. All figures are GST exclusive.
Objectives
Issues
Options for long term management will be considered over the next two years.
The aim of this paper was to monitor the spread of varroa through the North Island of New Zealand. The objective was to detect 95% of clusters of varroa infestation at the time of sampling 1 year after spread occurred from an index site in an area. The reason for the monitoring programme is to alert beekeepers of the spread of varroa to the proximity of their sites, before significant losses occur.
A grid sampling scheme was used to design an active surveillance programme for varroa mite spread detection through the currently uninfested parts of the North Island. A range of options was assessed placing a 10 x 10 km grid and a 20 x 20 km grid over the North Island.
The confidence of detecting varroa in a grid containing a cluster was calculated at a range of different intra-grid prevalences. A cluster of disease is defined as an apparent prevalence in excess of 33% of apiaries per grid.
The appropriate intra-grid prevalence to use was assessed by examination of the Hauraki cluster. The Hauraki cluster is approximately equivalent to a cluster resulting from spread one year after establishment of the index case.
Grid units containing one or more infested apiaries (as defined by the Varroa Delimiting Survey at 27/7/00) were identified and flagged as an infected grid unit. The number of apiaries, tested apiaries and positive apiaries were collated for each infected grid unit. The expected number of infested apiaries (had all apiaries within a grid unit been tested) was calculated by dividing the number of test positive apiaries by the proportion of apiaries tested.
Using a real example of a cluster such as Hauraki provides somewhat of a "benchmark". This cluster yielded an intra-grid prevalence of 86% within a 10 x 10 km grid centred on the area, or 48% prevalence within a 20 x 20 km cell.
It was felt that a 95% confidence of detection was satisfactory within the context of the North Island surveillance programme, although for zonal freedom, the OIE recommends a 99% confidence.
The confidence calculation was based on the hypergeometric distribution, which defines the probability of getting a particular outcome when sampling without replacement, given random distribution of infested and non-infested sites within a finite population. The specific calculation used the probability of finding no positives out of a range of randomly tested sites within an infected grid. This was done for each grid cell, using actual geographic data extracted from the Apiary database. The results were then summarised. The confidence was then taken to be 1 minus the probability of not finding any positives, i.e. the probability of finding at least one positive.
A total of 910 10 x 10 km grid units and 251 20 x 20 km grid units contained apiaries currently not infested. As of 27 June 2000, 50 infected grid units were present in the North Island. Of the infested grid units 21 were defined as clusters (apparent prevalence of infested apiaries in excess of 33%).
Tables are presented with a range of confidence levels and intra-grid prevalences to enable selection of the preferred option.
Table 1 shows confidence of detecting a cluster in a 10 x 10 km grid given various levels of test intensity and assuming various apparent prevalences. The Hauraki cluster was examined and found to have 86% intra grid prevalence in a 10 x 10 km grid.
Table 1. Confidence of detecting a cluster in a 10 x 10 km grid with different levels of testing and different apparent intra-grid prevalences.
| Apiaries to test | Apiaries to test per 10 by 10 km grid |
Apparent Prevalence | ||||
| 20% | 33% | 40% | 60% | 80% | ||
| 910 | 1 | 32 | 42 | 47 | 63 | 82 |
| 1710 | 2 | 53 | 67 | 74 | 90 | 98 |
| 2518 | 3 | 67 | 82 | 86 | 98 | 100 |
| 3341 | 4 | 77 | 91 | 95 | 99 | 100 |
Table 2 shows confidence of detecting a cluster in a 20 x 20 km grid given various levels of test intensity and assuming various apparent prevalences. The Hauraki cluster was examined and found to have 48% intra grid prevalence in a 20 x 20 km grid.
Table 2. Confidence of detecting a cluster in a 20 x 20 km grid with different levels of testing and different apparent intra-grid prevalences.| Apiaries to test | Apiaries to test per 20 by 20 km grid |
Apparent Prevalence | ||||
| 20% | 33% | 40% | 60% | 80% | ||
| 1 | 24 | 36 | 42 | 61 | 81||
| 496 | 2 | 42 | 59 | 67 | 87 | 97 |
| 745 | 3 | 56 | 75 | 83 | 96 | 100 |
| 991 | 4 | 67 | 85 | 91 | 99 | 100 |
The use of a grid based testing program yields an even test density across the North Island. By collation of results this will provide the desired knowledge of regional freedom. The grid based approach was preferable to district or regional level samples as it reflects the unit of interest and will actually show the spread of disease geographically.
The size of the grid should reflect the size of a cluster of cases. The total number of sites to be tested will be affected by the grid cell size. The length of time a cluster of infection may have been present, given an approximate local spread rate of 5 km per year should be used to decide which grid cell size is most appropriate.
It was not necessary to examine issues of hive sensitivity or intra site prevalence as empirical (apparent) prevalence was used in the calculations. However, by increasing the site level sampling to all hives on site with a maximum of 20 hives per site, a better indication of spread will result.
The preferred option for the 10 x 10 km grid was to test 2 apiaries per grid. This requires the testing of 1710 apiaries and yields a 98% confidence of detecting a grid with a prevalence of 86%, the equivalent of the Hauraki cluster.
The preferred option for the 20 x 20 km grid was to test 4 apiaries per grid. This requires the testing of 991 apiaries and gives a 95% confidence of detecting a grid with a prevalence of 48%, the equivalent of the Hauraki cluster at a less precise level. The disadvantage of the larger grid is that the discovery of an infected apiary, would require more follow up work, hence more testing.
If it is desired to increase the testing intensity to detect clusters with a prevalence of 33%, then there is a need to increase the numbers of apiaries to test per cell (E.g. 7 apiaries per cell to detect infestation within a 20 x 20 km grid with 98% confidence). However, the aim to actively monitor spread with the objective to enable beekeepers to time treatment before significant losses occur would be possible with both previous options proposed, the difference being precision in the size of the area that will be deemed infected once varroa is found in a grid.
To approve laboratories with appropriate technical skills and quality assurance capabilities to undertake diagnostic work resulting from field surveillance activities during Phase II of the varroa management plan.
Up until the present time, the MAF National Plant Pest Reference Laboratory (NPPRL) has performed all diagnostic work for varroa, as is appropriate for surveillance for an exotic disease and during a response to an exotic disease incursion.
On 12 July 2000 Cabinet decided not to attempt eradication of varroa, and directed MAF to develop a three phase management plan to mitigate the impacts of varroa in New Zealand. NPPRL have continued to act as diagnostic laboratory for surveillance undertaken during Phase I of the management plan (delivery of immediate assisted treatement in the infected area, and testing on request at the margins of this area). MAF's intention is to introduce, where appropriate, competition into the delivery of all components during Phase II of the management plan. Phase II includes monitoring spread of varroa in the North Island, and surveillance in the South Island to provide an early warning of an incursion to maximise the probability of successful eradication.
In line with MAF policies of not providing services in competition to the private sector, the delivery of field and laboratory components of surveillance in the North and South Islands will be contracted to private sector agencies with appropriate technical skills and quality assurance capabilities.
3.1 Laboratory personnel performing screening shall be trained to recognise Varroa destructor and other exotic bee mites. A scientist experienced in the diagnosis of exotic bee mites shall be on duty when the varroa screening laboratory is functioning.
3.2 The standard operating procedure for varroa screening shall be as provided in Appendix 1.
3.3 General requirements of approved laboratories will be as described in the relevant general chapters of the MAF Biosecurity Standard for Approved Veterinary Diagnostic Laboratories (available from MAF Biosecurity on request), specifically:
3.4 Reporting requirements
3.4.1 Routine reporting of results
All results shall be reported to the submitter, who shall be a MAF approved supplier of field surveillance activities during the Phase II varroa management plan. The approved supplier of field surveillance activities shall be responsible for ensuring overall collation of results, and reporting of targets against MAF's specifications for surveillance.
3.4.2 Finding varroa outside known distribution in New Zealand
The distribution of varroa shall be monitored by the laboratory, in accordance with MAF's de-limiting survey information and new findings during Phase II surveillance. Any laboratory confirmation of varroa in an area not previously known as infected shall be immediately notified to MAF Biosecurity Authority (attention: Programme Co-ordinator, Varroa). MAF Biosecurity Authority may request confirmation of the result from NPPRL.
3.4.3 Quarterly report
The supplier shall provide quarterly reports to MAF Biosecurity Authority (attention: Programme Co-ordinator, Varroa) on the following:
These shall cover the months of July to September, October to December, January to March, and April to June. They shall be submitted by 1 November (covering the months 1 July to 30 September) 1 February (covering the months 1 October to 31 December) 1 May (covering the months 1 January to 30 March) and 1 August (covering the months 1 April to 30 June) respectively.
Standard operating procedure for laboratory inspections of sticky boards for varroa
A Movement of samples.
1. Transport of samples outside the infested zone
2. Transport of samples within infested zone
B Inspection Procedures
1. Sticky board samples should be read within 2-3 working days of collection from hives (This will increase the readability of sticky board samples especially under wet weather condition).
2. All the sticky board samples should be examined under a X2 magnifying lamp (minimum 1.75 magnification).
3. Examine every mite specimen on the sticky board to determine whether it is varroa mite or not.
4. If mites suspected to be varroa are seen, these should be verified by examining under the binocular microscope.
5. Samples that are difficult to read under the magnifying lamp due to deposition of hive materials and/or fungal growth should be examined under the binocular microscope.
6. If requested by MAF Biosecurity Authority, positive varroa samples from outside known infested zone, should be submitted (with the Apiary Inspection Form) to a Reference Entomologist, NPPRL for verification within 1 working day.
7. On going training should be carried out to maintain the identification abilities of personnel screening samples.
8. Any suspect exotic disease of honeybees encountered during surveillance for varroa must be immediately notified to the Reference Entomologist, NPPRL, who shall provide instructions for submission to NPPRL for verification.
C Storage of samples after inspection
1. Samples should be sealed, sorted into storage boxes for easy retrieval of specific boards and placed in freezer within 3 working days after inspection, until permission is given for disposal.
D Reporting
1. Record all results on Apiary Inspection Form (EBD03).
2. Completed Apiary Inspection Forms should be duplicated and one should stay with the sample and the other form should be returned to the submitter.
3. Routine reporting of results to the submitter should include a daily summary result sheet is to be sent to the Incident Controller. This should include
4. All new exotics to be reported within 30 minutes of detection.
Facilitate a mediation process with the following outcomes:
A detailed briefing paper developed by Helen Benard, MAF NCDI, is attached.
3.1 Mediation must involve regional beekeeper representatives of Waikato, Bay of Plenty and lower North Island branches, the beekeepers most affected by movement controls between the current Buffer and Surveillance Zones, and the NBA executive.
3.2 The format for mediation is flexible. It may involve a meeting, conference calls, distribution of written materials, compilation of submissions or any other technique the facilitator considers appropriate. MAF requires a mediation plan to be presented for approval prior to the initiation of the mediation process.
3.3 MAF will finance all disbursements (travel of beekeepers to meeting, communication and correspondence costs) associated with the mediation process. However, MAF requires that approval is sought and obtained for costs prior to their being incurred, with an estimate of the cost likely to be incurred.
3.4 A written report detailing the full mediation process to be used and the outcomes of mediation, in particular addressing the objectives described above, must be developed and supplied to MAF.
3.5 The mediation process should be completed and the report submitted to MAF by Thursday 14 September 2000. However, this deadline should not be met at the expense of due attention to the concerns of all parties involved in the mediation process. If the deadline cannot be met, an interim report must be submitted on that date. The interim report must clearly state the process still to be completed and the likely date of completion.
3.6 A consensus outcome to mediation is desirable, but not absolutely necessary. If a clear consensus cannot be reached, the report should present recommendations that the facilitator considers address the majority of the concerns raised by participants in the mediation process.
3.7 Participants in the mediation process should be clearly informed that MAF will implement a consensus or majority recommendation, provided that:
3.8 In the event that mediation results in neither a consensus nor majority recommendation, or that the three conditions at 3.7 are not considered to have been met by the recommendation provided, MAF reserves that right to instigate another process for determining the movement control boundary between the upper and lower North Island. The process may or may not involve consultation with stakeholders.
The lower North Island NBA branches expressed the desire to rationalise the boundary between the upper and lower North Island.
The Wanganui Regional Branch meeting suggested to move the boundary around Taranaki and the Central Plateau north about 50 km to Mount Messenger then to Mount Ruapehu and continue with the existing line from there (see Figure 1). One reason behind this was that Taranaki beekeepers had their operations cut in half by the current boundary. By moving the boundary north to Mount Messenger, the boundary would be a better management (a natural boundary for most Taranaki operations) and topographical boundary. Another reason behind the request was that it would prevent movements of hives from affected areas into a clear area. The central plateau was considered a potential area for introduction of varroa into the lower North Island due to hives from the Bay of Plenty moving to honey sites on the central plateau.
This action would restrict access of upper North Island beekeepers to their honey sites. It was felt by the Wanganui meeting that, as they would possibly be eligible for compensation for loosing access to these honey sites through movement control restrictions and the reverse movements were not eligible for compensation, that it would be fairer to move the boundary to the North. A willingness to come to a contractual agreement for returning sites to upper North Island beekeepers when varroa had spread into the Surveillance Zone was expressed.
The Hamilton meeting considered that the boundary between the present Buffer Zone and Surveillance Zone should remain where it is, at least until further surveillance work is undertaken to understand the full extent of varroa's spread. Movements in the Infected and Buffer Zones should remain tightly controlled to reduce spread, with provision for compensation for affected beekeepers. All hives moved into pollination in the Infected and Buffer Zones should be subjected to prophylactic treatment.
The Auckland meeting considered that the current strict regime of movement control in the Infected and Buffer Zones should be maintained to reduce spread and preserve the option of future eradication. However, the meeting recognised that hive movements to pollination were necessary, and recommended that all hives moved to pollination be subjected to a prophylactic treatment using Apistan.
The Tauranga meeting did not want a movement control line (voluntary movement control only). The meeting did not define the movement control boundary between upper and lower North Island.
The Gisborne Regional Branch meeting suggested moving the boundary South to a more natural topographical and management boundary to Lotton Point to include Waikura Valley in the upper North Island Control Area. There was a strong desire that no Bay of Plenty pollination hives were to be moved into Poverty Bay The view was that not many beekeepers would be affected with only a small number of hives moving into the Poverty Bay area.
An obvious agreement was not reached and a mediation process was suggested to resolve the issues of boundary definition.
Figure 1: Proposed ( ) and existing Control Area boundaries between upper and lower North Island
1. That movement control remains in force between the upper and lower parts of the North Island.
2. Move the movement control boundary to the north as discussed (i.e., Mt. Messenger - Mt. Ruapehu, then continue the existing line to the east.
3. Ensure negotiation between affected beekeepers to resolve issues around longer-term access to southern manuka and northern pollination contracts.
4. Compensation must be regarded as a central issue in finalising movement controls.
No specific recommendations on CA boundary definition made.
No specific recommendations on CA boundary definition were made.
The surveillance/ buffer zone boundary is not a major issue for the majority of Northland beekeepers, except for Queen breeders. No specific recommendations on CA boundary definition made.
No specific recommendations on CA boundary definition were made. South Island branches indicated the desire to keep in place a Surveillance Zone separating the upper and lower North Island to delay spread over the North Island and add to the protection of the South Island.
This meeting recommends that the boundaries remain where they are until further review work is carried out.
This meeting recommends that the surveillance line should be maintained as drawn and compensation be paid as a result of any losses incurred by the present movement control conditions.
Like every other beekeeper, but urgently for the BOP beekeepers, we must now also maximise our returns to ensure each our businesses remain economically viable. We see that decisions taken now, with respect to 'Phase 2', can have either a significant negative or positive affect on many of our beekeepers. Now more than ever, they need their normal expected post pollination honey production opportunities.
Bay of Plenty Beekeepers moved at their Special Meeting, 24. August '00, preceding the Bay of Plenty Regional MAF meeting:
"That the spread of Varroa be controlled by Beekeeper Voluntary Co-operation and that a Branch Committee resolve the protocols to which Beekeepers will comply to protect the interest of all North Island Beekeepers" Carried Unanimously.
With respect to the objectives of control of varroa, the committee sees clearly number one objective 'to keep the SI free for as long as possible' as the most important one. Therefore expertise and money should be spent on where it is most effective. In this case that is Cook Straight.
The committee came up with three options for movement controls.
In order of preference:
Option 1.
No movement controls to be implemented on the NI, but concentrate on the natural barrier Cook Straight to keep the SI free for as long as possible. It was felt that movement controls other than this one will be very hard to police and costly. The SI would be better off with a concentrated effort that no mites make it across the Straight. This will be money very well spent.
Under this option it is proposed that the BioSecurity Act could allow prophylactic treatment in order to slow spread down. This in particular would apply for migratory beekeeping.
Option 2.
If there were to be any movement controls and a line drawn somewhere over the NI, that this be based on last year's migration of hives. The reasoning is that hives in particular from the Bay (Te Puke) can have spread mites, which means that the area in which these hives have been moved cannot be seen as mite free.
Based on this assumption, the line could be roughly starting on the East Coast: just south of Ruatoria in a line westwards till Mt Hikurangi, line to Rakaroa - Waikaremoana - Tarawera - Ashhurst and further just south of PN to Foxton.
The committee's understanding is that no hives coming from the Bay have gone beyond that line.
Also under this option it is proposed that the BioSecurity Act could allow prophylactic treatment in order to slow spread down.
This option is based on an historic reality.
Option 3.
Our least preferred option is based on the current surveillance line. The reality of this line is that it was drawn up too early during the initial surveying for the mite. Movements from the Bay were not taken into account because the line was drawn up before the Te Puke find. The committee's understanding is that this line does not represent any validated evidence of the southern side of it being mite free and therefore should not be adhered to.
However, if this line is adopted in principle IT MUST BE subjected to detailed negotiated change based on the following:
(a) The current surveillance line does not represent the best geographically suitable line. There are serious impacting flaws relating to the current "Districts" boundary line. This line must be made geographically practical.
(b) A significant number of beekeepers are severely economically impacted on by the current ad hoc 50km buffer zone at the surveillance line. There must be freedom of beehives movement up to the final chosen 'Phase 2' surveillance line, if any.
(c) With positive resolution of (a) and (b) there may still be some individual beekeeper livelihoods dramatically affected. Some beekeepers will need the right of each their cases negotiated, also with right of compensation for net income lost.
(d) Also under this option it is proposed that BioSecurity could allow prophylactic treatment in order to slow spread down. It is suggested that treatment be offered for all hives destined for the surveillance line.
Please note that we are currently canvassing each our affected beekeepers with respect to Option 3. We expect these responses to be available by August 11th.]
The movement control policy presented is a substantial revision of the existing movement control conditions. Control zones and movement permitting conditions should be reviewed at the end of Phase II or once varroa is introduced to the lower North Island or South Island.
The objectives of movement control in New Zealand are to:
Policies which will most effectively reduce the spread and therefore the economic impact of varroa may be in direct conflict with minimising the impact of regulatory controls. Conflicts of interest also exist between beekeepers in the upper North Island and those in lower North Island and South Island. It is recognised that most of the immediate negative impacts will be borne directly by beekeepers in the upper North Island. With regard to other stakeholders, industries which pay for pollination services would generally appear to benefit from more relaxed movement controls.
The competing demands were addressed by determining the emphasis of the objectives to be achieved within the different zones by industry consultation and justifying the movement restrictions on a technical basis. Emphasis has been placed on allowing beekeeping to continue as normal within all zones, as the effectiveness of the movement restrictions depend on the support of the beekeeping industry.
To accomplish movement control restrictions it is essential to define zones between which different levels of movement freedom exist. Once their boundary has been defined, keeping in mind the objectives listed above, permitting restrictions can be considered based on technical justification.
There are three distinct areas in New Zealand as far as varroa status: the South Island, the lower North Island and the upper North Island.
A reclassification of currently existing Control Zones is proposed:
The current Infected and Buffer Zones (declared on 29 April 00) within the upper North Island are amalgamated to one Infected Zone. As the Infected Zone is not separated from the lower North Island by a Buffer Zone, the previously-named Surveillance Zone is now classed as a Buffer Zone. As the North and South Island are sufficiently separated, there is no need to have a Surveillance Zone and the South Island is still classed as a Disease Free Zone.
The boundary between the upper and lower North Island would need to be defined taking into account the objectives of reducing spread of varroa while avoiding undue impacts from regulatory interventions and taking into account topography and density of apiary sites.
A mediation process was proposed by MAF for the beekeeping industry to redefine a boundary between the upper and lower North Island and find some solutions for beekeepers affected by the boundary.
The permitting conditions discussed in this paper assume the Control Area boundaries have been redefined and gazetted. It assumes a boundary between upper and lower North Island remains in place to more or less the same extent as before.
These movement control recommendations have been drafted taking into account objectives for movement control, technical grounds, industry views, integrated pest management practices, beekeeper education and long term workable statutory movement restrictions.
Statutory movement restrictions imply that enforcement will be used. Non-compliance with these movement restrictions will result in investigation by the MAF Enforcement Unit, followed by the appropriate actions (E.g. prosecution, destruction of risk goods).
The permitting conditions cater for beekeeper education in two ways. Firstly the permitting conditions aim to educate beekeepers about the risk that goods pose and the correct management of those risks. Secondly, the correct use of chemical treatments is promoted.
Movements within and from the defined Zones proposed are outlined below and given in detail in the following tables. Permit requirements for bee products are to be on a beekeeper/processor/business basis for a period of time (blanket permit) after education on risk management.
1. Movements within the Infected Zone
2. Movements from the Infected Zone to the Buffer or Disease Free Zone
3. Movements within the Buffer Zone
4. Movements from the Buffer Zone to the Infected Zone
5. Movements from the Buffer Zone to the Disease Free Zone
6. Movements within or from the Disease Free Zone
Significant changes from the previous movement control policy (iteration of 23 August) are:
1. The old Infected Zone and Buffer Zone are treated as a uniform area subject to the same movement control conditions.
2. All scheduled items within the Infected Zone can be moved without a permit.
3. Movements of bee products to the South Island are now subject to a permit on a beekeeper/processor/business basis for a period of time (blanket permits) after education on risk management.
Table 1 lists the products and their associated risk ratings. Technical justification of allowing products to move must be based on this risk rating and the ability of this risk to be managed through permitting requirements. If the risk cannot be managed satisfactorily it concludes that the product may not be moved.
Table 1: Risk of products, ability for risk management and statutory controls between zones.
| Product | Risk rating | Risk management | Statutory Controls |
| Royal jelly | Very low | Not necessary | No |
| Bee venom | Very low | Not necessary | No |
| Processed wax | Very low | Not necessary | No |
| Honey retail packs | Very low | Not necessary | No |
| New unassembled beekeeping equipment |
Very low | Not necessary | No |
| Used beekeeping equipment (Protective clothing, smokers and hive tools and vehicles) |
Low | Education | No |
| New boxes and frames containing wax foundation (that have had no contact with bees) |
Low | Possible | Permit |
| Pollen | Medium | Possible | Permit |
| Propolis | Medium | Possible | Permit |
| Crude wax | Medium | Possible | Permit |
| Used beekeeping equipment (boxed/supers and/or combs, undrawn foundations sheets that have been in contact with bees) |
High | Possible | Permit |
| Live bees and brood | Very high | Not possible | Prohibited |
1. Movements within the Infected Zone
All scheduled items can move freely within the Infected Zone, as regulatory controls are though to have serious impact on beekeeping in the Infected Zone and the benefits of regulatory control are not likely to outweigh the impacts.
Regulatory control conclusions
Movement control impacts on beekeeping and the movement permitting conditions on the movements of live bees are inconsistent with IPM practices. The definition of the appropriate population to which permitting conditions should apply would become increasingly unmanageable and unfair over time.
Prophylactic treatment conclusions
A prophylactic treatment of hives starting 14 days prior to pollination and continuing throughout pollination according to label instructions was considered as a possible means of reducing spread at a time when many hives come together from the upper North Island. Even if a reduction in spread could be achieved by this method, it would still not imply that less Apistan would need to be used for treatment in the short to medium term.
There are several disadvantages to the use of prophylactic treatment in pollination sites. Currently infected feral colonies in high-density pollination areas may still be able to transfer infection to managed colonies on pollination sites. Furthermore, according to integrated pest management principles, the appropriate use of a chemical control method is to treat only when necessary and use only according to the manufacturer specifications. This practice is recommended for a good reason: to delay the development of resistance and reduce the likelihood of residues in honey and wax. Therefore the prophylactic treatment is not justifiable as if it were defensible this pollination season, why would it then not be defensible longer term? The use of Apistan for prophylactic treatment even for this pollination season would send out the wrong message to beekeepers.
2. Movements from the Infected Zone to the Buffer or Disease Free Zone
The risk of live bees transferring varroa can not be managed therefore movements are prohibited.
The risk of beekeeping equipment can be managed and therefore permitting of movements can be allowed. A special case is used frames. The risk of brood can possibly be managed by storage for a period of time and specifying the season in which the frames were last used. For the Disease Free Zone an additional requirement can be incorporated to have the frames inspected prior to departure to this zone.
The risk of bee products can be managed and therefore permitting of movements can be allowed. For crude wax, pollen and propolis a blanket permit can be issued on a beekeeper/processor/business basis for a period of time after education on risk management. This will give opportunity for education as well as enforcement.
3. Movements within the Buffer Zone
Varroa is deemed not to be present in the Buffer Zone, therefore no restrictions exist of movements within this zone on any items.
4. Movements from the Buffer Zone to the Disease Free Zone or Infected Zone
Although varroa has not been found to date in the Buffer Zone, there is still considerable risk of it entering into the Buffer Zone from the Infected Zone. As there is an increased risk of it being present, movements to the Disease Free Zone should be aligned with the movements proposed from the Infected Zone to the Disease Free Zone. Movements to the Infected Zone can be managed without restrictions, as the Buffer Zone is not thought to be infested with varroa.
5. Movements within or from the Disease Free Zone
No restrictions for movements within or from the Disease Free Zone are proposed as this zone has the highest probability of freedom of varroa.
The Movement Control Notice allows for an Inspector or Authorised Person under the Biosecurity Act 1993 to grant permission for items listed in the Schedule to be moved under certain conditions. They can authorise the movement of Scheduled items into, within, or from any part of the Controlled Area . This is formalised by way of a Movement Control Permit which may be issued by Apiculture Officers from Regional Offices or by the Movement Control Group based at the Varroa Treatment Programme Headquarters (0800 109 383).
The following tables outline movement permitting conditions, tabulated separately for (1) Infected Zone (upper North Island); (2) Buffer Zone (lower North Island); and (3) Disease Free Zone (South Island).
Infected Zone (upper North Island)
| Product | Use | Conditions |
| All scheduled items | All uses, Movements within Infected Zone |
No permit required |
| Live bees and brood (hives, nucs, queens, bulk bees, packages, swarms placed in a container or hive) |
Movements to Buffer Zone or Disease Free Zone |
Prohibited |
| Honey bulk | Movements to Buffer Zone or Disease Free Zone |
Permit required 1, Drums are not to be attractive to bees and must be shipped in bee proof vehicles or screened to exclude hitchhiking bees. |
| Crude wax Propolis Pollen |
Movements to Buffer Zone or Disease Free Zone |
Permit required 1, Must be stored for 7 days prior to shipment in bee-free environment or frozen for 3 days. All products must be shipped in sealed bee-proof packaging |
| Beekeeping equipment new and unassembled |
Movements to Buffer Zone or Disease Free Zone |
No permit required |
| New boxes and frames containing wax foundation (that have had no contact with bees) |
Movements to Buffer Zone or Disease Free Zone |
Permit required. Must be shipped in bee proof vehicles or screened to exclude hitchhiking bees |
| Beekeeping equipment- used (protective clothing, smokers and hive tools) including vehicles |
Movements to Buffer Zone or Disease Free Zone |
No permit required. Education on cleaning practices especially of vehicles |
| Beekeeping equipment - used (boxes/supers and/or combs, includes undrawn foundation sheets if they have been on a beehive) |
Movements to Buffer Zone. |
Permit required. AAO assessment for risk: Must be stored for 30 days prior to shipment in bee-free environment. Must be shipped in a sealed container, with bees unable to access the equipment |
| Honey retail packs. Processed wax. Royal Jelly. Bee Venom |
Movements to Buffer Zone or Disease Free Zone |
No permit required |
| Laboratory samples (sticky boards, bees in containers) |
Research and survey purposes |
Movements to Buffer Zone or Disease Free Zone. Permit required 1. Must be transported in sealed containers |
Buffer Zone (lower North Island)
| Product | Use | Conditions |
| All Scheduled items | All uses. Movements within Buffer Zone |
No conditions, as long as site is not a Restricted Place |
| All scheduled items |
All uses. Movements to Infected Zone |
No conditions, as long as Buffer Zone site is not a Restricted Place |
| Live bees and brood |
Movements to Disease Free Zone |
Prohibited |
| Honey bulk | Movements to Disease Free Zone | Permit required 1. Drums are not to be attractive to bees and must be shipped in bee proof vehicles or screened to exclude hitchhiking bees. |
| Crude wax, Propolis,Pollen | Movements to Disease Free Zone |
Permit required 1. Must be stored for 7 days prior to shipment in bee-free environment or frozen for 3 days. All products must be shipped in sealed bee-proof packaging |
| Beekeeping equipment- used (protective clothing, smokers and hive tools) including vehicles |
Movements to Buffer Zone or Disease Free Zone |
No permit required. Education on cleaning practices especially of vehicles |
| Beekeeping equipment - used (boxes/supers and/or combs, includes undrawn foundation sheets if they have been on a beehive) |
Movements to Disease Free Zone |
Permit required. AAO assessment for risk and may be subject to inspection prior to departure. Honey frames/combs must be stored for 30 days prior to shipment in bee-free environment. Must be shipped in a sealed container, with bees unable to access the equipment |
| Beekeeping equipment new and unassembled |
Movements to Disease Free Zone |
No permit required |
| New boxes and frames containing wax foundation (that have had no contact with bees) |
Movements to Buffer Zone or Disease Free Zone |
Permit required. Must be shipped in bee proof vehicles or screened to exclude hitchhiking bees |
| Honey retail packs. Processed wax. Royal Jelly. Bee Venom. |
Movements to Disease Free Zone |
No permit required |
| Laboratory samples (sticky boards, bees in containers) |
Research and survey purposes. Movements to Disease Free Zone |
Permit required 1. Must be transported in sealed containers |
Disease Free Zone (South Island)
| Product | Use | Conditions |
| All Scheduled items | All uses | Movements within Disease Free Zone. No conditions, as long as site is not a Restricted Place |
| All Scheduled items |
All uses | Movements to Infected/Buffer Zones. No permit required, as long as site is not a Restricted Place |
1 To be permitted on a beekeeper/processor/business basis for a period of time (blanket permit) after education on risk management. Desirable to record the destination of the products to enable targeted surveillance of the Buffer and Disease Free Zones.
Definitions of risk management conditions
Screened: Bee proof mesh (e.g. insect screen on hives or shelter belt material over loads on trucks
Bee proof: Bees unable to gain access under normal circumstances
Bee free environment: Bees unable to gain access under normal circumstances
Sealed bee proof packaging: Plastic wrapped or sealed in wood, cardboard, plastic outer
Sealed container: Plastic wrapped or sealed in wood, cardboard, plastic outer
Crude wax: Wax scrapings or blocks of wax processed by beekeeper
Processed wax: Wax subjected to secondary processing into product (e.g. foundation sheets, candles)
Frozen: Minimum of -12oC
Robert L. Sanson, Clifton B. King, Graham F. Mackereth
The goals of the South Island (SI) surveillance plan are to:
1. Provide evidence of freedom from mite infection according to internationally agreed standards.
2. Provide sufficient detection power for a single cluster of infection, such that eradication could be attempted.
Five methods to achieve these objectives are considered.According to the International Committee of the OIE (1999), the proposed standard for bee disease freedom states that surveys should be designed to detect a prevalence not exceeding 0.2% with a 99% confidence.
Based on 9182 geo-coded apiaries in the South Island (as at 27 July 2000), the required number of sites to test to achieve this level of confidence using a simple random sample (SRS) would be 2071. This assumes that the 18 sites (0.2%) would be randomly distributed throughout the SI.
Evidence from the North Island (NI) Varroa delimiting survey indicates that apiaries with mite infestation are distinctly clustered.
For the purposes of providing a "benchmark", a cluster is defined as a geographical unit of the approximate dimensions of the Hauraki cluster in the North Island. Hence a 20 x 20 km grid was used to represent this. The Hauraki cluster was examined and found to have a 48% intra-grid prevalence within a grid cell of these dimensions.
It is proffered that if a single such cluster existed within the South Island (SI), then eradication would potentially be achievable. However, to detect a single cluster, every geographic unit would need to be tested. Within each cluster unit, a random sample of apiaries would then be selected for testing. There are 319 grid cells that contain apiaries throughout the SI. The geographical distribution of these cells is shown in Figure 1.
The confidence of detection calculation is based on the hypergeometric distribution, which defines the probability of getting a particular outcome when sampling without replacement, given random distribution of infected and non-infected sites within a finite population. The specific calculation uses the probability of finding zero positives out of 1 to 7 randomly tested sites within each grid cell, if it was infected. This was done for each grid cell containing apiaries in the SI, using actual geographic data extracted from the Apiary database. The results were then summarised. The confidence was then taken to be 1 minus the probability of not finding any positives, i.e. the probability of finding at least one positive.
Figure 1. Distribution and density of South Island apiaries, based on 20x20 km grid cells.
A histogram of the number of apiaries per grid cell is shown in Figure 2.
Figure 2. Distribution of number of apiaries per 20 x 20 km grid cell throughout the South Island.
Table 1 shows the confidence of detecting a cluster in a 20 x 20 km grid given various levels of random within grid-cell testing intensity and assuming various apparent intra-grid prevalences.
Table 1. Confidence of detecting a cluster in a 20 x 20 km grid with different levels of testing and different possible intra-grid prevalences.
| Apiaries tested per 20 km grid |
Total apiaries to test |
Apparent grid-level Prevalence | ||
| 20% | 30% | 48% | ||
| 1 | 319 | 28 | 39 | 53 |
| 2 | 615 | 46 | 62 | 79 |
| 3 | 896 | 60 | 78 | 91 |
| 4 | 1161 | 71 | 87 | 96 |
| 5 | 1414 | 79 | 93 | 98 |
| 7 | 1890 | 89 | 98 | 100 |
It is reasonable to postulate that some areas of the SI are at higher risk of introduction of Varroa, and that there are certain "threats" that would increase the rate of spread within the SI. Further, if it were possible to identify these risks and threats, then it would be possible to design a purposive surveillance plan that targeted those sites.
Air and Sea ports
It is believed that air and sea ports are likely to be the primary portals of entry for Varroa into the SI. A list of container-handling sea ports was obtained from the New Zealand Maritime Authority. These are listed in Table 2 below.
Port
Nelson
Picton
Lyttleton
Timaru
Dunedin
Bluff
Westport
Greymouth
Takaka
A list of airports in the South Island was compiled from commercial airline timetables and is shown in Table 3.
Airport
Nelson
Blenheim
Christchurch
Oamaru
Dunedin
Invercargill
Mt Cook
Tekapo (currently closed)
Twizel
Queenstown
Te Anau
Hokitika
Westport
Apiaries within 5 km of the above air and sea ports were identified using a geographic information system (GIS).
Large urban centres
Other risk sites are large urban centres due to the "importation" of cut flowers and fruits from the NI or overseas. Large urban centres (>= 100 ha in size) were extracted from the New Zealand Land Cover Database (LCDB). Sites within 2 km of these were identified.
Honey and wax collection / processing sites
Sites involved with honey, pollen and wax collection or processing were identified within a GIS. Apiaries within 5 km of these sites were selected.
Pollination areas
Horticultural areas visible on satellite imagery were identified off the LCDB. Apiaries within 2 km of these areas were located.
Large bee-keeping operations
Beekeepers with at least 100 sites were considered to represent a higher threat of spread, not least because they are also likely to be involved with pollination of orchards in the major fruit-growing areas of the SI. Fourteen beekeepers with a combined total of 1757 apiaries were classified as belonging to this threat category.
In total, 3157 apiaries were identified as being in the above risk and threat categories (see Figure 3). It would be required to test a random sample of 1691 of these to achieve a 99% confidence of detecting infection if it was present at a prevalence of 0.2%.
Figure 3. Apiaries classified as high risk of infection or constituting greater threat to spread.
If grid cells are also classified according to similar risk and threat criteria as those outlined above (see Method 3), then they too could be targeted in a purposive sampling manner. The specific risk criteria used included cells within 5 km of air and sea ports; cells within 2 km of major urban centres; cells within 2 km of significant horticultural areas; and cells within 5 km of honey and wax collection or processing houses. The grid cells identified are shown in Figure 4.
Figure 4. Grid cells classified as high risk of infection or of contributing greater threat to spread.
A total of 107 cells were identified, containing 5070 of the registered, geo-referenced sites in the SI. The numbers of sites to test are shown in Table 4.
Table 4. Numbers of sites to investigate for different testing levels, to achieve similar confidence levels to those shown in Table 1.
| Apiaries tested per 20 km grid |
Total apiaries to test |
| 1 | 107 |
| 2 | 212 |
| 3 | 315 |
| 4 | 414 |
| 5 | 512 |
| 7 | 703 |
Other risk or threat categories considered but excluded from calculation were cells containing apiaries belonging to large bee-keeping operations; and cells along major transport routes. The reasons for exclusion are basically that most areas of the SI would have been included, therefore the outcome would have been no different from that presented in Method 2.
A possible combination approach would be to test the major risk areas using a grid-based cluster detection approach (see Method 4), augmented by a SRS of remaining sites in the SI.
The numbers of sites to test would therefore include the 703 apiaries (at 7 sites per 20 km grid - see Method 4), plus a SRS of the 4112 remaining non-risk sites. The actual number to test for the latter scheme would depend on the chosen detection prevalence and the desired level of confidence. With a 0.2% prevalence, the numbers of sites to test for varying confidence levels are shown in Table 5.
Table 5. Number of sites to investigate (using a SRS) to detect a 0.2% prevalence of Varroa infection in the non-risk areas of the South Island at varying confidence levels.
| Desired confidence (%) | Total apiaries to test |
| 90 | 1028 |
| 95 | 1284 |
| 99 | 1799 |
If no evidence of infection was found during the testing of the high risk cells, then it is suggested that 90% confidence of freedom for the SRS part of the investigation would provide sufficient evidence of freedom. Hence the total number of apiaries to test would be 1731 (703 + 1028).
A variation of this theme, would be to do the grid-based cluster detection approach, augmented by a SRS of apiaries belonging to the14 large bee-keeping operations identified in Method 3 to ensure coverage of these enterprises and a SRS of apiaries of all of the remaining beekeepers.
Currently, no evidence of infestation of Varroa in the South Island exists, although some high-risk traces to the SI were investigated subsequent to the mite being detected in the North Island in April 2000. These inspections proved to be negative. However, most observers believe there is now an increased risk of entry to the SI since the mite is fairly well established in the upper NI.
Movement control restrictions are currently in place to stop further movements of live bee and specified risk goods from the North to the South Island. In order to gain international recognition of zonal freedom of disease in the SI, it will be necessary to implement a surveillance plan that is well-founded on epidemiological principles and conforms to internationally agreed standards.
Five methods have been studied. Method 1 is based on a simple random sample (SRS) of all apiaries in the SI, to provide a 99% confidence of detecting infection if it exists at a prevalence at or above 0.2%. However, the method assumes that infestation would be randomly distributed throughout SI apiaries. Evidence to date from the infection in the NI clearly shows that infection is clustered. The principles on which the SRS method is based are violated in the presence of distinct clustering.
Method 2 uses the Hauraki, NI cluster as a benchmark, and is designed to detect a single such cluster anywhere in the SI. If 7 sites per cell are randomly selected and tested, then the method will have achieve a greater than 99% confidence of detecting a single cluster, and should also provide sufficient evidence of freedom if all site tests prove negative. Under this methodology, 1890 sites would need to be tested.
Ultimately, the ideals of science may be tempered by economic realities. If full geographic surveillance of the SI is judged to be too expensive, then a purposive sampling regime could be adopted. Major air and sea ports, large urban centres, and honey and wax processing houses are believed to be at higher risk of entry. Similarly, large bee-keeping operations and pollination areas could pose threats in terms of rate of spread within the SI. Hence, apiaries or cells that fell into some or all of these criteria were selected in Methods 3 - 5. Using a SRS technique (Method 3), 1691 sites of 3157 apiaries would need to be tested to achieve a 99% confidence of detecting infection if it was present at a prevalence of 0.2% in these areas. Using a risk-based cluster detection approach (Method 4), 703 sites scattered through 107 cells (7 per cell) would need to be tested. Using a combination approach (Method 5), the 107 high-risk cells would be tested (as per Method 3) plus 1028 additional sites randomly selected from the remaining areas, for a total of 1731 sites.
The question of what intra-site level testing of hives should be adopted has also been briefly considered. Essentially, to achieve a combined sensitivity of 99% of detecting Varroa mite using either an apiary testing or cluster detection approach, 99.5% sensitivity at the hive level, plus 99.5% at the apiary or grid level would be required. Given that the hive level infection within an apiary could be low (10-30%), virtually every hive would need to be tested.
It must be realized that a single negative testing round using one of the five proposed methods would only provide temporary evidence of freedom from infection. Given that infection is now endemic in the NI, an on-going surveillance plan would be required. This would either require annual testing using one of the above methods, or could be based on a single negative testing round now, plus the installation of sentinel hives in the high-risk areas.
Office International des Epizooties (1999). Appendix XXIII on Bee Diseases. Addendum to the report of the Meeting of the OIE International Animal Health Code Commission. Paris, 18-22 January 1999.
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Yet to be developed.
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1. This paper considers the advantages and disadvantages of the Government subsidising the cost of varroa treatments in the North Island during the next two-years.
2. On 12 July 2000, the Cabinet, among other things, agreed in principle to a two year Government supported interim management programme for varroa mite. The programme objectives are to ensure the South Island remains varroa free for as long as possible, and that impacts in the North Island are mitigated.
3. The Cabinet directed MAF to finalise an operational plan in consultation with industry, and report back with a:
(i) recommended programme;
(ii) cost benefit analysis;
(iii) proposed implementation plan [CAB POL (00) M 17/1 refers].
4. There is general agreement within Government that the Crown will provide financial assistance to the North Island beekeeping industry for a period of two years while long-term varroa management solutions are developed. The level of assistance, and where it will be targeted, has yet to be finalised.
5. The cost per hive of treatment products is estimated at $25 per annum. The total treatment cost per hive, taking into account labour and travel costs, has been variously estimated at between $40 and $55 per annum. The National Beekeepers' Association (NBA) has indicated it favours beekeepers deciding when and how to treat, as well as applying treatments, during the interim two-year programme. The NBA has also indicated, however, that it favours the Government paying the full cost of treatment products during this period. This would represent a Government subsidy on total treatment costs of between 45 and 60 percent.
6. Effective long-term management of Varroa would involve a programme of integrated pest management, funded in a sustainable manner. The advantages and disadvantages of Government-subsidised treatments during the interim two-year programme should be assessed according to whether the subsidy would positively facilitate a transition to desired long-term arrangements.
7. The advantages of Government subsidising the cost of treatments are that it:
8. Varroa has impacts well beyond the beekeeping industry. It is reasonable to expect that the horticulture, pastoral and arable industries will contribute toward the cost of varroa management. The provision of a Government subsidy for a two-year period would provide breathing space for industries to negotiate and agree new market arrangements.
9. However, affected beekeepers already have relationships with the industries reliant on bees for crop pollination. A commercial market is particularly well developed for pollination services in the horticulture and arable sectors. It should be possible for beekeepers to re-define their relationships over the medium term to account for the additional costs of varroa management.
10. It is critical to long-term management of varroa in New Zealand that beekeepers understand and adopt the principles of integrated pest management. An important component of this will be the correct use of approved treatment products. The provision of Government-subsidised treatment products for a two-year period would provide incentives for beekeepers to use approved treatments in the prescribed manner. The subsidy would therefore have a positive extension benefit.
11. There are undoubted benefits to all affected industries if the spread of varroa throughout the North Island can be slowed. Beekeeping activity is the prime means through which varroa will spread, and it is important that affected beekeepers keep mite levels in their hives low.
12. The management of varroa will be most effective if approved products are used. The provision of Government-subsidised treatment products for a two-year period would maximise the uptake of approved treatments, and potentially delay the spread of varroa to areas not currently infested.
13. The disadvantages of Government subsidising the cost of treatments are it:
14. The provision of a Government subsidy for treatment products may create disincentives for industries to agree sustainable long-term funding arrangements. Industries may consider that in the absence of long-term arrangements, pressure could be placed on the Government to continue its subsidy indefinitely.
15. If the Government were to subsidise the cost of varroa treatment products, a number of equity issues would arise:
16. If the Government were to pay the cost of treatment products during the interim two-year programme, there would be considerable incentives for affected beekeepers to stockpile products for use in later years. A requirement that beekeepers pay the initial cost of treatments themselves, and apply for a rebate, would provide the Government with an opportunity to assess each claim for reasonableness. Measures against which to assess claims would be required. Options involve rebating only for sites in an infested area, or only upon the return of used strips. Both of these options are problematic, and stockpiling must be noted as a significant risk to a Government subsidy.
17. The fiscal cost of the Government paying the full cost of treatment products during the two-year interim programme is estimated at about $900,000. There would also be additional costs of administering the scheme. In terms of the total two-year support package, MAF considers that subsidised treatments are the lowest priority for Government expenditure. The Minister for Agriculture has indicated that he does not support the Government subsidising treatments, preferring instead to devote available resources to such things as surveillance, movement controls, extension, and South Island incursion response.
18. The Government has indicated it wishes to support varroa affected industries through a period of transition. A two-year support package is being proposed, targeted primarily at surveillance, movement controls, extension, and South Island incursion response.
19. Expenditure on each component of the package must be prioritised against other components. Although the provision of subsidised treatments would have some advantages, MAF considers that other components of the programme are a higher priority for available resources. There are also some disadvantages to a subsidy. In particular it would create a number of equity issues, and provide disincentives for industries to move toward long-term sustainable funding arrangements. The Minister for Agriculture agrees with MAF's analysis.
20. No Government subsidy will be provided for the cost of varroa treatments as part of the two year Government supported management programme.
To provide all registered beekeepers with an updateable resource to be used to increase understanding of:
The Technical Advisory Group identified a beekeeper extension service as a key component of a varroa management plan at the first meeting on 2 May 2000. In developing ideas for such a service, the AgriQuality draft Operational plan for control of varroa mooted the concept of a varroa control booklet to be distributed to all beekeepers prior to the 2000-01 beekeeping season. Although there has as yet been no specific financial appropriation for the project, MAF has decided that the urgency of the project dictates that preparation of the booklet should begin immediately.
The scope of the project involves:
a) Led by Contractor, under specific contract to MAF Biosecurity Authority.
b) Responsibility for development of specific sections may be delegated to sub-contractors, with agreement of MAF.
c) Terms of reference developed by MAF in consultation with identified potential contractors (HortResearch and AgriQuality) and National Beekeepers Association.
d) Tenders (project plan, timeframe, costs) developed by potential Contractors and submitted to MAF.
e) MAF and NBA evaluate tenders and agree on Contractor.
f) Contract developed and signed.
g) Regular (suggest weekly) progress reports.
h) Final sign-off of format and content by MAF in consultation with NBA.
i) Printing arranged by Contractor.
j) Distribution to all registered beekeepers arranged by Contractor.
a) Updateable to allow revisions and additions, either by distributing inserts or by printing revised editions.
b) Project a professional image for MAF, Contractor and NBA
c) Low cost
d) Information provided as text, diagrams, graphs and photos in colour format.
a) History of Varroa:
- A very brief history of Varroa, where it came from and how it spread around the world + when it came into NZ
b) Biology:
- Description of the biology of Varroa.
- How Varroa spreads between colonies
- How fast populations grow
- Role of populations in surrounding hives on population dynamics within a hive
- Acute and chronic phases
c) Effect on beehives:
- Effects on individual bees
- Effects on colonies
- Post-mite syndrome (viruses)
- Effect on production
- Effect on pollination
d) Diagnosis and evaluation of infestations
- ether roll
- sugar shake
- scratching drone brood
- screen boards
- Apistan as a surveillance tool
- How to make sticky boards
e) Control Methods
- Chemical controls
- synthetics
- plant-derived materials
- Biotechnical controls
- Breeding for resistance
- Resistance
- Residues
f) Integrated pest management
- Why integrated control
- Economic thresholds
- Monitoring
g) Co-ordinated Varroa control
- Why
- How to organise it
h) Examples of control programmes used by overseas beekeepers
i) Recommended control programmes for New Zealand beekeepers
j) Regulatory and legal issues related to treatment
k) Regulatory and legal issues relating to movements controls
l) Research
- setting priorities and managing research
- approval, monitoring and reporting research projects
- update on research projects underway and completed
l) A list of contacts and useful addresses
a) Terms of reference provided to potential contractors (by 31 August 2000)
b) Tenders received at MAF (by close of business Friday 8 September 2000)
Attention: Matthew Stonec) Decision on successful bid and agreement to proceed in lieu of contract (Monday 11 September 2000)
d) Contract developed based upon successful tender (asap following decision on successful bid).
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